[go: up one dir, main page]
More Web Proxy on the site http://driver.im/

WO2009021405A1 - Method, system and apparatus for tdd random access - Google Patents

Method, system and apparatus for tdd random access Download PDF

Info

Publication number
WO2009021405A1
WO2009021405A1 PCT/CN2008/001461 CN2008001461W WO2009021405A1 WO 2009021405 A1 WO2009021405 A1 WO 2009021405A1 CN 2008001461 W CN2008001461 W CN 2008001461W WO 2009021405 A1 WO2009021405 A1 WO 2009021405A1
Authority
WO
WIPO (PCT)
Prior art keywords
random access
preamble sequence
access channel
base station
length
Prior art date
Application number
PCT/CN2008/001461
Other languages
French (fr)
Chinese (zh)
Inventor
Hai Tang
Shiqiang Suo
Libo Wang
Original Assignee
Datang Mobile Communications Equipment Co., Ltd.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Datang Mobile Communications Equipment Co., Ltd. filed Critical Datang Mobile Communications Equipment Co., Ltd.
Publication of WO2009021405A1 publication Critical patent/WO2009021405A1/en

Links

Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W74/00Wireless channel access
    • H04W74/002Transmission of channel access control information
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04JMULTIPLEX COMMUNICATION
    • H04J13/00Code division multiplex systems
    • H04J13/0007Code type
    • H04J13/0055ZCZ [zero correlation zone]
    • H04J13/0059CAZAC [constant-amplitude and zero auto-correlation]
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W74/00Wireless channel access
    • H04W74/08Non-scheduled access, e.g. ALOHA
    • H04W74/0833Random access procedures, e.g. with 4-step access

