WO2017024441A1 - 一种全双工传输的控制方法和用户设备以及基站 - Google Patents
一种全双工传输的控制方法和用户设备以及基站 Download PDFInfo
- Publication number
- WO2017024441A1 WO2017024441A1 PCT/CN2015/086363 CN2015086363W WO2017024441A1 WO 2017024441 A1 WO2017024441 A1 WO 2017024441A1 CN 2015086363 W CN2015086363 W CN 2015086363W WO 2017024441 A1 WO2017024441 A1 WO 2017024441A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- time resource
- resource unit
- user equipment
- uplink
- information
- Prior art date
Links
Images
Classifications
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0044—Arrangements for allocating sub-channels of the transmission path allocation of payload
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/04—TPC
- H04W52/06—TPC algorithms
- H04W52/14—Separate analysis of uplink or downlink
- H04W52/146—Uplink power control
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/0001—Systems modifying transmission characteristics according to link quality, e.g. power backoff
- H04L1/0002—Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the transmission rate
- H04L1/0003—Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the transmission rate by switching between different modulation schemes
- H04L1/0005—Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the transmission rate by switching between different modulation schemes applied to payload information
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/14—Two-way operation using the same type of signal, i.e. duplex
- H04L5/16—Half-duplex systems; Simplex/duplex switching; Transmission of break signals non-automatically inverting the direction of transmission
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/02—Power saving arrangements
- H04W52/0209—Power saving arrangements in terminal devices
- H04W52/0212—Power saving arrangements in terminal devices managed by the network, e.g. network or access point is master and terminal is slave
- H04W52/0216—Power saving arrangements in terminal devices managed by the network, e.g. network or access point is master and terminal is slave using a pre-established activity schedule, e.g. traffic indication frame
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/02—Power saving arrangements
- H04W52/0209—Power saving arrangements in terminal devices
- H04W52/0225—Power saving arrangements in terminal devices using monitoring of external events, e.g. the presence of a signal
- H04W52/0229—Power saving arrangements in terminal devices using monitoring of external events, e.g. the presence of a signal where the received signal is a wanted signal
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/04—TPC
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
- H04W72/21—Control channels or signalling for resource management in the uplink direction of a wireless link, i.e. towards the network
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
- H04W72/23—Control channels or signalling for resource management in the downlink direction of a wireless link, i.e. towards a terminal
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/14—Two-way operation using the same type of signal, i.e. duplex
- H04L5/1423—Two-way operation using the same type of signal, i.e. duplex for simultaneous baseband signals
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02D—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
- Y02D30/00—Reducing energy consumption in communication networks
- Y02D30/70—Reducing energy consumption in communication networks in wireless communication networks
Definitions
- the embodiments of the present invention relate to the field of communications, and in particular, to a method, a user equipment, and a base station for controlling full-duplex transmission.
- Half-duplex transmission can only transmit signals in one direction, while full-duplex transmission can transmit signals in both directions at the same time. Therefore, the signal transmission efficiency of full-duplex transmission is very high. From the perspective of physical layer, full-duplex transmission phase Compared with half-duplex transmission, the system throughput is doubled, and full-duplex transmission also has a revolutionary impact on the design of media access control (English name: Media Access Control, English abbreviation: MAC), thus making future wireless communication systems Can achieve higher throughput.
- media access control English name: Media Access Control, English abbreviation: MAC
- the main use is half-duplex transmission.
- the half-duplex transmission cannot simultaneously transmit and receive signals on the same time-frequency resource.
- the prior art describes a full-duplex transmission method used in a WiFi system, which can simultaneously transmit and receive signals on the same channel in a WiFi system. Since WiFi transmission can occupy the entire channel, no frequency is needed. Reuse, so the resource allocation is fixed.
- the user equipment (English name: User Equipment, English abbreviation: UE) is prepared to transmit signals with little time. Therefore, the WiFi system can transmit immediately after detecting or receiving some preambles. Signal to achieve full duplex transmission.
- the above solution of full-duplex transmission is only applicable to the WiFi system, and cannot be applied to the LTE system that requires frequency reuse, because the resource allocation needs to be dynamically determined in the LTE system, and the UE needs to perform rate matching according to the obtained transport block size.
- UEs in the LTE system need more time for resource configuration.
- the frequency division duplex English full name: Frequency Division Dual, English abbreviation: FDD
- the base station sends uplink scheduling information to the UE 4 ms in advance.
- the UE needs to advance in advance.
- the scheduling related information is obtained from the base station, for example, a channel state indication (English name: Channel State Information, CSI), a buffer size, and a scheduling resource, and the downlink scheduling information and the downlink data may be transmitted in the same subframe.
- This scheduling process in FDD mode can be applied to LTE systems for full-duplex transmission.
- n is a natural number
- the base station sends uplink scheduling information for The nth subframe transmits the uplink channel, and the base station also transmits downlink scheduling information in the nth subframe. In this way, the UE can simultaneously transmit and receive signals in the nth subframe.
- the base station when the base station transmits the uplink scheduling information on the (n-4)th subframe, it is still uncertain whether the same UE will exist simultaneously in the nth subframe. Downlink transmission, and full-duplex transmission and half-duplex transmission have different transmission power requirements for uplink transmission, so the base station is uncertain whether the uplink transmission of the n-th subframe in full-duplex transmission will face self-interference cancellation. problem.
- the power control of the uplink channel of the nth subframe cannot be correctly set, because inaccurate power control may cause strong self-interference, and such self-interference is difficult to cancel, so that downlink data is undetectable, so existing
- the full-duplex transmission implemented in the LTE system in the technology has a problem that the system gain is low.
- Embodiments of the present invention provide a control method, a user equipment, and a base station for full-duplex transmission, which are applicable to full-duplex transmission in an LTE system and a WiFi system, and can implement power control on an uplink channel in full-duplex transmission. , to increase the system gain of full-duplex transmission.
- an embodiment of the present invention provides a method for controlling full-duplex transmission, including:
- the user equipment acquires the first time resource unit
- the user equipment performs the first uplink transmission for the half duplex transmission according to the power offset acquired by the user equipment.
- the power is corrected to obtain a second uplink transmission power for the full duplex transmission;
- the user equipment transmits an uplink signal on the first time resource unit or the second time resource unit according to the second uplink transmission power, where the second time resource unit is in the first time resource unit in time. After the time resource unit.
- the acquiring, by the user equipment, the first time resource unit includes:
- the user equipment detects, on a third time resource unit that is ahead of the first time resource unit, whether there is uplink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, and in the foregoing Detecting, by a time resource unit or a fourth time resource unit of the first time resource unit, whether there is downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, where the third time is Resource unit and the fourth time resource list Bits are two different time resource units;
- the uplink scheduling information is detected on the third time resource unit, and the number of time resource units that are different between the first time resource unit and the third time resource unit meets a preset difference, If the downlink scheduling information is detected on the first time resource unit or the fourth time resource unit, determining that the first time resource unit includes scheduling authorization information indicating full duplex transmission;
- the uplink scheduling information is not detected on the third time resource unit, or the number of time resource units that are different between the first time resource unit and the third time resource unit does not satisfy the preset difference a value, or the downlink scheduling information is not detected on the first time resource unit or the fourth time resource unit, determining that the first time resource unit does not include scheduling authorization information indicating full duplex transmission .
- the acquiring, by the user equipment, the first time resource unit includes:
- the user equipment detects, on the first time resource unit, whether there is uplink feedback information corresponding to downlink data information transmission in advance of the fifth time resource unit of the first time resource unit, and at the first time
- the resource unit or the fourth time resource unit in advance of the first time resource unit detects whether there is downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, where the fourth time resource unit And the fifth time resource unit is two different time resource units;
- the uplink feedback information corresponding to the downlink data information transmission of the fifth time resource unit is detected on the first time resource unit, and the first time resource unit and the fifth time resource unit are different from each other If the number of time resource units meets the preset difference, and the downlink scheduling information is detected on the first time resource unit or the fourth time resource unit, determining that the first time resource unit is included Scheduling information indicating full duplex transmission;
- the uplink feedback information is not detected on the first time resource unit, or the number of time resource units that are different between the first time resource unit and the fifth time resource unit does not satisfy the preset difference
- the value, or the downlink scheduling information is not detected on the first time resource unit or the fourth time resource unit, determining that the first time resource unit does not include information of full duplex transmission.
- the third in the first aspect in combination with the first possible or second possible implementation of the first aspect, the third in the first aspect, the uplink scheduling information is uplink authorization information, and the downlink scheduling information is downlink authorization information.
- the user equipment is used according to the power offset obtained by the user equipment Before the first uplink transmission power of the half-duplex transmission is corrected, the method further includes:
- the user equipment acquires the power offset in a predefined manner, or obtains the power offset from the first time resource unit or the fourth time resource unit.
- the uplink signal is the The uplink scheduling information in the three-time resource unit indicates uplink data information that is transmitted on the first time resource unit or the second time resource unit;
- the uplink signal is the uplink feedback information of the first time resource unit corresponding to the downlink data information in the fifth time resource unit.
- the uplink scheduling information is detected on the third time resource unit, and the first The number of time resource units that differ between the time resource unit and the third time resource unit satisfies a preset difference, and the downlink is detected on the first time resource unit or the fourth time resource unit.
- the scheduling information after the user equipment detects the presence of the uplink scheduling information on the third time resource unit of the first time resource unit, the method further includes:
- the user equipment cancels the third time resource unit according to the power offset included in the downlink scheduling information. Uplink data information transmission performed on the first time resource unit or the second time resource unit indicated by the uplink scheduling information.
- the power offset is obtained by the user equipment in a predefined manner, or the power offset is obtained by the user equipment from the first Detecting, in the downlink scheduling information of the time resource unit, or the power offset is detected by the user equipment from the scheduling authorization information in each of the configured multiple time resource units It is determined that the plurality of time resource units of the configuration are a subset of all authorized time resource unit sets capable of detecting full duplex transmission;
- the method further includes:
- the user equipment If the power offset is obtained by the user equipment in a predefined manner, the user equipment passes scheduling authorization information from the first time resource unit or one time resource unit in advance of the first time resource unit. When the corresponding trigger signaling is detected, the power offset is triggered to take effect.
- the power offset is obtained by the user equipment in a predefined manner, including:
- the user equipment receives broadcast signaling or proprietary signaling sent by the base station;
- the user equipment acquires the power offset by using the broadcast signaling or the dedicated signaling.
- the power offset is detected by the user equipment from scheduling authorization information of a first time resource unit
- the power offset is detected by the user equipment from the scheduling authorization information in each of the configured multiple time resource units, including:
- the user equipment detects the power offset from information newly added in the scheduling grant information
- the user equipment detects the power offset from the original information redefined in the scheduling grant information.
- the user equipment acquiring the first time resource unit includes:
- the user equipment detects, on the first time resource unit, whether there is uplink scheduling information and downlink scheduling information, and if the uplink scheduling information and the downlink scheduling information are simultaneously detected on the first time resource unit, Determining, in the first time resource unit, scheduling authorization information indicating full duplex transmission; if at least one of the uplink scheduling information and the downlink scheduling information is detected in the first time resource unit, Then, it is determined that the scheduling authorization information indicating the full duplex transmission is not included in the first time resource unit.
- the user equipment according to the power offset acquired by the user equipment, corrects a first uplink transmission power used for half-duplex transmission Obtaining a second uplink transmission power for the full duplex transmission, including:
- the user equipment calculates a second uplink transmission power for the full duplex transmission by:
- the P FD is the second uplink transmission power
- the P HD is the first uplink transmission power
- P offset is a power offset acquired by the user equipment.
- the user equipment according to the power offset acquired by the user equipment, corrects a first uplink transmission power for half duplex transmission Thereafter, the method further includes:
- the user equipment acquires a modulation and coding strategy MCS offset that matches the power offset
- the user equipment corrects the first MCS for half-duplex transmission according to the MCS offset to obtain a second MCS for the full-duplex transmission.
- the user equipment acquires a modulation and coding policy MCS offset that matches the power offset, include:
- the user equipment acquires the MCS offset by a mutual matching relationship between a predefined power offset and an MCS offset.
- the user equipment is used for a first MCS for half duplex transmission
- the index is modified to obtain a second MCS index for the full duplex transmission, including:
- the user equipment calculates a second MCS index for the full duplex transmission by:
- MCS FD MCS HD -MCS offset
- the MCS FD is the second MCS index
- the MCS HD is the first MCS index
- the MCS offset is the MCS offset.
- the time resource unit includes: a subframe, a frame, a time slot, and an orthogonal frequency division multiplexing OFDM symbol.
- an embodiment of the present invention provides a method for controlling full-duplex transmission, including:
- the base station transmitting scheduling authorization information indicating that the user equipment performs full-duplex transmission to the user equipment in the first time resource unit;
- the base station Receiving, by the base station, the second uplink transmission power obtained by modifying the first uplink transmission power for half-duplex transmission after the user equipment obtains the scheduling authorization information to indicate full-duplex transmission, in the first An uplink signal transmitted on a time resource unit or a second time resource unit, where the second time resource unit is a time resource unit that is temporally after the first time resource unit.
- the base station determines whether the user equipment can be in the first time resource unit to perform full duplex transmission, including:
- the base station transmits uplink scheduling information indicating that the first time resource unit or the second time resource unit is transmitted on a third time resource unit that is ahead of the first time resource unit, and the base station is Transmitting, by the first time resource unit or the fourth time resource unit of the first time resource unit, downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, where Determining, by the base station, that the user equipment may be in full-duplex transmission in the first time resource unit, where the third time resource unit and the fourth time resource unit are two different time resource units;
- the base station does not transmit the uplink scheduling information on the third time resource unit, or the base station determines the number of time resource units that are different between the first time resource unit and the third time resource unit If the preset difference is not met, or the base station does not detect the downlink scheduling information on the first time resource unit or the fourth time resource unit, the base station determines that the resource may not be in the first time.
- the unit indicates that the user equipment performs full duplex transmission.
- the base station determines whether the user equipment can be in the first time resource unit to perform full duplex transmission, including:
- the base station transmits, on the first time resource unit, uplink feedback information corresponding to downlink data information transmission of a fifth time resource unit that is advanced in the first time resource unit, and the base station is in the first And transmitting, by the time resource unit or the fourth time resource unit of the first time resource unit, downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, where the base station determines that the The user equipment is instructed to perform full-duplex transmission in a time resource unit, where the fourth time resource unit and the fifth time resource unit are two different time resource units;
- the base station does not transmit the uplink feedback information on the first time resource unit, or the base station determines the number of time resource units that are different between the first time resource unit and the fifth time resource unit If the preset difference is not met, or the base station does not detect the downlink scheduling information on the first time resource unit or the fourth time resource unit, the base station determines that the resource unit can be in the first time. Indicates that the user equipment is performing full duplex transmission.
- the downlink scheduling information includes: a pre-configured special defined offset value by the user The device cancels the uplink data information transmission performed on the first time resource unit or the second time resource unit indicated by the uplink scheduling information on the third time resource unit according to the power offset included in the downlink scheduling information.
- the method before the determining, by the base station, that the user equipment can perform the full-duplex transmission in the first time resource unit, the method further includes:
- the base station sends broadcast signaling or proprietary signaling to the user equipment, where the broadcast signaling or the proprietary signaling includes: a power offset and/or an MCS offset configured by the base station.
- the method before the determining, by the base station, that the user equipment can perform the full duplex transmission in the first time resource unit, the method further includes:
- the base station adds information to the scheduling grant information of the first time resource unit to carry the power offset and/or the MCS offset, or the base station redefines the scheduling authorization information of the first time resource unit.
- the original information carries the power offset and/or the MCS offset, or the base station adds new information to the scheduling grant information in each of the configured multiple time resource units to carry the a power offset and/or an MCS offset, or the base station carries a power offset and/or in the original information redefined in the scheduling grant information in each of the configured plurality of time resource units MCS offset.
- the time resource unit includes: a subframe, a frame, a time slot, and an orthogonal frequency division multiplexing OFDM symbol.
- an embodiment of the present invention provides a user equipment, including:
- a correction module configured to, when obtained from the first time resource unit, includes a full duplex transmission When scheduling the authorization information, correcting the first uplink transmission power for the half-duplex transmission according to the power offset acquired by the user equipment, to obtain the second uplink transmission power for the full-duplex transmission;
- An uplink control module configured to transmit an uplink signal on the first time resource unit or the second time resource unit according to the second uplink transmission power, where the second time resource unit is after the first time resource unit Time resource unit.
- the acquiring module is configured to detect whether an indication exists in a third time resource unit that is advanced in the first time resource unit Uplink scheduling information for transmission on a time resource unit or a second time resource unit, and detecting whether there is an indication in the first time resource unit or a fourth time resource unit in advance of the first time resource unit Downlink scheduling information for transmission on a time resource unit or a second time resource unit, where the third time resource unit and the fourth time resource unit are two different time resource units; if the third time resource is The uplink scheduling information is detected on the unit, and the number of time resource units that are different between the first time resource unit and the third time resource unit meets a preset difference, and the first time resource is If the downlink scheduling information is detected on the unit or the fourth time resource unit, determining that the first time resource unit includes the indication full double The scheduling authorization information of the transmission; if the uplink scheduling information is not detected on the third time resource unit, or the number of time resource units between the first time
- the acquiring module is configured to detect, on the first time resource unit, whether there is a resource element corresponding to the first time resource Uplink feedback information of downlink data information transmission of the fifth time resource unit, and detecting whether there is an indication at the first time resource unit or a fourth time resource unit of the first time resource unit
- the downlink scheduling information that is transmitted on the resource unit or the second time resource unit, where the fourth time resource unit and the fifth time resource unit are two different time resource units; if the first time resource unit is Detecting uplink feedback information corresponding to the downlink data information transmission of the fifth time resource unit, and the number of time resource units that are different between the first time resource unit and the fifth time resource unit meets a preset a difference, and detecting the downlink scheduling information on the first time resource unit or the fourth time resource unit, determining The first The one-time resource unit includes scheduling information indicating full-duplex transmission; if the uplink feedback information is not detected on the first time resource unit, or the first
- the uplink scheduling information is uplink authorization information
- the downlink scheduling information is downlink authorization information
- the acquiring module is further configured to obtain, according to the user equipment Obtaining the first for the half-duplex transmission from the uplink scheduling information in the third time resource unit before the power offset to the first uplink transmission power for the half-duplex transmission is corrected An uplink transmission power, or obtaining the first uplink transmission power for the half-duplex transmission from the fifth time resource unit; acquiring the power offset by a predefined manner, or from the The power offset is obtained in a time resource unit or in the fourth time resource unit.
- the uplink signal is the foregoing
- the uplink scheduling information in the three-time resource unit indicates the uplink data information that is transmitted on the first time resource unit or the second time resource unit; or the uplink signal is the downlink data in the fifth time resource unit.
- the uplink feedback information of the first time resource unit corresponding to the information.
- the uplink scheduling information is detected on the third time resource unit, and the first The number of time resource units that differ between the time resource unit and the third time resource unit satisfies a preset difference, and the downlink is detected on the first time resource unit or the fourth time resource unit
- the scheduling information, the uplink control module is further configured to: after the acquiring module detects, according to the third time resource unit of the first time resource unit, whether there is uplink scheduling information, if the downlink scheduling information is included
- the power offset is a preset special-defined offset value, and the first time resource unit indicated by the uplink scheduling information in the third time resource unit is cancelled according to the power offset included in the downlink scheduling information. Or uplink data information transmission on the second time resource unit.
- the acquiring module is further configured to obtain, by using a predefined manner, the power offset, or downlink scheduling information from a first time resource unit. Detecting the power offset, or detecting the power offset from the scheduling grant information in each of the configured plurality of time resource units, where the configured multiple time resource units are all A subset of the set of authorized time resource units capable of detecting full duplex transmission;
- the correction module is further configured to: before the first uplink transmission power for half-duplex transmission is corrected according to the power offset acquired by the user equipment, if the power offset is predefined by the user equipment The method obtains that the power offset is triggered when the corresponding trigger signaling is detected from the first time resource unit or the scheduling authorization information of a time resource unit of the first time resource unit.
- the acquiring module is specifically configured to receive broadcast signaling or proprietary signaling sent by the base station;
- the power offset is obtained by the broadcast signaling or the proprietary signaling.
- the acquiring module is specifically configured to detect the information that is newly added from the scheduling authorization information.
- the power offset is; or the power offset is detected from the original information redefined in the scheduling grant information.
- the acquiring module is configured to detect, by using the first time resource unit, whether uplink scheduling information and downlink scheduling information are present, if Determining, in the first time resource unit, the uplink scheduling information and the downlink scheduling information, determining that the first time resource unit includes scheduling authorization information indicating full duplex transmission;
- the resource unit detects at least one of the uplink scheduling information and the downlink scheduling information, and determines that the first time resource unit does not include scheduling authorization information indicating full duplex transmission.
- the modifying module is specifically configured to calculate a second uplink transmission power for the full duplex transmission by:
- the P FD is the second uplink transmission power
- the P HD is the first uplink transmission power
- P offset is a power offset acquired by the user equipment.
- the obtaining module is further configured to: after the correction module corrects the first uplink transmission power for the half-duplex transmission according to the power offset acquired by the user equipment, acquire the modulation that matches the power offset Offset with the coding strategy MCS;
- the correction module is further configured to correct a first MCS index for half-duplex transmission according to the MCS offset, to obtain a second MCS index for the full-duplex transmission.
- the acquiring module is specifically configured to receive, by using broadcast signaling or dedicated signaling, MCS offset; or, the MCS offset is obtained by a mutual matching relationship between a predefined power offset and an MCS offset.
- the modifying module is specifically configured to calculate, by using the following manner, the full duplex transmission Second MCS index:
- MCS FD MCS HD -MCS offset
- the MCS FD is the second MCS index
- the MCS HD is the first MCS index
- the MCS offset is the MCS offset.
- the time resource unit includes: a subframe, a frame, a time slot, and an orthogonal frequency division multiplexing OFDM symbol.
- an embodiment of the present invention provides a base station, including:
- a full-duplex determining module configured to determine whether the user equipment can be in full-duplex transmission in the first time resource unit, and obtain a determination result
- a sending module configured to: when the determining result is that the user equipment may perform full-duplex transmission in the first time resource unit, sending, by the first time resource unit, the indication device to the user equipment Decoding authorization information of the user equipment for full duplex transmission;
- a receiving module configured to receive, by the user equipment, a second uplink transmission power obtained by correcting a first uplink transmission power for half-duplex transmission after obtaining the scheduling authorization information indicating full-duplex transmission
- the full duplex determining module is specifically configured to: if the base station is in a third time resource list in advance of the first time resource unit Transmitting uplink scheduling information indicating transmission on the first time resource unit or the second time resource unit, and the base station is in the first time resource unit or in advance of the first time resource unit And transmitting, by the fourth time resource unit, the downlink scheduling information that is transmitted on the first time resource unit or the second time resource unit, determining that the user equipment may be in the first time resource unit to perform full duplex transmission, where The third time resource unit and the fourth time resource unit are two different time resource units; if the base station does not transmit the uplink scheduling information on the third time resource unit, or the base station determines the The number of time resource units that differ between the first time resource unit and the third time resource unit does not satisfy a preset difference, or the base station is in the first time resource unit or the fourth time resource unit If the downlink scheduling information is not detected, it is determined that the
- the full duplex determining module is specifically configured to: if the base station transmits on the first time resource unit, corresponding to the foregoing The uplink feedback information of the downlink data information transmission of the fifth time resource unit of the first time resource unit, and the base station is in the first time resource unit or the fourth time resource unit in advance of the first time resource unit Transmitting the downlink scheduling information that is transmitted on the first time resource unit or the second time resource unit, determining that the user equipment may be instructed to perform full duplex transmission in the first time resource unit, where the fourth time resource unit and the The fifth time resource unit is two different time resource units; if the base station does not transmit the uplink feedback information on the first time resource unit, or the base station determines the first time resource unit and The number of time resource units of the difference between the fifth time resource units does not satisfy the preset difference, or the base station is in the first time resource unit Does not detect the downlink scheduling information on the fourth time resource unit, it is determined that the user
- the downlink scheduling information includes: a pre-configured special defined offset value by the user The device cancels the uplink data information transmission performed on the first time resource unit or the second time resource unit indicated by the uplink scheduling information on the third time resource unit according to the power offset included in the downlink scheduling information.
- the base station further includes: a sending module, configured, by the full duplex determining module, to determine whether the user equipment can be indicated in the first time resource unit Sending broadcast signaling or proprietary signaling to the user equipment before performing full duplex transmission,
- the broadcast signaling or the proprietary signaling includes: a power offset and/or an MCS offset configured by the base station.
- the base station further includes: a configuration module, configured, by the full duplex determining module, to determine whether the user equipment can be indicated in the first time resource unit Before performing full-duplex transmission, newly added information is used to carry the power offset and/or MCS offset in the scheduling grant information of the first time resource unit, or the scheduling authorization of the base station in the first time resource unit
- the original information redefined in the information carries a power offset and/or an MCS offset, or the base station adds new information to the scheduling grant information in each time resource unit of the configured multiple time resource units.
- Carrying the power offset and/or the MCS offset, or the base station carries the power offset in the original information redefined in the scheduling grant information in each of the configured multiple time resource units. Shift and / or MCS offset.
- the time resource unit includes: a subframe, a frame, a time slot, and an orthogonal frequency division multiplexing OFDM symbol.
- the user equipment first acquires the first time resource unit, and if the scheduling authorization information indicating the full duplex transmission is obtained from the first time resource unit, the user equipment subsequently obtains the power offset according to the user equipment. Correcting the first uplink transmission power for the half-duplex transmission, obtaining the second uplink transmission power for the full-duplex transmission, and the user equipment finally according to the second uplink transmission power in the first time resource unit or the second time resource.
- the uplink signal is transmitted on the unit, and the second time resource unit is a time resource unit that is in time after the first time resource unit.
- the user equipment may determine the second uplink transmission power according to the obtained power offset.
- the power control of the uplink channel may be performed according to the user equipment determining that the first uplink transmission power is corrected when performing full-duplex transmission.
- the second uplink transmission power is correctly set, so accurate power control can be implemented, thereby avoiding self-interference, so that downlink data can be normally detected, and system gain of full-duplex transmission in the wireless communication system is improved, and the full-length provided by the present invention
- the control method of the transmission can be used for the LTE system and the WiFi system.
- FIG. 1 is a schematic block diagram of a method for controlling full-duplex transmission according to an embodiment of the present invention
- FIG. 2 is a schematic block diagram showing another method for controlling full-duplex transmission according to an embodiment of the present invention. intention;
- FIG. 3 is a schematic diagram of power control of a PUSCH according to an embodiment of the present disclosure
- FIG. 3 is a schematic diagram of power control of another PUCCH according to an embodiment of the present disclosure.
- FIG. 4 is a schematic structural diagram of a user equipment according to an embodiment of the present disclosure.