Definitions

  • Time division duplex random access method system and device thereof
  • the present invention relates to the field of mobile communication technologies, and in particular, to an Orthogonal Frequency Division Multiplexing (OFDM) based Time Division-Synchronous Code Division Multiple Access (TD-SCDMA) evolution system.
  • OFDM Orthogonal Frequency Division Multiplexing
  • TD-SCDMA Time Division-Synchronous Code Division Multiple Access
  • the random access technology more particularly relates to a time division duplex random access method, system and device thereof for medium coverage and large coverage systems. Background technique
  • TD-SCDMA is the only three-dimensional international standard for third-generation mobile communication systems that adopts Time Division Duplex (TDD), which supports international standards for uplink and downlink asymmetric service transmission, and has greater flexibility in spectrum utilization.
  • TDD Time Division Duplex
  • the system uses advanced technologies in wireless communication such as smart antenna, uplink synchronization, joint detection and software radio to make the system have higher performance and spectrum utilization.
  • smart antenna with the development of society and the advancement of technology, people's requirements for mobile communication are also increasing. It is hoped that the system can provide high-capacity, high-rate, low-latency data transmission services.
  • TD-SCDMA systems also need to evolve and improve performance.
  • a broadband time division duplex cellular system In the evolution scheme of TD-SCDMA, in order to obtain a high-speed and large-capacity service, it is required to occupy a wider bandwidth, so it is called a broadband time division duplex cellular system.
  • the radius of the cell to be covered can be divided into three levels, namely 5 km, 30 km and 100 km. For a 100km system, it is usually called a large coverage system, a 30km system is called a medium coverage system, and a 5km system is called a small coverage system.
  • the asynchronous random access preamble sequence of the broadband time division duplex cellular system is used for uplink clock synchronization and UE identifier detection.
  • the preamble sequence is immediately adjacent to the uplink and downlink transition point, and the uplink and downlink transition time at this time corresponds to the uplink and downlink protection of the cell radius, so the signal of the neighboring cell base station It is likely to interfere with the random access preamble sequence of the cell.
  • the data slot of the cell after the uplink and downlink guard interval may also be interfered, but for the data channel, interference to the data channel may be avoided by scheduling or using other interference avoidance or cancellation methods.
  • FIG. 1( a ) is a frame structure of an original TD-SCDMA evolved system in a prior art broadband time division duplex cellular system
  • FIG. 1 ( b ) is a frame structure in a large coverage case of a prior art broadband time division duplex cellular system.
  • the time slot TS0 is fixed as a downlink time slot
  • the DwPTS is a downlink pilot time slot
  • the GP is an uplink and downlink guard interval
  • the UpPTS is an uplink pilot time slot.
  • the indication marked with ⁇ is the uplink time slot
  • the indication marked with ⁇ is the downlink time slot
  • the dotted line between TS4 and TS6 or TSx indicates the omitting
  • the intermediate time slot is not shown.
  • TSx represents the Xth time slot. Since it is an uplink or downlink time slot, the uplink and downlink attributes are not marked in the figure.
  • the ⁇ 4 machine access channel occupies resources in the frequency domain and cannot be represented by the UpPTS time slot as in the small coverage system. Therefore, in the large coverage system of Figure 1 (b), the previous synchronization The code sequence is used to identify.
  • the random access preamble sequence is allocated next to the GP, wherein the length of the GP corresponds to twice the radius of the cell, that is, the time elapsed by the photospeed corresponding to the cell radius distance of 2 times.
  • the preamble sequence needs to be extended accordingly.
  • the random access preamble sequence arrives at the local cell together with the TS0 time slot or the DwPTS time slot signal of the remote cell.
  • the base station that is, the random access preamble sequence of the local cell is interfered by the TS0 time slot and the DwPTS time slot signal of the remote cell, for example, the first layer cell outside the local cell.
  • the uplink data slots of the UE in the cell such as TS2 and TS3 are also interfered by the remote cell TS0 slot and the DwPTS slot, but because the data is transmitted, the specific data transmission can pass through the base station.
  • the remote cell TS0 time slot and DwPTS time slot signal interference have a great influence on the preamble sequence. These interferences can reduce the reception quality of the preamble sequence by the base station of the cell, and the success rate of the random access detection is reduced.
  • the UE After the UE sends the preamble sequence for random access, it will perform reception detection on the corresponding channel during the feedback time of the waiting base station to see if there is any access back from the base station. Successful instructions.
  • the performance of the base station detecting the preamble sequence is degraded, so that the preamble sequence cannot be correctly detected. If the base station cannot correctly detect the preamble sequence, the base station does not send feedback information to the UE.
  • the UE If the UE does not detect the feedback signal on the corresponding feedback channel, the UE will wait until the preset waiting time expires, and the UE will re-initiate another random access. Due to the last random access detection, many UEs do not receive the correct feedback information, so more UEs will send a preamble sequence to the base station at the next moment, causing the base station to detect the performance of multiple preamble sequences. Further decline.
  • one of the objects of the present invention is to solve the technical problem of the interference of the downlink time slot of the remote cell to the random access preamble.
  • an aspect of the present invention provides a time division duplex random access method, including the following steps: a base station broadcasts location information of a random access channel and an optional preamble sequence through a broadcast channel, where The length of the random access channel is greater than the length of the preamble sequence; the base station receives the preamble sequence selected by the UE sent by the terminal UE through the random access channel, and the random access channel includes at least a blank area, as a guard interval of the preamble sequence selected by the UE; the base station performs random access detection on the UE according to the preamble sequence sent by the UE.
  • the location information of the random access channel is determined by: configuring a length of the random access channel according to a coverage of the base station and a length of an optional preamble sequence, The length of the random access channel is an integer multiple of the length of the uplink time slot; determining the location of the random access channel according to the uplink time slot scheduled by the base station and the length of the random access channel, so that the random access The access channel is located in an uplink time slot that is far from the uplink and downlink guard interval.
  • the guard interval is located after the preamble sequence, immediately adjacent to the preamble sequence.
  • the sum of the guard interval, the preamble sequence, and the length of the cyclic prefix is equal to the length of the random access channel.
  • the guard interval length ranges from greater than zero to less than or equal to 2 times the speed of light corresponding to the cell radius distance.
  • the method before the base station broadcasts the location information of the random access channel and the selectable preamble sequence through the broadcast channel, the method further includes: grouping the preamble sequence according to the channel transmission quality. And the UE selects the preamble sequence after the group according to the current downlink channel quality.
  • the random access preamble sequence is a directly generated long synchronization code sequence, or is formed by repeating a short synchronization code sequence.
  • the synchronization code sequence is a Zadoff-Chu sequence, a GCL sequence, a Golay sequence or a Barker sequence.
  • Another aspect of the present invention further provides a time division duplex random access method, comprising the steps of: receiving, by a UE, location information of a random access channel broadcast by a base station and an optional preamble sequence, where the random access channel The length is greater than the length of the preamble sequence; the UE randomly selects a preamble sequence in the selectable preamble sequence to send to the base station through a random access channel, the random access
  • the channel includes at least one blank area as a guard interval of the preamble sequence selected by the UE.
  • the UE detects the response channel of the base station, and obtains a result of the base station detecting the random access of the UE.
  • the location information of the random access channel is determined by: configuring a length of the random access channel according to a coverage of the base station and a length of an optional preamble sequence, The length of the random access channel is an integer multiple of the length of the uplink time slot; determining the location of the random access channel according to the uplink time slot scheduled by the base station and the length of the random access channel, so that the random access The access channel is located in an uplink time slot that is far from the uplink and downlink guard interval.
  • the guard interval is located after the preamble sequence, immediately adjacent to the preamble sequence, and the sum of the guard interval, the preamble sequence, and the length of the cyclic prefix is equal to the The length of the random access channel.
  • the guard interval length ranges from greater than zero to less than or equal to 2 times the distance traveled by the aperture distance.
  • the UE randomly selects one preamble sequence in the optional preamble sequence, where the UE is: according to the current downlink channel quality, the preamble sequence. Column to make a selection.
  • the random access preamble sequence is a directly generated long synchronization code sequence, or is formed by repeating a short synchronization code sequence.
  • the synchronization code sequence is a Zadoff-Chu sequence, a GCL sequence, a Golay sequence or a Barker sequence.
  • a further aspect of the present invention further provides a random access channel, where the length of the random access channel is greater than the length of the preamble sequence, and the random access channel includes at least one blank area as a UE to the base station.
  • the guard interval of the transmitted preamble sequence is not limited to the length of the preamble sequence.
  • the length of the random access channel is an integer multiple of the length of the uplink time slot.
  • the guard interval is located after the preamble sequence, immediately adjacent to the preamble sequence, and the sum of the guard interval, the preamble sequence, and the length of the cyclic prefix is equal to The length of the random access channel.
  • the guard interval length ranges from greater than zero to less than or equal to the time elapsed for the optical speed corresponding to the cell radius distance.
  • a further aspect of the present invention further provides a UE, comprising: a sequence selection module, configured to select a preamble sequence in the base station broadcast information; and a random access channel forming module, configured to use the broadcast information and the selected The preamble sequence forms a random access channel; the sending module is configured to send the preamble sequence to the base station of the cell by using a random access channel, where the random access channel further includes a blank area as the preamble sequence
  • the protection interval of the base station is used to detect the response channel of the base station to determine whether the access is successful.
  • the preamble sequence and the guard interval are located in an uplink slot that is away from the uplink and downlink guard interval.
  • the length of the random access channel is an integer multiple of the length of the uplink time slot.
  • a further aspect of the present invention provides a base station, including: a broadcast module, configured to broadcast location information of a random access channel and a preamble sequence usable by the current cell through a broadcast channel; and a random access sequence detecting module, And a preamble sequence for detecting a random access channel, where the random access channel further includes a blank area as a guard interval of the preamble sequence; a random access response mode a block, configured to respond to the detected preamble sequence by a response channel.
  • an uplink time slot setting module is further configured to configure an uplink time slot according to a coverage area and a time slot width occupied by the preamble sequence and the guard interval.
  • a preamble sequence grouping module is further included for grouping according to a grouping condition corresponding to each preamble sequence.
  • the present invention also provides a time division duplex random access system, comprising: a base station and at least one UE served by the base station, the base station comprising: a broadcast module, configured to use location information of the random access channel and the local cell to be used
  • the preamble sequence is broadcasted through a broadcast channel;
  • a random access sequence detection module is configured to detect a preamble sequence sent by the UE in the random access channel;
  • a random access response module is configured to detect the preamble through the response channel pair
  • the synchronization code sequence is responsive;
  • the UE includes: a sequence selection module, configured to select a preamble sequence in the base station broadcast information, and a random access channel formation module, configured to use the broadcast information and the selected preamble
  • the code sequence forms a random access channel;
  • the sending module is configured to send the preamble sequence to the cell base station by using a random access channel, where the random access channel further includes a blank area as a guard interval of the preamble sequence a
  • the preamble sequence and the guard interval are located in an uplink slot that is away from the uplink and downlink guard interval.
  • the present invention is directed to a broadband time division duplex cellular system.
  • the proposed random access channel design scheme with guard interval does not require the preamble sequence to be close to the uplink and downlink protection interval, so that the random access channel is The allocation is more flexible.
  • the present invention places the preamble sequence with the guard interval as far as possible from the uplink time slot position of the uplink and downlink guard interval, so that the interference of the remote base station can be avoided as much as possible according to the allocation criterion of the random access channel, and the base station of the base station is guaranteed. Correct detection of the random access channel can achieve accurate and fast random access of the UE, and provides an effective solution for the OFDM system to achieve random access of the UE.
  • 1(a) is a design diagram of a frame structure of a prior art original TD-SCDMA evolution system and a random access UpPTS;
  • FIG. 1(b) is a frame structure of a prior art TD-SCDMA evolution system in a case of large coverage
  • FIG. 2 is a Preamble sequence structure following a guard interval according to an embodiment of the present invention
  • FIG. 3 ( a ) is a diagram of a random access channel location allocation in a case of a small coverage of 5 km according to an embodiment of the present invention
  • FIG. 3(b) is a diagram showing a random access channel position allocation in a case of coverage of 30 km according to an embodiment of the present invention
  • FIG. 3(c) is a diagram showing a location allocation of a random access channel in a case of a large coverage of 100 km according to an embodiment of the present invention
  • 4(a) is a diagram showing a random access channel location allocation in the case where TS4 is a small coverage of 5 km downlink time slot according to an embodiment of the present invention
  • 4(b) is a diagram showing a random access channel location allocation in the case where the TS4 is a coverage of a downlink time slot of 30 km according to an embodiment of the present invention
  • 4(c) is a diagram showing a random access channel location allocation diagram in the case where TS4 is a 100 mL large coverage of a downlink time slot according to an embodiment of the present invention
  • FIG. 5 is a sequence diagram of a random access procedure between a UE and a base station according to an embodiment of the present invention
  • FIG. 6 is a block diagram of a random access part of a UE and a base station according to an embodiment of the present invention. detailed description
  • the main idea of the present invention is to redesign the random access channel structure, and in the case that uplink channel allocation is possible, the redesigned random access channel can be flexibly configured in the uplink channel, and the cell is randomly connected.
  • the sending position of the preamble sequence is far away from the time when the TS0 time slot and the DwPTS time slot of the remote base station reach the local cell, and the interference of the downlink time slot of the remote base station to the preamble sequence of the current cell is reduced as much as possible, thereby improving the detection of the random access channel. Success rate and access speed of the UE.
  • the present invention includes a blank area in the random access channel that does not transmit any data, and the guard interval (GT) as a preamble sequence in the blank area is used to eliminate the time due to the preamble sequence.
  • the guard interval As shown in Figure 2.
  • a guard interval is set in the random access channel, but those skilled in the art should understand that setting multiple guard intervals, such as setting a protection before and after. Intervals, as well as the objects of the invention, are also encompassed by the scope of the invention.
  • the sum of the guard interval GT, the preamble sequence, and the cyclic prefix CP is equal to the length of the random access channel.
  • the random access channel is not necessarily limited to the GP to allocate, because the preamble sequence in the random access channel allocation structure has its own guard interval, which can avoid the preamble sequence forward. Or when moving backwards, it interferes with the data slots before and after.
  • the range of values of the GT is theoretically greater than zero, and is less than or equal to the time required for the speed of light to travel twice the radius of the cell.
  • the value of the GT in the present invention is configurable, and in the case that the base station receives the signal to noise ratio, the base station antenna coverage distance may be determined by the base station antenna.
  • the UE estimates a timing advance when transmitting the preamble sequence such that the preamble sequence it transmits can reach the base station at its target time. As shown in Figure 3 (b), the target moment of the preamble sequence should be at the beginning of the TS3 slot. If a UE is at the cell edge, the UE needs to advance GT/2 time when transmitting the preamble sequence, which sends the preamble sequence. The cell base station will arrive at the start position of the TS3 slot, so that the preamble sequence will not affect the data slots before and after due to the guard interval.
  • the Preamble sequence can be placed as far as possible from the GP, which needs to be specifically set according to the number and location of uplink time slots scheduled by the base station, such as placing the random access preamble sequence in TS3 and The TS4 slot position, or the random access preamble sequence can be placed in the TS5 and TS6 slot positions, or even further slot positions.
  • the Preamble sequence can occupy more than two time slots, and the number of specific occupied slots will be described in detail in the following description. Therefore, it can be seen that the setting of the random access channel is different due to the specific conditions of the uplink time slot scheduled by the base station, and the structure of the random access channel may have multiple modes.
  • the following random access channels of the present invention are shown in FIG. 3 and FIG. The examples are only for the purpose of facilitating the understanding of the present invention, and it is not intended that the present invention can be realized only by the examples described below.
  • the random access preamble sequence can be placed in the TS3 and TS4 time slot positions.
  • the preamble sequence is placed at the TS3 and TS4 slot positions, so that the transmission position of the random access preamble sequence is far away from the time when the remote base station TS0 slot and the DwPTS slot reach the local cell, thereby avoiding the remote base station TS0 slot and DwPTS slot. Interference with the preamble sequence of the cell.
  • Figure 4 (c) and Figure 4 (c) show the comparison of the location allocation scheme of the random access preamble sequence with the small coverage and large coverage
  • TS4 is the downlink time slot
  • Figure 4 (b) shows the medium coverage
  • TS3 is a random access preamble sequence location allocation scheme for downlink time slots.
  • the random access preamble sequence can only be allocated in the TS1 and TS2 slot positions.
  • the random access preamble sequence can only be allocated in the TS2 and TS3 slot positions.
  • the preamble sequence does not occupy the GP time, and the interference of the remote base stations TS0 and DwPTS is small.
  • this structure can be mainly applied to cells in which TS0 and DwPTS interference is not very large.
  • the allocation criterion in the random access channel of the medium coverage and the large coverage system is: when there is enough uplink channel, according to the interference situation Random access preamble sequence location allocation.
  • the random access preamble sequence and its guard interval are allocated as far as possible to the uplink time slot position away from the uplink and downlink guard interval.
  • the interference of the remote base station can be avoided.
  • the interference of the TS0 and the DwPTS of a specific cell may be measured when the cell is initially set, and the random access channel may be allocated according to the measured value, without dynamic measurement, and dynamic measurement It is also complicated and difficult to measure.
  • the lengths of the random access preamble sequences with guard intervals given in FIG. 3 and FIG. 4 are both corresponding to the length of two time slots.
  • the random access preamble sequence and the GT may be longer, It is the length of N time slots. which is
  • Length represents a function of the length of time.
  • N is an integer greater than or equal to 1, that is, the length of the preamble and GT can be placed in one time slot.
  • N can only be taken.
  • preamble sequence and GT protection The sum of the occupied durations of the intervals is equal to an integer multiple of one slot in TD-SCDMA.
  • the allocation criterion of the random access preamble sequence with guard interval according to the present invention in the random access channel is applicable to the random access preamble sequence of any length.
  • the following method may be used to generate a long preamble sequence of a large-area cell:
  • A. Directly generate a long preamble sequence.
  • the advantage of this method is that the number of sequences that can be used is large, but the complexity of generating long preamble sequences is relatively high, and implementation is difficult;
  • the shorter length preamble sequence is repeated to form a long preamble sequence.
  • the advantage of this method is that while providing a sufficient number of sequences, it can avoid the high complexity of directly generating long sequences, and can improve the detection performance to some extent.
  • the selection of a specific preamble sequence in the present invention may select a Zadoff-Chu sequence, a GCL sequence, a Golay sequence, or a Barker sequence having good autocorrelation and cross-correlation properties.
  • FIG. 5 is a timing sequence diagram of a random access procedure between a UE and a base station. According to the time sequence of signal transmission, the entire random access procedure can be divided into four steps, which are described in detail below:
  • Step 1 The base station broadcasts the location information of the random access channel and all preamble sequence identifiers that can be used by the cell through the broadcast channel.
  • the number of uplink time slots allocated by the base station is also limited. Different from the prior art, with the technical solution disclosed by the present invention, the number of uplink time slots at this time needs to meet the requirement of sending a random access channel length. For medium coverage, the base station must allocate at least one uplink time slot. If the random access channel occupies the length of two uplink time slots, then the base station needs to allocate at least two uplink time slots; for large coverage, the base station at least Two uplink time slots are to be allocated, otherwise the random access channel cannot be allocated.
  • the base station After allocating the number of uplink time slots according to the length of the random access channel and the uplink data volume requirement of the system, the base station allocates the number of random access channels according to the estimated number of initiated random access users in the current cell. After determining the length of the random access channel, the location of the random access channel may be determined according to the uplink time slot and the length of the random access channel scheduled by the base station, so that the random access channel is located in an uplink time slot that is far away from the uplink and downlink protection interval. in. As shown in FIG. 3, the length of the random access channel can be set to two TSs, and when the TS4 is an uplink time slot, the random access channel is set on TS3 and TS4; and in FIG. 4, the same random access channel is used.
  • the length is set to two TSs, however, since TS4 is a downlink time slot, only random access channels can be set on TS2 and TS3. Of course, this is only for the convenience of understanding the case.
  • the setting of the random access channel may be different according to the scheduling of the base station. However, according to the main idea of the present invention, the protection interval in the random access channel should be protected by the invention. Covered by the scope. Finally, the base station broadcasts the location information of the random access channel and the preamble sequence used by the local cell through the broadcast channel.
  • the number of preamble sequences that can be used by a cell is planned in the cell planning. If the number of planning is 16, the cell base station broadcasts all available preamble sequences when broadcasting downwards. The UE randomly chooses itself.
  • all available preamble sequences are grouped, for example, 16 sequences are divided into two groups, namely, group 1 and group 2, then select The sequence in packet 1 implies that the downlink channel quality is better; if the selected sequence is located in packet 2, the downlink channel quality is implied.
  • the conditions for grouping may include other parameters in addition to the downlink channel quality described above.
  • Step 2 randomly select a preamble sequence from all preamble sequences, and send the selected preamble sequence to the base station on the random access channel according to the location information of the random access channel provided by the base station.
  • the UE randomly selects a preamble sequence from the optional preamble sequence group according to the broadcast information of the base station according to the current implicit information transmitted by the preamble sequence, and then arbitrarily selects one channel among all the random access channels, and sends the Preamble sequence.
  • the transmission timing advance of this preamble is determined according to the timing advance algorithm. Since the GT is placed after the preamble, it is necessary to subtract a constant from the time advance, ie GT/2, so that the preamble can be within the random access channel range without disturbing the data slots before and after.
  • Step 3 The base station performs preamble sequence detection on the allocated random access channel location.
  • the detection is correlation detection, and the base station responds to the detected preamble sequence, and the response channel is a fixed channel.
  • the response information of the base station includes the preamble sequence of the response, the timing advance information, and the like, and may also include resource allocation information corresponding to the preamble sequence.
  • the resource allocation information may also be default, that is, not sent.
  • Step 4 The UE detects the base station response channel within a fixed length of time, if When the preamble sequence sent by itself is detected, the UE considers that it has been detected by the base station. Then, the UE sends data on the uplink resource corresponding to the preamble.
  • FIG. 6 is a structural diagram of a time division duplex random access system according to an embodiment of the present invention, the system including a base station and at least one UE served by the base station.
  • the base station includes: a broadcast module, a random access sequence detection module, a random access response module, an uplink time slot setting module, and a preamble sequence grouping module.
  • a broadcast module configured to broadcast the location information of the random access channel and the preamble sequence usable by the local cell through the broadcast channel.
  • the random access sequence detecting module is configured to detect a preamble sequence in the random access channel, where the preamble sequence carries its own guard interval.
  • the random access response module is configured to respond to the detected preamble sequence through the response channel.
  • An uplink time slot setting module configured to configure an uplink time slot according to a coverage area and a time slot width occupied by the preamble sequence and the guard interval, wherein the purpose of the module is that the number of uplink time slots must meet the length of the random access channel.
  • the requirements can be set at system initialization.
  • the preamble sequence grouping module is configured to group the preamble sequence according to a packet condition corresponding to each preamble sequence, a channel quality, and the like.
  • the packet itself identifies information about the packet conditions to the client, and the client can perform the appropriate action based on the implicit information contained in the packet.
  • the UE includes: a sequence selection module, a random access channel forming module, a sending module, and a base station response detecting module.
  • a sequence selection module is configured to select a preamble sequence in the base station broadcast information.
  • a random access channel forming module configured to form a random access channel according to the cell broadcast information and the selected preamble sequence, where the preamble sequence in the formed random access channel carries its own guard interval, and the preamble sequence And its guard interval is located at the location of the upstream slot in the TD-SCDMA frame.
  • a sending module configured to send the preamble sequence to the cell base station by using a random access channel.
  • the base station response detecting module is configured to detect the base station response channel to determine whether the access is successful.
  • the invention improves the structure of the random access channel, and in combination with the allocation criterion of the random access channel disclosed by the present invention, the interference of the remote cell TS0 time slot and the DwPTS time slot to the random access process can be avoided as much as possible.
  • the impact of the UE thus achieving accurate and fast random access of the UE, improves the operational efficiency of the entire communication system.

Landscapes

  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Power Engineering (AREA)
  • Mobile Radio Communication Systems (AREA)

Abstract

The invention relates to an assignment method for random access channel of medium-scale and large-scale systems in TD-SCDMA evolution system, and the preamble sequence can be assigned to the uplink slots far apart from the GP by appending guard period to the random access preamble sequence when the interference is large. The invention can solve the technical problem that the TS0 and DwPTS timeslots of the remote cells produce interference to the random access preamble sequence of the current cell. The assignment of the random access channel becomes more flexible and the detection success probability of the preamble sequence by the base station is improved by application of the invention.

Description

时分双工随机接入方法、 系统及其装置  Time division duplex random access method, system and device thereof
技术领域  Technical field
本发明涉及移动通信技术领域, 特别涉及基于正交频分复用(Orthogonal Frequency Division Multiplexing, OFDM) 的时分—同步码分多址 ( Time Division-Synchronous Code Division Multiple Access, TD-SCDMA )演进系统中 的随机接入技术,更特别涉及一种中等覆盖和大覆盖系统的时分双工随机接入 方法、 系统及其装置。 背景技术  The present invention relates to the field of mobile communication technologies, and in particular, to an Orthogonal Frequency Division Multiplexing (OFDM) based Time Division-Synchronous Code Division Multiple Access (TD-SCDMA) evolution system. The random access technology, more particularly relates to a time division duplex random access method, system and device thereof for medium coverage and large coverage systems. Background technique
TD-SCDMA是第三代移动通信系统三大国际标准中唯一采用时分双工 ( TDD )方式, 支持上下行非对称业务传输的国际标准, 在频谱利用上具有较 大的灵活性。 该系统综合采用了智能天线、 上行同步、联合检测和软件无线电 等无线通信中的先进技术,使系统具有较高的性能和频谱利用率。 随着社会的 发展以及技术的进步,人们对移动通信的要求也不断提高, 希望系统能够提供 大容量、 高速率、 低时延的数据传输服务。 为了满足这种日益增长的需求, TD-SCDMA系统同样需要不断演进和提高性能。  TD-SCDMA is the only three-dimensional international standard for third-generation mobile communication systems that adopts Time Division Duplex (TDD), which supports international standards for uplink and downlink asymmetric service transmission, and has greater flexibility in spectrum utilization. The system uses advanced technologies in wireless communication such as smart antenna, uplink synchronization, joint detection and software radio to make the system have higher performance and spectrum utilization. With the development of society and the advancement of technology, people's requirements for mobile communication are also increasing. It is hoped that the system can provide high-capacity, high-rate, low-latency data transmission services. To meet this growing demand, TD-SCDMA systems also need to evolve and improve performance.
在 TD-SCDMA的演进方案中, 为了得到高速率大容量的服务, 需要占用 更宽的带宽, 因此将其称之为宽带时分双工蜂窝系统。在宽带时分双工蜂窝系 统中, 需要覆盖的小区半径可分为三个等级, 即 5km, 30km和 100km。 对于 100km系统来说,通常称之为大覆盖系统, 30km系统称为中等覆盖系统, 5km 系统称为小覆盖系统。  In the evolution scheme of TD-SCDMA, in order to obtain a high-speed and large-capacity service, it is required to occupy a wider bandwidth, so it is called a broadband time division duplex cellular system. In a broadband time division duplex cellular system, the radius of the cell to be covered can be divided into three levels, namely 5 km, 30 km and 100 km. For a 100km system, it is usually called a large coverage system, a 30km system is called a medium coverage system, and a 5km system is called a small coverage system.
宽带时分双工蜂窝系统的非同步随机接入前同步码(preamble )序列用于 上行时钟的同步和 UE识别符的检测。在为中等覆盖和大覆盖设计的宽带时分 双工蜂窝系统中, preamble序列紧邻上下行转换点, 而此时的上下行转换时间 刚好对应小区半径的上下行保护, 所以,相邻小区基站的信号很可能会干扰到 本小区的随机接入 preamble序列。 在实际中, 本小区在上下行保护间隔后的 数据时隙也可能会受到干扰,但对于数据信道来说,可以通过调度或采用其它 的干扰避免或者消除方法避免对数据信道的干扰。 即便出现了数据块解调错 误, 也可以通过重传来保证正确的接收。 但是, 对于随机接入信道来说, 大的 干扰对用户 UE (终端) 的影响是非常大的, 会降低 UE的接入成功率, 延长 UE随机接入的时间, 对用户具体使用的影响也很大。 The asynchronous random access preamble sequence of the broadband time division duplex cellular system is used for uplink clock synchronization and UE identifier detection. In a broadband time division duplex cellular system designed for medium coverage and large coverage, the preamble sequence is immediately adjacent to the uplink and downlink transition point, and the uplink and downlink transition time at this time corresponds to the uplink and downlink protection of the cell radius, so the signal of the neighboring cell base station It is likely to interfere with the random access preamble sequence of the cell. In practice, the data slot of the cell after the uplink and downlink guard interval may also be interfered, but for the data channel, interference to the data channel may be avoided by scheduling or using other interference avoidance or cancellation methods. Even if there is a block demodulation error Mistakes can also be guaranteed by retransmission. However, for a random access channel, the impact of large interference on the user UE (terminal) is very large, which reduces the access success rate of the UE, and prolongs the random access time of the UE, and affects the specific use of the user. Very big.
图 1 ( a )为现有技术宽带时分双工蜂窝系统中原始 TD-SCDMA演进系统 的帧结构, 图 1 ( b ) 为现有技术宽带时分双工蜂窝系统中大覆盖情况下的帧 结构, 图中时隙 TS0 固定为下行时隙, DwPTS为下行导频时隙, GP为上下 行保护间隔, UpPTS为上行导频时隙。 图中, 标有†的表示是上行时隙, 标有 丄的表示是下行时隙, TS4与 TS6或 TSx之间的虚线表示省略, 未画出中间的 时隙。 在大覆盖系统中 TSx表示第 X个时隙, 由于其是上行还是下行时隙不 确定, 因此, 在图中未标出其上下行属性。 由于在大覆盖系统中, Ρ4机接入信 道占用的是频域的资源,不能象小覆盖系统那样以 UpPTS时隙的方式来表示, 因此在图 1 ( b ) 的大覆盖系统中, 以前同步码序列来标识。  1( a ) is a frame structure of an original TD-SCDMA evolved system in a prior art broadband time division duplex cellular system, and FIG. 1 ( b ) is a frame structure in a large coverage case of a prior art broadband time division duplex cellular system. In the figure, the time slot TS0 is fixed as a downlink time slot, the DwPTS is a downlink pilot time slot, the GP is an uplink and downlink guard interval, and the UpPTS is an uplink pilot time slot. In the figure, the indication marked with † is the uplink time slot, the indication marked with 丄 is the downlink time slot, and the dotted line between TS4 and TS6 or TSx indicates the omitting, and the intermediate time slot is not shown. In the large coverage system, TSx represents the Xth time slot. Since it is an uplink or downlink time slot, the uplink and downlink attributes are not marked in the figure. In the large coverage system, the 接入4 machine access channel occupies resources in the frequency domain and cannot be represented by the UpPTS time slot as in the small coverage system. Therefore, in the large coverage system of Figure 1 (b), the previous synchronization The code sequence is used to identify.
图 1 ( b ) 中, 随机接入 preamble序列紧邻 GP而分配, 其中, GP的长度 对应小区半径的两倍, 即 2倍小区半径距离对应的光速所经历的时间。在中等 覆盖和大覆盖情况下, 为了满足基站接收信噪比的要求, preamble序列相对小 覆盖的情况, 还需要相应的对其进行延长。 在中等覆盖和大覆盖情况下, 当本 小区 UE向本小区基站发送随机接入 preamble序列时,这些随机接入 preamble 序列就会和远端小区的 TS0时隙或 DwPTS时隙信号一起到达本小区基站,也 就是说, 本小区随机接入 preamble序列受到了远端小区, 例如本小区外的第 一层小区, 的 TS0时隙和 DwPTS时隙信号的干扰。 实际上, 本小区 UE的上 行数据时隙, 如 TS2、 TS3等, 也受到了远端小区 TS0时隙和 DwPTS时隙的 干扰, 但由于其传输的是数据, 具体的数据传输可以通过基站之间进行调度, 或者采用干扰协调,或者采用干扰避免的方法, 降低远端小区对本小区上行数 据时隙的影响。 即使其中的数据块在干扰的情况下, 出现了检测错误, 那么也 可以通过重传的方式来保证正确的传输。  In Figure 1 (b), the random access preamble sequence is allocated next to the GP, wherein the length of the GP corresponds to twice the radius of the cell, that is, the time elapsed by the photospeed corresponding to the cell radius distance of 2 times. In the case of medium coverage and large coverage, in order to meet the requirement of receiving signal to noise ratio of the base station, the preamble sequence needs to be extended accordingly. In the case of medium coverage and large coverage, when the UE of the local cell sends a random access preamble sequence to the base station of the local cell, the random access preamble sequence arrives at the local cell together with the TS0 time slot or the DwPTS time slot signal of the remote cell. The base station, that is, the random access preamble sequence of the local cell is interfered by the TS0 time slot and the DwPTS time slot signal of the remote cell, for example, the first layer cell outside the local cell. In fact, the uplink data slots of the UE in the cell, such as TS2 and TS3, are also interfered by the remote cell TS0 slot and the DwPTS slot, but because the data is transmitted, the specific data transmission can pass through the base station. To perform scheduling, or to use interference coordination, or to use interference avoidance, to reduce the impact of the remote cell on the uplink data slot of the local cell. Even if the data block in the case of interference, a detection error occurs, the correct transmission can be ensured by retransmission.
但远端小区 TS0时隙和 DwPTS时隙信号干扰对于 preamble序列来说影响 非常大。 这些千扰会降低本小区基站对 preamble序列的接收质量, 使得随机 接入检测成功率降低。 UE发送 preamble序列进行随机接入后, 会在其等待基 站的反馈时间内在相应的信道进行接收检测,看是否有从基站反馈回来的接入 成功指示。 然而由于干扰的存在, 基站检测 preamble序列的性能下降, 导致 不能正确检测出 preamble序列,基站在不能正确检测 preamble序列的情况下, 是不发送反馈信息给 UE的。 若 UE在相应的反馈信道检测不到反馈信号, 则 UE会一直等待直至预先设定的等待时间超时, UE 才会重新发起另外一次随 机接入。 由于上一次的随机接入检测, 很多 UE都没有收到正确的反馈信息, 因此在接下来的时刻会有更多的 UE向本小区基站发送 preamble序列,从而导 致基站检测多个 preamble序列的性能进一步下降。 However, the remote cell TS0 time slot and DwPTS time slot signal interference have a great influence on the preamble sequence. These interferences can reduce the reception quality of the preamble sequence by the base station of the cell, and the success rate of the random access detection is reduced. After the UE sends the preamble sequence for random access, it will perform reception detection on the corresponding channel during the feedback time of the waiting base station to see if there is any access back from the base station. Successful instructions. However, due to the existence of interference, the performance of the base station detecting the preamble sequence is degraded, so that the preamble sequence cannot be correctly detected. If the base station cannot correctly detect the preamble sequence, the base station does not send feedback information to the UE. If the UE does not detect the feedback signal on the corresponding feedback channel, the UE will wait until the preset waiting time expires, and the UE will re-initiate another random access. Due to the last random access detection, many UEs do not receive the correct feedback information, so more UEs will send a preamble sequence to the base station at the next moment, causing the base station to detect the performance of multiple preamble sequences. Further decline.
综上所述,远端小区 TS0时隙和 DwPTS时隙的干扰对随机接入过程的影 响 4艮大, 进而影响到了整个通信系统的正常运作。 发明内容  In summary, the interference of the TS0 time slot and the DwPTS time slot of the remote cell has a large impact on the random access process, which in turn affects the normal operation of the entire communication system. Summary of the invention
有鉴于此,本发明的目的之一是解决远端小区下行时隙对随机接入前同步 码干扰的技术问题。  In view of this, one of the objects of the present invention is to solve the technical problem of the interference of the downlink time slot of the remote cell to the random access preamble.
为达到上述目的,本发明一方面提出一种时分双工随机接入方法, 包括以 下步骤:基站将随机接入信道的位置信息和可供选择的前同步码序列通过广播 信道进行广播, 所述随机接入信道的长度大于所述前同步码序列的长度; 所述 基站接收终端 UE通过所述随机接入信道发送的所述 UE选择的前同步码序 列, 所述随机接入信道内包含至少一空白区域, 作为所述 UE选择的前同步码 序列的保护间隔; 所述基站根据所述 UE发送的前同步码序列对所述 UE进行 随机接入检测。  In order to achieve the above object, an aspect of the present invention provides a time division duplex random access method, including the following steps: a base station broadcasts location information of a random access channel and an optional preamble sequence through a broadcast channel, where The length of the random access channel is greater than the length of the preamble sequence; the base station receives the preamble sequence selected by the UE sent by the terminal UE through the random access channel, and the random access channel includes at least a blank area, as a guard interval of the preamble sequence selected by the UE; the base station performs random access detection on the UE according to the preamble sequence sent by the UE.
作为本发明的一个实施例,所述随机接入信道的位置信息通过以下步骤确 定:根据所述基站的覆盖范围和可供选择的前同步码序列的长度配置所述随机 接入信道的长度, 所述随机接入信道的长度为上行时隙长度的整数倍;根据所 述基站调度的上行时隙和所述随机接入信道的长度确定所述随机接入信道的 位置, 以使所述随机接入信道位于远离上下行保护间隔的上行时隙中。  As an embodiment of the present invention, the location information of the random access channel is determined by: configuring a length of the random access channel according to a coverage of the base station and a length of an optional preamble sequence, The length of the random access channel is an integer multiple of the length of the uplink time slot; determining the location of the random access channel according to the uplink time slot scheduled by the base station and the length of the random access channel, so that the random access The access channel is located in an uplink time slot that is far from the uplink and downlink guard interval.