- FIG. 5-a is a schematic structural diagram of a base station according to an embodiment of the present disclosure.
- FIG. 5-b is a schematic structural diagram of another base station according to an embodiment of the present disclosure.
- FIG. 6 is a schematic structural diagram of another user equipment according to an embodiment of the present disclosure.
- FIG. 7 is a schematic structural diagram of another base station according to an embodiment of the present invention.
- Embodiments of the present invention provide a control method, a user equipment, and a base station for full-duplex transmission, which are applicable to full-duplex transmission in an LTE system and a WiFi system, and can implement power control on an uplink channel in full-duplex transmission. , to increase the system gain of full-duplex transmission.
- control method for the full-duplex transmission of the present invention can be applied to the uplink power control scenario in the full-duplex transmission on the user equipment side.
- the full-duplex provided by one embodiment of the present invention is provided.
- the control method of the transmission may include:
- the user equipment acquires a first time resource unit.
- the user equipment taking the full-duplex transmission control of the first time resource unit by the user equipment as an example, the user equipment first acquires the first time resource unit, and detects the first time resource unit, and detects whether it can be from the first.
- the time resource unit obtains the scheduling authorization information indicating the full-duplex transmission.
- the user equipment can detect the time resource unit header in the first time resource unit, and the resource unit in the first time resource unit A specific field information or indicator bit in the time resource unit header determines whether to include scheduling authorization information indicating full duplex transmission, and if the user equipment can detect other time resource units other than the first time resource unit, and through other time resource unit pairs.
- Determining information of the first time resource unit to determine whether the first time resource unit includes scheduling authorization information indicating full duplex transmission, and if the user equipment can detect signaling sent by the base station, the user equipment determines by using signaling sent by the base station. Whether the first time resource unit includes a full duplex transmission Of authorization information, and if the user device may also be determined whether a first resource unit comprises time scheduling full-duplex transmission authorization information indicating through predefined configuration information. For a first time resource unit including scheduling grant information indicating full duplex transmission, the user equipment may perform full duplex transmission on the first time resource unit, for the first part that does not include scheduling grant information indicating full duplex transmission.
- the time resource unit the user equipment can perform half-duplex transmission on the first time resource unit, and no full-duplex transmission is performed. After detecting the first time resource unit including the scheduling grant information indicating the full duplex transmission, the user equipment performs the subsequent step 102.
- the time resource unit acquired by the user equipment in step 101 is a first time resource unit, where the time resource unit may specifically include: a subframe, a frame, a time slot, and an orthogonal frequency division multiplexing. (English full name: Orthogonal Frequency Division Multiplexing, English abbreviation: OFDM) symbol. That is, a time resource unit described in some embodiments of the present invention may be specifically one subframe.
- the first time resource unit described in the following embodiments is specifically a first subframe
- the second time resource unit is specifically The second time resource unit may be the third subframe
- the fourth time resource unit is specifically the fourth subframe
- the fifth time resource unit may be the fifth subframe.
- a time resource unit described in other embodiments of the present invention may specifically be one frame (ie, a radio frame).
- the first time resource unit described in the following embodiments is specifically the first frame, and the second time resource unit.
- the second frame, the third time resource unit may be the third frame, the fourth time resource unit is specifically the fourth frame, and the fifth time resource unit may be the fifth frame.
- one time resource unit may be one time slot, or one time resource unit may be one OFDM symbol. It should be noted that the time resource unit can be selected according to the needs of the application scenario.
- the relationship between a subframe, a frame, a time slot, and an OFDM symbol is in an achievable manner, and is one of the framing, the frame, the time slot, and the OFDM symbol.
- the user equipment of step 101 acquires the first time resource unit, which may specifically include the following steps:
- A1 The user equipment detects, on a third time resource unit that is ahead of the first time resource unit, whether there is uplink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, and the resource unit in the first time resource unit Or detecting, in advance of the fourth time resource unit of the first time resource unit, whether there is downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, and the third time resource unit and the fourth time resource unit Are two different time resource units;
- the uplink scheduling information is detected on the resource unit in the third time, the number of time resource units that are different between the first time resource unit and the third time resource unit meets the preset difference, and the resource is in the first time. If the downlink scheduling information is detected on the unit or the fourth time resource unit, determining that the first time resource unit includes scheduling authorization information indicating full duplex transmission;
- the uplink scheduling information is not detected on the resource unit in the third time, or the number of time resource units that differ between the first time resource unit and the third time resource unit does not satisfy the preset difference, or is in the first If the downlink scheduling information is not detected on the time resource unit or the fourth time resource unit, it is determined that the scheduling authorization information indicating the full duplex transmission is not included in the first time resource unit.
- the third time resource unit is a time resource unit that is ahead of the first time resource unit
- the fourth time resource unit is a time resource unit that is earlier than the first time resource unit
- the The third time resource unit and the fourth time resource unit are two different time resource units
- the user equipment detects, on the third time resource unit before the first time resource unit, whether there is uplink scheduling information in the third time resource unit, and the uplink
- the scheduling information is used to indicate that the uplink data information is transmitted on the first time resource unit or the second time resource unit.
- the user equipment detects the time resource unit header of the third time resource unit to obtain whether the uplink scheduling information exists, because the uplink scheduling is Before the signal transmission, a certain preparation time is required.
- the base station needs to send the uplink scheduling information in a time resource unit before the first time resource unit, in the embodiment of the present invention.
- the user device detects the resource at the first time Each time resource unit before the unit, for example, the user equipment can detect before the first time resource unit
- the third time resource unit the user equipment determines whether the uplink scheduling information exists in the third time resource unit, and if the user equipment detects the uplink scheduling information sent by the base station in the third time resource unit, the user equipment may be in the third time resource.
- the uplink scheduling transmission is performed on the resource unit at a certain time after the unit.
- the fourth time resource unit is a time resource unit that is ahead of the first time resource unit, and the fourth time resource unit and the third time resource unit are both before the first time resource unit, but the fourth time resource unit and the third time
- the time resource unit is two different time resource units, and the user equipment detects, on the first time resource unit or the fourth time resource unit, whether there is downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit. That is, when the user equipment can determine whether the first time resource unit includes the scheduling authorization information indicating the full duplex transmission, the detection of the downlink scheduling information by the user equipment may be the current time resource unit (ie, the first time resource unit).
- the downlink scheduling information is used to indicate that the downlink data information is transmitted on the first time resource unit or the second time resource unit, for example, the user equipment detects the time resource unit header of the fourth time resource unit to obtain whether downlink scheduling information exists, and if the user The device detects the downlink scheduling information sent by the base station in the fourth time resource unit, and indicates that the user equipment can perform downlink scheduling transmission on a certain time resource unit after the fourth time resource unit.
- the first time resource unit includes scheduling authorization information indicating full duplex transmission
- the three conditions are: 1) at the third time The uplink scheduling information is detected on the resource unit, and 2) the number of time resource units that differ between the first time resource unit and the third time resource unit is a preset difference, for example, the difference is 4 time resource units, and That is to say, if the first time resource unit is the nth time resource unit, n is a natural number, and if the uplink scheduling information is detected on the n-4th time resource unit, the third time resource unit is the n-4th.
- the time resource unit, the number of time resource units that differ between the first time resource unit and the third time resource unit is 4. 3
- the downlink scheduling information is detected on the first time resource unit or the fourth time resource unit.
- the user equipment may determine that the nth time resource unit includes scheduling grant information indicating full duplex transmission. If the above condition 1), condition 2), and condition 3) cannot be satisfied at the same time, it indicates that the scheduling authorization information indicating the full duplex transmission is not included in the first time resource unit.
- the uplink scheduling information is not detected on the third time resource unit, or the uplink scheduling information is detected even in the third time resource unit, but the first time The number of time resource units that differ between the resource unit and the third time resource unit does not satisfy the preset difference, or the downlink scheduling information is not detected in the first time resource unit or the fourth time resource unit, in the above case It is stated that the scheduling authorization information indicating the full duplex transmission is not included in the first time resource unit.
- step A2 After the user equipment detects, on the third time resource unit of the first time resource unit, whether there is uplink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, the embodiment of the present invention provides
- the control method of full-duplex transmission may further include the following steps:
- the user equipment cancels the indication of the uplink scheduling information in the third time resource unit according to the power offset included in the downlink scheduling information.
- the uplink data information transmission on the first time resource unit or the second time resource unit.
- the downlink scheduling information is information transmitted in the first time resource unit or the fourth time resource unit, and if the base station in the third time resource unit, the uplink scheduling information indicates the first time resource unit or the second.
- the uplink data information transmission of the time resource unit when the base station needs to cancel the transmission of the uplink data information, the value of the power offset included in the downlink scheduling information by the base station is a preset special defined offset value, so that the user After detecting the offset value of the special meaning, the device cancels the uplink data transmission indicated by the uplink scheduling information in the third time resource unit.
- the user equipment After the user equipment detects the power offset from the first time resource unit or the fourth time resource unit, the user equipment finds that the power offset is a preset special defined offset value, and the user equipment cancels the first time.
- the uplink data information transmission in the resource unit or the second time resource unit For example, when the user equipment can take a value of the power offset as a specially defined power offset value, the specially defined power offset value is used to prevent uplink transmission in the same time resource unit from the downlink transmission.
- the user equipment of step 101 acquires the first time resource unit, which may specifically include the following steps:
- the user equipment detects, on the first time resource unit, whether it corresponds to the first time.
- the uplink feedback information corresponding to the downlink data information transmission of the fifth time resource unit is detected on the first time resource unit, and the time resource unit number between the first time resource unit and the fifth time resource unit is different If the preset difference is met, and the downlink scheduling information is detected on the first time resource unit or the fourth time resource unit, determining that the first time resource unit includes scheduling information indicating full duplex transmission, and the fourth time resource unit And the fifth time resource unit is two different time resource units;
- the uplink feedback information is not detected on the resource unit in the first time, or the time resource unit between the first time resource unit and the fifth time resource unit does not satisfy the preset difference, or is in the first If the downlink scheduling information is not detected on the time resource unit or the fourth time resource unit, it is determined that the information of the full duplex transmission is not included in the first time resource unit.
- the fifth time resource unit is a time resource unit that is earlier than the first time resource unit, and the user equipment detects, on the first time resource unit, whether there is uplink feedback information, and the uplink feedback information It is feedback information corresponding to the downlink data information transmitted on the resource unit in the fifth time.
- the user equipment detects the time resource unit header of the first time resource unit to obtain whether there is uplink feedback information, and the uplink feedback information may be acknowledge information.
- the user equipment detects the first time resource unit, and the user equipment determines whether there is uplink feedback information in the first time resource unit. If the user equipment detects the uplink feedback information in the first time resource unit, the user indicates that the user The device can perform uplink scheduling transmission on the first time resource unit.
- the fourth time resource unit is a time resource unit that is ahead of the first time resource unit, and the fourth time resource unit and the fifth time resource unit are both before the first time resource unit, but the fourth time resource unit and the fifth time
- the time resource unit is two different time resource units, and the user equipment detects, on the first time resource unit or the fourth time resource unit, whether there is downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit.
- the user equipment can determine whether the first time resource unit includes scheduling authorization information indicating full duplex transmission, and the user equipment
- the detection of the downlink scheduling information may be a resource unit in the current time (ie, the first time resource unit), or a time resource unit (for example, a fourth time resource unit) before the current resource unit.
- the downlink scheduling information is used to indicate that the downlink data information is transmitted on the first time resource unit or the second time resource unit, for example, the user equipment detects the time resource unit header of the fourth time resource unit to obtain whether downlink scheduling information exists, and if the user The device detects the downlink scheduling information sent by the base station in the fourth time resource unit, and indicates that the user equipment can perform downlink scheduling transmission on a certain time resource unit after the fourth time resource unit.
- the first time resource unit includes scheduling authorization information indicating full duplex transmission
- the three conditions are: 1) at the first time The uplink feedback information is detected on the resource unit, and 2) the number of time resource units that differ between the first time resource unit and the fifth time resource unit is a preset difference, for example, the difference is two time resource units, and That is, if the first time resource unit is the nth time resource unit, n is a natural number, and if the downlink data information is detected on the n-2th time resource unit, the corresponding corresponding to the nth time resource unit is detected.
- the uplink feedback information of the downlink data information where the resource unit in the fifth time is the n-2th time resource unit, and the number of time resource units in the difference between the first time resource unit and the fifth time resource unit is 2.
- the downlink scheduling information is detected on the first time resource unit or the fourth time resource unit. While satisfying the above three conditions at the same time, the user equipment may determine that the nth time resource unit includes scheduling grant information indicating full duplex transmission. If the above condition 1), condition 2), and condition 3) cannot be satisfied at the same time, it indicates that the scheduling authorization information indicating the full duplex transmission is not included in the first time resource unit.
- the uplink feedback information is not detected on the first time resource unit, or the number of time resource units that are different between the first time resource unit and the fifth time resource unit does not satisfy the preset difference, or is in the first time.
- the downlink scheduling information is not detected on the resource unit or the fourth time resource unit.
- the scheduling authorization information indicating the full duplex transmission is not included in the first time resource unit.
- the user equipment of step 101 acquires the first time resource unit, which may specifically include the following steps:
- the user equipment detects, on the first time resource unit, whether uplink scheduling information and downlink scheduling information exist;
- the uplink scheduling information and the downlink scheduling information are simultaneously detected on the first time resource unit, determining that the scheduling resource information indicating the full duplex transmission is included in the first time resource unit;
- the first time resource unit determines that the first time resource unit does not include scheduling authorization information indicating full duplex transmission.
- the user equipment only needs to detect the first time resource unit. Specifically, the user equipment needs to detect whether the uplink scheduling information and the downlink scheduling information are included in the first time resource unit.
- full-duplex transmission can simultaneously schedule uplink and downlink transmission resources and simultaneously transmit and receive signals.
- PDCCH Physical Downlink Control Channel
- the full-duplex transmission is realized by allocating the uplink and downlink resources simultaneously transmitted to the user equipment. In this manner, whether the first time resource unit can be used for full-duplex transmission can be detected by a single scheduling authorization information.
- the user equipment Determining, by the detection of the first time resource unit itself, whether the first time resource unit includes the scheduling authorization information, for example, the user equipment detects whether the uplink and downlink scheduling information is included in the first time resource unit, and if the resource unit is in the first time If the uplink scheduling information and the downlink scheduling information are detected at the same time, the user equipment may determine that the first time resource unit can be used for full-duplex transmission, and if only the uplink scheduling information and the downlink scheduling information are detected in the first time resource unit, If the user equipment determines that the first time resource unit is not available for full-duplex transmission, that is, the scheduling authorization information for indicating full-duplex transmission is not included in the first time resource unit.
- the uplink scheduling information may be the uplink authorization information
- the downlink scheduling information may be the downlink authorization information, where the uplink authorization information and the downlink authorization information may be.
- the uplink grant information includes the time at which the user equipment can transmit data on the carrier (eg, a physical resource block), and the adopted MCS, which is one of the contents of the PDCCH.
- the downlink authorization information is that the base station dynamically allocates resources to the user equipment, including the physical resource block and the adopted MCS, in each transmission time interval (English name: Transmission Time Interval, TTI) (ie, a time resource unit), which is One of the contents of the PDCCH.
- TTI Transmission Time Interval
- the uplink scheduling information and the downlink scheduling information may also be configured with other control information, as long as the user equipment side can detect the uplink scheduling information and the indication content carried in the downlink scheduling information.
- the user equipment corrects the first uplink transmission power used for the half duplex transmission according to the power offset acquired by the user equipment, A second uplink transmission power for full duplex transmission is obtained.
- the user equipment determines that the first time resource unit can be used for full-duplex transmission, and the resource unit needs to perform full-duplex transmission in the first time.
- the transmission power of the uplink transmission in the full-duplex transmission can be obtained by correcting the power offset obtained by the user equipment for the first uplink transmission power used for the half-duplex transmission. Specifically, the user equipment can use the predefined power offset. Transmitting the first uplink transmission power for half-duplex transmission to obtain a second uplink transmission power for full-duplex transmission, or the user equipment may use the first time resource unit or other time resource units configured in advance A power offset was detected in .
- the power offset acquired by the user equipment is a power offset predefined by the user equipment or a power offset obtained by the user equipment by using scheduling authorization information sent by the base station, and the power offset is performed under full-duplex transmission.
- the first uplink transmission power for half-duplex transmission is modified with an offset power value.
- the first uplink transmission power is the uplink transmission power used by the user equipment when the downlink transmission is not performed, that is, the first uplink transmission power is obtained by the user equipment for the half-double The uplink transmission power of the transmission.
- step 102 is performed by the user equipment according to the power offset acquired by the user equipment for half-duplex transmission.
- the method for controlling full-duplex transmission provided by the embodiment of the present invention may further include the following steps:
- the user equipment acquires the first uplink transmission power for the half-duplex transmission from the uplink scheduling information in the third time resource unit, or the user equipment acquires the half-duplex transmission from the fifth time resource unit.
- First uplink transmission power
- the user equipment acquires a power offset in a predefined manner, or obtains a power offset from the first time resource unit or the fourth time resource unit.
- the method for obtaining the first uplink transmission power by the user equipment is described in the step D1, and the user equipment may obtain the first uplink transmission power from a time resource unit that is advanced in the first time resource unit, for example, from the foregoing third time. Obtained in the resource unit or the fifth time resource unit.
- the user equipment needs to use the power offset when calculating the second uplink transmission power.
- step D2 the manner in which the user equipment obtains the power offset is described, and the user equipment may obtain the method in a predefined manner, and the base station may also The power offset is sent in the first time resource unit or the fourth time resource unit, and the user equipment may also obtain the power offset from the first time resource unit or the fourth time resource unit.
- the power offset is obtained by the user equipment in a predefined manner, or the power offset is detected by the user equipment from the downlink scheduling information of the first time resource unit, or the power offset is determined by the user equipment.
- the plurality of time resource units configured are all subsets of the set of authorized time resource units capable of detecting full duplex transmission, from the scheduling authorization information in each of the configured time resource units.
- the configured multiple time resource units may be a set of multiple time resource units specified by the base station, and the configured multiple time resource units are a subset of all authorized time resource unit sets capable of detecting full duplex transmission.
- the configured multiple time resource units may be a set of time resource units, which is a subset of the set of authorized time resource units capable of detecting full duplex transmission, and the base station does not need resources at each time.
- the unit carries the power offset, which increases the system overhead.
- the base station pre-configures the power offset on each time resource unit in the time resource unit set.
- the user equipment only needs to configure the time resource unit from the base station. The power offset is detected in each time resource unit in the set, and the user equipment does not perform power offset detection outside the time resource unit set.
- the user equipment only detects whether each time resource unit in the time resource unit set carries a power offset, and does not detect whether a power offset is carried in a time resource unit other than the time resource unit set. Therefore, in the embodiment of the present invention, the user equipment performs power offset detection only on all time resource units in the time resource unit set, and the user equipment does not need to perform power offset for time resource units other than the time resource unit set. Detection, so the user equipment detects whether the power offset is carried only for the time resource unit in the time resource unit set, and does not generate excessive load.
- the control method of the full-duplex transmission before the user equipment corrects the first uplink transmission power for the half-duplex transmission according to the power offset acquired by the user equipment, the control method of the full-duplex transmission provided by the embodiment of the present invention is further It can include the following steps:
- the user equipment detects the corresponding trigger signaling by using the scheduling authorization information from the first time resource unit or a time resource unit of the first time resource unit.
- the trigger power offset is in effect.
- the user equipment if the power offset is obtained by the user equipment in a predefined manner, the user equipment also needs the trigger signaling sent by the base station to trigger the power offset to be valid, and the trigger signaling is carried by the base station in the first time resource unit. Or, in the scheduling authorization information of a time resource unit of the resource unit in the first time, the user equipment may trigger the trigger signaling corresponding to the scheduling authorization information.
- the power offset is in effect.
- the power offset is obtained by the user equipment in a predefined manner, and specifically includes the following steps:
- the user equipment receives broadcast signaling or proprietary signaling sent by the base station;
- the user equipment obtains a power offset through broadcast signaling or proprietary signaling.
- the predefined manner of the power offset may be that the base station sends the power offset by using the broadcast signaling or the dedicated signaling. After the user equipment receives the power offset through the broadcast signaling or the dedicated signaling, the user equipment may save the power offset.
- the power offset is used to trigger the power offset when the triggering of the power offset is received, where the dedicated signaling sent by the base station may be preset radio resource control signaling, and the proprietary signal
- the commands may also be other signaling known to the base station and user equipment.
- the power offset is detected by the user equipment from the scheduling grant information of the first time resource unit, or the power offset is set by the user equipment from each of the configured multiple time resource units.
- the detection authorization information in the time resource unit is detected, and specifically includes the following steps:
- the user equipment detects a power offset from the newly added information in the scheduling grant information
- the user equipment detects a power offset from the original information redefined in the scheduling grant information.
- the base station may set the power offset by the user equipment to detect the power offset by using the scheduling grant information, for example, the base station may be in the scheduling.
- a new information is added to the authorization information, and the power offset is carried in the newly added information, so that the user equipment can detect the newly added information in the scheduling authorization information.
- the base station can also redefine the original information in the scheduling authorization information. Then, the re-defined original information can be used to carry the power offset, so the user equipment can detect the original information redefined in the scheduling authorization information.
- the user equipment corrects the first uplink transmission power for the half-duplex transmission according to the power offset acquired by the user equipment, and obtains the second uplink transmission for the full-duplex transmission.
- the power may specifically include the following steps:
- the user equipment calculates the second uplink transmission power for full-duplex transmission by:
- the P FD is the second uplink transmission power
- the P HD is the first uplink transmission power
- the P offset is the power offset obtained by the user equipment.
- the user equipment can calculate the first uplink transmission power by using the power offset, and subtract the power offset from the first uplink transmission power, so that the transmission power on the second line can be obtained, and it should be noted that in other embodiments of the present invention, the modification of the first uplink transmission power according to the power offset may also be performed in other manners, for example, by subtracting the power offset from the first uplink transmission power and multiplying by a preset ratio value, Alternatively, after subtracting the power offset from the first uplink transmission power and then subtracting a preset compensation value, the second uplink transmission power for the half-duplex transmission can be calculated, and the specific implementation can be combined with the needs of the application scenario. This is only an example.
- Step 102 may specifically include the following steps:
- the second uplink transmission power for full duplex transmission is calculated as follows:
- P FD (n) P PUSCH (n)-P offset (n);
- the nth time resource unit is the first time resource unit
- P FD (n) is the second uplink transmission power
- P PUSCH (n) is the first uplink transmission power of the PUSCH for half duplex transmission
- P offset (n) The power offset obtained for the user equipment.
- Step 102 may specifically include the following steps:
- the second uplink transmission power for full duplex transmission is calculated as follows:
- P FD (n) P PUCCH (n)-P offset (n);
- the nth time resource unit is the first time resource unit
- P FD (n) is the second uplink transmission power
- P PUCCH (n) is the first uplink transmission power of the PUCCH for half duplex transmission
- P offset (n ) The power offset obtained for the user equipment.
- control method may further include the following steps:
- the user equipment acquires a modulation and coding strategy (English full name Modulation and Coding Scheme, English abbreviation: MCS) offset matching the power offset;
- MCS Modulation and Coding Scheme
- the user equipment corrects the first MCS index for half-duplex transmission according to the MCS offset, and obtains a second MCS index for full-duplex transmission.
- the power offset can be matched with the MCS offset, that is, by using one
- the power offset can obtain the MCS offset corresponding to the power offset, and the MCS can represent the quality of the uplink channel.
- different coding rates of each control part can be determined, that is, the occupied part is determined.
- the base station may notify the user equipment of the MCS offset through the explicit signaling, and the user equipment may obtain the power offset by using the explicit signaling, or the user equipment may obtain the MCS bias by the matching relationship between the MCS offset and the power offset.
- the first MCS index may be corrected according to the MCS offset to obtain a second MCS index that can be used for full-duplex transmission.
- the user equipment in step E1 obtains a modulation and coding strategy MCS offset that matches the power offset, and may specifically include the following steps:
- the user equipment receives the MCS offset by using broadcast signaling or proprietary signaling.
- the user equipment acquires the MCS offset by a mutual matching relationship between the predefined power offset and the MCS offset.
- the manner in which the user equipment obtains the MCS offset may be through broadcast signaling or proprietary signaling, where the broadcast signaling or the dedicated signaling is configured by the base station, and the base station sends the MCS by using broadcast signaling or proprietary signaling.
- the user equipment may obtain an MCS offset.
- the dedicated signaling configured by the base station may be radio resource control signaling.
- there is a mutual matching relationship between the power offset and the MCS offset and the MCS offset can be obtained according to the predefined mutual matching relationship.
- the MCS offset matching the power offset may be indicated by explicit signaling or stealth signaling.
- the explicit signaling indicates that the power offset is notified
- the MCS offset is specifically indicated by the extra bits.
- the implicit signaling indication is to notify the power offset, it is not necessary to specifically indicate the MCS offset by the extra bits, but the MCS offset is obtained by a predefined mutual matching.
- step E2 may specifically include the following steps:
- the second MCS index for full duplex transmission is calculated as follows:
- MCS FD (n) MCS PUSCH (n)-MCS offset (n);
- the nth time resource unit is the first time resource unit
- the MCS FD (n) is the second MCS index
- the MCS PUSCH (n) is the first MCS index of the half-duplex transmission of the PUCCH
- the MCS offset (n) is The MCS offset obtained by the user equipment.
- the user equipment can calculate the first MCS index by using the MCS offset, and subtract the MCS offset from the first MCS index, so that the second MCS index can be obtained.
- the correction of the first MCS index according to the MCS offset may also In other ways, for example, by subtracting the MCS offset from the first MCS index and multiplying it by a preset ratio value, or subtracting the MCS offset from the first MCS index and subtracting a preset offset
- the value of the second MCS index can be calculated for the half-duplex transmission.
- the specific implementation can be combined with the requirements of the application scenario.
- the user equipment transmits an uplink signal on the first time resource unit or the second time resource unit according to the second uplink transmission power, where the second time resource unit is a time resource unit that is in time after the first time resource unit.
- the user equipment acquires the scheduling authorization information indicating the full duplex transmission from the first time resource unit, and the user equipment acquires the second uplink transmission power for the full duplex transmission, and the second uplink.
- the transmission power may be used to transmit an uplink signal in a first time resource unit or a second time resource unit after the first time resource unit.
- the uplink signal transmission may be performed according to the second uplink transmission power determined in step 102, so that the power control of the uplink channel is performed. Can be set correctly, accurate power control can avoid self-interference, so that downlink data can be detected normally, improving the system gain of full-duplex transmission realized in LTE system and WiFi system.
- the uplink signal in step 103 indicates that the uplink scheduling information in the third time resource unit indicates the first time resource.
- the uplink data information that is transmitted on the unit or the second time resource unit, or the uplink signal is the uplink information of the first time resource unit corresponding to the downlink data information in the fifth time resource unit, where the uplink feedback information may be specifically Confirm information or deny information.