在上述实施例中,所述保护间隔位于所述前同步码序列之后, 紧临所述前 同步码序列。  In the above embodiment, the guard interval is located after the preamble sequence, immediately adjacent to the preamble sequence.
在上述实施例中, 所述保护间隔、所述前同步码序列和循环前缀的长度之 和等于所述随机接入信道的长度。 在上述实施例中,所述保护间隔长度的取值范围为大于零小于等于 2倍小 区半径距离对应的光速所经历的时间。 In the above embodiment, the sum of the guard interval, the preamble sequence, and the length of the cyclic prefix is equal to the length of the random access channel. In the above embodiment, the guard interval length ranges from greater than zero to less than or equal to 2 times the speed of light corresponding to the cell radius distance.
在上述实施例中,在所述基站将随机接入信道的位置信息和可供选择的前 同步码序列通过广播信道进行广播之前,还包括: 根据信道传输质量对所述前 同步码序列进行分组,所述 UE根据当前的下行信道质量对分组后所述前同步 码序列进行选择。  In the above embodiment, before the base station broadcasts the location information of the random access channel and the selectable preamble sequence through the broadcast channel, the method further includes: grouping the preamble sequence according to the channel transmission quality. And the UE selects the preamble sequence after the group according to the current downlink channel quality.
在上述实施例中, 所述随机接入前同步码序列为直接产生的长同步码序 列, 或由短同步码序列进行重复后形成。  In the above embodiment, the random access preamble sequence is a directly generated long synchronization code sequence, or is formed by repeating a short synchronization code sequence.
在上述实施例中, 所述同步码序列为 Zadoff-Chu序列、 GCL序列、 Golay 序列或 Barker序列。  In the above embodiment, the synchronization code sequence is a Zadoff-Chu sequence, a GCL sequence, a Golay sequence or a Barker sequence.
本发明另一方面还提出一种时分双工随机接入方法, 包括以下步骤: UE 接收基站广播的随机接入信道的位置信息和可供选择的前同步码序列,所述随 机接入信道的长度大于所述前同步码序列的长度; 所述 UE在所述可供选择的 前同歩码序列中随机选取一个前同步码序列通过随机接入信道向所述基站发 送, 所述随机接入信道内包含至少一空白区域, 作为所述 UE选择的前同步码 序列的保护间隔; 所述 UE对所述基站的响应信道进行检测, 得到所述基站对 所述 UE随机接入检测的结果。  Another aspect of the present invention further provides a time division duplex random access method, comprising the steps of: receiving, by a UE, location information of a random access channel broadcast by a base station and an optional preamble sequence, where the random access channel The length is greater than the length of the preamble sequence; the UE randomly selects a preamble sequence in the selectable preamble sequence to send to the base station through a random access channel, the random access The channel includes at least one blank area as a guard interval of the preamble sequence selected by the UE. The UE detects the response channel of the base station, and obtains a result of the base station detecting the random access of the UE.
作为本发明的一个实施例,所述随机接入信道的位置信息通过以下步骤确 定:根据所述基站的覆盖范围和可供选择的前同步码序列的长度配置所述随机 接入信道的长度, 所述随机接入信道的长度为上行时隙长度的整数倍;根据所 述基站调度的上行时隙和所述随机接入信道的长度确定所述随机接入信道的 位置, 以使所述随机接入信道位于远离上下行保护间隔的上行时隙中。  As an embodiment of the present invention, the location information of the random access channel is determined by: configuring a length of the random access channel according to a coverage of the base station and a length of an optional preamble sequence, The length of the random access channel is an integer multiple of the length of the uplink time slot; determining the location of the random access channel according to the uplink time slot scheduled by the base station and the length of the random access channel, so that the random access The access channel is located in an uplink time slot that is far from the uplink and downlink guard interval.
在上述实施例中, 所述保护间隔位于所述前同步码序列之后, 紧临所述前 同步码序列,且所述保护间隔、所述前同步码序列和循环前缀的长度之和等于 所述随机接入信道的长度。  In the above embodiment, the guard interval is located after the preamble sequence, immediately adjacent to the preamble sequence, and the sum of the guard interval, the preamble sequence, and the length of the cyclic prefix is equal to the The length of the random access channel.
在上述实施例中,所述保护间隔长度的取值范围为大于零小于等于 2倍小 区半径距离对应的光速所经历的时间。  In the above embodiment, the guard interval length ranges from greater than zero to less than or equal to 2 times the distance traveled by the aperture distance.
在上述实施例中,所述 UE在所述可供选择的前同步码序列中随机选取一 个前同步码序列具体为: 所述 UE根据当前的下行信道质量对所述前同步码序 列进行选择。 In the above embodiment, the UE randomly selects one preamble sequence in the optional preamble sequence, where the UE is: according to the current downlink channel quality, the preamble sequence. Column to make a selection.
在上述实施例中, 所述随机接入前同步码序列为直接产生的长同步码序 列, 或由短同步码序列进行重复后形成。  In the above embodiment, the random access preamble sequence is a directly generated long synchronization code sequence, or is formed by repeating a short synchronization code sequence.
在上述实施例中, 所述同步码序列为 Zadoff-Chu序列、 GCL序列、 Golay 序列或 Barker序列。  In the above embodiment, the synchronization code sequence is a Zadoff-Chu sequence, a GCL sequence, a Golay sequence or a Barker sequence.
本发明再一方面还提出了一种随机接入信道,所述随机接入信道的长度大 于所述前同步码序列的长度,所述随机接入信道内包含至少一空白区域,作为 UE向基站发送的前同步码序列的保护间隔。  A further aspect of the present invention further provides a random access channel, where the length of the random access channel is greater than the length of the preamble sequence, and the random access channel includes at least one blank area as a UE to the base station. The guard interval of the transmitted preamble sequence.
作为本发明的一个实施例,所述随机接入信道的长度为上行时隙长度的整 数倍。  As an embodiment of the present invention, the length of the random access channel is an integer multiple of the length of the uplink time slot.
作为本发明的一个实施例, 所述保护间隔位于所述前同步码序列之后, 紧 临所述前同步码序列, 所述保护间隔、所述前同步码序列和循环前缀的长度之 和等于所述随机接入信道的长度。  As an embodiment of the present invention, the guard interval is located after the preamble sequence, immediately adjacent to the preamble sequence, and the sum of the guard interval, the preamble sequence, and the length of the cyclic prefix is equal to The length of the random access channel.
在上述实施例中, 所述保护间隔时间长度的取值范围为大于零小于等于 2 倍小区半径距离对应的光速所经历的时间。  In the above embodiment, the guard interval length ranges from greater than zero to less than or equal to the time elapsed for the optical speed corresponding to the cell radius distance.
本发明再一方面还提出了一种 UE, 包括: 序列选择模块, 用于选择获取 基站广播信息中的前同步码序列; 随机接入信道形成模块, 用于依据所述广播 信息及所选择的前同步码序列形成随机接入信道; 发送模块, 用于通过随机接 入信道将前同步码序列发送给小区的基站 ,所述随机接入信道还包含有一空白 区域, 作为所述前同步码序列的保护间隔; 基站响应检测模块, 用于对基站响 应信道进行检测判断是否接入成功。  A further aspect of the present invention further provides a UE, comprising: a sequence selection module, configured to select a preamble sequence in the base station broadcast information; and a random access channel forming module, configured to use the broadcast information and the selected The preamble sequence forms a random access channel; the sending module is configured to send the preamble sequence to the base station of the cell by using a random access channel, where the random access channel further includes a blank area as the preamble sequence The protection interval of the base station is used to detect the response channel of the base station to determine whether the access is successful.
作为本发明的一个实施例,所述前同步码序列及保护间隔位于远离上下行 保护间隔的上行时隙当中。  As an embodiment of the present invention, the preamble sequence and the guard interval are located in an uplink slot that is away from the uplink and downlink guard interval.
作为本发明的一个实施例,所述随机接入信道的长度为上行时隙长度的整 数倍。  As an embodiment of the present invention, the length of the random access channel is an integer multiple of the length of the uplink time slot.
本发明再一方面还提出了一种基站, 包括: 广播模块, 用于将随机接入信 道的位置信息及本小区可使用的前同步码序列通过广播信道进行广播;随机接 入序列检测模块, 用于检测随机接入信道内的前同步码序列, 所述随机接入信 道还包含有一空白区域,作为所述前同步码序列的保护间隔; 随机接入响应模 块, 用于通过响应信道对检测到的前同步码序列进行响应。 A further aspect of the present invention provides a base station, including: a broadcast module, configured to broadcast location information of a random access channel and a preamble sequence usable by the current cell through a broadcast channel; and a random access sequence detecting module, And a preamble sequence for detecting a random access channel, where the random access channel further includes a blank area as a guard interval of the preamble sequence; a random access response mode a block, configured to respond to the detected preamble sequence by a response channel.
作为本发明的一个实施例,还包括上行时隙设置模块, 用于根据覆盖范围 及所述前同步码序列及保护间隔所占用的时隙宽度配置上行时隙。  As an embodiment of the present invention, an uplink time slot setting module is further configured to configure an uplink time slot according to a coverage area and a time slot width occupied by the preamble sequence and the guard interval.
作为本发明的一个实施例,还包括前同步码序列分组模块, 用于依据各前 同步码序列所对应的分组条件进行分组。  As an embodiment of the present invention, a preamble sequence grouping module is further included for grouping according to a grouping condition corresponding to each preamble sequence.
本发明还提出了一种时分双工随机接入系统,包括基站和所述基站服务的 至少一个 UE, 所述基站包括: 广播模块, 用于将随机接入信道的位置信息及 本小区可使用的前同步码序列通过广播信道进行广播; 随机接入序列检测模 块, 用于检测随机接入信道内 UE发送的前同步码序列; 随机接入响应模块, 用于通过响应信道对检测到的前同步码序列进行响应;, 所述 UE包括: 序列 选择模块, 用于选择获取基站广播信息中的前同步码序列; 随机接入信道形成 模块, 用于依据所述广播信息及所选择的前同步码序列形成随机接入信道; 发 送模块, 用于通过随机接入信道将前同步码序列发送给小区基站, 所述随机接 入信道还包含有一空白区域,作为所述前同步码序列的保护间隔;基站响应检 测模块, 用于对基站响应信道进行检测判断是否接入成功。  The present invention also provides a time division duplex random access system, comprising: a base station and at least one UE served by the base station, the base station comprising: a broadcast module, configured to use location information of the random access channel and the local cell to be used The preamble sequence is broadcasted through a broadcast channel; a random access sequence detection module is configured to detect a preamble sequence sent by the UE in the random access channel; and a random access response module is configured to detect the preamble through the response channel pair The synchronization code sequence is responsive; the UE includes: a sequence selection module, configured to select a preamble sequence in the base station broadcast information, and a random access channel formation module, configured to use the broadcast information and the selected preamble The code sequence forms a random access channel; the sending module is configured to send the preamble sequence to the cell base station by using a random access channel, where the random access channel further includes a blank area as a guard interval of the preamble sequence a base station response detecting module, configured to detect, according to a response channel of the base station, whether the access is successful
作为本发明的一个实施例,所述前同步码序列及保护间隔位于远离上下行 保护间隔的上行时隙当中。本发明针对宽带时分双工蜂窝系统,在中等覆盖和 大覆盖情况下, 提出的自身含有保护间隔的随机接入信道设计方案, 不要求 preamble序列紧临上下行保护间隔,使随机接入信道的分配更加灵活。本发明 通过将带有保护间隔的 preamble序列尽量置于远离上下行保护间隔的上行时 隙位置,从而依据该随机接入信道的分配准则可以尽可能的避免远端基站的干 扰, 保证本小区基站对随机接入信道进行正确检测, 能够实现 UE准确、 快速 的随机接入, 为 OFDM系统实现 UE随机接入提供了有效的解决方案。 附图说明  As an embodiment of the present invention, the preamble sequence and the guard interval are located in an uplink slot that is away from the uplink and downlink guard interval. The present invention is directed to a broadband time division duplex cellular system. In the case of medium coverage and large coverage, the proposed random access channel design scheme with guard interval does not require the preamble sequence to be close to the uplink and downlink protection interval, so that the random access channel is The allocation is more flexible. The present invention places the preamble sequence with the guard interval as far as possible from the uplink time slot position of the uplink and downlink guard interval, so that the interference of the remote base station can be avoided as much as possible according to the allocation criterion of the random access channel, and the base station of the base station is guaranteed. Correct detection of the random access channel can achieve accurate and fast random access of the UE, and provides an effective solution for the OFDM system to achieve random access of the UE. DRAWINGS
图 1(a)为现有技术原始 TD-SCDMA演进系统帧结构及随机接入 UpPTS 的设计图;  1(a) is a design diagram of a frame structure of a prior art original TD-SCDMA evolution system and a random access UpPTS;
图 1(b)为现有技术 TD-SCDMA演进系统在大覆盖情况下的帧结构; 图 2为本发明一个实施例提出的跟随保护间隔的 Preamble序列结构; 8 001461 图 3 ( a ) 为本发明一个实施例提出的 5km小覆盖情况下随机接入信道位 置分配图; 1(b) is a frame structure of a prior art TD-SCDMA evolution system in a case of large coverage; FIG. 2 is a Preamble sequence structure following a guard interval according to an embodiment of the present invention; 8 001461 FIG. 3 ( a ) is a diagram of a random access channel location allocation in a case of a small coverage of 5 km according to an embodiment of the present invention;
图 3 ( b )为本发明一个实施例提出的 30km中覆盖情况下随机接入信道位 置分配图;  FIG. 3(b) is a diagram showing a random access channel position allocation in a case of coverage of 30 km according to an embodiment of the present invention;
图 3 ( c ) 为本发明一个实施例提出的 100km大覆盖情况下随机接入信道 位置分配图;  FIG. 3(c) is a diagram showing a location allocation of a random access channel in a case of a large coverage of 100 km according to an embodiment of the present invention;
图 4 ( a )为本发明一个实施例提出的 TS4为下行时隙 5km小覆盖情况下 随机接入信道位置分配图;  4(a) is a diagram showing a random access channel location allocation in the case where TS4 is a small coverage of 5 km downlink time slot according to an embodiment of the present invention;
图 4 ( b ) 为本发明一个实施例提出的 TS4为下行时隙 30km中覆盖情况 下随机接入信道位置分配图;  4(b) is a diagram showing a random access channel location allocation in the case where the TS4 is a coverage of a downlink time slot of 30 km according to an embodiment of the present invention;
图 4 ( c )为本发明一个实施例提出的 TS4为下行时隙 100km大覆盖情况 下随机接入信道位置分配图;  4(c) is a diagram showing a random access channel location allocation diagram in the case where TS4 is a 100 mL large coverage of a downlink time slot according to an embodiment of the present invention;
图 5为本发明一个实施例提出的 UE与基站之间随机接入过程的时序步骤 图;  FIG. 5 is a sequence diagram of a random access procedure between a UE and a base station according to an embodiment of the present invention;
图 6为本发明一个实施例提出的 UE及基站的随机接入部分的模块组成 图。 具体实施方式  FIG. 6 is a block diagram of a random access part of a UE and a base station according to an embodiment of the present invention. detailed description
本发明的主要思想是,对随机接入信道结构进行重新设计,在可以进行上 行信道分配的情况下,使得该重新设计的随机接入信道能够在上行信道中灵活 的配置, 将本小区随机接入 preamble序列的发送位置远离远端基站的 TS0时 隙和 DwPTS时隙到达本小区的时刻, 尽可能的减少远端基站的下行时隙对本 小区 preamble序列的干扰,从而提高随机接入信道的检测成功率及 UE的接入 速度。  The main idea of the present invention is to redesign the random access channel structure, and in the case that uplink channel allocation is possible, the redesigned random access channel can be flexibly configured in the uplink channel, and the cell is randomly connected. The sending position of the preamble sequence is far away from the time when the TS0 time slot and the DwPTS time slot of the remote base station reach the local cell, and the interference of the downlink time slot of the remote base station to the preamble sequence of the current cell is reduced as much as possible, thereby improving the detection of the random access channel. Success rate and access speed of the UE.
作为本发明的一个实施例,本发明为在随机接入信道内包含有一个不发送 任何数据的空白区域, 该空白区域内作为 preamble序列的保护间隔 (GT), 用 来消除由于 preamble序列的时间不确定性而造成的对前后数据时隙的干扰, 如图 2所示。当然作为本发明的一个优选方案在随机接入信道内设置一个保护 间隔,但本领域技术人员应当明白设置多个保护间隔,如前后各设置一个保护 间隔, 同样也能够达到本发明的目的, 同样也应为本发明保护范围所涵盖。 作 为本发明的一个优选方案, 保护间隔 GT、 前同步码序列和循环前缀 CP的长 度之和等于随机接入信道的长度。使用该改进的随机接入信道分配结构, 随机 接入信道就不必限定在紧邻 GP来进行分配了, 因为这个随机接入信道分配结 构中的 preamble序列有自己的保护间隔, 可以避免 preamble序列向前或者是 向后移动时, 干扰到前后的数据时隙。 其中, GT的取值范围理论上为大于零, 小于等于光速经历小区半径的两倍距离所需时间。 作为本发明的一个实施例, 本发明中 GT的取值可配置, 在满足基站接收信噪比的情况下, 可主要由基站 天线覆盖距离决定其值大小。 一般, UE在发送 preamble序列时会预估一个时 间提前量使得其发送的 preamble序列能够在其目标时刻到达基站。 以图 3 ( b ) 为例, preamble序列的目标时刻应当在 TS3时隙起始位置,假若某个 UE在小 区边缘, 该 UE在发送 preamble序列时需提前 GT/2的时间, 其发送 preamble 序列就会在 TS3时隙起始位置到达本小区基站, 这样 preamble序列由于有了 保护间隔就不会影响到前后的数据时隙。 As an embodiment of the present invention, the present invention includes a blank area in the random access channel that does not transmit any data, and the guard interval (GT) as a preamble sequence in the blank area is used to eliminate the time due to the preamble sequence. The interference caused by the uncertainty to the data slots before and after, as shown in Figure 2. Of course, as a preferred solution of the present invention, a guard interval is set in the random access channel, but those skilled in the art should understand that setting multiple guard intervals, such as setting a protection before and after. Intervals, as well as the objects of the invention, are also encompassed by the scope of the invention. As a preferred embodiment of the present invention, the sum of the guard interval GT, the preamble sequence, and the cyclic prefix CP is equal to the length of the random access channel. With the improved random access channel allocation structure, the random access channel is not necessarily limited to the GP to allocate, because the preamble sequence in the random access channel allocation structure has its own guard interval, which can avoid the preamble sequence forward. Or when moving backwards, it interferes with the data slots before and after. The range of values of the GT is theoretically greater than zero, and is less than or equal to the time required for the speed of light to travel twice the radius of the cell. As an embodiment of the present invention, the value of the GT in the present invention is configurable, and in the case that the base station receives the signal to noise ratio, the base station antenna coverage distance may be determined by the base station antenna. In general, the UE estimates a timing advance when transmitting the preamble sequence such that the preamble sequence it transmits can reach the base station at its target time. As shown in Figure 3 (b), the target moment of the preamble sequence should be at the beginning of the TS3 slot. If a UE is at the cell edge, the UE needs to advance GT/2 time when transmitting the preamble sequence, which sends the preamble sequence. The cell base station will arrive at the start position of the TS3 slot, so that the preamble sequence will not affect the data slots before and after due to the guard interval.
将图 1 ( b )与图 3 ( b )和图 3 ( c )对照可以看出, 在现有的中等覆盖和 大覆盖系统的随机接入信道的分配结构中, preamble序列只能分配在紧临 GP 的位置, 而在可以进行上行信道分配的情况下,使用图 2所示的带保护间隔的 Preamble序列结构, 其在随机接入信道中发送的具体位置, 不再被限制在 GP 后面的第一个时隙中, 而是可以在基站调度的上行信道中进行灵活的配置。作 为本发明的一个实施例, Preamble序列可置于尽可能与 GP远离的位置, 其需 要根据基站调度的上行时隙的数量及位置具体设定,如可将随机接入 preamble 序列置于 TS3和 TS4时隙位置,或可将随机接入 preamble序列置于 TS5和 TS6 时隙位置, 甚至更远的时隙位置。 另外 Preamble序列也可占用 2个以上的时 隙,其具体占用的时隙数在以下的描述中将详细介绍。 因此可以看出随机接入 信道的设置会因为基站调度的上行时隙的具体情况而不同,随机接入信道的结 构会有多种方式,本发明以下随机接入信道的图 3和图 4的示例仅是为了便于 理解本发明, 并不是说本发明仅能通过下述的示例实现。  Comparing Fig. 1(b) with Fig. 3(b) and Fig. 3(c), it can be seen that in the allocation structure of the random access channel of the existing medium coverage and large coverage systems, the preamble sequence can only be assigned tightly. The location of the GP, and in the case where uplink channel allocation is possible, the Preamble sequence structure with guard interval shown in FIG. 2 is used, and the specific location transmitted in the random access channel is no longer limited to the GP. In the first time slot, it can be flexibly configured in the uplink channel scheduled by the base station. As an embodiment of the present invention, the Preamble sequence can be placed as far as possible from the GP, which needs to be specifically set according to the number and location of uplink time slots scheduled by the base station, such as placing the random access preamble sequence in TS3 and The TS4 slot position, or the random access preamble sequence can be placed in the TS5 and TS6 slot positions, or even further slot positions. In addition, the Preamble sequence can occupy more than two time slots, and the number of specific occupied slots will be described in detail in the following description. Therefore, it can be seen that the setting of the random access channel is different due to the specific conditions of the uplink time slot scheduled by the base station, and the structure of the random access channel may have multiple modes. The following random access channels of the present invention are shown in FIG. 3 and FIG. The examples are only for the purpose of facilitating the understanding of the present invention, and it is not intended that the present invention can be realized only by the examples described below.
如图 3 ( c )所示的大覆盖系统中, 在干扰比较大的情况下, 当 TS3和 TS4 也是上行时隙, 可以将随机接入 preamble序列置于 TS3和 TS4时隙位置。 将 preamble序列置于 TS3和 TS4时隙位置, 使得随机接入 preamble序列的发送 位置远离了远端基站 TS0时隙和 DwPTS时隙到达本小区的时刻,从而避免远 端基站 TS0时隙和 DwPTS时隙对本小区 preamble序列的干扰。 In the large coverage system shown in Figure 3 (c), when the interference is relatively large, when TS3 and TS4 are also uplink time slots, the random access preamble sequence can be placed in the TS3 and TS4 time slot positions. will The preamble sequence is placed at the TS3 and TS4 slot positions, so that the transmission position of the random access preamble sequence is far away from the time when the remote base station TS0 slot and the DwPTS slot reach the local cell, thereby avoiding the remote base station TS0 slot and DwPTS slot. Interference with the preamble sequence of the cell.
图 4 )和图 4 ( c )分别给出了小覆盖情况和大覆盖情况下, TS4为下 行时隙, 随机接入 preamble序列位置分配方案对照图, 图 4 ( b )给出了中覆 盖情况, TS3 为下行时隙时随机接入 preamble序列位置分配方案。 在中覆盖 情况下,由于 TS3为下行,因此随机接入 preamble序列只能分配在 TS1和 TS2 时隙位置。 在大覆盖情况下, 由于 TS4为下行, 这样随机接入 preamble序列 只能分配在 TS2和 TS3时隙位置。 与不含 GT的方案相比, 这种随机接入信 道分配方案中, preamble序列不会占用 GP的时间,因而远端基站 TS0和 DwPTS 的干扰会小。 实际中, 这种结构可主要应用在 TS0和 DwPTS干扰不是很大的 小区中。  Figure 4) and Figure 4 (c) show the comparison of the location allocation scheme of the random access preamble sequence with the small coverage and large coverage, TS4 is the downlink time slot, and Figure 4 (b) shows the medium coverage. TS3 is a random access preamble sequence location allocation scheme for downlink time slots. In the case of medium coverage, since TS3 is downlink, the random access preamble sequence can only be allocated in the TS1 and TS2 slot positions. In the case of large coverage, since TS4 is downlink, the random access preamble sequence can only be allocated in the TS2 and TS3 slot positions. Compared with the GT-free scheme, in the random access channel allocation scheme, the preamble sequence does not occupy the GP time, and the interference of the remote base stations TS0 and DwPTS is small. In practice, this structure can be mainly applied to cells in which TS0 and DwPTS interference is not very large.
使用本发明所设计的带有保护间隔的随机接入 preamble序列结构, 在中 等覆盖和大覆盖系统的随机接入信道中的分配准则是: 在有足够的上行信道 时, 根据干扰的情况来进行随机接入 preamble序列位置的分配, 当干扰比较 大的时候, 将随机接入 preamble序列及其保护间隔的位置尽量分配在远离上 下行保护间隔的上行时隙位置。 这样, 在有足够多的上行时隙的情况下, 就能 够避免远端基站的干扰。  With the random access preamble sequence structure with guard interval designed by the present invention, the allocation criterion in the random access channel of the medium coverage and the large coverage system is: when there is enough uplink channel, according to the interference situation Random access preamble sequence location allocation. When the interference is relatively large, the random access preamble sequence and its guard interval are allocated as far as possible to the uplink time slot position away from the uplink and downlink guard interval. Thus, in the case where there are enough uplink time slots, the interference of the remote base station can be avoided.
作为本发明的一个实施例,具体某个小区的 TS0和 DwPTS的干扰可以在 小区进行初始设置时进行测定,根据测定值进行随机接入信道的分配即可, 不 必动态的测定, 而且动态的测定也比较复杂并且比较难于测准。  As an embodiment of the present invention, the interference of the TS0 and the DwPTS of a specific cell may be measured when the cell is initially set, and the random access channel may be allocated according to the measured value, without dynamic measurement, and dynamic measurement It is also complicated and difficult to measure.
图 3和图 4中给出的带保护间隔的随机接入 preamble序列长度都是对应 两个时隙的长度, 然而实际中, 为了保证检测概率, 随机接入 preamble序列 和 GT可能更长, 也就是 N个时隙的长度。 即  The lengths of the random access preamble sequences with guard intervals given in FIG. 3 and FIG. 4 are both corresponding to the length of two time slots. However, in practice, in order to ensure the detection probability, the random access preamble sequence and the GT may be longer, It is the length of N time slots. which is
Length ( preamble序歹 'J + GT ) = NxLength ( TS )  Length ( preamble serial number 'J + GT ) = NxLength ( TS )
Length表示求取时间长度的函数, 对于中等覆盖来说, N 为大于等于 1 的整数, 也就是说, preamble和 GT的时间长度可以放在一个时隙内; 对于大 覆盖来说, N只能取大于 1的整数, 因为仅仅一个时隙用来进行 preamble的 传输对于大覆盖来说是不够的。 上述公式的含义是, preamble序列与 GT保护 间隔的所占用时长之和等于 TD-SCDMA中一个时隙的整数倍。 Length represents a function of the length of time. For medium coverage, N is an integer greater than or equal to 1, that is, the length of the preamble and GT can be placed in one time slot. For large coverage, N can only be taken. An integer greater than 1, because only one time slot is used for preamble transmission is not sufficient for large coverage. The meaning of the above formula is: preamble sequence and GT protection The sum of the occupied durations of the intervals is equal to an integer multiple of one slot in TD-SCDMA.
在干扰比较强的情况下, 本发明所述的带保护间隔的随机接入 preamble 序列在随机接入信道中的分配准则适用于任意长度的随机接入 preamble序列。  In the case that the interference is relatively strong, the allocation criterion of the random access preamble sequence with guard interval according to the present invention in the random access channel is applicable to the random access preamble sequence of any length.