- the PDSCH is used as an example.
- the user equipment detects the downlink data information on the fifth time resource unit. According to the downlink data information, the user equipment needs to feed back the acknowledgement information or the denial information on the first time resource unit.
- the user equipment may also detect the downlink scheduling information on the first time resource unit. If the downlink scheduling information is also detected in the first time resource unit, the user equipment may be in the first time resource unit. The full-duplex transmission is performed, and the user equipment adjusts the transmission power that can be used for the confirmation information or the denial information to the foregoing second uplink transmission power.
- the user equipment first obtains the first time resource unit. If the scheduling authorization information including the full duplex transmission is obtained from the first time resource unit, the user equipment obtains the scheduling information according to the user equipment. Power offset for the first uplink used for half-duplex transmission The transmission power is corrected to obtain a second uplink transmission power for full-duplex transmission, and the user equipment finally transmits an uplink signal according to the second uplink transmission power on the first time resource unit or the second time resource unit, and the second time resource unit The resource unit for the time after the resource unit in the first time. In the embodiment of the present invention, the user equipment may determine the second uplink transmission power by using the preset power offset.
- the power control of the uplink channel may be obtained by correcting the first uplink transmission power when the user equipment determines to perform full duplex transmission.
- the second uplink transmission power is correctly set, so that precise power control can be implemented, thereby avoiding self-interference, so that downlink data can be normally detected, and system gain of full-duplex transmission in the wireless communication system is improved, and the method provided by the present invention can Used in LTE systems and WiFi systems.
- the foregoing embodiment introduces the control method of the full-duplex transmission provided by the present invention from the user equipment side, and then introduces the control method of the full-duplex transmission provided by the present invention from the base station side, as shown in FIG. 2, the embodiment of the present invention
- the control method for providing full duplex transmission may include the following steps:
- the base station determines whether the user equipment is instructed to perform full duplex transmission in the first time resource unit, and the determination result is obtained.
- the base station determines the full-duplex transmission control of the first time resource unit, and the base station determines the first time resource unit that needs to perform control processing, and determines whether the user equipment is instructed in the first time resource unit.
- the duplex transmission is performed to obtain a certain result.
- the determination result has two cases: one is that the result is that the user equipment can be instructed to perform full-duplex transmission in the first time resource unit, in which case step 202 can be triggered.
- the other is to determine that the user equipment is not allowed to perform full-duplex transmission in the first time resource unit. In this case, the base station does not indicate that the user equipment performs full-duplex transmission in the first subframe.
- the achievable manner is that the base station can determine whether the user equipment performs full-duplex transmission in the first time resource unit by using specific transmission in the first time resource unit, and the base station can pass the resource unit in the first time.
- the specific transmission in the previous time resource unit determines whether the user equipment is indicated to perform full duplex transmission in the first time resource unit.
- the user equipment can obtain whether the full-duplex transmission can be performed by the base station, and the user equipment can further determine whether the resource unit or the second resource is in the first time.
- the full-duplex transmission is performed on the time resource unit.
- the base station determines in step 201 whether the user equipment can perform full-duplex transmission in the second time resource unit, the user equipment can obtain whether the base station can perform the full indication. For duplex transmission, the user equipment can then determine whether to perform full duplex transmission on the second time resource unit.
- the time resource unit acquired by the base station in step 201 is a first time resource unit, where the time resource unit may specifically include: a subframe, a frame, a time slot, and an OFDM symbol. That is, a time resource unit described in some embodiments of the present invention may be specifically one subframe.
- the first time resource unit described in the following embodiments is specifically a first subframe
- the second time resource unit is specifically The second time resource unit may be the third subframe
- the fourth time resource unit is specifically the fourth subframe
- the fifth time resource unit may be the fifth subframe.
- a time resource unit described in other embodiments of the present invention may specifically be one frame (ie, a radio frame).
- the first time resource unit described in the following embodiments is specifically the first frame, and the second time resource unit.
- the second frame, the third time resource unit may be the third frame, the fourth time resource unit is specifically the fourth frame, and the fifth time resource unit may be the fifth frame.
- one time resource unit may be one time slot, or one time resource unit may be one OFDM symbol. It should be noted that the time resource unit may be selected as a subframe, a frame, a time slot, and an OFDM symbol according to the requirements of the application scenario, and is not limited.
- the step 201 determines whether the user equipment is in the first time resource unit to perform full-duplex transmission.
- the method may include the following steps:
- the base station transmits the uplink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, the base station is in the first time resource unit or the third time resource unit in advance of the first time resource unit. Transmitting downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit in advance on the fourth time resource unit of the first time resource unit, the base station determines that the user equipment can perform in the first time resource unit.
- Full-duplex transmission, the third-time resource unit and the fourth-time resource unit are two different time resource units;
- the base station does not transmit uplink scheduling information on the third time resource unit, or the base station determines that the number of time resource units that are different between the first time resource unit and the third time resource unit does not satisfy the preset difference, or the base station The downlink scheduling information is not detected on the first time resource unit or the fourth time resource unit, and the base station determines that the user equipment cannot perform full duplex transmission in the first time resource unit.
- the third time resource unit is a time resource unit ahead of the first time resource unit
- the fourth time resource unit is a time resource unit ahead of the first time resource unit
- the third time resource unit and the fourth time resource unit It is two different time resource units
- the base station transmits uplink scheduling information on the third time resource unit before the first time resource unit, where the uplink scheduling information is used to indicate that the resource unit is in the first time resource unit or the second time resource unit.
- the fourth time The resource unit is a time resource unit that is ahead of the first time resource unit, and the fourth time resource unit and the third time resource unit are both before the first time resource unit, but the fourth time resource unit and the third time resource unit are two
- the base station transmits downlink scheduling information on the first time resource unit or the fourth time resource unit.
- the base station confirms that the user equipment can be instructed to perform full duplex in the first time resource unit. transmission.
- the downlink scheduling information includes: a pre-configured special defined offset value, and the user equipment cancels the third time resource unit according to the power offset included in the downlink scheduling information.
- the downlink scheduling information is information transmitted in the first time resource unit or the fourth time resource unit, and if the base station in the third time resource unit, the uplink scheduling information indicates the first time resource unit or the second time resource unit.
- the uplink data information transmission when the base station needs to cancel the transmission of the uplink data information, the value of the power offset included by the base station in the downlink scheduling information is a preset special defined offset value, so that the user equipment is detecting After the offset value of this special meaning is canceled, the uplink data transmission indicated by the uplink scheduling information in the third time resource unit is cancelled.
- the user equipment After the user equipment detects the power offset from the first time resource unit or the fourth time resource unit, the user equipment finds that the power offset is a preset special defined offset value, and the user equipment cancels the first time.
- the uplink data information transmission in the resource unit or the second time resource unit For example, when the user equipment can take a value of the power offset as a specially defined power offset value, the specially defined power offset value is used to prevent uplink transmission in the same time resource unit from the downlink transmission.
- the step 201 determines whether the user equipment is in the first time resource unit to perform full-duplex transmission.
- the method may include the following steps:
- the base station transmits, on the first time resource unit, uplink feedback information corresponding to the downlink data information transmission of the fifth time resource unit that is advanced in the first time resource unit, and the base station is in the first time resource unit or is ahead of the first
- the downlink resource information indicating the transmission on the first time resource unit or the second time resource unit is transmitted on the fourth time resource unit of the time resource unit, and the base station determines that the user equipment can perform full duplex transmission in the first time resource unit.
- the fourth time resource unit and the fifth time resource unit are two different time resource units;
- the base station determines that the number of time resource units between the first time resource unit and the fifth time resource unit does not satisfy the pre- If the difference is set, or the base station does not detect the downlink scheduling information on the first time resource unit or the fourth time resource unit, the base station determines that the user equipment can perform full duplex transmission in the first time resource unit.
- the fifth time resource unit is a time resource unit ahead of the first time resource unit
- the fourth time resource unit is a time resource unit ahead of the first time resource unit
- the fifth time resource unit and the fourth time resource unit The data is transmitted by the base station on the fifth time resource unit before the first time resource unit, and the base station transmits the uplink feedback information corresponding to the downlink data information on the first time resource unit.
- the four-time resource unit is a time resource unit that is ahead of the first time resource unit, and the fourth time resource unit and the fifth time resource unit are both before the first time resource unit, but the fourth time resource unit and the third time resource unit
- the two base station units transmit the downlink scheduling information on the first time resource unit or the fourth time resource unit. When the foregoing conditions are met, the base station confirms that the user equipment can be instructed in the first time resource unit. Duplex transmission.
- the step 201 determines whether the user equipment performs the full-duplex transmission in the first time resource unit, and the method for controlling the full-duplex transmission provided by the embodiment of the present invention further includes the following steps:
- the base station sends broadcast signaling or proprietary signaling to the user equipment, and the broadcast signaling or the proprietary signaling includes: a power offset and/or an MCS offset configured by the base station.
- the predefined manner of the power offset may be that the base station sends the power offset and/or the MCS offset by using the broadcast signaling or the dedicated signaling, and the base station sends the power offset and/or by using the broadcast signaling or the dedicated signaling.
- the user equipment can receive the power offset and/or MCS offset through broadcast signaling or proprietary signaling, and then the power offset and/or MCS offset can be saved for receiving in the pair.
- the power offset and/or the MCS offset triggering the triggering of the power offset and/or the MCS offset, wherein the dedicated signaling sent by the base station may be preset radio resource control signaling, and Signaling may also be other signaling known to the base station and user equipment.
- the step 201 determines whether the user equipment performs the full-duplex transmission in the first time resource unit, and the method for controlling the full-duplex transmission provided by the embodiment of the present invention further includes the following steps:
- the base station adds information to carry the power offset, or the base station carries the power offset in the original information redefined in the scheduling authorization information of the resource unit in the first time. Or, the base station is in each time resource unit of the configured multiple time resource units The newly added information in the scheduling grant information is used to carry the power offset, or the base station carries the power offset in the original information redefined in the scheduling grant information in each of the configured time resource units. .
- the base station may set the power offset by using the following manner to enable the user equipment to detect the power offset by using the scheduling grant information, for example, the base station may The information is newly added in the scheduling authorization information, and the power offset is carried in the newly added information, so that the user equipment can detect the newly added information in the scheduling authorization information.
- the base station can also perform the original information in the scheduling authorization information. After the redefinition, the re-defined original information can be used to carry the power offset, so the user equipment can detect the original information redefined in the scheduling authorization information.
- the base station sends, to the user equipment, scheduling authorization information indicating that the user equipment performs full-duplex transmission.
- the determination result obtained in step 201 shows that if the determination result indicates that the user equipment can perform full-duplex transmission in the first time resource unit, the base station can indicate the user equipment in the first time resource unit.
- the full-duplex transmission is performed.
- the base station may send scheduling authorization information indicating that the user equipment performs full-duplex transmission to the user equipment in the first time resource unit.
- the scheduling authorization information is detected by the user equipment in the first time resource unit.
- the first time resource unit or the second time resource unit obtained by the base station receiving the user equipment according to the first uplink transmission power corrected for the half duplex transmission after obtaining the scheduling authorization information indicating full duplex transmission.
- the transmitted uplink signal, the second time resource unit is a time resource unit that is in time after the first time resource unit.
- the user equipment when the user equipment acquires the base station in the first time resource unit to indicate that the user equipment can perform full-duplex transmission, the user equipment performs the first uplink for the half-duplex transmission according to the obtained power offset.
- the transmission power is corrected to obtain a second uplink transmission power for full-duplex transmission.
- the information may be obtained according to the modified first uplink transmission power.
- the second uplink transmission power is used for transmitting the uplink signal, and the base station may receive the uplink signal transmitted by the user equipment on the first time resource unit or the second time resource unit.
- the second uplink transmission power used by the user equipment is set according to whether the user equipment performs full-duplex transmission, accurate power control can be implemented by using the second uplink transmission power, The self-interference can be avoided, so that the downlink data can be detected normally, and the system gain of the full-duplex transmission realized in the LTE system and the WiFi system is improved.
- the base station determines whether the user equipment can be instructed to perform full-duplex transmission in the first time resource unit, and obtains a determination result. If the determination result is that the user equipment can be indicated in the first time resource unit.
- Full-duplex transmission the base station sends scheduling authorization information indicating that the user equipment performs full-duplex transmission to the user equipment in the first time resource unit, and the base station receives the user equipment according to the pair after obtaining the scheduling authorization information indicating full-duplex transmission.
- the second uplink transmission power obtained by modifying the first uplink transmission power of the half-duplex transmission is an uplink signal transmitted on the first time resource unit or the second time resource unit, and the second time resource unit is in the first time in time.
- the user equipment may determine the second uplink transmission power by using the preset power offset. Therefore, the power control of the uplink channel may be obtained by correcting the first uplink transmission power when the user equipment determines to perform full duplex transmission.
- the second uplink transmission power is correctly set, so that precise power control can be implemented, thereby avoiding self-interference, so that downlink data can be normally detected, and system gain of full-duplex transmission in the wireless communication system is improved, and the method provided by the present invention can Used in LTE systems and WiFi systems.
- the above downlink authorization scheduling is respectively used as a basis to implement an effective full-duplex power control operation solution.
- a power offset (hereinafter referred to as P offset ) is introduced, and the power offset is used to define a first uplink transmission power P PUSCH (or P PUCCH ) for half-duplex transmission and
- the power difference between the second uplink transmission power P FD for the full-duplex transmission, specifically, the first time resource unit is the n-th time resource unit, where
- P FD (n) P PUCCH (n)-P offset (n).
- n refers to a time resource unit that needs to modify the uplink transmission power.
- n may refer to a subframe that needs to modify the uplink transmission power.
- the power offset acquired by the user equipment may be predefined or indicated in the scheduling authorization information. Specifically, for a predefined power offset, if the resource unit in the same time detects the scheduling signaling used for both the uplink scheduling and the downlink scheduling, the power offset is triggered. Used to correct the first uplink transmission power.
- the indication for the power offset in the scheduling grant information of the first time resource unit may be an offset value, or 1 bit in the first time resource unit (English: bit ) Triggering the application of a predefined offset value takes effect.
- the power offset may also take a special meaning offset value, and the user equipment cancels an already scheduled uplink transmission by using the power offset value of the special meaning.
- the detection of the power offset may be performed in some defined set of time resource units, where the power offset may be sent as an additional bit, or the power offset may be reinterpreted by a normal downlink grant Some specific values are obtained. For time resource units other than the time resource unit set, the usual downlink uplink grants can be detected separately.
- scheduling grants and power control may be applied to the same time resource unit, such as the current first time resource unit, and scheduling grants and power control may also be applied to two time resource units, such as scheduling.
- Authorization is implemented in the first time resource unit, and power control is implemented in the second time resource unit.
- the power offset adjusting the PUSCH transmission power may be implicitly matched to one MCS offset, or the base station may signal an MCS offset while signaling the power offset.
- the first time resource unit is used as the nth time resource unit.
- multiple methods may be used to enable a user equipment to know whether there is full duplex transmission on the nth time resource unit. For example, an uplink grant is sent in the n-4th time resource unit, and then a downlink grant is sent in the nth time resource unit. Based on the downlink and uplink scheduling moments, the user equipment can know that there are both downlink scheduling and uplink scheduling in the nth time resource unit. As another example, uplink scheduling and downlink scheduling at the nth time resource unit can be simultaneously indicated in a single scheduling grant. Next, the scheduling detection of the uplink and downlink is not the same time resource unit as an example.
- the user equipment may adjust the second uplink transmission power based on whether the n-th time resource unit has full-duplex transmission, and whether full-duplex transmission can be authorized by scheduling. Detection is known.
- the time resource unit is specifically a subframe as an example.
- the nt 1 subframe is the scheduling authorization A
- the nt 2 subframe is the scheduling authorization B
- the user equipment obtains the first uplink transmission power for the half-duplex transmission from the power control command in the uplink authorization A, and corrects the first uplink transmission power by using the predefined power offset.
- the second uplink transmission power is specifically a subframe as an example.
- the nt 1 subframe is the scheduling authorization A
- the nt 2 subframe is the scheduling authorization B
- the user equipment obtains the first uplink transmission power for the half-duplex transmission from the power control command in the uplink authorization A, and corrects the first uplink transmission power by using the predefined power offset.
- the second uplink transmission power is the first uplink transmission power for
- the MCS offset is also used for the correction of the first MCS index.
- the user equipment is configured to adjust the first uplink transmission power based on the power offset detected in the downlink grant B.
- the user equipment Based on the power offset in the downlink grant B and the first uplink transmit power in the uplink grant A, the user equipment can obtain the second uplink transmit power for full duplex transmission.
- a special valued power offset may be used to prevent PUSCH transmissions that are transmitted simultaneously with the PDSCH in the same subframe.
- the power offset in the downlink grant B indication may result in a larger downlink control information (English name: Downlink Control Information, DCI), in order to reduce the load, this A large DCI does not need to be detected in every subframe, but only in a defined subframe set, and subframes other than the subframe set only detect uplink scheduling or downlink scheduling.
- DCI Downlink Control Information
- the downlink grant for the nth subframe is sent in advance t 2 ms, t 2 can be set to 0 to avoid latency, in which case the user equipment can be configured
- a short PUSCH is always sent, which is sent after the downlink grant detection of each subframe.
- the time resource unit is still a subframe. If the user equipment detects PDSCH D in the nt 1 subframe, it needs to feed back ACK or NACK in the nth subframe. Before the feedback, the user equipment also tries to detect the potential downlink scheduling on the same nth subframe. For example, if the received downlink grant n th frame, the first such authorization nt 2 F th downlink grant E, or the first downlink subframe n, meaning ACK / NACK in the downlink while transmitting ACK reception or NACK.
- the user equipment will adjust the transmission power of the ACK or NACK according to the predefined power offset, or adjust based on the power offset in the E or F of the downlink scheduling. Note that if the downlink pre-scheduling is not configured and the user equipment needs to detect the downlink grant on the same subframe before the uplink transmission, the ACK or NACK needs to be sent in a short format, allowing the downlink grant to have sufficient detection time.
- the full-duplex transmission application power control may be a user equipment-specific configuration, or may be dynamically activated/deactivated by the PDCCH, for example, may be through a radio resource control protocol (English full name: Radio Resource Control, English abbreviation: The RRC) signaling configuration notifies whether or not to apply such a rule by one bit in the downlink grant.
- a radio resource control protocol English full name: Radio Resource Control, English abbreviation: The RRC
- the method provided by embodiments of the present invention can be used for more precise power control of full duplex transmission.
- a user equipment 400 may include: an obtaining module 401, a modifying module 402, and an uplink control module 403, where
- An obtaining module 401 configured to acquire a first time resource unit
- the correction module 402 is configured to, when acquiring the scheduling authorization information indicating the full duplex transmission from the first time resource unit, according to the power offset acquired by the user equipment, for the half duplex transmission Correcting an uplink transmission power to obtain a second uplink transmission power for the full duplex transmission;
- the uplink control module 403 is configured to transmit an uplink signal on the first time resource unit or the second time resource unit according to the second uplink transmission power, where the second time resource unit is in the first time resource unit After the time resource unit.
- the obtaining module 401 is specifically configured to detect, on a third time resource unit that is advanced in the first time resource unit, whether there is an indication of the first time resource unit or the second time resource.
- Uplink scheduling information for transmitting on the unit, and detecting, at the first time resource unit or a fourth time resource unit of the first time resource unit, whether there is an indication of the first time resource unit or the second time resource Downstream scheduling information for transmission on the unit, third The time resource unit and the fourth time resource unit are two different time resource units; if the uplink scheduling information is detected on the third time resource unit, and the first time resource unit and the third time And determining, by the first time resource unit or the fourth time resource unit, the downlink scheduling information, where the first time resource unit is different from each other, and determining the first
- the time resource unit includes scheduling authorization information indicating full duplex transmission; if the uplink scheduling information is not detected on the third time resource unit, or the first time resource unit and the third time resource unit If the number of time resource units that are different from
- the acquiring module 401 is specifically configured to detect, on the first time resource unit, whether there is downlink data corresponding to a fifth time resource unit that is advanced in the first time resource unit.
- Uplink feedback information of the information transmission and detecting, on the first time resource unit or the fourth time resource unit in advance of the first time resource unit, whether there is an indication on the first time resource unit or the second time resource unit.
- the downlink scheduling information, the fourth time resource unit and the fifth time resource unit are two different time resource units; if the downlink resource unit corresponding to the fifth time resource unit is detected on the first time resource unit
- the uplink scheduling information is uplink grant information
- the downlink scheduling information is downlink grant information
- the obtaining module 401 is further configured to: before the correcting module corrects the first uplink transmission power for the half-duplex transmission according to the power offset acquired by the user equipment, Acquiring the first uplink transmission power for the half-duplex transmission in the uplink scheduling information in the third time resource unit, or acquiring the used information from the fifth time resource unit
- the half-duplex transmits the first uplink transmission power; the power offset is obtained by a predefined manner, or the power offset is obtained from the first time resource unit or the fourth time resource unit.
- the uplink signal is uplink data information in the third time resource unit indicating uplink data information that is transmitted on the first time resource unit or the second time resource unit; or
- the uplink signal is uplink feedback information of the first time resource unit corresponding to the downlink data information in the fifth time resource unit.
- the uplink scheduling information is detected on the third time resource unit, and the time resource unit between the first time resource unit and the third time resource unit is different The number of the presets meets the preset difference, and the downlink scheduling information is detected on the first time resource unit or the fourth time resource unit, and the uplink control module 403 is further used by the acquiring module.
- the uplink control module 403 After detecting, according to the third time resource unit of the first time resource unit, whether there is uplink scheduling information, if the power offset included in the downlink scheduling information is a preset special defined offset value, according to the The power offset included in the downlink scheduling information cancels uplink data information transmission performed on the first time resource unit or the second time resource unit indicated by the uplink scheduling information in the third time resource unit.
- the obtaining module 401 is further configured to obtain the power offset by using a predefined manner, or detect the power offset from the downlink scheduling information of the first time resource unit, or The power offset is detected in the scheduling grant information in each of the configured time resource units, and the configured multiple time resource units are all authorized time resources capable of detecting full duplex transmission. a subset of the set of units;
- the correction module 402 is further configured to: before the first uplink transmission power for half-duplex transmission is corrected according to the power offset acquired by the user equipment, if the power offset is passed by the user equipment Defining the method, when the corresponding trigger signaling is detected from the first time resource unit or the scheduling authorization information of a time resource unit of the first time resource unit, triggering the power offset to take effect .
- the obtaining module 401 is specifically configured to receive broadcast signaling or proprietary signaling sent by the base station, and obtain the power offset by using the broadcast signaling or the dedicated signaling.
- the obtaining module 401 is specifically configured to: detect the power offset from newly added information in the scheduling grant information; or redefine the original from the scheduling grant information.
- the power offset is detected in the information.
- the obtaining module 401 is specifically configured to detect, on the first time resource unit, whether uplink scheduling information and downlink scheduling information are present, if the first time resource unit is simultaneously detected. Determining the uplink scheduling information and the downlink scheduling information, determining that the first time resource unit includes scheduling authorization information indicating full duplex transmission; if the uplink scheduling information is detected at most in the first time resource unit And one of the downlink scheduling information, determining that the first time resource unit does not include scheduling authorization information indicating full duplex transmission.
- the modifying module 402 is specifically configured to calculate a second uplink transmission power for the full duplex transmission by:
- the P FD is the second uplink transmission power
- the P HD is the first uplink transmission power
- P offset is a power offset acquired by the user equipment.
- the obtaining module 401 is further configured to: after the correction module 402 corrects the first uplink transmission power for half-duplex transmission according to the power offset acquired by the user equipment, Obtaining a modulation and coding strategy MCS offset that matches the power offset;
- the correction module 402 is further configured to perform a modification on the first MCS index for half-duplex transmission according to the MCS offset, to obtain a second MCS index for the full-duplex transmission.
- the acquiring module 401 is specifically configured to receive the MCS offset by using broadcast signaling or dedicated signaling; or, by mutual predefined power offset and MCS offset The matching relationship acquires the MCS offset.
- the modification module 402 is specifically configured to calculate a second MCS index for the full duplex transmission by:
- MCS FD MCS HD -MCS offset
- the MCS FD is the second MCS index
- the MCS HD is the first MCS index
- the MCS offset is the MCS offset.
- the time resource unit includes: a subframe, a frame, a time slot, and an OFDM symbol.
- the user equipment first obtains the first time resource unit. If the scheduling authorization information including the full duplex transmission is obtained from the first time resource unit, the user equipment obtains the scheduling information according to the user equipment.
- the power offset is modified for the first uplink transmission power used for the half-duplex transmission to obtain the second uplink transmission power for the full-duplex transmission, and the user equipment finally according to the second uplink transmission power in the first time resource unit or
- the uplink signal is transmitted on the second time resource unit, and the second time resource unit is the time resource unit after the first time resource unit.
- the user equipment may determine the second uplink transmission power by using the preset power offset.
- the power control of the uplink channel may be obtained by correcting the first uplink transmission power when the user equipment determines to perform full duplex transmission.
- the second uplink transmission power is correctly set, so that precise power control can be implemented, thereby avoiding self-interference, so that downlink data can be normally detected, and system gain of full-duplex transmission in the wireless communication system is improved, and the method provided by the present invention can Used in LTE systems and WiFi systems.
- a base station 500 may include: a full duplex determination module 501, a sending module 502, and a receiving module 503, where
- the full-duplex determination module 501 is configured to determine whether the user equipment is in the first time resource unit to perform full-duplex transmission, and obtain a determination result;
- the sending module 502 is configured to: when the determining result is that the user equipment can perform full-duplex transmission in the first time resource unit, sending, by the first time resource unit, the indication to the user equipment Scheduling authorization information of the user equipment for full duplex transmission;
- the receiving module 503 is configured to receive an uplink signal that is sent by the user equipment on the first time resource unit or the second time resource unit, where the second time resource unit is a time after the first time resource unit Resource unit.
- the full duplex determination module 501 is specifically configured to: if the base station transmits an indication on a third time resource unit that is in advance of the first time resource unit, in the first time Uplink scheduling information that is transmitted on the resource unit or the second time resource unit, and the base station transmits an indication on the first time resource unit or the fourth time resource unit in advance of the first time resource unit.
- the downlink scheduling information that is transmitted on the first time resource unit or the second time resource unit determines that the user equipment may be instructed to perform full duplex transmission in the first time resource unit, where the third time resource unit and the fourth time resource unit are Two different time resource units; if the base station does not transmit the uplink scheduling information on the third time resource unit, or the base station determines The number of time resource units that are different between the first time resource unit and the third time resource unit does not satisfy a preset difference, or the base station is in the first time resource unit or the fourth time If the downlink scheduling information is not detected on the resource unit, it is determined that the user equipment is not allowed to perform full duplex transmission in the first time resource unit.