作为本发明的一个实施例,本发明具体实施例中可采用以下方法产生大半 径小区的长 preamble序列:  As an embodiment of the present invention, in the specific embodiment of the present invention, the following method may be used to generate a long preamble sequence of a large-area cell:
A、 直接产生长的 preamble序列。 这种方法的好处是可以使用的序列数目 多, 但是产生长 preamble序列的复杂度比较高, 实现较为困难;  A. Directly generate a long preamble sequence. The advantage of this method is that the number of sequences that can be used is large, but the complexity of generating long preamble sequences is relatively high, and implementation is difficult;
B、将较短长度的 preamble序列进行重复, 来构成长的 preamble序列。这 种方法的好处是在提供足够多的序列数目的同时,能够避免直接产生长序列的 高复杂度, 还能够在一定程度上提高检测性能。  B. The shorter length preamble sequence is repeated to form a long preamble sequence. The advantage of this method is that while providing a sufficient number of sequences, it can avoid the high complexity of directly generating long sequences, and can improve the detection performance to some extent.
作为本发明的一个实施例, 本发明中具体 preamble序列的选择, 可以选 择具有良好自相关和互相关特性的 Zadoff-Chu序列, GCL序列, Golay序列, 或者是 Barker序列等。  As an embodiment of the present invention, the selection of a specific preamble sequence in the present invention may select a Zadoff-Chu sequence, a GCL sequence, a Golay sequence, or a Barker sequence having good autocorrelation and cross-correlation properties.
图 5为 UE与基站之间随机接入过程的时序步骤图,根据信号发送的时间 顺序, 整个随机接入过程可以分为 4个步骤, 以下进行详细描述:  FIG. 5 is a timing sequence diagram of a random access procedure between a UE and a base station. According to the time sequence of signal transmission, the entire random access procedure can be divided into four steps, which are described in detail below:
步骤 1:基站将随机接入信道的位置信息,和本小区可使用的全部 preamble 序列标识通过广播信道进行广播。  Step 1: The base station broadcasts the location information of the random access channel and all preamble sequence identifiers that can be used by the cell through the broadcast channel.
由于随机接入信道长度的限制,基站分配的上行时隙数目也会受到一定的 限制。 与现有技术不同的是, 采用本发明所揭示的技术方案, 此时的上行时隙 数目需要满足发送随机接入信道长度的要求。对于中等覆盖来说,基站至少要 分配一个上行时隙,如果随机接入信道占用了两个上行时隙的长度的话, 那么 基站至少要分配两个上行时隙; 对于大覆盖来说,基站至少要分配两个上行时 隙, 否则随机接入信道无法分配。 在根据随机接入信道的长度, 以及系统上行 数据量要求, 分配完上行时隙个数之后, 基站再根据当前小区中, 估计的发起 随机接入用户的数目来分配随机接入信道的数目。在确定了随机接入信道的长 度之后,可根据基站调度的上行时隙和随机接入信道的长度确定随机接入信道 的位置, 以使随机接入信道位于远离上下行保护间隔的上行时隙中。 如图 3 中, 可将随机接入信道的长度设为两个 TS, 在 TS4为上行时隙时将随机接入 信道设在 TS3和 TS4上;而在图 4中,同样随机接入信道的长度设为两个 TS, 但由于 TS4为下行时隙, 则只能将随机接入信道设在 TS2和 TS3上。 当然这 仅是为了便于理解所例举的情况,随机接入信道的设置会根据基站调度的不同 而不同,但是基于本发明主要思想在随机接入信道内设置保护间隔的均应为本 发明保护范围所涵盖。 最后, 基站将随机接入信道的位置信息, 和本小区使用 的 preamble序列通过广播信道进行广播。 Due to the limitation of the random access channel length, the number of uplink time slots allocated by the base station is also limited. Different from the prior art, with the technical solution disclosed by the present invention, the number of uplink time slots at this time needs to meet the requirement of sending a random access channel length. For medium coverage, the base station must allocate at least one uplink time slot. If the random access channel occupies the length of two uplink time slots, then the base station needs to allocate at least two uplink time slots; for large coverage, the base station at least Two uplink time slots are to be allocated, otherwise the random access channel cannot be allocated. After allocating the number of uplink time slots according to the length of the random access channel and the uplink data volume requirement of the system, the base station allocates the number of random access channels according to the estimated number of initiated random access users in the current cell. After determining the length of the random access channel, the location of the random access channel may be determined according to the uplink time slot and the length of the random access channel scheduled by the base station, so that the random access channel is located in an uplink time slot that is far away from the uplink and downlink protection interval. in. As shown in FIG. 3, the length of the random access channel can be set to two TSs, and when the TS4 is an uplink time slot, the random access channel is set on TS3 and TS4; and in FIG. 4, the same random access channel is used. The length is set to two TSs, However, since TS4 is a downlink time slot, only random access channels can be set on TS2 and TS3. Of course, this is only for the convenience of understanding the case. The setting of the random access channel may be different according to the scheduling of the base station. However, according to the main idea of the present invention, the protection interval in the random access channel should be protected by the invention. Covered by the scope. Finally, the base station broadcasts the location information of the random access channel and the preamble sequence used by the local cell through the broadcast channel.
在 TD-SCDMA中,一个小区可使用的 preamble序列的个数在小区规划时 已规划好, 如规划个数为 16 , 则小区基站在向下广播时会将所有可用的 preamble序列广播下去, 由 UE自己随机选择。  In TD-SCDMA, the number of preamble sequences that can be used by a cell is planned in the cell planning. If the number of planning is 16, the cell base station broadcasts all available preamble sequences when broadcasting downwards. The UE randomly chooses itself.
在本发明的一个具体实施例中,为了向 UE标识 preamble序列所对应的信 道传输质量, 将所有可用的 preamble序列进行分组, 如 16个序列分为两组 , 即分组 1和分组 2,那么选择分组 1中的序列,就隐含其下行信道质量比较好; 如果选择的序列位于分组 2中,就隐含其下行信道质量比较差。进行分组的条 件除上述的下行信道质量外, 还可选择其它一些参数。  In a specific embodiment of the present invention, in order to identify the channel transmission quality corresponding to the preamble sequence to the UE, all available preamble sequences are grouped, for example, 16 sequences are divided into two groups, namely, group 1 and group 2, then select The sequence in packet 1 implies that the downlink channel quality is better; if the selected sequence is located in packet 2, the downlink channel quality is implied. The conditions for grouping may include other parameters in addition to the downlink channel quality described above.
步骤 2: 从全部 preamble序列中随机选取一个 preamble序列, 并从根据 基站提供的随机接入信道的位置信息在随机接入信道上将选取的 preamble序 列发送给基站。  Step 2: randomly select a preamble sequence from all preamble sequences, and send the selected preamble sequence to the base station on the random access channel according to the location information of the random access channel provided by the base station.
UE根据基站的广播信息,根据当前需要利用 preamble序列传输的隐含信 息, 从可选的 preamble序列组中随机选择一个 preamble序列 , 然后, 再在全 部随机接入信道中任意选择一个信道, 发送该 preamble序列。  The UE randomly selects a preamble sequence from the optional preamble sequence group according to the broadcast information of the base station according to the current implicit information transmitted by the preamble sequence, and then arbitrarily selects one channel among all the random access channels, and sends the Preamble sequence.
此 preamble的发送定时提前量根据时间提前量算法进行确定。 由于将 GT 放在了 preamble 的后面, 所以需要在该时间提前量上面减去一个常数, 即 GT/2, 这样可以使得 preamble在随机接入信道范围内, 不至于干扰到前后的 数据时隙。  The transmission timing advance of this preamble is determined according to the timing advance algorithm. Since the GT is placed after the preamble, it is necessary to subtract a constant from the time advance, ie GT/2, so that the preamble can be within the random access channel range without disturbing the data slots before and after.
步骤 3: 基站在分配的随机接入信道位置进行 preamble序列的检测。 该检 测为相关检测, 基站对检测出的 preamble序列进行响应, 响应信道为固定信 道。 基站的响应信息包括响应的 preamble序列、 时间提前量信息等, 也可以 包括该 preamble序列对应的资源分配信息, 当然, 所述的资源分配信息也可 以是默认的, 即不用发送。  Step 3: The base station performs preamble sequence detection on the allocated random access channel location. The detection is correlation detection, and the base station responds to the detected preamble sequence, and the response channel is a fixed channel. The response information of the base station includes the preamble sequence of the response, the timing advance information, and the like, and may also include resource allocation information corresponding to the preamble sequence. Of course, the resource allocation information may also be default, that is, not sent.
步骤 4: UE在一个固定的时间长度内, 对基站响应信道进行检测, 如果 检测到了自己发送的 preamble序列,那么 UE就认为自己被基站检测到了。然 后, UE在该 preamble对应的上行资源上, 发送数据。 Step 4: The UE detects the base station response channel within a fixed length of time, if When the preamble sequence sent by itself is detected, the UE considers that it has been detected by the base station. Then, the UE sends data on the uplink resource corresponding to the preamble.
图 6为本发明一个实施例的时分双工随机接入系统结构图,该系统包括基 站和所述基站服务的至少一个 UE。  6 is a structural diagram of a time division duplex random access system according to an embodiment of the present invention, the system including a base station and at least one UE served by the base station.
其中, 作为本发明的一个实施例, 基站包括: 广播模块、 随机接入序列检 测模块、 随机接入响应模块、 上行时隙设置模块、 前同步码序列分组模块。 广 播模块,用于将随机接入信道的位置信息及本小区可使用的前同步码序列通过 广播信道进行广播。 随机接入序列检测模块, 用于检测随机接入信道内的前同 步码序列, 所述前同步码序列携带有自身的保护间隔。 随机接入响应模块, 用 于通过响应信道对检测到的前同步码序列进行响应。上行时隙设置模块, 用于 根据覆盖范围及所述前同步码序列及保护间隔所占用的时隙宽度配置上行时 隙, 该模块的目的是使上行时隙数目必须满足发送随机接入信道长度的要求, 所述设置可在系统初始化时设定。前同步码序列分组模块, 用于依据各前同步 码序列所对应的分组条件,如下行信道质量等,对所述前同步码序列进行分组。 分组本身就向客户端标识了有关分组条件的有关信息,客户端可根据分组包含 的隐含信息执行相应的操作。  As an embodiment of the present invention, the base station includes: a broadcast module, a random access sequence detection module, a random access response module, an uplink time slot setting module, and a preamble sequence grouping module. And a broadcast module, configured to broadcast the location information of the random access channel and the preamble sequence usable by the local cell through the broadcast channel. The random access sequence detecting module is configured to detect a preamble sequence in the random access channel, where the preamble sequence carries its own guard interval. The random access response module is configured to respond to the detected preamble sequence through the response channel. An uplink time slot setting module, configured to configure an uplink time slot according to a coverage area and a time slot width occupied by the preamble sequence and the guard interval, wherein the purpose of the module is that the number of uplink time slots must meet the length of the random access channel. The requirements can be set at system initialization. The preamble sequence grouping module is configured to group the preamble sequence according to a packet condition corresponding to each preamble sequence, a channel quality, and the like. The packet itself identifies information about the packet conditions to the client, and the client can perform the appropriate action based on the implicit information contained in the packet.
其中, 作为本发明的一个实施例, UE包括: 序列选择模块、 随机接入信 道形成模块、 发送模块、 基站响应检测模块。 序列选择模块, 用于选择获取基 站广播信息中的前同步码序列。 随机接入信道形成模块, 用于依据小区广播信 息及所选择的前同步码序列形成随机接入信道,所形成的随机接入信道中前同 步码序列携带有自身的保护间隔, 前同步码序列及其保护间隔位于 TD-SCDMA帧中上行时隙的位置。 发送模块, 用于通过随机接入信道将前同 步码序列发送给小区基站。基站响应检测模块,用于对基站响应信道进行检测 判断是否接入成功。  As an embodiment of the present invention, the UE includes: a sequence selection module, a random access channel forming module, a sending module, and a base station response detecting module. A sequence selection module is configured to select a preamble sequence in the base station broadcast information. a random access channel forming module, configured to form a random access channel according to the cell broadcast information and the selected preamble sequence, where the preamble sequence in the formed random access channel carries its own guard interval, and the preamble sequence And its guard interval is located at the location of the upstream slot in the TD-SCDMA frame. And a sending module, configured to send the preamble sequence to the cell base station by using a random access channel. The base station response detecting module is configured to detect the base station response channel to determine whether the access is successful.
本发明对随机接入信道的结构进行了改进,结合使用本发明所揭示的随机 接入信道的分配准则,可以尽可能的避免远端小区 TS0时隙和 DwPTS时隙的 干扰对随机接入过程的影响, 从而实现 UE的准确、 快速的随机接入, 提高了 整个通信系统的运作效率。  The invention improves the structure of the random access channel, and in combination with the allocation criterion of the random access channel disclosed by the present invention, the interference of the remote cell TS0 time slot and the DwPTS time slot to the random access process can be avoided as much as possible. The impact of the UE, thus achieving accurate and fast random access of the UE, improves the operational efficiency of the entire communication system.
本发明还可有其它多种实施例, 在不背离本发明精神及其实质的情况下, 本领域技术人员当可根据本发明作出各种相应的改变和变形,但这些相应的改 变和变形都应属于本发明所附的权利要求的保护范围。 The invention may be embodied in a variety of other embodiments without departing from the spirit and scope of the invention. A person skilled in the art can make various corresponding changes and modifications in accordance with the present invention, but these respective changes and modifications are intended to fall within the scope of the appended claims.