- the full duplex determination module 501 is specifically configured to: if the base station transmits, on the first time resource unit, a fifth time corresponding to the first time resource unit Uplink feedback information of the downlink data information transmission of the resource unit, and the base station transmits the indication in the first time resource unit or the fourth time resource unit in advance of the first time resource unit in the first time resource unit or The downlink scheduling information that is transmitted on the second time resource unit determines that the user equipment may be in full-duplex transmission in the first time resource unit, where the fourth time resource unit and the fifth time resource unit are two different time resources.
- Said downlink scheduling information may indicate that the user equipment is determined for a first time full-duplex transmission resource units.
- the downlink scheduling information includes: a pre-configured special defined offset value, where the user equipment cancels the third according to a power offset included in the downlink scheduling information.
- the sending module 502 is further configured to determine, by the full duplex determining module 501, whether to send a broadcast to the user equipment before indicating that the user equipment performs full duplex transmission in the first time resource unit.
- Signaling or proprietary signaling the broadcast signaling or proprietary signaling includes: a power offset configured by the base station.
- the base station 500 further includes: a configuration module 504, configured to determine, by the full duplex determination module 501, whether to indicate in the first time resource unit.
- a configuration module 504 configured to determine, by the full duplex determination module 501, whether to indicate in the first time resource unit.
- newly added information is used to carry the power offset and/or the MCS offset in the scheduling grant information of the first time resource unit, or the base station is in the first time resource unit.
- the original information redefined in the scheduling grant information carries a power offset and/or an MCS offset, or the scheduling of the base station in each of the configured multiple time resource units.
- the newly added information in the authorization information is used to carry the power offset and/or the MCS offset, or the base station is redefined in the scheduling grant information in each of the configured multiple time resource units.
- the original information carries power offset and/or MCS offset.
- the time resource unit includes: a subframe, a frame, a time slot, and an OFDM symbol.
- the base station determines whether the user equipment can be instructed to perform full-duplex transmission in the first time resource unit, and obtains a determination result. If the determination result is that the user equipment can be indicated in the first time resource unit.
- Full-duplex transmission the base station sends scheduling authorization information indicating that the user equipment performs full-duplex transmission to the user equipment in the first time resource unit, and the base station receives the user equipment according to the pair after obtaining the scheduling authorization information indicating full-duplex transmission.
- the second uplink transmission power obtained by modifying the first uplink transmission power of the half-duplex transmission is an uplink signal transmitted on the first time resource unit or the second time resource unit, and the second time resource unit is in the first time in time.
- the user equipment may determine the second uplink transmission power by using the preset power offset. Therefore, the power control of the uplink channel may be obtained by correcting the first uplink transmission power when the user equipment determines to perform full duplex transmission.
- the second uplink transmission power is correctly set, so that precise power control can be implemented, thereby avoiding self-interference, so that downlink data can be normally detected, and system gain of full-duplex transmission in the wireless communication system is improved, and the method provided by the present invention can Used in LTE systems and WiFi systems.
- the embodiment of the present invention further provides a computer storage medium, wherein the computer storage medium stores a program, and the program executes some or all of the steps described in the foregoing method embodiments.
- the user equipment 600 includes:
- the input device 601, the output device 602, the processor 603, and the memory 604 (wherein the number of processors 603 in the user device 600 may be one or more, and one processor in FIG. 6 is taken as an example).
- the input device 601, the output device 602, the processor 603, and the memory 604 may be connected by a bus or other means, wherein the bus connection is taken as an example in FIG.
- the processor 603 is configured to perform the method performed by the user equipment side in the foregoing embodiment. Specifically, the processor 603 is configured to perform the following steps:
- the scheduling grant information indicating the full duplex transmission is obtained from the first time resource unit, the first uplink transmission power used for the half duplex transmission is corrected according to the power offset acquired by the user equipment, Obtaining a second uplink transmission power for the full duplex transmission;
- the second time resource unit is a time resource that is in time after the first time resource unit unit.
- the processor 603 is specifically configured to perform the following steps:
- the uplink scheduling information is detected on the third time resource unit, and the number of time resource units that are different between the first time resource unit and the third time resource unit meets a preset difference, If the downlink scheduling information is detected on the first time resource unit or the fourth time resource unit, determining that the first time resource unit includes scheduling authorization information indicating full duplex transmission;
- the uplink scheduling information is not detected on the third time resource unit, or the number of time resource units that are different between the first time resource unit and the third time resource unit does not satisfy the preset difference a value, or the downlink scheduling information is not detected on the first time resource unit or the fourth time resource unit, determining that the first time resource unit does not include scheduling authorization information indicating full duplex transmission .
- the processor 603 is specifically configured to perform the following steps:
- the first time resource unit If the first time resource unit is detected, corresponding to the fifth time resource unit Uplink feedback information of the data information transmission, and the number of time resource units that are different between the first time resource unit and the fifth time resource unit meets a preset difference, and the first time resource unit Or detecting the downlink scheduling information on the fourth time resource unit, determining that the first time resource unit includes scheduling information indicating full duplex transmission;
- the uplink feedback information is not detected on the first time resource unit, or the number of time resource units that are different between the first time resource unit and the fifth time resource unit does not satisfy the preset difference
- the value, or the downlink scheduling information is not detected on the first time resource unit or the fourth time resource unit, determining that the first time resource unit does not include information of full duplex transmission.
- the uplink scheduling information stored in the memory 604 is uplink grant information
- the downlink scheduling information is downlink grant information
- the processor 603 is further configured to perform the following steps: before the first uplink transmission power for half-duplex transmission is corrected according to the power offset acquired by the user equipment, Obtaining the first uplink transmission power for the half-duplex transmission in the uplink scheduling information in the third time resource unit, or obtaining the half-double from the fifth time resource unit
- the first uplink transmission power is transmitted; the power offset is obtained in a predefined manner, or the power offset is obtained from the first time resource unit or the fourth time resource unit.
- the uplink signal stored in the memory 604 indicates that the uplink scheduling information in the third time resource unit is transmitted on the first time resource unit or the second time resource unit.
- Uplink data information; or the uplink signal is uplink feedback information of the first time resource unit corresponding to downlink data information in the fifth time resource unit.
- the processor 603 is further configured to: if the uplink scheduling information is detected on the third time resource unit, and the first time resource unit and the first The number of time resource units that are different between the three time resource units meets a preset difference, and the downlink scheduling information is detected on the first time resource unit or the fourth time resource unit, If the uplink scheduling information indicating the transmission on the first time resource unit or the second time resource unit is detected on the third time resource unit of the first time resource unit, if the power offset included in the downlink scheduling information is included For a preset special-defined offset value, canceling, according to the power offset included in the downlink scheduling information, the first time resource unit or the second indicated by the uplink scheduling information in the third time resource unit Uplink data transmission on time resource units lose.
- the power offset stored in the memory 604 is obtained by the user equipment in a predefined manner, or the power offset is downlinked by the user equipment from a first time resource unit. Detected in the scheduling information, or the power offset is detected by the user equipment from scheduling authorization information in each of the configured multiple time resource units, the configured multiple time resource units a subset of all authorized time resource unit sets for which full duplex transmission can be detected;
- the processor 603 is further configured to perform the following steps: before the first uplink transmission power for half-duplex transmission is corrected according to the power offset acquired by the user equipment,
- the power offset is obtained by the user equipment in a predefined manner, and the corresponding trigger is detected by scheduling authorization information from the first time resource unit or a time resource unit of the first time resource unit.
- the power offset is triggered to take effect.
- the processor 603 is further configured to: receive broadcast signaling or proprietary signaling sent by the base station; and obtain the power offset by using the broadcast signaling or the dedicated signaling. shift.
- the processor 603 is specifically configured to: perform the following steps: detecting the power offset from the newly added information in the scheduling grant information; or deleting the original information from the scheduling grant information The power offset is detected.
- the processor 603 is further configured to: detect, on the first time resource unit, whether there is uplink scheduling information and downlink scheduling information, if the first time resource unit is Simultaneously detecting the uplink scheduling information and the downlink scheduling information, determining that the first time resource unit includes scheduling authorization information indicating full duplex transmission; if at most the first time resource unit is detected, Determining, in the uplink scheduling information, one of the downlink scheduling information, determining that the first time resource unit does not include scheduling authorization information indicating full duplex transmission.
- the processor 603 is specifically configured to perform the following steps: calculating a second uplink transmission power for the full duplex transmission by:
- the P FD is the second uplink transmission power
- the P HD is the first uplink transmission power
- P offset is a power offset acquired by the user equipment.
- the processor 603 is further configured to perform the following steps: after correcting the first uplink transmission power for the half-duplex transmission according to the power offset acquired by the user equipment, acquiring The modulation of the power offset matching is offset from the coding strategy MCS; the first MCS for half-duplex transmission is modified according to the MCS offset to obtain a second MCS for the full-duplex transmission.
- the processor 603 is specifically configured to perform the following steps:
- the MCS offset is received by broadcast signaling or proprietary signaling; or the MCS offset is obtained by a mutual matching relationship between a predefined power offset and an MCS offset.
- the processor 603 is specifically configured to perform the following steps: calculating a second MCS index for the full duplex transmission by:
- MCS FD MCS HD -MCS offset
- the MCS FD is the second MCS index
- the MCS HD is the first MCS index
- the MCS offset is the MCS offset.
- the time resource unit stored in the memory 60 includes: a subframe, a frame, a time slot, and an orthogonal frequency division multiplexing OFDM symbol.
- the user equipment first obtains the first time resource unit. If the scheduling authorization information including the full duplex transmission is obtained from the first time resource unit, the user equipment obtains the scheduling information according to the user equipment.
- the power offset is modified for the first uplink transmission power used for the half-duplex transmission to obtain the second uplink transmission power for the full-duplex transmission, and the user equipment finally according to the second uplink transmission power in the first time resource unit or
- the uplink signal is transmitted on the second time resource unit, and the second time resource unit is the time resource unit after the first time resource unit.
- the user equipment may determine the second uplink transmission power by using the preset power offset.
- the power control of the uplink channel may be obtained by correcting the first uplink transmission power when the user equipment determines to perform full duplex transmission.
- the second uplink transmission power is correctly set, so that precise power control can be implemented, thereby avoiding self-interference, so that downlink data can be normally detected, and system gain of full-duplex transmission in the wireless communication system is improved, and the method provided by the present invention can Used in LTE systems and WiFi systems.
- the base station 700 includes:
- Input device 701, output device 702, processor 703, and memory 704 (where base station 700 The number of processors 703 may be one or more, and one processor is taken as an example in FIG. 7). In some embodiments of the present invention, the input device 701, the output device 702, the processor 703, and the memory 704 may be connected by a bus or other means, wherein the bus connection is taken as an example in FIG.
- the processor 703 is configured to perform the method performed by the base station side in the foregoing embodiment. Specifically, the processor 703 is configured to perform the following steps:
- the determining result is that the user equipment may be in the first time resource unit to perform full-duplex transmission, sending, by the first time resource unit, the user equipment includes indicating that the user equipment performs a full double Scheduling authorization information for the transmission of the work;
- the second uplink transmission power obtained after correcting the first uplink transmission power for half-duplex transmission after obtaining the scheduling authorization information indicating full-duplex transmission, in the first time resource unit Or an uplink signal transmitted on the resource unit in the second time, where the second time resource unit is a time resource unit that is in time after the first time resource unit.
- the processor 703 is specifically configured to perform the following steps:
- the base station transmits uplink scheduling information indicating that the first time resource unit or the second time resource unit is transmitted on a third time resource unit that is ahead of the first time resource unit, and the base station is Determining, by the first time resource unit or the fourth time resource unit of the first time resource unit, downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit,
- the user equipment may be instructed to perform full-duplex transmission in the first time resource unit, where the third time resource unit and the fourth time resource unit are two different time resource units;
- the base station does not transmit the uplink scheduling information on the third time resource unit, or the base station determines the number of time resource units that are different between the first time resource unit and the third time resource unit If the preset difference is not met, or the base station does not detect the downlink scheduling information on the first time resource unit or the fourth time resource unit, it is determined that the preset time resource unit is not indicated.
- User equipment performs full duplex transmission.
- the processor 703 is specifically configured to perform the following steps:
- the base station transmits, on the first time resource unit, uplink feedback information corresponding to downlink data information transmission of a fifth time resource unit that is advanced in the first time resource unit, and the base And transmitting, by the first time resource unit or the fourth time resource unit of the first time resource unit, downlink scheduling information indicating that the transmission is performed on the first time resource unit or the second time resource unit, and then determining
- the user equipment may be instructed to perform full-duplex transmission in the first time resource unit, where the fourth time resource unit and the fifth time resource unit are two different time resource units;
- the base station If the base station does not transmit the uplink feedback information on the first time resource unit, or the base station determines the number of time resource units that are different between the first time resource unit and the fifth time resource unit If the preset difference is not met, or the base station does not detect the downlink scheduling information on the first time resource unit or the fourth time resource unit, determining that the user may be indicated in the first time resource unit
- the device performs full duplex transmission.
- the downlink scheduling information stored in the memory 704 includes: a pre-configured special defined offset value, and the user equipment according to the power offset included in the downlink scheduling information. And canceling uplink data information transmission performed on the first time resource unit or the second time resource unit indicated by the uplink scheduling information on the third time resource unit.
- the processor 703 is further configured to: determine whether the broadcast signaling may be sent to the user equipment before the user equipment is instructed to perform full-duplex transmission in the first time resource unit or
- the proprietary signaling, the broadcast signaling or the proprietary signaling includes: a power offset and/or an MCS offset of the base station configuration.
- the processor 703 is further configured to: determine whether the scheduling authorization information of the resource unit in the first time period before the user equipment is instructed to perform full-duplex transmission in the first time resource unit
- the new information is used to carry the power offset and/or the MCS offset, or the original information redefined in the scheduling grant information of the first time resource unit carries the power offset and/or the MCS offset.
- newly added information is used to carry the power offset and/or the MCS offset, or multiple time resources in the configuration.
- the original information redefined in the scheduling grant information in each time resource unit in the unit carries a power offset and/or an MCS offset.
- the time resource unit stored in the memory 704 includes: a subframe, a frame, a time slot, and an orthogonal frequency division multiplexing OFDM symbol.
- the base station determines whether the user equipment can be instructed to perform full-duplex transmission in the first time resource unit, and obtains a determination result. If the determination result is that the user equipment can be indicated in the first time resource unit.
- Full-duplex transmission the base station in the first time resource unit The user equipment sends scheduling authorization information indicating that the user equipment performs full-duplex transmission, and the base station receives the user equipment to obtain the first uplink transmission power for half-duplex transmission after obtaining the scheduling authorization information indicating full-duplex transmission.
- the second uplink transmission power is an uplink signal transmitted on the first time resource unit or the second time resource unit, and the second time resource unit is a time resource unit that is in time after the first time resource unit.
- the user equipment may determine the second uplink transmission power by using the preset power offset. Therefore, the power control of the uplink channel may be obtained by correcting the first uplink transmission power when the user equipment determines to perform full duplex transmission.
- the second uplink transmission power is correctly set, so that precise power control can be implemented, thereby avoiding self-interference, so that downlink data can be normally detected, and system gain of full-duplex transmission in the wireless communication system is improved, and the method provided by the present invention can Used in LTE systems and WiFi systems.
- the device embodiments described above are merely illustrative, wherein the units described as separate components may or may not be physically separated, and the components displayed as units may or may not be Physical units can be located in one place or distributed to multiple network elements. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the embodiment.
- the connection relationship between the modules indicates that there is a communication connection between them, and specifically, one or more communication buses or signal lines can be realized.
- the present invention can be implemented by means of software plus necessary general hardware, and of course, dedicated hardware, dedicated CPU, dedicated memory, dedicated memory, Special components and so on.
- functions performed by computer programs can be easily implemented with the corresponding hardware, and the specific hardware structure used to implement the same function can be various, such as analog circuits, digital circuits, or dedicated circuits. Circuits, etc.
- software program implementation is a better implementation in more cases.
- the technical solution of the present invention which is essential or contributes to the prior art, can be embodied in the form of a software product stored in a readable storage medium, such as a floppy disk of a computer.
- U disk mobile hard disk, read-only memory (ROM, Read-Only Memory), random access memory (RAM, Random Access Memory), disk or optical disk, etc., including a number of instructions to make a computer device (may be A personal computer, server, or network device, etc.) performs the methods described in various embodiments of the present invention.
- a computer device may be A personal computer, server, or network device, etc.
Landscapes
- Engineering & Computer Science (AREA)
- Signal Processing (AREA)
- Computer Networks & Wireless Communication (AREA)
- Quality & Reliability (AREA)
- Mobile Radio Communication Systems (AREA)
Abstract
一种全双工传输的控制方法和用户设备以及基站。其中,一种全双工传输的控制方法包括:用户设备获取第一时间资源单位;若从所述第一时间资源单位中获取到包括指示全双工传输的调度授权信息,所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于所述全双工传输的第二上行传输功率;所述用户设备按照所述第二上行传输功率在所述第一时间资源单位或第二时间资源单位上传输上行信号,所述第二时间资源单位为在时间上处于所述第一时间资源单位之后的时间资源单位。
Description
本发明实施例涉及通信领域,尤其涉及一种全双工传输的控制方法和用户设备以及基站。
半双工传输只能够进行信号的单向传输,而全双工传输可以同时进行信号的双向传输,因此全双工传输的信号传输效率很高,从物理层角度来看,全双工传输相比于半双工传输,系统吞吐量提高一倍,全双工传输也对介质访问控制(英文全称:Media Access Control,英文简称:MAC)的设计产生革新性的影响,从而使得未来无线通信系统能获得更高的吞吐量。
在目前的无线通信系统例如无线保真(英文名称:Wireless Fidelity,英文简称:WiFi)系统、长期演进(英文全称:Long Term Evolution,英文简称:LTE)系统中,主要使用的是半双工传输,半双工传输在相同的时频资源上不能同时进行信号的发送和接收。现有技术中描述了一种在WiFi系统中使用的全双工传输方法,可以实现在WiFi系统中的同一个信道上同时进行信号的发送和接收,由于WiFi传输可以占据整个信道,不需要频率复用,因此资源分配是固定的,用户设备(英文全称:User Equipment,英文简称:UE)准备好传输信号所需要的时间很少,因此WiFi系统可以在检测或接收到一些前导码后立即传输信号,从而实现全双工传输。
但是上述全双工传输的解决方案只适用于WiFi系统,而无法适用于需要频率复用的LTE系统,因为在LTE系统中资源分配需要动态决定,UE需要根据得到的传输块尺寸进行速率匹配,相比于WiFi系统,LTE系统中UE需要更多的时间用于资源配置。在目前的LTE系统中的频分双工(英文全称:Frequency Division Dual,英文简称:FDD)模式下,对于上行调度,基站会提前4毫秒向UE发送上行调度信息,对于下行调度,UE需要提前从基站获取调度相关信息,例如信道状态指示(英文全称:Channel State Information,英文简称:CSI)、缓存大小以及调度资源,下行调度信息和下行数据可以在相同的子帧中传输。这种FDD模式下的调度过程可以应用于LTE系统实现全双工传输。例如,n为自然数,在第(n-4)个子帧,基站发送上行调度信息用于在
第n个子帧传输上行信道,同时基站也在第n个子帧传输下行调度信息。这样UE在第n个子帧可以同时进行信号的发送和接收。
对于如上描述的LTE系统中实现的全双工传输方案中,当基站在第(n-4)个子帧上发送上行调度信息时,仍然不确定是否在第n个子帧对同一个UE会同时存在下行传输,而全双工传输和半双工传输中对上行传输会有不同的传输功率要求,这样基站就不确定在全双工传输中第n个子帧的上行传输是否会面临自干扰取消的问题。因此,第n个子帧的上行信道的功率控制就无法被正确设置,因不精确的功率控制会导致强烈的自干扰,这种自干扰很难被取消,从而使得下行数据不可检测,因此现有技术中LTE系统中实现的全双工传输存在系统增益很低的问题。
发明内容
本发明实施例提供了一种全双工传输的控制方法和用户设备以及基站,适用于LTE系统以及WiFi系统中实现全双工传输,并且可以实现在全双工传输时对上行信道的功率控制,提高全双工传输的系统增益。
第一方面,本发明实施例提供一种全双工传输的控制方法,包括:
用户设备获取第一时间资源单位;
若从所述第一时间资源单位中获取到包括指示全双工传输的调度授权信息,所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于所述全双工传输的第二上行传输功率;
所述用户设备按照所述第二上行传输功率在所述第一时间资源单位或第二时间资源单位上传输上行信号,所述第二时间资源单位为在时间上处于所述第一时间资源单位之后的时间资源单位。
结合第一方面,在第一方面的第一种可能的实现方式中,所述用户设备获取第一时间资源单位,包括:
所述用户设备在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,以及在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,所述第三时间资源单位和所述第四时间资源单
位是两个不同的时间资源单位;
若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;
若在所述第三时间资源单位上未检测到所述上行调度信息,或所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
结合第一方面,在第一方面的第二种可能的实现方式中,所述用户设备获取第一时间资源单位,包括:
所述用户设备在所述第一时间资源单位上检测是否有对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,并在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,所述第四时间资源单位和所述第五时间资源单位是两个不同的时间资源单位;
若在所述第一时间资源单位上检测到对应于所述第五时间资源单位的下行数据信息传输的上行反馈信息,且所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度信息;
若在所述第一时间资源单位上未检测到所述上行反馈信息,或所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括全双工传输的信息。
结合第一方面的第一种可能或第二种可能的实现方式,在第一方面的第三
种可能的实现方式中,所述上行调度信息为上行授权信息,所述下行调度信息为下行授权信息。
结合第一方面的第一种可能或第二种可能的实现方式,在第一方面的第四种可能的实现方式中,所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,所述方法还包括:
所述用户设备从所述第三时间资源单位中的所述上行调度信息中获取到所述用于半双工传输的第一上行传输功率,或,所述用户设备从所述第五时间资源单位中获取到所述用于半双工传输第一上行传输功率;
所述用户设备通过预定义的方式获取到所述功率偏移,或从所述第一时间资源单位中或所述第四时间资源单位中获取到所述功率偏移。
结合第一方面的第一种可能或第二种可能或第三种可能或第四种可能的实现方式,在第一方面的第五种可能的实现方式中,所述上行信号为所述第三时间资源单位中的上行调度信息指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行数据信息;
或者,所述上行信号为所述第五时间资源单位中的下行数据信息对应的所述第一时间资源单位的上行反馈信息。
结合第一方面的第一种可能的实现方式,在第一方面的第六种可能的实现方式中,若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,所述用户设备在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在上行调度信息之后,所述方法还包括:
若所述下行调度信息中包括的功率偏移为一个预置的特殊定义的偏移值,所述用户设备根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位中的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
结合第一方面,在第一方面的第七种可能的实现方式中,所述功率偏移由所述用户设备通过预定义的方式得到,或者所述功率偏移由所述用户设备从第一时间资源单位的下行调度信息中检测得到,或者所述功率偏移由所述用户设备从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检
测得到,所述配置的多个时间资源单位为所有能检测到全双工传输的授权时间资源单位集合的子集;
所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,所述方法还包括:
若所述功率偏移由所述用户设备通过预定义的方式得到,所述用户设备通过从所述第一时间资源单位或提前于所述第一时间资源单位的一个时间资源单位的调度授权信息中检测到对应的触发信令时,触发所述功率偏移生效。
结合第一方面的第七种可能的实现方式,在第一方面的第八种可能的实现方式中,所述功率偏移由所述用户设备通过预定义的方式得到,包括:
所述用户设备接收基站发送的广播信令或者专有信令;
所述用户设备通过所述广播信令或者专有信令获取到所述功率偏移。
结合第一方面的第七种可能的实现方式,在第一方面的第九种可能的实现方式中,所述功率偏移由所述用户设备从第一时间资源单位的调度授权信息中检测得到,或者所述功率偏移由所述用户设备从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检测得到,包括:
所述用户设备从所述调度授权信息中新增加的信息中检测到所述功率偏移;
或者,所述用户设备从所述调度授权信息中重新定义的原有信息中检测到所述功率偏移。
结合第一方面,在第一方面的第十种可能的实现方式中,所述用户设备获取第一时间资源单位,包括:
所述用户设备在所述第一时间资源单位上检测是否存在上行调度信息和下行调度信息,若在所述第一时间资源单位上同时检测到所述上行调度信息和所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;若在所述第一时间资源单位上至多检测到所述上行调度信息和所述下行调度信息中的一个调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
结合第一方面,在第一方面的第十一种可能的实现方式中,所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于所述全双工传输的第二上行传输功率,包括:
所述用户设备通过如下方式计算用于所述全双工传输的第二上行传输功率:
PFD=PHD-Poffset;
其中,所述PFD为所述第二上行传输功率,所述PHD为所述第一上行传输功率,Poffset为所述用户设备获取到的功率偏移。
结合第一方面,在第一方面的第十二种可能的实现方式中,所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之后,所述方法还包括:
所述用户设备获取与所述功率偏移匹配的调制与编码策略MCS偏移;
所述用户设备根据所述MCS偏移对用于半双工传输的第一MCS进行修正,得到用于所述全双工传输的第二MCS。
结合第一方面的第十二种可能的实现方式,在第一方面的第十三种可能的实现方式中,所述用户设备获取与所述功率偏移匹配的调制与编码策略MCS偏移,包括:
所述用户设备通过广播信令或者专有信令接收到所述MCS偏移;
或者,所述用户设备通过预定义的功率偏移和MCS偏移的相互匹配关系获取到所述MCS偏移。
结合第一方面的第十二种可能的实现方式,在第一方面的第十四种可能的实现方式中,所述用户设备根据所述MCS偏移对用于半双工传输的第一MCS索引进行修正,得到用于所述全双工传输的第二MCS索引,包括:
所述用户设备通过如下方式计算用于所述全双工传输的第二MCS索引:
MCSFD=MCSHD-MCSoffset;
其中,所述MCSFD为所述第二MCS索引,所述MCSHD为所述第一MCS索引,MCSoffset为所述MCS偏移。
结合第一方面,在第一方面的第十五种可能的实现方式中,所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
第二方面,本发明实施例提供一种全双工传输的控制方法,包括:
基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果;
若所述确定结果为可以在所述第一时间资源单位中指示所述用户设备进
行全双工传输,所述基站在所述第一时间资源单位向所述用户设备发送包括指示所述用户设备进行全双工传输的调度授权信息;
所述基站接收所述用户设备在获取到所述调度授权信息指示全双工传输之后按照对用于半双工传输的第一上行传输功率修正后得到的第二上行传输功率在所述第一时间资源单位或者第二时间资源单位上传输的上行信号,所述第二时间资源单位为在时间上处于所述第一时间资源单位之后的时间资源单位。
结合第二方面,在第二方面的第一种可能的实现方式中,所述基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,包括:
若所述基站在提前于所述第一时间资源单位的第三时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则所述基站确定可以在第一时间资源单位中指示用户设备进行全双工传输,所述第三时间资源单位和所述第四时间资源单位是两个不同的时间资源单位;
若所述基站未在所述第三时间资源单位上传输所述上行调度信息,或所述基站确定所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则所述基站确定不可以在第一时间资源单位中指示用户设备进行全双工传输。
结合第二方面,在第二方面的第二种可能的实现方式中,所述基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,包括:
若所述基站在所述第一时间资源单位上传输对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则所述基站确定可以在第一时间资源单位中指示用户设备进行全双工传输,所述第四时间资源单位和所述第五时间资源单位是两个不同的时间资源单位;
若所述基站未在所述第一时间资源单位上传输所述上行反馈信息,或所述基站确定所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则所述基站确定可以在第一时间资源单位中指示用户设备进行全双工传输。
结合第二方面的第一种可能的实现方式,在第二方面的第三种可能的实现方式中,所述下行调度信息,包括:一个预先配置的特殊定义的偏移值,由所述用户设备根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位上的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
结合第二方面,在第二方面的第四种可能的实现方式中,所述基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,所述方法还包括:
所述基站向所述用户设备发送广播信令或者专有信令,所述广播信令或者专有信令包括:所述基站配置的功率偏移和/或MCS偏移。
结合第二方面,在第二方面的第五种可能的实现方式中,所述基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,所述方法还包括:
所述基站在第一时间资源单位的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,所述基站在第一时间资源单位的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移。
结合第二方面,在第二方面的第六种可能的实现方式中,所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
第三方面,本发明实施例提供一种用户设备,包括:
获取模块,用于获取第一时间资源单位;
修正模块,用于当从所述第一时间资源单位中获取到包括指示全双工传输
的调度授权信息时,根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于所述全双工传输的第二上行传输功率;
上行控制模块,用于按照所述第二上行传输功率在所述第一时间资源单位或第二时间资源单位上传输上行信号,所述第二时间资源单位为在所述第一时间资源单位之后的时间资源单位。
结合第三方面,在第三方面的第一种可能的实现方式中,所述获取模块,具体用于在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,以及在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,所述第三时间资源单位和所述第四时间资源单位是两个不同的时间资源单位;若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;若在所述第三时间资源单位上未检测到所述上行调度信息,或所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
结合第三方面,在第三方面的第二种可能的实现方式中,所述获取模块,具体用于在所述第一时间资源单位上检测是否有对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,并在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,所述第四时间资源单位和所述第五时间资源单位是两个不同的时间资源单位;若在所述第一时间资源单位上检测到对应于所述第五时间资源单位的下行数据信息传输的上行反馈信息,且所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第
一时间资源单位中包括指示全双工传输的调度信息;若在所述第一时间资源单位上未检测到所述上行反馈信息,或所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括全双工传输的信息。
结合第三方面的第一种可能或第二种可能的实现方式,在第三方面的第三种可能的实现方式中,所述上行调度信息为上行授权信息,所述下行调度信息为下行授权信息。
结合第三方面的第一种可能或第二种可能的实现方式,在第三方面的第四种可能的实现方式中,所述获取模块,还用于所述修正模块根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,从所述第三时间资源单位中的所述上行调度信息中获取到所述用于半双工传输的第一上行传输功率,或,从所述第五时间资源单位中获取到所述用于半双工传输第一上行传输功率;通过预定义的方式获取到所述功率偏移,或从所述第一时间资源单位中或所述第四时间资源单位中获取到所述功率偏移。
结合第三方面的第一种可能或第二种可能或第三种可能或第四种可能的实现方式,在第三方面的第五种可能的实现方式中,所述上行信号为所述第三时间资源单位中的上行调度信息指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行数据信息;或者,所述上行信号为所述第五时间资源单位中的下行数据信息对应的所述第一时间资源单位的上行反馈信息。
结合第三方面的第一种可能的实现方式,在第三方面的第六种可能的实现方式中,若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,所述上行控制模块,还用于所述获取模块在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在上行调度信息之后,若所述下行调度信息中包括的功率偏移为一个预置的特殊定义的偏移值,根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位中的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
结合第三方面,在第三方面的第七种可能的实现方式中,所述获取模块,还用于通过预定义的方式得到所述功率偏移,或者从第一时间资源单位的下行调度信息中检测得到所述功率偏移,或者从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检测得到所述功率偏移,所述配置的多个时间资源单位为所有能检测到全双工传输的授权时间资源单位集合的子集;
所述修正模块,还用于根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,若所述功率偏移由所述用户设备通过预定义的方式得到,通过从所述第一时间资源单位或提前于所述第一时间资源单位的一个时间资源单位的调度授权信息中检测到对应的触发信令时,触发所述功率偏移生效。
结合第三方面的第七种可能的实现方式,在第三方面的第八种可能的实现方式中,所述获取模块,具体用于接收基站发送的广播信令或者专有信令;通过所述广播信令或者专有信令获取到所述功率偏移。
结合第三方面的第七种可能的实现方式,在第三方面的第九种可能的实现方式中,所述获取模块,具体用于从所述调度授权信息中新增加的信息中检测到所述功率偏移;或者,从所述调度授权信息中重新定义的原有信息中检测到所述功率偏移。
结合第三方面,在第三方面的第十种可能的实现方式中,所述获取模块,具体用于在所述第一时间资源单位上检测是否存在上行调度信息和下行调度信息,若在所述第一时间资源单位上同时检测到所述上行调度信息和所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;若在所述第一时间资源单位上至多检测到所述上行调度信息和所述下行调度信息中的一个调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
结合第三方面,在第三方面的第十一种可能的实现方式中,所述修正模块,具体用于通过如下方式计算用于所述全双工传输的第二上行传输功率:
PFD=PHD-Poffset;
其中,所述PFD为所述第二上行传输功率,所述PHD为所述第一上行传输功率,Poffset为所述用户设备获取到的功率偏移。
结合第三方面,在第三方面的第十二种可能的实现方式中,
所述获取模块,还用于所述修正模块根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之后,获取与所述功率偏移匹配的调制与编码策略MCS偏移;
所述修正模块,还用于根据所述MCS偏移对用于半双工传输的第一MCS索引进行修正,得到用于所述全双工传输的第二MCS索引。
结合第三方面的第十二种可能的实现方式,在第三方面的第十三种可能的实现方式中,所述获取模块,具体用于通过广播信令或者专有信令接收到所述MCS偏移;或者,通过预定义的功率偏移和MCS偏移的相互匹配关系获取到所述MCS偏移。
结合第三方面的第十二种可能的实现方式,在第三方面的第十四种可能的实现方式中,所述修正模块,具体用于通过如下方式计算用于所述全双工传输的第二MCS索引:
MCSFD=MCSHD-MCSoffset;
其中,所述MCSFD为所述第二MCS索引,所述MCSHD为所述第一MCS索引,MCSoffset为所述MCS偏移。
结合第三方面,在第三方面的第十五种可能的实现方式中,所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
第四方面,本发明实施例提供一种基站,包括:
全双工确定模块,用于确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果;
发送模块,用于当所述确定结果为可以在所述第一时间资源单位中指示所述用户设备进行全双工传输时,在所述第一时间资源单位向所述用户设备发送包括指示所述用户设备进行全双工传输的调度授权信息;
接收模块,用于接收所述用户设备在获取到所述调度授权信息指示全双工传输之后按照对用于半双工传输的第一上行传输功率修正后得到的第二上行传输功率在所述第一时间资源单位或者第二时间资源单位上传输的上行信号,所述第二时间资源单位为在时间上处于所述第一时间资源单位之后的时间资源单位。
结合第四方面,在第四方面的第一种可能的实现方式中,所述全双工确定模块,具体用于若所述基站在提前于所述第一时间资源单位的第三时间资源单
位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输,所述第三时间资源单位和所述第四时间资源单位是两个不同的时间资源单位;若所述基站未在所述第三时间资源单位上传输所述上行调度信息,或所述基站确定所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定不可以在第一时间资源单位中指示用户设备进行全双工传输。
结合第四方面,在第四方面的第二种可能的实现方式中,所述全双工确定模块,具体用于若所述基站在所述第一时间资源单位上传输对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输,所述第四时间资源单位和所述第五时间资源单位是两个不同的时间资源单位;若所述基站未在所述第一时间资源单位上传输所述上行反馈信息,或所述基站确定所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输。
结合第四方面的第一种可能的实现方式,在第四方面的第三种可能的实现方式中,所述下行调度信息,包括:一个预先配置的特殊定义的偏移值,由所述用户设备根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位上的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
结合第四方面,在第四方面的第四种可能的实现方式中,所述基站还包括:发送模块,用于所述全双工确定模块确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,向所述用户设备发送广播信令或者专有信令,
所述广播信令或者专有信令包括:所述基站配置的功率偏移和/或MCS偏移。
结合第四方面,在第四方面的第五种可能的实现方式中,所述基站还包括:配置模块,用于所述全双工确定模块确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,在第一时间资源单位的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,所述基站在第一时间资源单位的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移。
结合第四方面,在第四方面的第六种可能的实现方式中,所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
从以上技术方案可以看出,本发明实施例具有以下优点:
本发明实施例中,用户设备首先获取第一时间资源单位,若从第一时间资源单位中获取到包括指示全双工传输的调度授权信息,用户设备接下来根据用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于全双工传输的第二上行传输功率,用户设备最后按照第二上行传输功率在第一时间资源单位或第二时间资源单位上传输上行信号,第二时间资源单位为在时间上处于第一时间资源单位之后的时间资源单位。本发明实施例中用户设备可以根据获取到的功率偏移确定出第二上行传输功率,因此上行信道的功率控制可以按照用户设备确定进行全双工传输时对第一上行传输功率进行修正得到的第二上行传输功率进行正确设置,因此可以实现精确的功率控制,从而可以避免自干扰,使得下行数据可以被正常检测,提高无线通信系统中全双工传输的系统增益,本发明提供的全双工传输的控制方法可以用于LTE系统和WiFi系统。
图1为本发明实施例提供的一种全双工传输的控制方法的流程方框示意图;
图2为本发明实施例提供的另一种全双工传输的控制方法的流程方框示
意图;
图3-a为本发明实施例提供的一种PUSCH的功率控制示意图;
图3-b为本发明实施例提供的另一种PUCCH的功率控制示意图;
图4为本发明实施例提供的一种用户设备的组成结构示意图;
图5-a为本发明实施例提供的一种基站的组成结构示意图;
图5-b为本发明实施例提供的另一种基站的组成结构示意图;
图6为本发明实施例提供的另一种用户设备的组成结构示意图;
图7为本发明实施例提供的另一种基站的组成结构示意图。
本发明实施例提供了一种全双工传输的控制方法和用户设备以及基站,适用于LTE系统以及WiFi系统中实现全双工传输,并且可以实现在全双工传输时对上行信道的功率控制,提高全双工传输的系统增益。
为使得本发明的发明目的、特征、优点能够更加的明显和易懂,下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进行清楚、完整地描述,显然,下面所描述的实施例仅仅是本发明一部分实施例,而非全部实施例。基于本发明中的实施例,本领域的技术人员所获得的所有其他实施例,都属于本发明保护的范围。
本发明的说明书和权利要求书及上述附图中的术语“第一”、“第二”等是用于区别类似的对象,而不必用于描述特定的顺序或先后次序。应该理解这样使用的术语在适当情况下可以互换,这仅仅是描述本发明的实施例中对相同属性的对象在描述时所采用的区分方式。此外,术语“包括”和“具有”以及他们的任何变形,意图在于覆盖不排他的包含,以便包含一系列单元的过程、方法、系统、产品或设备不必限于那些单元,而是可包括没有清楚地列出的或对于这些过程、方法、产品或设备固有的其它单元。
以下分别进行详细说明。
本发明全双工传输的控制方法的一个实施例,可应用于用户设备侧实现在全双工传输中的上行功率控制场景中,请参阅图1所示,本发明一个实施例提供的全双工传输的控制方法,可以包括:
101、用户设备获取第一时间资源单位。
在本发明实施例中以用户设备对第一时间资源单位的全双工传输控制为例,用户设备首先获取第一时间资源单位,对该第一时间资源单位进行检测,检测是否可以从第一时间资源单位中获取到包括指示全双工传输的调度授权信息,具体的,可实现的方式是,用户设备可以检测第一时间资源单位中的时间资源单位头,通过在第一时间资源单位的时间资源单位头中特定的字段信息或者指示位来确定是否包括指示全双工传输的调度授权信息,又如用户设备可以检测第一时间资源单位以外的其他时间资源单位,通过其他时间资源单位对第一时间资源单位的指示信息来确定第一时间资源单位中是否包括指示全双工传输的调度授权信息,又如用户设备可以检测基站发送的信令,用户设备通过基站发送的信令来确定第一时间资源单位中是否包括指示全双工传输的调度授权信息,又如用户设备还可以通过预定义的配置信息来确定第一时间资源单位中是否包括指示全双工传输的调度授权信息。对于包括指示全双工传输的调度授权信息的第一时间资源单位,用户设备可以在上述第一时间资源单位上进行全双工传输,对于不包括指示全双工传输的调度授权信息的第一时间资源单位,用户设备在上述第一时间资源单位上可以进行半双工传输,而不再进行全双工传输。在检测到包括指示全双工传输的调度授权信息的第一时间资源单位之后,用户设备执行后续步骤102。
在本发明的一些实施例中,步骤101中用户设备获取到的时间资源单位是第一时间资源单位,其中,时间资源单位具体可以包括:子帧、帧、时隙、正交频分复用(英文全称:Orthogonal Frequency Division Multiplexing,英文简称:OFDM)符号。即在本发明的一些实施例中描述的一个时间资源单位可以具体为一个子帧,例如,后续实施例中描述的第一时间资源单位具体为第一子帧,第二时间资源单位具体为第二子帧,第三时间资源单位具体可以为第三子帧,第四时间资源单位具体为第四子帧,第五时间资源单位具体可以为第五子帧。在本发明的另一些实施例中描述的一个时间资源单位具体可以为一个帧(即无线帧),例如,后续实施例中描述的第一时间资源单位具体为第一帧,第二时间资源单位具体为第二帧,第三时间资源单位具体可以为第三帧,第四时间资源单位具体为第四帧,第五时间资源单位具体可以为第五帧。或者,一个时间资源单位具体可以为一个时隙,或者一个时间资源单位具体可以为一个OFDM符号。需要说明的是,时间资源单位具体可根据应用场景的需要来选
取为子帧、帧、时隙、OFDM符号,具体不做限定,在本发明实施例中,子帧、帧、时隙、OFDM符号之间的关系在一种可实现的方式中,1个帧=10个子帧=10毫秒(ms)=20个时隙=140个OFDM符号。
在本发明的一些实施例中,步骤101用户设备获取第一时间资源单位,具体可以包括如下步骤:
A1、用户设备在提前于第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,以及在第一时间资源单位或提前于第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,第三时间资源单位和第四时间资源单位是两个不同的时间资源单位;
A2、若在第三时间资源单位上检测到上行调度信息,且第一时间资源单位和第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在第一时间资源单位或第四时间资源单位上检测到下行调度信息,则确定第一时间资源单位中包括指示全双工传输的调度授权信息;
A3、若在第三时间资源单位上未检测到上行调度信息,或第一时间资源单位和第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在第一时间资源单位或第四时间资源单位上未检测到下行调度信息,则确定第一时间资源单位中没有包括指示全双工传输的调度授权信息。
在上述步骤A1至步骤A3的实现方式中,第三时间资源单位为提前于第一时间资源单位的时间资源单位,第四时间资源单位为提前于第一时间资源单位的时间资源单位,并且第三时间资源单位和第四时间资源单位是两个不同的时间资源单位,用户设备在第一时间资源单位之前的第三时间资源单位上检测第三时间资源单位中是否存在上行调度信息,该上行调度信息用于指示在第一时间资源单位或第二时间资源单位上进行传输上行数据信息,例如用户设备检测第三时间资源单位的时间资源单位头来获取是否存在上行调度信息,由于上行调度在信号传输之前需要占用一定的准备时间,因此若需要在第一时间资源单位中进行上行传输,就需要基站在第一时间资源单位之前的一个时间资源单位中发送上行调度信息,本发明实施例中,用户设备检测在第一时间资源单位之前的每个时间资源单位,例如用户设备可以检测在第一时间资源单位之前的
第三时间资源单位,用户设备判断第三时间资源单位中是否存在上行调度信息,若用户设备在第三时间资源单位中检测到基站发送的上行调度信息,则说明用户设备可以在第三时间资源单位之后的某个时间资源单位上进行上行调度传输。
另外,第四时间资源单位为提前于第一时间资源单位的时间资源单位,该第四时间资源单位和第三时间资源单位都在第一时间资源单位之前,但是第四时间资源单位和第三时间资源单位是两个不同的时间资源单位,用户设备在第一时间资源单位或第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,也就是说,用户设备可以判断第一时间资源单位是否包括指示全双工传输的调度授权信息时,用户设备对下行调度信息的检测可以是在本时间资源单位(即第一时间资源单位),也可以在本时间资源单位之前的一个时间资源单位(例如是第四时间资源单位)。该下行调度信息用于指示在第一时间资源单位或第二时间资源单位上进行传输下行数据信息,例如用户设备检测第四时间资源单位的时间资源单位头来获取是否存在下行调度信息,若用户设备在第四时间资源单位中检测到基站发送的下行调度信息,则说明用户设备可以在第四时间资源单位之后的某个时间资源单位上进行下行调度传输。
在上述步骤A1至步骤A3的实现方式中,若满足如下三个条件就说明第一时间资源单位中包括了指示全双工传输的调度授权信息,该三个条件为:1)在第三时间资源单位上检测到了上行调度信息,2)第一时间资源单位和第三时间资源单位之间相差的时间资源单位个数为预置的差值,例如该差值为4个时间资源单位,也就是说,若第一时间资源单位为第n个时间资源单位,n为自然数,若在第n-4个时间资源单位上检测到了上行调度信息,此时第三时间资源单位为第n-4个时间资源单位,第一时间资源单位和第三时间资源单位之间相差的时间资源单位个数为4。3)、第一时间资源单位或第四时间资源单位上检测到了下行调度信息。在同时满足如上的3个条件时,用户设备可以确定第n个时间资源单位包括指示全双工传输的调度授权信息。若不能同时满足上述条件1)、条件2)和条件3),则说明第一时间资源单位中没有包括指示全双工传输的调度授权信息。例如,在第三时间资源单位上未检测到上行调度信息,或者即使在第三时间资源单位上检测到了上行调度信息,但是第一时间
资源单位和第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或者在第一时间资源单位或第四时间资源单位上没有检测到下行调度信息,在上述情况下都说明第一时间资源单位中不包括指示全双工传输的调度授权信息。
通过步骤A1对于第三时间资源单位的检测,以及对第一时间资源单位或第四时间资源单位的检测可知,若在第三时间资源单位上检测到上行调度信息,且第一时间资源单位和第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在第一时间资源单位或第四时间资源单位上检测到下行调度信息,在本发明的一些实施例中,步骤A2用户设备在提前于第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息之后,本发明实施例提供的全双工传输的控制方法,还可以包括如下步骤:
A4、若下行调度信息中包括的功率偏移为一个预置的特殊定义的偏移值,用户设备根据下行调度信息中包括的功率偏移取消第三时间资源单位中的上行调度信息指示的在第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
在步骤A4中,下行调度信息为在第一时间资源单位或者第四时间资源单位中传输的信息,若基站在第三时间资源单位中的上行调度信息指示了在第一时间资源单位或第二时间资源单位的上行数据信息传输,在基站需要取消这个上行数据信息传输时,基站可以在该下行调度信息中包括的功率偏移的取值为一个预置的特殊定义的偏移值,使用户设备在检测到这个特殊含义的偏移值之后取消第三时间资源单位中的上行调度信息指示的上行数据传输。则用户设备从第一时间资源单位或第四时间资源单位中检测到功率偏移之后,用户设备发现该功率偏移为一个预置的特殊定义的偏移值,用户设备会取消在第一时间资源单位或者第二时间资源单位中的上行数据信息传输。举例说明,用户设备可以根据功率偏移的取值为一个特殊定义的功率偏移值时,该特殊定义的功率偏移值被用来阻止相同时间资源单位中与下行传输同时进行的上行传输。
在本发明的一些实施例中,步骤101用户设备获取第一时间资源单位,具体可以包括如下步骤:
B1、用户设备在第一时间资源单位上检测是否有对应于提前于第一时间
资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,并在第一时间资源单位或提前于第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息;
B2、若在第一时间资源单位上检测到对应于第五时间资源单位的下行数据信息传输的上行反馈信息,且第一时间资源单位和第五时间资源单位之间相差的时间资源单位个数满足预置的差值,且在第一时间资源单位或第四时间资源单位上检测到下行调度信息,则确定第一时间资源单位中包括指示全双工传输的调度信息,第四时间资源单位和第五时间资源单位是两个不同的时间资源单位;
B3、若在第一时间资源单位上未检测到上行反馈信息,或第一时间资源单位和第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在第一时间资源单位或第四时间资源单位上未检测到下行调度信息,则确定第一时间资源单位中没有包括全双工传输的信息。
在上述步骤B1至步骤B3的实现方式中,第五时间资源单位为提前于第一时间资源单位的时间资源单位,用户设备在第一时间资源单位上检测是否存在上行反馈信息,该上行反馈信息是对应于在第五时间资源单位上传输的下行数据信息的反馈信息,例如用户设备检测第一时间资源单位的时间资源单位头来获取是否存在上行反馈信息,该上行反馈信息可以是确认信息(英文全称:Acknowledgement,英文简称:ACK)或者否认信息(英文全称:Negative Acknowledgement,英文简称:NACK),具体取决于用户设备在第五时间资源单位上接收下行数据信息的接收情况。本发明实施例中,用户设备检测在第一时间资源单位,用户设备判断第一时间资源单位中是否存在上行反馈信息,若用户设备在第一时间资源单位中检测到上行反馈信息,则说明用户设备可以在第一时间资源单位上进行上行调度传输。
另外,第四时间资源单位为提前于第一时间资源单位的时间资源单位,该第四时间资源单位和第五时间资源单位都在第一时间资源单位之前,但是第四时间资源单位和第五时间资源单位是两个不同的时间资源单位,用户设备在第一时间资源单位或第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,也就是说,用户设备可以判断第一时间资源单位是否包括指示全双工传输的调度授权信息时,用户设备
对下行调度信息的检测可以是在本时间资源单位(即第一时间资源单位),也可以在本时间资源单位之前的一个时间资源单位(例如是第四时间资源单位)。该下行调度信息用于指示在第一时间资源单位或第二时间资源单位上进行传输下行数据信息,例如用户设备检测第四时间资源单位的时间资源单位头来获取是否存在下行调度信息,若用户设备在第四时间资源单位中检测到基站发送的下行调度信息,则说明用户设备可以在第四时间资源单位之后的某个时间资源单位上进行下行调度传输。
在上述步骤B1至步骤B3的实现方式中,若满足如下三个条件就说明第一时间资源单位中包括了指示全双工传输的调度授权信息,该三个条件为:1)在第一时间资源单位上检测到了上行反馈信息,2)第一时间资源单位和第五时间资源单位之间相差的时间资源单位个数为预置的差值,例如该差值为2个时间资源单位,也就是说,若第一时间资源单位为第n个时间资源单位,n为自然数,若在第n-2个时间资源单位上检测到了下行数据信息,在第n个时间资源单位上检测到了对应于该下行数据信息的上行反馈信息,此时第五时间资源单位为第n-2个时间资源单位,第一时间资源单位和第五时间资源单位之间相差的时间资源单位个数为2。3)、第一时间资源单位或第四时间资源单位上检测到了下行调度信息。在同时满足如上的3个条件时,用户设备可以确定第n个时间资源单位包括指示全双工传输的调度授权信息。若不能同时满足上述条件1)、条件2)和条件3),则说明第一时间资源单位中没有包括指示全双工传输的调度授权信息。例如,在第一时间资源单位上未检测到上行反馈信息,或者第一时间资源单位和第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或者在第一时间资源单位或第四时间资源单位上没有检测到下行调度信息,在上述情况下都说明第一时间资源单位中不包括指示全双工传输的调度授权信息。
在本发明的一些实施例中,步骤101用户设备获取第一时间资源单位,具体可以包括如下步骤:
C1、用户设备在第一时间资源单位上检测是否存在上行调度信息和下行调度信息;
C2、若在第一时间资源单位上同时检测到上行调度信息和下行调度信息,则确定第一时间资源单位中包括指示全双工传输的调度授权信息;
C3、若在第一时间资源单位上至多检测到上行调度信息和下行调度信息中的一个调度信息,则确定第一时间资源单位中没有包括指示全双工传输的调度授权信息。
在上述步骤C1至C3的实现方式中,用户设备只需要检测第一时间资源单位即可,具体的,用户设备需要检测第一时间资源单位中是否同时包括上行调度信息和下行调度信息,在步骤C1至C3的实现方式下,全双工传输可以同时调度上下行的传输资源同时实现信号的发送和接收,例如,在物理下行控制信道(英文全称:Physical Downlink Control Channel,英文简称:PDCCH)中通过同时传输的上下行资源分配给用户设备实现全双工传输,在这种方式下,可以通过一个单一的调度授权信息检测出第一时间资源单位是否可用于全双工传输。通过对第一时间资源单位自身的检测来确定第一时间资源单位是否包括上述调度授权信息,例如,用户设备检测第一时间资源单位中是否同时包括上下行调度信息,若在第一时间资源单位中同时检测到了上行调度信息和下行调度信息,则用户设备可以确定第一时间资源单位可以用于全双工传输,若在第一时间资源单位中最多只检测到上行调度信息和下行调度信息中的其中一个,则用户设备确定第一时间资源单位不可以用于全双工传输,即在第一时间资源单位中不包括用于指示全双工传输的调度授权信息。
在前述描述的实施例中,上行调度信息可以为上行授权信息,下行调度信息可以是下行授权信息,其中,上行授权信息和下行授权信息可以是。上行授权信息包括用户设备可以在哪个时间哪个载波上(例如物理资源块)上传输数据,以及采用的MCS,它是PDCCH的内容之一。下行授权信息为基站在每个传输时间间隔(英文全称:Transmission Time Interval,英文简称:TTI)(即一个时间资源单位)动态的给用户设备分配资源,包括物理资源块以及采用的MCS,它是PDCCH的内容之一。另外上行调度信息和下行调度信息也可以预先配置的其它控制信息,只要用户设备侧可以检测上行调度信息和下行调度信息携带的指示内容即可。
102、若从第一时间资源单位中获取到包括指示全双工传输的调度授权信息,用户设备根据用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于全双工传输的第二上行传输功率。
在本发明实施例中,若通过步骤101获取到第一时间资源单位,从第一时
间资源单位中获取到了包括指示全双工传输的调度授权信息,则用户设备确定第一时间资源单位可以用于进行全双工传输,在第一时间资源单位需要进行全双工传输的情况下,全双工传输中上行传输的传输功率可以通过用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率的修正得到,具体的,用户设备可以使用预定义的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于全双工传输的第二上行传输功率,或者用户设备可以使用从第一时间资源单位或者预先配置的其它时间资源单位中检测到功率偏移。也就是说,用户设备获取到的功率偏移是用户设备预先定义的功率偏移或者用户设备通过基站发送的调度授权信息获取到的功率偏移,该功率偏移为在全双工传输下对用于半双工传输的第一上行传输功率进行修改的偏移功率值。另外,在本发明实施例中,第一上行传输功率为在不进行下行传输只进行上行传输时用户设备使用的上行传输功率,即该第一上行传输功率是用户设备获取到的用于半双工传输的上行传输功率。
在本发明的一些实施例中,在前述执行步骤A1至A3的实现方式或者执行步骤B1至B3的实现方式中,步骤102用户设备根据用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,本发明实施例提供的全双工传输的控制方法,还可以包括如下步骤:
D1、用户设备从第三时间资源单位中的上行调度信息中获取到用于半双工传输的第一上行传输功率,或,用户设备从第五时间资源单位中获取到用于半双工传输第一上行传输功率;
D2、用户设备通过预定义的方式获取到功率偏移,或从第一时间资源单位中或第四时间资源单位中获取到功率偏移。
其中,步骤D1中描述了用户设备获取第一上行传输功率的方式,用户设备可以从提前于第一时间资源单位的一个时间资源单位中获取到第一上行传输功率,例如从前述的第三时间资源单位或者第五时间资源单位中获取到。在步骤102中用户设备计算第二上行传输功率时还需要使用到功率偏移,步骤D2中描述了用户设备获取功率偏移的方式,用户设备可以通过预定义的方式获取到,另外基站还可以在第一时间资源单位或第四时间资源单位中发送功率偏移,用户设备还可以从第一时间资源单位或第四时间资源单位中获取到功率偏移。
在本发明的一些实施例中,功率偏移由用户设备通过预定义的方式得到,或者功率偏移由用户设备从第一时间资源单位的下行调度信息中检测得到,或者功率偏移由用户设备从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检测得到,配置的多个时间资源单位为所有能检测到全双工传输的授权时间资源单位集合的子集。其中,配置的多个时间资源单位可以是基站指定的多个时间资源单位的集合,则配置的多个时间资源单位为所有能够检测到全双工传输的授权时间资源单位集合的子集,也就是说,配置的多个时间资源单位可以是一个时间资源单位集合,该时间资源单位集合是能够检测到全双工传输的授权时间资源单位集合的一个子集,基站不需要在每个时间资源单位都携带功率偏移,这会增加系统开销,而是基站会预先配置在上述时间资源单位集合中的每个时间资源单位上携带功率偏移,用户设备只需要从基站配置的这个时间资源单位集合中的每个时间资源单位中检测功率偏移,而在时间资源单位集合以外用户设备不做功率偏移的检测。
因此,用户设备只检测时间资源单位集合中的每个时间资源单位是否携带有功率偏移,而对于时间资源单位集合以外的时间资源单位则不检测是否携带有功率偏移。因此,本发明实施例中,用户设备只对时间资源单位集合中的所有时间资源单位进行功率偏移的检测,而对于时间资源单位集合以外的时间资源单位,用户设备不需要进行功率偏移的检测,因此用户设备检测是否携带有功率偏移只会针对时间资源单位集合内的时间资源单位,不会产生过多的负荷。
在上述实现场景下,步骤102用户设备根据用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,本发明实施例提供的全双工传输的控制方法还可以包括如下步骤:
若功率偏移由用户设备通过预定义的方式得到,用户设备通过从第一时间资源单位或提前于第一时间资源单位的一个时间资源单位的调度授权信息中检测到对应的触发信令时,触发功率偏移生效。
在前述描述中若功率偏移是由用户设备通过预定义的方式得到,那么用户设备还需要基站发送的触发信令来触发功率偏移生效,该触发信令被基站携带在第一时间资源单位或者提前于第一时间资源单位的一个时间资源单位的调度授权信息中,用户设备获取到该调度授权信息对应的触发信令时就可以触发
功率偏移生效。
进一步的,在本发明的一些实施例中,功率偏移由用户设备通过预定义的方式得到,具体包括如下步骤:
用户设备接收基站发送的广播信令或者专有信令;
用户设备通过广播信令或者专有信令获取到功率偏移。
其中,功率偏移的预定义方式可以是基站通过广播信令或者专有信令来发送功率偏移,用户设备通过广播信令或者专有信令接收到功率偏移之后,用户设备就可以保存该功率偏移,用于在接收对该功率偏移的触发信令时触发该功率偏移生效,其中,基站发送的专有信令可以是预置的无线资源控制信令,另外专有信令也可是基站和用户设备公知的其它信令。
进一步的,在本发明的一些实施例中,功率偏移由用户设备从第一时间资源单位的调度授权信息中检测得到,或者功率偏移由用户设备从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检测得到,具体可以包括如下步骤:
用户设备从调度授权信息中新增加的信息中检测到功率偏移;
或者,用户设备从调度授权信息中重新定义的原有信息中检测到功率偏移。
也就是说,在功率偏移由用户设备检测得到的情况下,基站可以通过如下方式来设置功率偏移,以使用户设备通过从调度授权信息中检测出功率偏移,例如,基站可以在调度授权信息中新增加信息,在新增加的信息中携带功率偏移,则用户设备可以检测调度授权信息中新增加的信息,又如,基站还可以对调度授权信息中的原有信息进行重新定义,则重新定义后的原有信息就可以用于携带功率偏移,因此用户设备可以检测调度授权信息中重新定义的原有信息。
在本发明的一些实施例中,步骤102用户设备根据用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于全双工传输的第二上行传输功率,具体可以包括如下步骤:
用户设备通过如下方式计算用于全双工传输的第二上行传输功率:
PFD=PHD-Poffset;
其中,PFD为第二上行传输功率,PHD为第一上行传输功率,Poffset为用户设
备获取到的功率偏移。
也就是说,用户设备可以使用功率偏移对第一上行传输功率进行运算,从第一上行传输功率中减去功率偏移,从而可以得到第二行上传输功率,需要说明的是,在本发明的其它实施例中,根据功率偏移对第一上行传输功率的修正还可以采用其它方式,例如根据从第一上行传输功率中减去功率偏移后再乘以一个预置的比例值,或者从第一上行传输功率中减去功率偏移后再减去一个预置的补偿值,都可以计算出用于半双工传输的第二上行传输功率,具体实现可以结合应用场景的需要,此处仅作举例说明。
具体的,以物理上行共享信道(英文全称:Physical Uplink Shared Channel,英文简称:PUSCH)为例,步骤102具体可以包括如下步骤:
通过如下方式计算用于全双工传输的第二上行传输功率:
PFD(n)=PPUSCH(n)-Poffset(n);
其中,第n个时间资源单位为第一时间资源单位,PFD(n)为第二上行传输功率,PPUSCH(n)为PUSCH进行半双工传输的第一上行传输功率,Poffset(n)为用户设备获取到的功率偏移。
具体的,以物理上行控制信道(英文全称:Physical Uplink Control Channel,英文简称:PUCCH)为例,步骤102具体可以包括如下步骤:
通过如下方式计算用于全双工传输的第二上行传输功率:
PFD(n)=PPUCCH(n)-Poffset(n);
其中,第n个时间资源单位为第一时间资源单位,PFD(n)为第二上行传输功率,PPUCCH(n)为PUCCH进行半双工传输的第一上行传输功率,Poffset(n)为用户设备获取到的功率偏移。
在本发明的一些实施例中,步骤102用户设备根据用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之后,本发明实施例提供的全双工传输的控制方法,还可以包括如下步骤:
E1、用户设备获取与功率偏移匹配的调制与编码策略(英文全称Modulation and Coding Scheme,英文简称:MCS)偏移;
E2、用户设备根据MCS偏移对用于半双工传输的第一MCS索引进行修正,得到用于全双工传输的第二MCS索引。
其中,本发明实施例中,功率偏移可以和MCS偏移相匹配,即通过一个
功率偏移可以获取到对应于该功率偏移的MCS偏移,MCS可以代表上行信道的质量,根据上行信道采用的MCS可以确定各个控制部分不同的编码速率,也就是决定了各个部分所占用的资源块数目。基站可以将MCS偏移通过显性信令通知给用户设备,用户设备可以通过该显性信令获取到功率偏移,或者用户设备可以通过MCS偏移与功率偏移的匹配关系获取到MCS偏移,用户设备获取到MCS偏移之后,可以根据MCS偏移对第一MCS索引进行修正,得到可用于全双工传输的第二MCS索引。
在本发明的一些实施例中,步骤E1用户设备获取与功率偏移匹配的调制与编码策略MCS偏移,具体可以包括如下步骤:
E11、用户设备通过广播信令或者专有信令接收到MCS偏移;
或者,E12、用户设备通过预定义的功率偏移和MCS偏移的相互匹配关系获取到MCS偏移。
其中,用户设备获取MCS偏移的方式可以是通过广播信令或者专有信令,该广播信令或者专有信令由基站来配置,当基站使用广播信令或者专有信令来发送MCS偏移时,用户设备可以获取到MCS偏移,例如基站配置的专有信令可以是无线资源控制信令。另外,功率偏移和MCS偏移之间有相互匹配关系,可以根据该预定义的相互匹配关系获取到MCS偏移。举例说明,与功率偏移匹配的MCS偏移可以通过显性信令指示或者隐形信令指示。显性信令指示为通知功率偏移时,明确通过额外的比特专门指示MCS偏移。隐性信令指示为通知功率偏移时,不需要通过额外的比特专门指示MCS偏移,而是通过预先定义的相互匹配来获取到MCS偏移。
具体的,以PUSCH为例,步骤E2具体可以包括如下步骤:
通过如下方式计算用于全双工传输的第二MCS索引:
MCSFD(n)=MCSPUSCH(n)-MCSoffset(n);
其中,第n个时间资源单位为第一时间资源单位,MCSFD(n)为第二MCS索引,MCSPUSCH(n)为PUCCH进行半双工传输的第一MCS索引,MCSoffset(n)为用户设备获取到的MCS偏移。
也就是说,用户设备可以使用MCS偏移对第一MCS索引进行运算,从第一MCS索引中减去MCS偏移,从而可以得到第二MCS索引,需要说明的是,在本发明的其它实施例中,根据MCS偏移对第一MCS索引的修正还可
以采用其它方式,例如根据从第一MCS索引中减去MCS偏移后再乘以一个预置的比例值,或者从第一MCS索引中减去MCS偏移后再减去一个预置的补偿值,都可以计算出用于半双工传输的第二MCS索引,具体实现可以结合应用场景的需要,此处仅作举例说明。
103、用户设备按照第二上行传输功率在第一时间资源单位或第二时间资源单位上传输上行信号,第二时间资源单位为在时间上处于第一时间资源单位之后的时间资源单位。
在本发明实施例中,用户设备从第一时间资源单位中获取到包括指示全双工传输的调度授权信息,用户设备获取到用于全双工传输的第二上行传输功率,则第二上行传输功率可以用于在第一时间资源单位或者第一时间资源单位之后的第二时间资源单位传输上行信号。本发明实施例中在第一时间资源单位或者第二时间资源单位进行全双工传输时,可以按照步骤102中确定出的第二上行传输功率进行上行信号的传输,从而使得上行信道的功率控制可以被正确设置,精确的功率控制可以避免自干扰,使得下行数据可以被正常检测,提高LTE系统和WiFi系统中实现的全双工传输的系统增益。
在本发明的一些实施例中,在前述执行步骤A1至A3、步骤B1至B3的实现场景下,步骤103中的上行信号为对第三时间资源单位中的上行调度信息指示在第一时间资源单位或第二时间资源单位上进行传输的上行数据信息,或者,上行信号为第五时间资源单位中的下行数据信息对应的第一时间资源单位的上行反馈信息,其中,上行反馈信息具体可以为确认信息或者否认信息。举例说明如下,以PDSCH为例,用户设备在第五时间资源单位上检测到下行数据信息,根据该下行数据信息,用户设备需要在第一时间资源单位上反馈确认信息或者否认信息,用户设备在反馈确认信息或者否认信息之前,用户设备还可以在第一时间资源单位上检测下行调度信息,若在第一时间资源单位上还检测到下行调度信息,则说明用户设备可以在第一时间资源单位上进行全双工传输,用户设备将确认信息或者否认信息可使用的传输功率调整为前述的第二上行传输功率。
通过前述实施例对本发明的描述可知,用户设备首先获取第一时间资源单位,若从第一时间资源单位中获取到包括指示全双工传输的调度授权信息,用户设备接下来根据用户设备获取到的功率偏移对用于半双工传输的第一上行
传输功率进行修正,得到用于全双工传输的第二上行传输功率,用户设备最后按照第二上行传输功率在第一时间资源单位或第二时间资源单位上传输上行信号,第二时间资源单位为在第一时间资源单位之后的时间资源单位。本发明实施例中用户设备可以通过预置的功率偏移确定出第二上行传输功率,因此上行信道的功率控制可以按照用户设备确定进行全双工传输时对第一上行传输功率进行修正得到的第二上行传输功率进行正确设置,因此可以实现精确的功率控制,从而可以避免自干扰,使得下行数据可以被正常检测,提高无线通信系统中全双工传输的系统增益,本发明提供的方法可以用于LTE系统和WiFi系统。
前述实施例从用户设备侧介绍本发明提供的全双工传输的控制方法,接下来从基站侧介绍本发明提供的全双工传输的控制方法,请参阅如图2所示,本发明实施例提供的全双工传输的控制方法可以包括如下步骤:
201、基站确定是否在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果。
在本发明实施例中以基站对第一时间资源单位的全双工传输控制为例,基站确定需要进行控制处理的第一时间资源单位,确定是否在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果,该确定结果有两种情况:一种是确定结果为可以在第一时间资源单位中指示用户设备进行全双工传输,在这种情况下可以触发执行步骤202,另一种是确定结果为不可以在第一时间资源单位中指示用户设备进行全双工传输,在这种情况下基站不会在第一子帧指示用户设备进行全双工传输。具体的,可实现的方式是,基站可以通过在第一时间资源单位中的具体传输来确定是否在第一时间资源单位中指示用户设备进行全双工传输,基站可以通过在第一时间资源单位之前的其它时间资源单位中的具体传输来确定是否在第一时间资源单位中指示用户设备进行全双工传输。基站确定是否在第一时间资源单位中指示用户设备进行全双工传输之后,用户设备可以得到基站指示的是否可以进行全双工传输,用户设备进而可以确定是否在第一时间资源单位或第二时间资源单位上进行全双工传输,需要说明的是,若步骤201中基站确定用户设备是否可以在第二时间资源单位中进行全双工传输,则用户设备可以得到基站指示的是否可以进行全双工传输,用户设备进而可以确定是否在第二时间资源单位上进行全双工传输。
在本发明的一些实施例中,步骤201中基站获取到的时间资源单位是第一时间资源单位,其中,时间资源单位具体可以包括:子帧、帧、时隙、OFDM符号。即在本发明的一些实施例中描述的一个时间资源单位可以具体为一个子帧,例如,后续实施例中描述的第一时间资源单位具体为第一子帧,第二时间资源单位具体为第二子帧,第三时间资源单位具体可以为第三子帧,第四时间资源单位具体为第四子帧,第五时间资源单位具体可以为第五子帧。在本发明的另一些实施例中描述的一个时间资源单位具体可以为一个帧(即无线帧),例如,后续实施例中描述的第一时间资源单位具体为第一帧,第二时间资源单位具体为第二帧,第三时间资源单位具体可以为第三帧,第四时间资源单位具体为第四帧,第五时间资源单位具体可以为第五帧。或者,一个时间资源单位具体可以为一个时隙,或者一个时间资源单位具体可以为一个OFDM符号。需要说明的是,时间资源单位具体可根据应用场景的需要来选取为子帧、帧、时隙、OFDM符号,具体不做限定。
在本发明的一些实施例中,步骤201基站确定是否在第一时间资源单位中指示用户设备进行全双工传输,具体可以包括如下步骤:
F1、若基站在提前于第一时间资源单位的第三时间资源单位上传输指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,且基站在第一时间资源单位或提前于第一时间资源单位的第四时间资源单位上传输指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则基站确定用户设备可以在第一时间资源单位中进行全双工传输,第三时间资源单位和第四时间资源单位是两个不同的时间资源单位;
F2、若基站未在第三时间资源单位上传输上行调度信息,或基站确定第一时间资源单位和第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或基站在第一时间资源单位或第四时间资源单位上未检测到下行调度信息,则基站确定用户设备不可以在第一时间资源单位中进行全双工传输。
其中,第三时间资源单位为提前于第一时间资源单位的时间资源单位,第四时间资源单位为提前于第一时间资源单位的时间资源单位,并且第三时间资源单位和第四时间资源单位是两个不同的时间资源单位,基站在第一时间资源单位之前的第三时间资源单位上传输上行调度信息,该上行调度信息用于指示在第一时间资源单位或第二时间资源单位上进行传输上行数据信息,第四时间
资源单位为提前于第一时间资源单位的时间资源单位,该第四时间资源单位和第三时间资源单位都在第一时间资源单位之前,但是第四时间资源单位和第三时间资源单位是两个不同的时间资源单位,基站在第一时间资源单位或第四时间资源单位上传输下行调度信息,在满足上述条件时,表示基站确认可以在第一时间资源单位中指示用户设备进行全双工传输。
进一步的,在本发明的一些实施例中,下行调度信息,包括:一个预先配置的特殊定义的偏移值,由用户设备根据下行调度信息中包括的功率偏移取消第三时间资源单位上的上行调度信息指示的在第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
其中,下行调度信息为在第一时间资源单位或者第四时间资源单位中传输的信息,若基站在第三时间资源单位中的上行调度信息指示了在第一时间资源单位或第二时间资源单位的上行数据信息传输,在基站需要取消这个上行数据信息传输时,基站可以在该下行调度信息中包括的功率偏移的取值为一个预置的特殊定义的偏移值,使用户设备在检测到这个特殊含义的偏移值之后取消第三时间资源单位中的上行调度信息指示的上行数据传输。则用户设备从第一时间资源单位或第四时间资源单位中检测到功率偏移之后,用户设备发现该功率偏移为一个预置的特殊定义的偏移值,用户设备会取消在第一时间资源单位或者第二时间资源单位中的上行数据信息传输。举例说明,用户设备可以根据功率偏移的取值为一个特殊定义的功率偏移值时,该特殊定义的功率偏移值被用来阻止相同时间资源单位中与下行传输同时进行的上行传输。
在本发明的一些实施例中,步骤201基站确定是否在第一时间资源单位中指示用户设备进行全双工传输,具体可以包括如下步骤:
G1、若基站在第一时间资源单位上传输对应于提前于第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,且基站在第一时间资源单位或提前于第一时间资源单位的第四时间资源单位上传输指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则基站确定用户设备可以在第一时间资源单位中进行全双工传输,第四时间资源单位和第五时间资源单位是两个不同的时间资源单位;
G2、若基站未在第一时间资源单位上传输上行反馈信息,或基站确定第一时间资源单位和第五时间资源单位之间相差的时间资源单位个数不满足预
置的差值,或基站在第一时间资源单位或第四时间资源单位上未检测到下行调度信息,则基站确定用户设备可以在第一时间资源单位中进行全双工传输。
其中,第五时间资源单位为提前于第一时间资源单位的时间资源单位,第四时间资源单位为提前于第一时间资源单位的时间资源单位,并且第五时间资源单位和第四时间资源单位是两个不同的时间资源单位,基站在第一时间资源单位之前的第五时间资源单位上传输下行数据信息,基站在第一时间资源单位上传输与该下行数据信息对应的上行反馈信息,第四时间资源单位为提前于第一时间资源单位的时间资源单位,该第四时间资源单位和第五时间资源单位都在第一时间资源单位之前,但是第四时间资源单位和第三时间资源单位是两个不同的时间资源单位,基站在第一时间资源单位或第四时间资源单位上传输下行调度信息,在满足上述条件时,表示基站确认可以在第一时间资源单位中指示用户设备进行全双工传输。
在本发明的一些实施例中,步骤201基站确定是否在第一时间资源单位中指示用户设备进行全双工传输之前,本发明实施例提供的全双工传输的控制方法还包括如下步骤:
H1、基站向用户设备发送广播信令或者专有信令,广播信令或者专有信令包括:基站配置的功率偏移和/或MCS偏移。
其中,功率偏移的预定义方式可以是基站通过广播信令或者专有信令来发送功率偏移和/或MCS偏移,基站通过广播信令或者专有信令发送功率偏移和/或MCS偏移之后,用户设备通过广播信令或者专有信令可以接收到该功率偏移和/或MCS偏移,然后就可以保存该功率偏移和/或MCS偏移,用于在接收对该功率偏移和/或MCS偏移的触发信令时触发该功率偏移和/或MCS偏移生效,其中,基站发送的专有信令可以是预置的无线资源控制信令,另外专有信令也可是基站和用户设备公知的其它信令。
在本发明的一些实施例中,步骤201基站确定是否在第一时间资源单位中指示用户设备进行全双工传输之前,本发明实施例提供的全双工传输的控制方法还包括如下步骤:
I1、基站在第一时间资源单位的调度授权信息中新增加信息用于携带功率偏移,或,基站在第一时间资源单位的调度授权信息中重新定义的原有信息中携带功率偏移,或,基站在配置的多个时间资源单位中的每个时间资源单位中
的调度授权信息中新增加信息用于携带功率偏移,或,基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中重新定义的原有信息中携带功率偏移。
也就是说,在功率偏移由基站发送给用户设备的实现方式中,基站可以通过如下方式来设置功率偏移,以使用户设备通过从调度授权信息中检测出功率偏移,例如,基站可以在调度授权信息中新增加信息,在新增加的信息中携带功率偏移,则用户设备可以检测调度授权信息中新增加的信息,又如,基站还可以对调度授权信息中的原有信息进行重新定义,则重新定义后的原有信息就可以用于携带功率偏移,因此用户设备可以检测调度授权信息中重新定义的原有信息。
202、若确定结果为可以在第一时间资源单位中指示用户设备进行全双工传输,基站在第一时间资源单位向用户设备发送包括指示用户设备进行全双工传输的调度授权信息。
在本发明实施例中,通过步骤201得到的确定结果可知,若确定结果为可以在第一时间资源单位中指示用户设备进行全双工传输,则说明基站可以在第一时间资源单位指示用户设备进行全双工传输,具体的,基站可以在第一时间资源单位向用户设备发送包括指示用户设备进行全双工传输的调度授权信息。由用户设备在第一时间资源单位对上述调度授权信息进行检测。
203、基站接收用户设备在获取到所述调度授权信息指示全双工传输之后按照对用于半双工传输的第一上行传输功率修正后得到的第一时间资源单位或者第二时间资源单位上传输的上行信号,第二时间资源单位为在时间上处于第一时间资源单位之后的时间资源单位。
在本发明实施例中,用户设备在第一时间资源单位获取到基站指示该用户设备可以进行全双工传输时,用户设备根据获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于全双工传输的第二上行传输功率,用户设备在第一时间资源单位或者第二时间资源单位进行全双工传输时,可以按照修正第一上行传输功率得到的第二上行传输功率进行上行信号的传输,基站可以接收用户设备在第一时间资源单位或者第二时间资源单位上传输的上行信号。由于用户设备使用的第二上行传输功率是按照用户设备是否进行全双工传输进行设置的,因此通过第二上行传输功率可以实现精确的功率控制,从
而可以避免自干扰,使得下行数据可以被正常检测,提高LTE系统和WiFi系统中实现的全双工传输的系统增益。
通过前述实施例对本发明的描述可知,基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果,若确定结果为可以在第一时间资源单位中指示用户设备进行全双工传输,基站在第一时间资源单位向用户设备发送包括指示用户设备进行全双工传输的调度授权信息,基站接收用户设备在获取到调度授权信息指示全双工传输之后按照对用于半双工传输的第一上行传输功率修正后得到的第二上行传输功率在第一时间资源单位或者第二时间资源单位上传输的上行信号,第二时间资源单位为在时间上处于第一时间资源单位之后的时间资源单位。本发明实施例中用户设备可以通过预置的功率偏移确定出第二上行传输功率,因此上行信道的功率控制可以按照用户设备确定进行全双工传输时对第一上行传输功率进行修正得到的第二上行传输功率进行正确设置,因此可以实现精确的功率控制,从而可以避免自干扰,使得下行数据可以被正常检测,提高无线通信系统中全双工传输的系统增益,本发明提供的方法可以用于LTE系统和WiFi系统。
为便于更好的理解和实施本发明实施例的上述方案,下面举例相应的应用场景来进行具体说明。
本发明实施例中分别以上下行授权调度作为基础,实现有效的全双工功率控制操作的解决方案。对于能够进行全双工传输的用户设备,引入一个功率偏移(以下简称Poffset),功率偏移被用来定义用于半双工传输的第一上行传输功率PPUSCH(或PPUCCH)和用于全双工传输的第二上行传输功率PFD之间的功率差值,具体的,以第一时间资源单位为第n个时间资源单位为例,其中,
对于PUSCH,存在PFD(n)=PPUSCH(n)-Poffset(n);
对于PUCCH,存在PFD(n)=PPUCCH(n)-Poffset(n)。
其中,n指的是需要修改上行传输功率的时间资源单位,举例说明,n可以指的是一个需要修改上行传输功率的子帧。
本发明实施例中,用户设备获取到的功率偏移可以是被预定义的或者在调度授权信息中指示。具体的,对于预定义的功率偏移,如果在相同时间资源单位检测到既用于上行调度又用于下行调度的调度信令,则该功率偏移被触发使
用于对第一上行传输功率的修正。
在本发明的一些实施例中,在第一时间资源单位的调度授权信息中用于功率偏移的指示可以是一个偏移值,或者在第一时间资源单位中通过1个比特(英文:bit)触发应用一个预定义的偏移值的生效。本发明的一些实施例中中还可以对功率偏移取一个特殊含义的偏移值,用户设备通过该特殊含义的功率偏移取值来取消一个已经调度的上行传输。
在本发明的一些实施例中,功率偏移的检测可以在一些定义的时间资源单位集合中执行,其中功率偏移可以被发送作为额外的比特,或者功率偏移可以凭借重新解释一个通常下行授权中的一些特定值得到。对于时间资源单位集合以外的时间资源单位,通常的下行上行授权都可以被分别检测。
在本发明的一些实施例中,调度授权和功率控制可应用于同一个时间资源单位,例如目前的第一时间资源单位,调度授权和功率控制也可以分别应用于两个时间资源单位,例如调度授权在第一时间资源单位中实现,而功率控制在第二时间资源单位中实现。
在本发明的一些实施例中,调整PUSCH传输功率的功率偏移可以隐含匹配于一个MCS偏移,或者基站发信令通知功率偏移时,同时显性信令通知一个MCS偏移。具体的,MCS偏移的具体使用与功率偏移相类似,例如:对于PUSCH,MCSFD(n)=MCSPUSCH(n)-MCSoffset(n)。
接下来以第一时间资源单位为第n时间资源单位为例,本发明实施例中可以采用多种方法使得一个用户设备获知在第n个时间资源单位上是否存在全双工传输。例如,一个上行授权在第n-4个时间资源单位被发送,接着一个下行授权在第n时间资源单位被发送。基于下行和上行的调度时刻,用户设备可以知道在第n个时间资源单位既有下行调度又有上行调度。又如,可以在一个单一的调度授权中同时指示在第n个时间资源单位的的上行调度和下行调度。接下来对上下行的调度检测不在同一个时间资源单位为例进行说明。
在本发明的一种实现方式中,通过配置功率偏移,用户设备可以基于第n个时间资源单位是否有全双工传输来调整第二上行传输功率,是否有全双工传输可以通过调度授权检测获知。接下来以时间资源单位具体为子帧为例,例如,如图3-a所示,第n-t1个子帧为调度授权A,第n-t2个子帧为调度授权B,当调度授权A和B都被检测到时,用户设备从基于上行授权A中的功率控制命
令中得到用于半双工传输的第一上行传输功率,使用预定义的功率偏移对该第一上行传输功率进行修正,得到第二上行传输功率。并且对于PUSCH传输,也将基于MCS偏移用于对第一MCS索引的修正。MCS偏移可以通过与功率偏移的相互匹配关系得到,例如MCSoffset=f(Poffset),或者MCS偏移也可以被显性信令通知给用户设备。
在本发明的另一种实现方式中,用户设备将基于在下行授权B中检测到的功率偏移用于调整第一上行传输功率。在图3-a中,在下行授权B中可以有1比特的字段,如果该字段是1的话,用户设备将应用一个固定的功率偏移;或者在下行授权B中有一个或多个比特,可用于指示功率偏移的具体取值。基于这个下行授权B中的功率偏移,及上行授权A中的第一上行传输功率,用户设备可得到用于全双工传输的第二上行传输功率。
在本发明的一些实施例中,对于在下行授权B中传输的功率偏移,一个特殊取值的功率偏移可以被用来阻止相同子帧中与PDSCH同时传输的PUSCH传输。
在本发明的一些实施例中,功率偏移在下行授权B指示可以导致一个更大的下行控制信息(英文全称:Downlink Control Information,英文简称:DCI)的尺寸,为了减少这种负荷,这种大的DCI不需要在每个子帧中都被检测,而只在定义的子帧集合中进行检测,而子帧集合以外的子帧只检测上行调度或者下行调度。
尽管在图3-a所示的例子中,第n个子帧的下行授权是提前t2ms发送的,t2可以被设置为0以避免时延,在这种情形下,用户设备可以被配置总是发送一个简短的PUSCH,该PUSCH在每个子帧的下行授权检测之后发送。
请参阅如图3-b所示,仍以时间资源单位具体为子帧为例,如果用户设备在第n-t1个子帧检测到PDSCH D,需要在第n个子帧反馈ACK或NACK。反馈前,用户设备也尽力检测相同第n个子帧上的潜在的下行调度。例如,如果收到第n个子帧的下行授权,比如在第n-t2个的下行授权E,或者第n个子帧的下行授权F,意味着ACK/NACK将在下行接收时同时发送ACK或NACK。在这种情况下,用户设备将根据预定义的功率偏移调整ACK或NACK的传输功率,或者基于下行调度的E或F中的功率偏移进行调整。注意到,如果下行预调度未被配置,并且用户设备在上行传输前需要在相同子帧上检测下行授
权,ACK或NACK需要被以简短的格式发送,允许下行授权有足够的检测时间。
需要说明的是,全双工传输是否应用功率控制可以是用户设备特定的配置,也可以被PDCCH动态的激活/去激活,例如可以通过无线资源控制协议(英文全称:Radio Resource Control,英文简称:RRC)信令配置,通过下行授权中的1个比特来通知是否应用这种规则。
通过如上对本发明的举例说明可知,本发明实施例提供的方法能够用于全双工传输的更精确地功率控制。
需要说明的是,对于前述的各方法实施例,为了简单描述,故将其都表述为一系列的动作组合,但是本领域技术人员应该知悉,本发明并不受所描述的动作顺序的限制,因为依据本发明,某些步骤可以采用其他顺序或者同时进行。其次,本领域技术人员也应该知悉,说明书中所描述的实施例均属于优选实施例,所涉及的动作和模块并不一定是本发明所必须的。
为便于更好的实施本发明实施例的上述方案,下面还提供用于实施上述方案的相关装置。
请参阅图4所示,本发明实施例提供的一种用户设备400,可以包括:获取模块401、修正模块402、上行控制模块403,其中,
获取模块401,用于获取第一时间资源单位;
修正模块402,用于当从所述第一时间资源单位中获取到包括指示全双工传输的调度授权信息时,根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于所述全双工传输的第二上行传输功率;
上行控制模块403,用于按照所述第二上行传输功率在所述第一时间资源单位或第二时间资源单位上传输上行信号,所述第二时间资源单位为在所述第一时间资源单位之后的时间资源单位。
在本发明的一些实施例中,所述获取模块401,具体用于在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,以及在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,第三
时间资源单位和第四时间资源单位是两个不同的时间资源单位;若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;若在所述第三时间资源单位上未检测到所述上行调度信息,或所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
在本发明的一些实施例中,所述获取模块401,具体用于在所述第一时间资源单位上检测是否有对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,并在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,第四时间资源单位和第五时间资源单位是两个不同的时间资源单位;若在所述第一时间资源单位上检测到对应于所述第五时间资源单位的下行数据信息传输的上行反馈信息,且所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度信息;若在所述第一时间资源单位上未检测到所述上行反馈信息,或所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括全双工传输的信息。
在本发明的一些实施例中,所述上行调度信息为上行授权信息,所述下行调度信息为下行授权信息。
在本发明的一些实施例中,获取模块401,还用于所述修正模块根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,从所述第三时间资源单位中的所述上行调度信息中获取到所述用于半双工传输的第一上行传输功率,或,从所述第五时间资源单位中获取到所述用于
半双工传输第一上行传输功率;通过预定义的方式获取到所述功率偏移,或从所述第一时间资源单位中或所述第四时间资源单位中获取到所述功率偏移。
在本发明的一些实施例中,所述上行信号为所述第三时间资源单位中的上行调度信息指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行数据信息;或者,所述上行信号为所述第五时间资源单位中的下行数据信息对应的所述第一时间资源单位的上行反馈信息。
在本发明的一些实施例中,若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,所述上行控制模块403,还用于所述获取模块在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在上行调度信息之后,若所述下行调度信息中包括的功率偏移为一个预置的特殊定义的偏移值,根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位中的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
在本发明的一些实施例中,获取模块401,还用于通过预定义的方式得到所述功率偏移,或者从第一时间资源单位的下行调度信息中检测得到所述功率偏移,或者从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检测得到所述功率偏移,所述配置的多个时间资源单位为所有能检测到全双工传输的授权时间资源单位集合的子集;
所述修正模块402,还用于根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,若所述功率偏移由所述用户设备通过预定义的方式得到,通过从所述第一时间资源单位或提前于所述第一时间资源单位的一个时间资源单位的调度授权信息中检测到对应的触发信令时,触发所述功率偏移生效。
在本发明的一些实施例中,获取模块401,具体用于接收基站发送的广播信令或者专有信令;通过所述广播信令或者专有信令获取到所述功率偏移。
在本发明的一些实施例中,获取模块401,具体用于从所述调度授权信息中新增加的信息中检测到所述功率偏移;或者,从所述调度授权信息中重新定义的原有信息中检测到所述功率偏移。
在本发明的一些实施例中,获取模块401,具体用于在所述第一时间资源单位上检测是否存在上行调度信息和下行调度信息,若在所述第一时间资源单位上同时检测到所述上行调度信息和所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;若在所述第一时间资源单位上至多检测到所述上行调度信息和所述下行调度信息中的一个调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
在本发明的一些实施例中,所述修正模块402,具体用于通过如下方式计算用于所述全双工传输的第二上行传输功率:
PFD=PHD-Poffset;
其中,所述PFD为所述第二上行传输功率,所述PHD为所述第一上行传输功率,Poffset为所述用户设备获取到的功率偏移。
在本发明的一些实施例中,所述获取模块401,还用于所述修正模块402根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之后,获取与所述功率偏移匹配的调制与编码策略MCS偏移;
所述修正模块402,还用于根据所述MCS偏移对用于半双工传输的第一MCS索引进行修正,得到用于所述全双工传输的第二MCS索引。
在本发明的一些实施例中,所述获取模块401,具体用于通过广播信令或专有信令接收到所述MCS偏移;或者,通过预定义的功率偏移和MCS偏移的相互匹配关系获取到所述MCS偏移。
在本发明的一些实施例中,所述修正模块402,具体用于通过如下方式计算用于所述全双工传输的第二MCS索引:
MCSFD=MCSHD-MCSoffset;
其中,所述MCSFD为所述第二MCS索引,所述MCSHD为所述第一MCS索引,MCSoffset为所述MCS偏移。
在本发明的一些实施例中,所述时间资源单位,包括:子帧、帧、时隙、OFDM符号。
需要说明的是,上述装置各模块/单元之间的信息交互、执行过程等内容,由于与本发明方法实施例基于同一构思,其带来的技术效果与本发明方法实施例相同,具体内容可参见本发明前述所示的方法实施例中的叙述,此处不再赘述。
通过前述实施例对本发明的描述可知,用户设备首先获取第一时间资源单位,若从第一时间资源单位中获取到包括指示全双工传输的调度授权信息,用户设备接下来根据用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于全双工传输的第二上行传输功率,用户设备最后按照第二上行传输功率在第一时间资源单位或第二时间资源单位上传输上行信号,第二时间资源单位为在第一时间资源单位之后的时间资源单位。本发明实施例中用户设备可以通过预置的功率偏移确定出第二上行传输功率,因此上行信道的功率控制可以按照用户设备确定进行全双工传输时对第一上行传输功率进行修正得到的第二上行传输功率进行正确设置,因此可以实现精确的功率控制,从而可以避免自干扰,使得下行数据可以被正常检测,提高无线通信系统中全双工传输的系统增益,本发明提供的方法可以用于LTE系统和WiFi系统。
请参阅图5-a所示,本发明实施例提供的一种基站500,可以包括:全双工确定模块501、发送模块502、接收模块503,其中,
全双工确定模块501,用于确定是否在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果;
发送模块502,用于当所述确定结果为可以在所述第一时间资源单位中指示所述用户设备进行全双工传输时,在所述第一时间资源单位向所述用户设备发送包括指示所述用户设备进行全双工传输的调度授权信息;
接收模块503,用于接收所述用户设备在所述第一时间资源单位或者第二时间资源单位上传输的上行信号,所述第二时间资源单位为在所述第一时间资源单位之后的时间资源单位。
在本发明的一些实施例中,所述全双工确定模块501,具体用于若所述基站在提前于所述第一时间资源单位的第三时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输,第三时间资源单位和第四时间资源单位是两个不同的时间资源单位;若所述基站未在所述第三时间资源单位上传输所述上行调度信息,或所述基站确定
所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定不可以在第一时间资源单位中指示用户设备进行全双工传输。
在本发明的一些实施例中,所述全双工确定模块501,具体用于若所述基站在所述第一时间资源单位上传输对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输,第四时间资源单位和第五时间资源单位是两个不同的时间资源单位;若所述基站未在所述第一时间资源单位上传输所述上行反馈信息,或所述基站确定所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输。
在本发明的一些实施例中,所述下行调度信息,包括:一个预先配置的特殊定义的偏移值,由所述用户设备根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位上的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
在本发明的一些实施例中,发送模块502,还用于所述全双工确定模块501确定是否在第一时间资源单位中指示用户设备进行全双工传输之前,向所述用户设备发送广播信令或者专有信令,所述广播信令或者专有信令包括:所述基站配置的功率偏移。
在本发明的一些实施例中,请参阅如图5-b所示,所述基站500还包括:配置模块504,用于所述全双工确定模块501确定是否在第一时间资源单位中指示用户设备进行全双工传输之前,在第一时间资源单位的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,所述基站在第一时间资源单位的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度
授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移。
在本发明的一些实施例中,所述时间资源单位,包括:子帧、帧、时隙、OFDM符号。
通过前述实施例对本发明的描述可知,基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果,若确定结果为可以在第一时间资源单位中指示用户设备进行全双工传输,基站在第一时间资源单位向用户设备发送包括指示用户设备进行全双工传输的调度授权信息,基站接收用户设备在获取到调度授权信息指示全双工传输之后按照对用于半双工传输的第一上行传输功率修正后得到的第二上行传输功率在第一时间资源单位或者第二时间资源单位上传输的上行信号,第二时间资源单位为在时间上处于第一时间资源单位之后的时间资源单位。本发明实施例中用户设备可以通过预置的功率偏移确定出第二上行传输功率,因此上行信道的功率控制可以按照用户设备确定进行全双工传输时对第一上行传输功率进行修正得到的第二上行传输功率进行正确设置,因此可以实现精确的功率控制,从而可以避免自干扰,使得下行数据可以被正常检测,提高无线通信系统中全双工传输的系统增益,本发明提供的方法可以用于LTE系统和WiFi系统。
本发明实施例还提供一种计算机存储介质,其中,该计算机存储介质存储有程序,该程序执行包括上述方法实施例中记载的部分或全部步骤。
接下来介绍本发明实施例提供的另一种用户设备,请参阅图6所示,用户设备600包括:
输入装置601、输出装置602、处理器603和存储器604(其中用户设备600中的处理器603的数量可以一个或多个,图6中以一个处理器为例)。在本发明的一些实施例中,输入装置601、输出装置602、处理器603和存储器604可通过总线或其它方式连接,其中,图6中以通过总线连接为例。
其中,处理器603,用于执行前述实施例中用户设备侧执行的方法。具体的,处理器603,用于执行如下步骤:
获取第一时间资源单位;
若从所述第一时间资源单位中获取到包括指示全双工传输的调度授权信息,根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于所述全双工传输的第二上行传输功率;
按照所述第二上行传输功率在所述第一时间资源单位或第二时间资源单位上传输上行信号,所述第二时间资源单位为在时间上处于所述第一时间资源单位之后的时间资源单位。
在本发明的一些实施例中,处理器603,具体用于执行如下步骤:
在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,以及在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,第三时间资源单位和第四时间资源单位是两个不同的时间资源单位;
若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;
若在所述第三时间资源单位上未检测到所述上行调度信息,或所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
在本发明的一些实施例中,处理器603,具体用于执行如下步骤:
在所述第一时间资源单位上检测是否有对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,并在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,第四时间资源单位和第五时间资源单位是两个不同的时间资源单位;
若在所述第一时间资源单位上检测到对应于所述第五时间资源单位的下
行数据信息传输的上行反馈信息,且所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度信息;
若在所述第一时间资源单位上未检测到所述上行反馈信息,或所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括全双工传输的信息。
在本发明的一些实施例中,存储器604中存储的所述上行调度信息为上行授权信息,所述下行调度信息为下行授权信息。
在本发明的一些实施例中,处理器603,还用于执行如下步骤:根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,从所述第三时间资源单位中的所述上行调度信息中获取到所述用于半双工传输的第一上行传输功率,或,从所述第五时间资源单位中获取到所述用于半双工传输第一上行传输功率;通过预定义的方式获取到所述功率偏移,或从所述第一时间资源单位中或所述第四时间资源单位中获取到所述功率偏移。
在本发明的一些实施例中,存储器604中存储的所述上行信号为所述第三时间资源单位中的上行调度信息指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行数据信息;或者,所述上行信号为所述第五时间资源单位中的下行数据信息对应的所述第一时间资源单位的上行反馈信息。
在本发明的一些实施例中,处理器603,还用于执行如下步骤:若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息之后,若所述下行调度信息中包括的功率偏移为一个预置的特殊定义的偏移值,根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位中的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传
输。
在本发明的一些实施例中,存储器604中存储的所述功率偏移由所述用户设备通过预定义的方式得到,或者所述功率偏移由所述用户设备从第一时间资源单位的下行调度信息中检测得到,或者所述功率偏移由所述用户设备从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检测得到,所述配置的多个时间资源单位为所有能检测到全双工传输的授权时间资源单位集合的子集;
在本发明的一些实施例中,处理器603,还用于执行如下步骤:根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,若所述功率偏移由所述用户设备通过预定义的方式得到,通过从所述第一时间资源单位或提前于所述第一时间资源单位的一个时间资源单位的调度授权信息中检测到对应的触发信令时,触发所述功率偏移生效。
在本发明的一些实施例中,处理器603,还用于执行如下步骤:接收基站发送的广播信令或者专有信令;通过所述广播信令或者专有信令获取到所述功率偏移。
进一步的,处理器603,具体用于执行如下步骤:从所述调度授权信息中新增加的信息中检测到所述功率偏移;或者,从所述调度授权信息中重新定义的原有信息中检测到所述功率偏移。
在本发明的一些实施例中,处理器603,还用于执行如下步骤:在所述第一时间资源单位上检测是否存在上行调度信息和下行调度信息,若在所述第一时间资源单位上同时检测到所述上行调度信息和所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;若在所述第一时间资源单位上至多检测到所述上行调度信息和所述下行调度信息中的一个调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
在本发明的一些实施例中,处理器603,具体用于执行如下步骤:通过如下方式计算用于所述全双工传输的第二上行传输功率:
PFD=PHD-Poffset;
其中,所述PFD为所述第二上行传输功率,所述PHD为所述第一上行传输功率,Poffset为所述用户设备获取到的功率偏移。
在本发明的一些实施例中,处理器603,还用于执行如下步骤:根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之后,获取与所述功率偏移匹配的调制与编码策略MCS偏移;根据所述MCS偏移对用于半双工传输的第一MCS进行修正,得到用于所述全双工传输的第二MCS。
在本发明的一些实施例中,处理器603,具体用于执行如下步骤:
通过广播信令或者专有信令接收到所述MCS偏移;或者,通过预定义的功率偏移和MCS偏移的相互匹配关系获取到所述MCS偏移。
在本发明的一些实施例中,处理器603,具体用于执行如下步骤:通过如下方式计算用于所述全双工传输的第二MCS索引:
MCSFD=MCSHD-MCSoffset;
其中,所述MCSFD为所述第二MCS索引,所述MCSHD为所述第一MCS索引,MCSoffset为所述MCS偏移。
在本发明的一些实施例中,存储器60中存储的所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
通过前述实施例对本发明的描述可知,用户设备首先获取第一时间资源单位,若从第一时间资源单位中获取到包括指示全双工传输的调度授权信息,用户设备接下来根据用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于全双工传输的第二上行传输功率,用户设备最后按照第二上行传输功率在第一时间资源单位或第二时间资源单位上传输上行信号,第二时间资源单位为在第一时间资源单位之后的时间资源单位。本发明实施例中用户设备可以通过预置的功率偏移确定出第二上行传输功率,因此上行信道的功率控制可以按照用户设备确定进行全双工传输时对第一上行传输功率进行修正得到的第二上行传输功率进行正确设置,因此可以实现精确的功率控制,从而可以避免自干扰,使得下行数据可以被正常检测,提高无线通信系统中全双工传输的系统增益,本发明提供的方法可以用于LTE系统和WiFi系统。
接下来介绍本发明实施例提供的另一种基站,请参阅图7所示,基站700包括:
输入装置701、输出装置702、处理器703和存储器704(其中基站700中
的处理器703的数量可以一个或多个,图7中以一个处理器为例)。在本发明的一些实施例中,输入装置701、输出装置702、处理器703和存储器704可通过总线或其它方式连接,其中,图7中以通过总线连接为例。
其中,处理器703,用于执行前述实施例中基站侧执行的方法。具体的,处理器703,用于执行如下步骤:
确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果;
若所述确定结果为可以在所述第一时间资源单位中指示所述用户设备进行全双工传输,在所述第一时间资源单位向所述用户设备发送包括指示所述用户设备进行全双工传输的调度授权信息;
接收所述用户设备在获取到所述调度授权信息指示全双工传输之后按照对用于半双工传输的第一上行传输功率修正后得到的第二上行传输功率在所述第一时间资源单位或者第二时间资源单位上传输的上行信号,所述第二时间资源单位为在时间上处于所述第一时间资源单位之后的时间资源单位。
在本发明的一些实施例中,处理器703,具体用于执行如下步骤:
若所述基站在提前于所述第一时间资源单位的第三时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输,第三时间资源单位和第四时间资源单位是两个不同的时间资源单位;
若所述基站未在所述第三时间资源单位上传输所述上行调度信息,或所述基站确定所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定不可以在第一时间资源单位中指示用户设备进行全双工传输。
在本发明的一些实施例中,处理器703,具体用于执行如下步骤:
若所述基站在所述第一时间资源单位上传输对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,且所述基
站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输,第四时间资源单位和第五时间资源单位是两个不同的时间资源单位;
若所述基站未在所述第一时间资源单位上传输所述上行反馈信息,或所述基站确定所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输。
在本发明的一些实施例中,存储器704中存储的所述下行调度信息,包括:一个预先配置的特殊定义的偏移值,由所述用户设备根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位上的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
在本发明的一些实施例中,处理器703,还用于执行如下步骤:确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,向所述用户设备发送广播信令或者专有信令,所述广播信令或者专有信令包括:所述基站配置的功率偏移和/或MCS偏移。
在本发明的一些实施例中,处理器703,还用于执行如下步骤:确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,在第一时间资源单位的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,在第一时间资源单位的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移,或,在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移。
在本发明的一些实施例中,存储器704中存储的所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
通过前述实施例对本发明的描述可知,基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果,若确定结果为可以在第一时间资源单位中指示用户设备进行全双工传输,基站在第一时间资源单位向
用户设备发送包括指示用户设备进行全双工传输的调度授权信息,基站接收用户设备在获取到调度授权信息指示全双工传输之后按照对用于半双工传输的第一上行传输功率修正后得到的第二上行传输功率在第一时间资源单位或者第二时间资源单位上传输的上行信号,第二时间资源单位为在时间上处于第一时间资源单位之后的时间资源单位。本发明实施例中用户设备可以通过预置的功率偏移确定出第二上行传输功率,因此上行信道的功率控制可以按照用户设备确定进行全双工传输时对第一上行传输功率进行修正得到的第二上行传输功率进行正确设置,因此可以实现精确的功率控制,从而可以避免自干扰,使得下行数据可以被正常检测,提高无线通信系统中全双工传输的系统增益,本发明提供的方法可以用于LTE系统和WiFi系统。
另外需说明的是,以上所描述的装置实施例仅仅是示意性的,其中所述作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是或者也可以不是物理单元,即可以位于一个地方,或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或者全部模块来实现本实施例方案的目的。另外,本发明提供的装置实施例附图中,模块之间的连接关系表示它们之间具有通信连接,具体可以实现为一条或多条通信总线或信号线。本领域普通技术人员在不付出创造性劳动的情况下,即可以理解并实施。
通过以上的实施方式的描述,所属领域的技术人员可以清楚地了解到本发明可借助软件加必需的通用硬件的方式来实现,当然也可以通过专用硬件包括专用集成电路、专用CPU、专用存储器、专用元器件等来实现。一般情况下,凡由计算机程序完成的功能都可以很容易地用相应的硬件来实现,而且,用来实现同一功能的具体硬件结构也可以是多种多样的,例如模拟电路、数字电路或专用电路等。但是,对本发明而言更多情况下软件程序实现是更佳的实施方式。基于这样的理解,本发明的技术方案本质上或者说对现有技术做出贡献的部分可以以软件产品的形式体现出来,该计算机软件产品存储在可读取的存储介质中,如计算机的软盘、U盘、移动硬盘、只读存储器(ROM,Read-Only Memory)、随机存取存储器(RAM,Random Access Memory)、磁碟或者光盘等,包括若干指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)执行本发明各个实施例所述的方法。
综上所述,以上实施例仅用以说明本发明的技术方案,而非对其限制;尽
管参照上述实施例对本发明进行了详细的说明,本领域的普通技术人员应当理解:其依然可以对上述各实施例所记载的技术方案进行修改,或者对其中部分技术特征进行等同替换;而这些修改或者替换,并不使相应技术方案的本质脱离本发明各实施例技术方案的精神和范围。
Claims (46)
- 一种全双工传输的控制方法,其特征在于,包括:用户设备获取第一时间资源单位;若从所述第一时间资源单位中获取到包括指示全双工传输的调度授权信息,所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于所述全双工传输的第二上行传输功率;所述用户设备按照所述第二上行传输功率在所述第一时间资源单位或第二时间资源单位上传输上行信号,所述第二时间资源单位为在时间上处于所述第一时间资源单位之后的时间资源单位。
- 根据权利要求1所述的方法,其特征在于,所述用户设备获取第一时间资源单位,包括:所述用户设备在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,以及在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,所述第三时间资源单位和所述第四时间资源单位是两个不同的时间资源单位;若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;若在所述第三时间资源单位上未检测到所述上行调度信息,或所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
- 根据权利要求1所述的方法,其特征在于,所述用户设备获取第一时间资源单位,包括:所述用户设备在所述第一时间资源单位上检测是否有对应于提前于所述 第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,并在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,所述第四时间资源单位和所述第五时间资源单位是两个不同的时间资源单位;若在所述第一时间资源单位上检测到对应于所述第五时间资源单位的下行数据信息传输的上行反馈信息,且所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度信息;若在所述第一时间资源单位上未检测到所述上行反馈信息,或所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括全双工传输的信息。
- 根据权利要求2或3所述的方法,其特征在于,所述上行调度信息为上行授权信息,所述下行调度信息为下行授权信息。
- 根据权利要求2或3所述的方法,其特征在于,所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,所述方法还包括:所述用户设备从所述第三时间资源单位中的所述上行调度信息中获取到所述用于半双工传输的第一上行传输功率,或,所述用户设备从所述第五时间资源单位中获取到所述用于半双工传输第一上行传输功率;所述用户设备通过预定义的方式获取到所述功率偏移,或从所述第一时间资源单位中或所述第四时间资源单位中获取到所述功率偏移。
- 根据权利要求2至5中任一项所述的方法,其特征在于,所述上行信号为所述第三时间资源单位中的上行调度信息指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行数据信息;或者,所述上行信号为所述第五时间资源单位中的下行数据信息对应的所述第一时间资源单位的上行反馈信息。
- 根据权利要求2所述的方法,其特征在于,若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,所述用户设备在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息之后,所述方法还包括:若所述下行调度信息中包括的功率偏移为一个预置的特殊定义的偏移值,所述用户设备根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位中的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
- 根据权利要求1所述的方法,其特征在于,所述功率偏移由所述用户设备通过预定义的方式得到,或者所述功率偏移由所述用户设备从第一时间资源单位的下行调度信息中检测得到,或者所述功率偏移由所述用户设备从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检测得到,所述配置的多个时间资源单位为所有能检测到全双工传输的授权时间资源单位集合的子集;所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,所述方法还包括:若所述功率偏移由所述用户设备通过预定义的方式得到,所述用户设备通过从所述第一时间资源单位或提前于所述第一时间资源单位的一个时间资源单位的调度授权信息中检测到对应的触发信令时,触发所述功率偏移生效。
- 根据权利要求8所述的方法,其特征在于,所述功率偏移由所述用户设备通过预定义的方式得到,包括:所述用户设备接收基站发送的广播信令或者专有信令;所述用户设备通过所述广播信令或者专有信令获取到所述功率偏移。
- 根据权利要求8所述的方法,其特征在于,所述功率偏移由所述用户设备从第一时间资源单位的调度授权信息中检测得到,或者所述功率偏移由所述用户设备从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检测得到,包括:所述用户设备从所述调度授权信息中新增加的信息中检测到所述功率偏移;或者,所述用户设备从所述调度授权信息中重新定义的原有信息中检测到所述功率偏移。