Claims

权利要求书 Claim
1、 一种时分双工随机接入方法, 其特征在于, 包括以下步骤: A time division duplex random access method, characterized in that the method comprises the following steps:
基站将随机接入信道的位置信息和可供选择的前同步码序列通过广播信道 进行广播, 所述随机接入信道的长度大于所述前同步码序列的长度;  The base station broadcasts the location information of the random access channel and the selectable preamble sequence through a broadcast channel, where the length of the random access channel is greater than the length of the preamble sequence;
所述基站接收终端 UE通过所述随机接入信道发送的所述 UE选择的前同 步码序列, 所述随机接入信道内包含至少一空白区域, 作为所述 UE选择的前 同步码序列的保护间隔;  The base station receives a preamble sequence selected by the UE that is sent by the UE by using the random access channel, and the random access channel includes at least one blank area, which is used as protection of the preamble sequence selected by the UE. Interval
所述基站根据所述 UE发送的前同步码序列对所述 UE进行随机接入检测。 The base station performs random access detection on the UE according to a preamble sequence sent by the UE.
2、如权利要求 1所述时分双工随机接入方法, 其特征在于, 所述随机接入 信道的位置信息通过以下步骤确定: The time division duplex random access method according to claim 1, wherein the location information of the random access channel is determined by the following steps:
根据所述基站的覆盖范围和可供选择的前同步码序列的长度配置所述随机 接入信道的长度, 所述随机接入信道的长度为上行时隙长度的整数倍;  And configuring a length of the random access channel according to a coverage of the base station and a length of an optional preamble sequence, where a length of the random access channel is an integer multiple of an uplink time slot length;
根据所述基站调度的上行时隙和所述随机接入信道的长度确定所述随机接 入信道的位置,以使所述随机接入信道位于远离上下行保护间隔的上行时隙中。  And determining, according to the uplink time slot scheduled by the base station and the length of the random access channel, the location of the random access channel, so that the random access channel is located in an uplink time slot that is far away from the uplink and downlink guard interval.
3、如权利要求 1或 2所述时分双工随机接入方法, 其特征在于, 所述保护 间隔位于所述前同步码序列之后, 紧临所述前同步码序列。  The time division duplex random access method according to claim 1 or 2, wherein the guard interval is located after the preamble sequence and is immediately adjacent to the preamble sequence.
4、如权利要求 3所述时分双工随机接入方法,其特征在于,所述保护间隔、 所述前同步码序列和循环前缀的长度之和等于所述随机接入信道的长度。  The time division duplex random access method according to claim 3, wherein the sum of the guard interval, the length of the preamble sequence and the cyclic prefix is equal to the length of the random access channel.
5、如权利要求 4所述时分双工随机接入方法, 其特征在于, 所述保护间隔 长度的取值范围为大于零小于等于 2 倍小区半径距离对应的光速所经历的时 间。  The time division duplex random access method according to claim 4, wherein the guard interval length ranges from greater than zero to less than or equal to 2 times the speed of light corresponding to the cell radius distance.
6、如权利要求 4所述时分双工随机接入方法, 其特征在于, 在所述基站将 随机接入信道的位置信息和可供选择的前同步码序列通过广播信道进行广播之 前, 还包括:  The time division duplex random access method according to claim 4, further comprising: before the base station broadcasts the location information of the random access channel and the selectable preamble sequence through the broadcast channel, :
根据信道传输质量对所述前同步码序列进行分组, 所述 UE根据当前的下 行信道质量对分组后的所述前同步码序列进行选择。  The preamble sequence is grouped according to channel transmission quality, and the UE selects the grouped preamble sequence according to current downlink channel quality.
7、如权利要求 1所述时分双工随机接入方法, 其特征在于, 所述随机接入 前同步码序列为直接产生的长同步码序列,或由短同步码序列进行重复后形成。 The time division duplex random access method according to claim 1, wherein the random access preamble sequence is a directly generated long synchronization code sequence, or is formed by repeating a short synchronization code sequence.
8、如权利要求 1所述时分双工随机接入方法, 其特征在于, 所述同步码序 列为 Zadoff-Chu序列、 GCL序列、 Golay序列或 Barker序列。 The time division duplex random access method according to claim 1, wherein the synchronization code sequence is a Zadoff-Chu sequence, a GCL sequence, a Golay sequence or a Barker sequence.
9、 一种时分双工随机接入方法, 其特征在于, 包括以下步骤:  9. A time division duplex random access method, comprising: the following steps:
UE接收基站广播的随机接入信道的位置信息和可供选择的前同步码序列, 所述随机接入信道的长度大于所述前同步码序列的长度;  Receiving, by the UE, location information of the random access channel broadcast by the base station and an optional preamble sequence, where a length of the random access channel is greater than a length of the preamble sequence;
所述 UE在所述可供选择的前同步码序列中随机选取一个前同步码序列通 过随机接入信道向所述基站发送, 所述随机接入信道内包含至少一空白区域, 作为所述 UE选择的前同步码序列的保护间隔;  The UE randomly selects one preamble sequence in the optional preamble sequence to send to the base station by using a random access channel, where the random access channel includes at least one blank area as the UE. The guard interval of the selected preamble sequence;
所述 UE对所述基站的响应信道进行检测, 得到所述基站对所述 UE随机 接入检测的结果。  The UE detects a response channel of the base station, and obtains a result of the base station detecting the random access of the UE.
10、 如权利要求 9所述时分双工随机接入方法, 其特征在于, 所述随机接 入信道的位置信息通过以下步骤确定:  10. The time division duplex random access method according to claim 9, wherein the location information of the random access channel is determined by the following steps:
根据所述基站的覆盖范围和可供选择的前同步码序列的长度配置所述随机 接入信道的长度, 所述随机接入信道的长度为上行时隙长度的整数倍;  And configuring a length of the random access channel according to a coverage of the base station and a length of an optional preamble sequence, where a length of the random access channel is an integer multiple of an uplink time slot length;
根据所述基站调度的上行时隙和所述随机接入信道的长度确定所述随机接 入信道的位置,以使所述随机接入信道位于远离上下行保护间隔的上行时隙中。  And determining, according to the uplink time slot scheduled by the base station and the length of the random access channel, the location of the random access channel, so that the random access channel is located in an uplink time slot that is far away from the uplink and downlink guard interval.
11、 如权利要求 9或 10所述时分双工随机接入方法, 其特征在于, 所述保 护间隔位于所述前同步码序列之后, 紧临所述前同步码序列,且所述保护间隔、 所述前同步码序列和循环前缀的长度之和等于所述随机接入信道的长度。  The time division duplex random access method according to claim 9 or 10, wherein the guard interval is located after the preamble sequence, immediately adjacent to the preamble sequence, and the guard interval, The sum of the lengths of the preamble sequence and the cyclic prefix is equal to the length of the random access channel.
12、 如权利要求 11所述时分双工随机接入方法, 其特征在于, 所述保护间 隔长度的取值范围为大于零小于等于 2倍小区半径距离对应的光速所经历的时 间。  The time division duplex random access method according to claim 11, wherein the guard interval length ranges from greater than zero to less than or equal to 2 times the speed of light corresponding to the cell radius distance.
13、 如权利要求 9所述时分双工随机接入方法, 其特征在于, 所述 UE在 所述可供选择的前同步码序列中随机选取一个前同步码序列具体为:  The time division duplex random access method according to claim 9, wherein the UE randomly selects a preamble sequence in the selectable preamble sequence as follows:
所述 UE根据当前的下行信道质量对分组的所述前同步码序列进行选择。 The UE selects the preamble sequence of the packet according to the current downlink channel quality.
14、 如权利要求 9所述时分双工随机接入方法, 其特征在于, 所述随机接 入前同步码序列为直接产生的长同步码序列, 或由短同步码序列进行重复后形 成。 The time division duplex random access method according to claim 9, wherein the random access preamble sequence is a directly generated long synchronization code sequence, or is formed by repeating a short synchronization code sequence.
15、 如权利要求 9所述时分双工随机接入方法, 其特征在于, 所述同步码 序列为 Zadoff-Chu序列、 GCL序列、 Golay序列或 Barker序列。 The time division duplex random access method according to claim 9, wherein the synchronization code The sequence is a Zadoff-Chu sequence, a GCL sequence, a Golay sequence or a Barker sequence.
16、 一种随机接入信道, 其特征在于, 所述随机接入信道的长度大于其携 带的前同步码序列的长度,所述随机接入信道内包含至少一空白区域,作为 UE 向基站发送的前同步码序列的保护间隔。  A random access channel, wherein the length of the random access channel is greater than the length of the preamble sequence carried by the random access channel, and the random access channel includes at least one blank area, and the UE sends the base station to the base station. The guard interval of the preamble sequence.
17、如权利要求 16所述随机接入信道, 其特征在于, 所述随机接入信道的 长度为上行时隙长度的整数倍。  The random access channel according to claim 16, wherein the length of the random access channel is an integer multiple of the length of the uplink time slot.
18、如权利要求 16所述随机接入信道, 其特征在于, 所述保护间隔位于所 述前同步码序列之后, 紧临所述前同步码序列, 所述保护间隔与所述前同步码 序列的长度之和等于所述随机接入信道的长度。  The random access channel according to claim 16, wherein the guard interval is located after the preamble sequence, immediately adjacent to the preamble sequence, the guard interval and the preamble sequence The sum of the lengths is equal to the length of the random access channel.
19、如权利要求 18所述随机接入信道, 其特征在于, 所述保护间隔时间长 度的取值范围为大于零小于等于 2倍小区半径距离对应的光速所经历的时间。  The random access channel according to claim 18, wherein the guard interval time length ranges from greater than zero to less than or equal to 2 times the speed of light corresponding to the cell radius distance.
20、 一种 UE, 其特征在于, 包括:  20. A UE, comprising:
序列选择模块, 用于选择获取基站广播信息中的前同步码序列;  a sequence selection module, configured to select a preamble sequence in the base station broadcast information;
随机接入信道形成模块, 用于依据所述广播信息及所选择的前同步码序列 形成随机接入信道;  a random access channel forming module, configured to form a random access channel according to the broadcast information and the selected preamble sequence;
发送模块, 用于通过随机接入信道将前同步码序列发送给小区的基站, 所 述随机接入信道还包含有一空白区域, 作为所述前同步码序列的保护间隔; 基站响应检测模块, 用于对基站响应信道进行检测判断是否接入成功。 a sending module, configured to send a preamble sequence to a base station of a cell by using a random access channel, where the random access channel further includes a blank area as a guard interval of the preamble sequence; The base station response channel is detected to determine whether the access is successful.
21、 根据权利要求 20所述 UE, 其特征在于, 所述前同步码序列及保护间 隔位于远离上下行保护间隔的上行时隙当中。 The UE according to claim 20, wherein the preamble sequence and the guard interval are located in an uplink slot that is away from the uplink and downlink guard interval.
22、 根据权利要求 20所述 UE, 其特征在于, 所述随机接入信道的长度为 上行时隙长度的整数倍。  The UE according to claim 20, wherein the length of the random access channel is an integer multiple of the length of the uplink time slot.
23、 一种基站, 其特征在于, 包括:  A base station, comprising:
广播模块, 用于将随机接入信道的位置信息及本小区可使用的前同步码序 列通过广播信道进行广播, 所述随机接入信道的长度大于所述前同步码序列的 长度;  a broadcast module, configured to broadcast the location information of the random access channel and the preamble sequence usable by the local cell by using a broadcast channel, where a length of the random access channel is greater than a length of the preamble sequence;
随机接入序列检测模块, 用于检测随机接入信道内的前同步码序列, 所述 随机接入信道还包含有一空白区域, 作为所述前同步码序列的保护间隔;  a random access sequence detecting module, configured to detect a preamble sequence in a random access channel, where the random access channel further includes a blank area as a guard interval of the preamble sequence;
随机接入响应模块,用于通过响应信道对检测到的前同步码序列进行响应。 And a random access response module, configured to respond to the detected preamble sequence by using a response channel.
24、 如权利要求 23所述基站, 其特征在于, 还包括上行时隙设置模块, 用 于根据覆盖范围及所述前同步码序列及保护间隔所占用的时隙宽度配置上行时 隙。 The base station according to claim 23, further comprising an uplink time slot setting module, configured to configure an uplink time slot according to the coverage area and the time slot width occupied by the preamble sequence and the guard interval.
25、如权利要求 24所述基站,其特征在于,还包括前同步码序列分组模块, 用于依据各前同步码序列所对应的分组条件进行分组。  The base station according to claim 24, further comprising a preamble sequence grouping module, configured to perform grouping according to a grouping condition corresponding to each preamble sequence.
26、 一种时分双工随机接入系统, 其特征在于, 包括基站和所述基站服务 的至少一个 UE,  26. A time division duplex random access system, comprising: a base station and at least one UE served by the base station,
所述基站包括:  The base station includes:
广播模块, 用于将随机接入信道的位置信息及本小区可使用的前同步码序 列通过广播信道进行广播, 所述随机接入信道的长度大于所述前同步码序列的 长度;  a broadcast module, configured to broadcast the location information of the random access channel and the preamble sequence usable by the local cell by using a broadcast channel, where a length of the random access channel is greater than a length of the preamble sequence;
随机接入序列检测模块, 用于检测随机接入信道内 UE发送的前同步码序 列;  a random access sequence detecting module, configured to detect a preamble sequence sent by the UE in the random access channel;
随机接入响应模块,用于通过响应信道对检测到的前同步码序列进行响应; 所述 UE包括:  a random access response module, configured to respond to the detected preamble sequence by using a response channel; the UE includes:
序列选择模块, 用于选择获取基站广播信息中的前同步码序列;  a sequence selection module, configured to select a preamble sequence in the base station broadcast information;
随机接入信道形成模块, 用于依据所述广播信息及所选择的前同步码序列 形成随机接入信道;  a random access channel forming module, configured to form a random access channel according to the broadcast information and the selected preamble sequence;
发送模块, 用于通过随机接入信道将前同步码序列发送给小区基站, 所述 随机接入信道还包含有一空白区域, 作为所述前同步码序列的保护间隔;  a sending module, configured to send a preamble sequence to the cell base station by using a random access channel, where the random access channel further includes a blank area as a guard interval of the preamble sequence;
基站响应检测模块, 用于对基站响应信道进行检测判断是否接入成功。 The base station response detecting module is configured to detect, according to the base station response channel, whether the access is successful.
27、如权利要求 26所述时分双工随机接入系统, 其特征在于, 所述前同步 码序列及保护间隔位于远离上下行保护间隔的上行时隙当中。 The time division duplex random access system according to claim 26, wherein the preamble sequence and the guard interval are located in an uplink slot that is away from the uplink and downlink guard interval.
PCT/CN2008/001461 2007-08-13 2008-08-13 Method, system and apparatus for tdd random access WO2009021405A1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
CN2007101202316A CN101369840B (en) 2007-08-13 2007-08-13 TDD accidental access method, system and its composition modules
CN200710120231.6 2007-08-13