- 根据权利要求1所述的方法,其特征在于,所述用户设备获取第一时间资源单位,包括:所述用户设备在所述第一时间资源单位上检测是否存在上行调度信息和下行调度信息,若在所述第一时间资源单位上同时检测到所述上行调度信息和所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;若在所述第一时间资源单位上至多检测到所述上行调度信息和所述下行调度信息中的一个调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
- 根据权利要求1所述的方法,其特征在于,所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于所述全双工传输的第二上行传输功率,包括:所述用户设备通过如下方式计算用于所述全双工传输的第二上行传输功率:PFD=PHD-Poffset;其中,所述PFD为所述第二上行传输功率,所述PHD为所述第一上行传输功率,Poffset为所述用户设备获取到的功率偏移。
- 根据权利要求1所述的方法,其特征在于,所述用户设备根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之后,所述方法还包括:所述用户设备获取与所述功率偏移匹配的调制与编码策略MCS偏移;所述用户设备根据所述MCS偏移对用于半双工传输的第一MCS进行修正,得到用于所述全双工传输的第二MCS。
- 根据权利要求13所述的方法,其特征在于,所述用户设备获取与所述功率偏移匹配的调制与编码策略MCS偏移,包括:所述用户设备通过广播信令或者专有信令接收到所述MCS偏移;或者,所述用户设备通过预定义的功率偏移和MCS偏移的相互匹配关系 获取到所述MCS偏移。
- 根据权利要求13所述的方法,其特征在于,所述用户设备根据所述MCS偏移对用于半双工传输的第一MCS索引进行修正,得到用于所述全双工传输的第二MCS索引,包括:所述用户设备通过如下方式计算用于所述全双工传输的第二MCS索引:MCSFD=MCSHD-MCSoffset;其中,所述MCSFD为所述第二MCS索引,所述MCSHD为所述第一MCS索引,MCSoffset为所述MCS偏移。
- 根据权利要求1所述的方法,其特征在于,所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
- 一种全双工传输的控制方法,其特征在于,包括:基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果;若所述确定结果为可以在所述第一时间资源单位中指示所述用户设备进行全双工传输,所述基站在所述第一时间资源单位向所述用户设备发送包括指示所述用户设备进行全双工传输的调度授权信息;所述基站接收所述用户设备在获取到所述调度授权信息指示全双工传输之后按照对用于半双工传输的第一上行传输功率修正后得到的第二上行传输功率在所述第一时间资源单位或者第二时间资源单位上传输的上行信号,所述第二时间资源单位为在时间上处于所述第一时间资源单位之后的时间资源单位。
- 根据权利要求17所述的方法,其特征在于,所述基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,包括:若所述基站在提前于所述第一时间资源单位的第三时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则所述基站确定可以在第一时间资源单位中指示用户设备进行全双工传输,所述第三时间资源单位和所述第四时间资源单位是两个不同的时间资源单位;若所述基站未在所述第三时间资源单位上传输所述上行调度信息,或所述基站确定所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则所述基站确定不可以在第一时间资源单位中指示用户设备进行全双工传输。
- 根据权利要求17所示的方法,其特征在于,所述基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,包括:若所述基站在所述第一时间资源单位上传输对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则所述基站确定可以在第一时间资源单位中指示用户设备进行全双工传输,所述第四时间资源单位和所述第五时间资源单位是两个不同的时间资源单位;若所述基站未在所述第一时间资源单位上传输所述上行反馈信息,或所述基站确定所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则所述基站确定可以在第一时间资源单位中指示用户设备进行全双工传输。
- 根据权利要求18所述的方法,其特征在于,所述下行调度信息,包括:一个预先配置的特殊定义的偏移值,由所述用户设备根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位上的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
- 根据权利要求17所述的方法,其特征在于,所述基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,所述方法还包括:所述基站向所述用户设备发送广播信令或者专有信令,所述广播信令或者专有信令包括:所述基站配置的功率偏移和/或MCS偏移。
- 根据权利要求17所述的方法,其特征在于,所述基站确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,所述方法还包括:所述基站在第一时间资源单位的调度授权信息中新增加信息用于携带所 述功率偏移和/或MCS偏移,或,所述基站在第一时间资源单位的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移。
- 根据权利要求17所述的方法,其特征在于,所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
- 一种用户设备,其特征在于,包括:获取模块,用于获取第一时间资源单位;修正模块,用于当从所述第一时间资源单位中获取到包括指示全双工传输的调度授权信息时,根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正,得到用于所述全双工传输的第二上行传输功率;上行控制模块,用于按照所述第二上行传输功率在所述第一时间资源单位或第二时间资源单位上传输上行信号,所述第二时间资源单位为在所述第一时间资源单位之后的时间资源单位。
- 根据权利要求24所述的用户设备,其特征在于,所述获取模块,具体用于在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,以及在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,所述第三时间资源单位和所述第四时间资源单位是两个不同的时间资源单位;若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信息;若在所述第三时间资源单位上未检测到所述上行调度信息,或所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括指 示全双工传输的调度授权信息。
- 根据权利要求24所述的用户设备,其特征在于,所述获取模块,具体用于在所述第一时间资源单位上检测是否有对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,并在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,所述第四时间资源单位和所述第五时间资源单位是两个不同的时间资源单位;若在所述第一时间资源单位上检测到对应于所述第五时间资源单位的下行数据信息传输的上行反馈信息,且所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度信息;若在所述第一时间资源单位上未检测到所述上行反馈信息,或所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定所述第一时间资源单位中没有包括全双工传输的信息。
- 根据权利要求25或26所述的方法,其特征在于,所述上行调度信息为上行授权信息,所述下行调度信息为下行授权信息。
- 根据权利要求25或26所述的方法,其特征在于,所述获取模块,还用于所述修正模块根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,从所述第三时间资源单位中的所述上行调度信息中获取到所述用于半双工传输的第一上行传输功率,或,从所述第五时间资源单位中获取到所述用于半双工传输第一上行传输功率;通过预定义的方式获取到所述功率偏移,或从所述第一时间资源单位中或所述第四时间资源单位中获取到所述功率偏移。
- 根据权利要求25至28中任一项所述的用户设备,其特征在于,所述上行信号为所述第三时间资源单位中的上行调度信息指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行数据信息;或者,所述上行信号为所述第五时间资源单位中的下行数据信息对应的所述第一时间资源单位的上行反馈信息。
- 根据权利要求25所述的用户设备,其特征在于,若在所述第三时间资源单位上检测到所述上行调度信息,且所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数满足预置的差值,且在所述第一时间资源单位或所述第四时间资源单位上检测到所述下行调度信息,所述上行控制模块,还用于所述获取模块在提前于所述第一时间资源单位的第三时间资源单位上检测是否存在指示在第一时间资源单位或第二时间资源单位上进行传输的上行调度信息之后,若所述下行调度信息中包括的功率偏移为一个预置的特殊定义的偏移值,根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位中的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
- 根据权利要求24所述的用户设备,其特征在于,所述获取模块,还用于通过预定义的方式得到所述功率偏移,或者从第一时间资源单位的下行调度信息中检测得到所述功率偏移,或者从配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中检测得到所述功率偏移,所述配置的多个时间资源单位为所有能检测到全双工传输的授权时间资源单位集合的子集;所述修正模块,还用于根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之前,若所述功率偏移由所述用户设备通过预定义的方式得到,通过从所述第一时间资源单位或提前于所述第一时间资源单位的一个时间资源单位的调度授权信息中检测到对应的触发信令时,触发所述功率偏移生效。
- 根据权利要求31所述的用户设备,其特征在于,所述获取模块,具体用于接收基站发送的广播信令或者专有信令;通过所述广播信令或者专有信令获取到所述功率偏移。
- 根据权利要求31所述的用户设备,其特征在于,所述获取模块,具体用于从所述调度授权信息中新增加的信息中检测到所述功率偏移;或者,从所述调度授权信息中重新定义的原有信息中检测到所述功率偏移。
- 根据权利要求24所述的用户设备,其特征在于,所述获取模块,具体用于在所述第一时间资源单位上检测是否存在上行调度信息和下行调度信息,若在所述第一时间资源单位上同时检测到所述上行调度信息和所述下行调度信息,则确定所述第一时间资源单位中包括指示全双工传输的调度授权信 息;若在所述第一时间资源单位上至多检测到所述上行调度信息和所述下行调度信息中的一个调度信息,则确定所述第一时间资源单位中没有包括指示全双工传输的调度授权信息。
- 根据权利要求24所述的用户设备,其特征在于,所述修正模块,具体用于通过如下方式计算用于所述全双工传输的第二上行传输功率:PFD=PHD-Poffset;其中,所述PFD为所述第二上行传输功率,所述PHD为所述第一上行传输功率,Poffset为所述用户设备获取到的功率偏移。
- 根据权利要求24所述的用户设备,其特征在于,所述获取模块,还用于所述修正模块根据所述用户设备获取到的功率偏移对用于半双工传输的第一上行传输功率进行修正之后,获取与所述功率偏移匹配的调制与编码策略MCS偏移;所述修正模块,还用于根据所述MCS偏移对用于半双工传输的第一MCS索引进行修正,得到用于所述全双工传输的第二MCS索引。
- 根据权利要求36所述的用户设备,其特征在于,所述获取模块,具体用于通过广播信令或者专有信令接收到所述MCS偏移;或者,通过预定义的功率偏移和MCS偏移的相互匹配关系获取到所述MCS偏移。
- 根据权利要求36所述的用户设备,其特征在于,所述修正模块,具体用于通过如下方式计算用于所述全双工传输的第二MCS索引:MCSFD=MCSHD-MCSoffset;其中,所述MCSFD为所述第二MCS索引,所述MCSHD为所述第一MCS索引,MCSoffset为所述MCS偏移。
- 根据权利要求24所述的用户设备,其特征在于,所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
- 一种基站,其特征在于,包括:全双工确定模块,用于确定是否可以在第一时间资源单位中指示用户设备进行全双工传输,得到确定结果;发送模块,用于当所述确定结果为可以在所述第一时间资源单位中指示所述用户设备进行全双工传输时,在所述第一时间资源单位向所述用户设备发送包括指示所述用户设备进行全双工传输的调度授权信息;接收模块,用于接收所述用户设备在获取到所述调度授权信息指示全双工传输之后按照对用于半双工传输的第一上行传输功率修正后得到的第二上行传输功率在所述第一时间资源单位或者第二时间资源单位上传输的上行信号,所述第二时间资源单位为在时间上处于所述第一时间资源单位之后的时间资源单位。
- 根据权利要求40所述的基站,其特征在于,所述全双工确定模块,具体用于若所述基站在提前于所述第一时间资源单位的第三时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的上行调度信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在所述第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输,所述第三时间资源单位和所述第四时间资源单位是两个不同的时间资源单位;若所述基站未在所述第三时间资源单位上传输所述上行调度信息,或所述基站确定所述第一时间资源单位和所述第三时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定不可以在第一时间资源单位中指示用户设备进行全双工传输。
- 根据权利要求40所示的基站,其特征在于,所述全双工确定模块,具体用于若所述基站在所述第一时间资源单位上传输对应于提前于所述第一时间资源单位的第五时间资源单位的下行数据信息传输的上行反馈信息,且所述基站在所述第一时间资源单位或提前于所述第一时间资源单位的第四时间资源单位上传输指示在第一时间资源单位或第二时间资源单位上进行传输的下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输,所述第四时间资源单位和所述第五时间资源单位是两个不同的时间资源单位;若所述基站未在所述第一时间资源单位上传输所述上行反馈信息,或所述基站确定所述第一时间资源单位和所述第五时间资源单位之间相差的时间资源单位个数不满足预置的差值,或所述基站在所述第一时间资源单位或所述第四时间资源单位上未检测到所述下行调度信息,则确定可以在第一时间资源单位中指示用户设备进行全双工传输。
- 根据权利要求41所述的基站,其特征在于,所述下行调度信息,包 括:一个预先配置的特殊定义的偏移值,由所述用户设备根据所述下行调度信息中包括的功率偏移取消所述第三时间资源单位上的上行调度信息指示的在所述第一时间资源单位或第二时间资源单位上进行的上行数据信息传输。
- 根据权利要求40所述的基站,其特征在于,所述发送模块,还用于所述全双工确定模块确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,向所述用户设备发送广播信令或者专有信令,所述广播信令或者专有信令包括:所述基站配置的功率偏移和/或MCS偏移。
- 根据权利要求40所述的基站,其特征在于,所述基站还包括:配置模块,用于所述全双工确定模块确定是否可以在第一时间资源单位中指示用户设备进行全双工传输之前,在第一时间资源单位的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,所述基站在第一时间资源单位的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中新增加信息用于携带所述功率偏移和/或MCS偏移,或,所述基站在配置的多个时间资源单位中的每个时间资源单位中的调度授权信息中重新定义的原有信息中携带功率偏移和/或MCS偏移。
- 根据权利要求40所述的基站,其特征在于,所述时间资源单位,包括:子帧、帧、时隙、正交频分复用OFDM符号。
Priority Applications (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US15/750,746 US10779241B2 (en) | 2015-08-07 | 2015-08-07 | Full-duplex transmission control method, user equipment, and base station |
EP15900640.2A EP3322118B1 (en) | 2015-08-07 | 2015-08-07 | Control method for full-duplex transmission, and user equipment and base station |
PCT/CN2015/086363 WO2017024441A1 (zh) | 2015-08-07 | 2015-08-07 | 一种全双工传输的控制方法和用户设备以及基站 |
CN201580072497.0A CN107113156B (zh) | 2015-08-07 | 2015-08-07 | 一种全双工传输的控制方法和用户设备以及基站 |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PCT/CN2015/086363 WO2017024441A1 (zh) | 2015-08-07 | 2015-08-07 | 一种全双工传输的控制方法和用户设备以及基站 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2017024441A1 true WO2017024441A1 (zh) | 2017-02-16 |
Family
ID=57982926
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/CN2015/086363 WO2017024441A1 (zh) | 2015-08-07 | 2015-08-07 | 一种全双工传输的控制方法和用户设备以及基站 |
Country Status (4)
Country | Link |
---|---|
US (1) | US10779241B2 (zh) |
EP (1) | EP3322118B1 (zh) |
CN (1) | CN107113156B (zh) |
WO (1) | WO2017024441A1 (zh) |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20190068355A1 (en) * | 2016-05-11 | 2019-02-28 | Fujitsu Limited | Radio communication system, base station, and radio terminal |
WO2019125374A1 (en) * | 2017-12-18 | 2019-06-27 | Intel IP Corporation | Methods and apparatus to mitigate coexistence interference in a wireless network |
WO2020207143A1 (en) * | 2019-04-06 | 2020-10-15 | Qualcomm Incorporated | Communicating multiple transport formats in a slot with full-duplex |
WO2023088158A1 (zh) * | 2021-11-22 | 2023-05-25 | 华为技术有限公司 | 一种功率确定方法及通信装置 |
Families Citing this family (17)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US10985862B2 (en) * | 2016-08-30 | 2021-04-20 | Mediatek Inc. | Wireless communicating method and associated electronic device |
CN108882384B (zh) * | 2017-05-12 | 2022-08-02 | 华硕电脑股份有限公司 | 无线通信系统中改善调度的方法和设备 |
CN111213411B (zh) * | 2017-10-12 | 2024-03-26 | Oppo广东移动通信有限公司 | 传输数据的方法、终端设备和网络设备 |
WO2020043932A1 (en) * | 2018-08-29 | 2020-03-05 | Nokia Solutions And Networks Oy | Scheduling downlink data and uplink data based on received resource requirements |
US12096374B2 (en) * | 2019-04-06 | 2024-09-17 | Qualcomm Incorporated | Physical uplink shared channel transmit power configuration |
WO2020237612A1 (en) * | 2019-05-31 | 2020-12-03 | Qualcomm Incorporated | Csi report configuration for full-duplex communications |
KR20210071470A (ko) * | 2019-12-06 | 2021-06-16 | 삼성전자주식회사 | 무선 통신 시스템에서 신호를 송수신하는 방법 및 장치 |
US11582017B2 (en) * | 2020-02-28 | 2023-02-14 | Qualcomm Incorporated | Energy per resource element determination for sub-band full-duplex communication |
US20220104245A1 (en) * | 2020-09-28 | 2022-03-31 | Qualcomm Incorporated | Control channel designs for dynamic full duplex enabling |
US11895652B2 (en) * | 2020-12-04 | 2024-02-06 | Qualcomm Incorporated | Beam adjustment/cancellation rules for non-compatible UL/DL beams |
US11949504B2 (en) * | 2021-04-20 | 2024-04-02 | Qualcomm Incorporated | Techniques for indicating duplex mode capability |
US20240129101A1 (en) * | 2021-05-12 | 2024-04-18 | Qualcomm Incorporated | Rate matching for full duplex communications |
US20230010875A1 (en) * | 2021-07-07 | 2023-01-12 | Qualcomm Incorporated | Parameter switch per semi-persistent scheduling and configured grant occasion |
US11876755B2 (en) * | 2021-07-19 | 2024-01-16 | Qualcomm Incorporated | Activation and periodicity indications for full duplex and half duplex transmissions of periodic communications |
US11871405B2 (en) * | 2021-07-27 | 2024-01-09 | Qualcomm Incorporated | Scheduling parameters for unequal downlink and uplink transmissions |
US12052668B2 (en) * | 2021-09-20 | 2024-07-30 | Qualcomm Incorporated | Techniques for uplink power control |
GB2619500A (en) * | 2022-05-31 | 2023-12-13 | Nec Corp | Communication system |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2012095683A1 (en) * | 2011-01-14 | 2012-07-19 | Nokia Corporation | Method and apparatus for implementing a dynamically switching duplex mode |
CN103109490A (zh) * | 2010-10-04 | 2013-05-15 | 诺基亚公司 | 用于避免在用户设备中的多个无线电之间的干扰的方法和装置 |
WO2015077987A1 (zh) * | 2013-11-29 | 2015-06-04 | 华为技术有限公司 | 传输模式的选择、配置方法、基站及用户设备 |
Family Cites Families (14)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101669382B (zh) * | 2007-03-01 | 2014-02-12 | 株式会社Ntt都科摩 | 基站装置和通信控制方法 |
CN103493556B (zh) | 2011-02-21 | 2020-02-14 | 安华高科技股份有限公司 | 用于时分双工的动态上行链路/下行链路配置 |
WO2012139272A1 (en) | 2011-04-11 | 2012-10-18 | Renesas Mobile Corporation | Method and apparatus for providing for discontinuous reception via cells having different time division duplex subframe configurations |
WO2012145922A1 (en) | 2011-04-29 | 2012-11-01 | Renesas Mobile Corporation | Method and apparatus for rebalancing the sizes of the downlink (dl) association sets for component carriers having different time division duplex subframe configurations |
WO2012167431A1 (en) | 2011-06-09 | 2012-12-13 | Renesas Mobile Corporation | Interference control in time division duplex communication |
US20140348040A1 (en) | 2011-12-21 | 2014-11-27 | Broadcom Corporation | Semi-Full-Duplex Single-Carrier Transmission Technique |
GB2498561A (en) | 2012-01-20 | 2013-07-24 | Renesas Mobile Corp | Allocating part of the frequency domain for full duplex communication and part for half duplex communication between a Node B and UEs |
GB2499259A (en) * | 2012-02-13 | 2013-08-14 | Renesas Mobile Corp | Scheduling a User Device for half-duplex or full-duplex operation based on the self-interference cancellation capability of the device |
WO2013134930A1 (en) | 2012-03-13 | 2013-09-19 | Renesas Mobile Corporation | Method and apparatus for reducing radio interferences |
EP2938147A4 (en) | 2013-01-18 | 2015-12-30 | Huawei Tech Co Ltd | METHOD AND DEVICE FOR TRANSMITTING INFORMATION |
CN110224797B (zh) * | 2013-08-09 | 2022-06-07 | 太阳专利信托公司 | 用于在通信系统中与基站通信的移动站、方法和存储介质 |
JP6721506B2 (ja) * | 2013-12-18 | 2020-07-15 | アイディーエーシー ホールディングス インコーポレイテッド | 全二重無線システムにおける干渉管理のための方法、装置、およびシステム |
KR102287100B1 (ko) | 2013-12-24 | 2021-08-06 | 엘지전자 주식회사 | Fdr 통신 환경에서 자기 간섭을 완화하는 방법 |
US20180184409A1 (en) * | 2016-12-23 | 2018-06-28 | Intel Corporation | Methods of triggering simultaneous multi-user uplink and downlink ofdma transmissions for full- duplex communications |
-
2015
- 2015-08-07 WO PCT/CN2015/086363 patent/WO2017024441A1/zh active Application Filing
- 2015-08-07 US US15/750,746 patent/US10779241B2/en active Active
- 2015-08-07 EP EP15900640.2A patent/EP3322118B1/en active Active
- 2015-08-07 CN CN201580072497.0A patent/CN107113156B/zh active Active
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103109490A (zh) * | 2010-10-04 | 2013-05-15 | 诺基亚公司 | 用于避免在用户设备中的多个无线电之间的干扰的方法和装置 |
WO2012095683A1 (en) * | 2011-01-14 | 2012-07-19 | Nokia Corporation | Method and apparatus for implementing a dynamically switching duplex mode |
WO2015077987A1 (zh) * | 2013-11-29 | 2015-06-04 | 华为技术有限公司 | 传输模式的选择、配置方法、基站及用户设备 |
Non-Patent Citations (2)
Title |
---|
"3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA); Physical Channels and Modulation (Release 9", 3GPP TS 36. 211 V9. 1. 0, 31 March 2010 (2010-03-31), XP055364571 * |
See also references of EP3322118A4 * |
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20190068355A1 (en) * | 2016-05-11 | 2019-02-28 | Fujitsu Limited | Radio communication system, base station, and radio terminal |
WO2019125374A1 (en) * | 2017-12-18 | 2019-06-27 | Intel IP Corporation | Methods and apparatus to mitigate coexistence interference in a wireless network |
US11272516B2 (en) | 2017-12-18 | 2022-03-08 | Intel Corporation | Methods and apparatus to mitigate coexistence interference in a wireless network |
WO2020207143A1 (en) * | 2019-04-06 | 2020-10-15 | Qualcomm Incorporated | Communicating multiple transport formats in a slot with full-duplex |
US12016032B2 (en) | 2019-04-06 | 2024-06-18 | Qualcomm Incorporated | Communicating multiple transport formats in a slot with full-duplex |
WO2023088158A1 (zh) * | 2021-11-22 | 2023-05-25 | 华为技术有限公司 | 一种功率确定方法及通信装置 |
Also Published As
Publication number | Publication date |
---|---|
EP3322118A4 (en) | 2018-07-25 |
US10779241B2 (en) | 2020-09-15 |
EP3322118A1 (en) | 2018-05-16 |
CN107113156B (zh) | 2020-08-07 |
EP3322118B1 (en) | 2020-05-13 |
CN107113156A (zh) | 2017-08-29 |
US20190357149A1 (en) | 2019-11-21 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
WO2017024441A1 (zh) | 一种全双工传输的控制方法和用户设备以及基站 | |
CN111656840B (zh) | 用于时域免授权pusch资源分配的系统和方法 | |
US20230353432A1 (en) | Uplink operation for lte in an unlicensed band | |
CN109845180B (zh) | 无线通信系统中用于支持短传输时间间隔的终端发送或者接收上行链路信号的方法及其装置 | |
CN110352582B (zh) | 无线通信系统中的上行链路信号发送或接收方法及其设备 | |
JP6721506B2 (ja) | 全二重無線システムにおける干渉管理のための方法、装置、およびシステム | |
CN110036586B (zh) | 用于处理时间缩减信令的系统和方法 | |
EP3471314B1 (en) | Method for reporting channel state in wireless communication system and device therefor | |
US9497747B2 (en) | Data transmission in carrier aggregation with different carrier configurations | |
CN102355325B (zh) | 一种pucch资源映射的方法及装置 | |
CN113785525A (zh) | 用于新无线电(nr)通信中的上行链路(ul)复用和优先化的方法和装置 | |
KR20200018273A (ko) | 무선 통신 시스템에 있어서 비면허 스펙트럼 내의 셀에 대한 슬롯 포맷 지시 적용 방법 및 장치 | |
JP2019036951A (ja) | 無線通信システムにおけるsfi(スロットフォーマット情報)衝突を処理するための方法及び装置 | |
CN110612751A (zh) | 用于在新型无线电(nr)系统中执行功率控制的方法 | |
EP2982057B1 (en) | Method and apparatus for transmitting channel state information in wireless communication system | |
JP7350034B2 (ja) | 無線通信システムにおいて送信電力制御のための方法及びそのための装置 | |
EP3744146B1 (en) | Multi-bit scheduling request | |
JP2022550971A (ja) | 上りリンク取り消し指示をモニタリングする方法、ユーザ機器、装置及びコンピュータ読み取り可能な格納媒体、並びに上りリンク取り消し指示を送信する方法及び基地局 | |
AU2018240040B2 (en) | Methods and devices for uplink puncturing transmission | |
US11121786B2 (en) | Method and apparatus for measuring interference in wireless communication system | |
WO2018203104A1 (en) | Subframe handling for extra-standard information in ofdm | |
WO2017055186A1 (en) | Transmission of uplink control information in unlicensed spectrum | |
US20240323937A1 (en) | Method and apparatus for cancellation sequence in a wireless communication system |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
121 | Ep: the epo has been informed by wipo that ep was designated in this application |
Ref document number: 15900640 Country of ref document: EP Kind code of ref document: A1 |
|
NENP | Non-entry into the national phase |
Ref country code: DE |
|
WWE | Wipo information: entry into national phase |
Ref document number: 2015900640 Country of ref document: EP |