Publications (1)

Publication Number Publication Date
WO2009021405A1 true WO2009021405A1 (en) 2009-02-19

Family

ID=40350363

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/CN2008/001461 WO2009021405A1 (en) 2007-08-13 2008-08-13 Method, system and apparatus for tdd random access

Country Status (2)

Country Link
CN (1) CN101369840B (en)
WO (1) WO2009021405A1 (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2020087497A1 (en) * 2018-11-02 2020-05-07 Qualcomm Incorporated Implicit base station identification for remote interference management

Families Citing this family (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101159526B (en) * 2007-10-29 2014-03-19 中兴通讯股份有限公司 Data transmission method
US8406780B2 (en) * 2011-01-14 2013-03-26 Intel Mobile Communications GmbH LTE operation in white spaces
CN102938931B (en) * 2011-08-15 2016-05-18 重庆航讯时代科技有限责任公司 Asynchronous up-link access method and device on a large scale
CN102427441B (en) * 2011-12-09 2014-05-14 浙江宏睿通信技术有限公司 Anti-interference method applied to time-division OFDM (Orthogonal Frequency Division Multiplexing) system
CN105532068A (en) * 2014-07-01 2016-04-27 华为技术有限公司 Random access method and apparatus
CN107872817B (en) * 2016-09-27 2021-02-09 华为技术有限公司 Resource allocation method, network equipment and terminal equipment
CN111918405B (en) * 2019-05-10 2022-12-16 中国移动通信有限公司研究院 Random access method, terminal and network side equipment
CN114584920B (en) * 2022-03-04 2023-06-27 北京邮电大学 Target object access method, device, system and computer equipment

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1511190A1 (en) * 2003-08-27 2005-03-02 Siemens Aktiengesellschaft Method for transmission in a TDD system with variable length guard period
CN1913418A (en) * 2005-08-08 2007-02-14 大唐移动通信设备有限公司 Method for supporting changable cover by time division duplex system
CN1992969A (en) * 2005-12-30 2007-07-04 北京三星通信技术研究有限公司 Method for random access channel allocation in TDD-OFDMA system
WO2007082407A1 (en) * 2006-01-18 2007-07-26 Zte Corporation A random access method for user equipment in time division synchronization code division multiple access communication system

Family Cites Families (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN1905428B (en) * 2005-07-25 2010-08-18 上海原动力通信科技有限公司 Transmission method of TDD mobile communication system with low delay character
CN101005308B (en) * 2006-01-17 2012-08-29 上海原动力通信科技有限公司 Physical layer random access method for broad band time division duplex mobile communication system

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1511190A1 (en) * 2003-08-27 2005-03-02 Siemens Aktiengesellschaft Method for transmission in a TDD system with variable length guard period
CN1913418A (en) * 2005-08-08 2007-02-14 大唐移动通信设备有限公司 Method for supporting changable cover by time division duplex system
CN1992969A (en) * 2005-12-30 2007-07-04 北京三星通信技术研究有限公司 Method for random access channel allocation in TDD-OFDMA system
WO2007082407A1 (en) * 2006-01-18 2007-07-26 Zte Corporation A random access method for user equipment in time division synchronization code division multiple access communication system

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
ERICSSON: "E-UTRA Scalability of Random Access Preamble, R1-061367", TSG-RAN WG1 #45., 8 May 2006 (2006-05-08) - 12 May 2006 (2006-05-12), Shanghai, China, XP050102240 *

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2020087497A1 (en) * 2018-11-02 2020-05-07 Qualcomm Incorporated Implicit base station identification for remote interference management
US12035281B2 (en) 2018-11-02 2024-07-09 Qualcomm Incorporated Implicit base station identification for remote interference management

Also Published As

Publication number Publication date
CN101369840A (en) 2009-02-18
CN101369840B (en) 2012-07-04

Similar Documents

Publication Publication Date Title
US11985547B2 (en) Method and apparatus for supporting flexible UE bandwidth in next generation communication system
RU2727183C1 (en) Method for transmitting and receiving random access channel and device for transmitting and receiving
US11368998B2 (en) System and method for a tracking channel
WO2009021405A1 (en) Method, system and apparatus for tdd random access
KR100735277B1 (en) Method for ranging in broadband wireless access communication system
JP6482132B2 (en) Insertion of virtual carrier into conventional OFDM host carrier in communication system
US8072932B2 (en) Method, device, and terminal for physical layer random access in wideband TDD mobile communication system
US20220182200A1 (en) Methods and apparatus for configuring 5g new radio uplink positioning reference signals
JP5976681B2 (en) Insertion of virtual carrier into conventional OFDM host carrier in communication system
KR101612358B1 (en) Multi-access scheme and signal structure for d2d communications
EP1124347B1 (en) Uplink timing synchronization and access control
JP2014504835A (en) Insertion of virtual carrier into conventional OFDM host carrier in communication system
KR20050015119A (en) Apparatus for modulation ranging signals in broadband wireless access communication system and method thereof
CN112087805A (en) Random access leader sequence distribution, determination and data transmission method and equipment
KR20160107976A (en) Data Frame Structure and Operation Method for Sharing a Spectrum asynchronous Cells in Wireless Communication System
WO2023052569A1 (en) Random access improvement for 5g air-to-ground-system
CN103796194B (en) The transmission method and device of upstream data in carrier convergence
KR20230127915A (en) Method and apparatus for transmitting data to extend coverage

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: 08783644

Country of ref document: EP

Kind code of ref document: A1

NENP Non-entry into the national phase

Ref country code: DE

122 Ep: pct application non-entry in european phase

Ref document number: 08783644

Country of ref document: EP

Kind code of ref document: A1