RU2352069C2 - Systems and methods for application of selected frame durations in system of wireless communication - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: system and method for installation of data transfer parameters from mobile station to base station in system of wireless communication. One version of realisation develops the method, according to which network detects entry or exit of mobile station from mode of soft transfer, and in response it changes transfer parameter. Transfer parameter may include frame duration, at that, if mobile station enters mode of soft transfer, then frame duration is established with larger value, and if mobile station exits mode of soft transfer, then frame duration is established with lower value. Network may define whether mobile station should enter or exit from mode of soft transfer on the basis of pilot signal power measurement (PSMM), and may send messages on direction of soft transfer mode (HDM) to mobile station, therefore, making mobile station enter or exit soft transfer mode and, accordingly, establish transfer parameter.

EFFECT: improved system characteristics relative to all basic stations and appropriate sectors.

30 cl, 6 dwg

Description

This application has priority in accordance with provisional application No. 60/448269 "REVERSE LINK DATA COMMUNICATION" dated February 18, 2003, provisional application No. 60/452790 "METHOD AND APPARATUS FOR A REVERSE LINK COMMUNICATION IN A COMMUNICATION SYSTEM" dated March 6, 2003 and provisional application No. 60/470770 "OUTER-LOOP POWER CONTROL FOR REL. D" dated May 14, 2003, filed with the US Patent Office.

FIELD OF THE INVENTION

The invention relates, in General, to the field of telecommunications and, more specifically, to control mechanisms for transmitting data parameters for wireless channels based on the prevailing characteristics of the transmission channels.

State of the art

Wireless technologies are advancing rapidly and wireless systems are being used to provide more and more communication bandwidth that is available to users. This is true, despite the additional technological obstacles that arise in the implementation of a wireless communication system, compared with a wired communication system. For example, in order to maximize system performance, wireless communication systems face problems regarding power control between the base station and its mobile stations, while these problems are not encountered in a wired communication system.

One type of wireless communication system includes a CDMA (Code Division Multiple Access) cellular system that is configured to support voice and data. This system may include multiple base stations that communicate with multiple mobile stations via radiotelephone channels. (Base stations also typically connect through wired networks to various other systems, such as a public switched telephone network.) Each base station communicates with a number of mobile stations that are within a sector corresponding to the base station.

The goal of a wireless communication system is usually to optimize system performance by maximizing system throughput. This throughput may include assistance from each of the mobile stations with which the base station communicates. Since the base station usually communicates with many mobile stations, the system simply cannot allow the communication between the base station and one of the mobile stations to be optimized by communication with other mobile stations. On the other hand, the system cannot provide communication with all mobile stations using the highest levels of power, speed, data transfer and other transmission parameters that are physically possible, due to the fact that they would probably create such a large interference, that a small amount, if any, of the data will actually be transferred successfully. Therefore, for the system, it is necessary to implement communication management with other mobile stations to ensure an acceptable level of service for each of them.

A difficulty factor in managing communications between a base station and various mobile stations is that mobile stations can be in communication with more than one base station. While the mobile station, which is located in close proximity to the first base station, creates interference, which primarily affects mobile stations in the same sector, mobile stations that are located farther from the base station can create interference, which significantly affects mobile stations located in other sectors. While a separate base station can handle the first situation relatively easily, it does not matter for mobile stations located in other sectors, and therefore may require that a sophisticated return signaling flight handle the second situation. Therefore, it would be desirable to provide a means to handle the second situation, which will increase the system characteristics with respect to all base stations and corresponding sectors.

Disclosure of invention

One or more of the problems described above can be solved by various embodiments of the invention. In general terms, the invention includes systems and methods for setting parameters for transmitting data from a mobile station to a base station in a wireless communication system. One embodiment of the present invention includes a method for determining when states are appropriate for a mobile station for entering or exiting soft transmission modes and for setting transmission parameters for a mobile station based on the following: is the mobile station really in soft transmission mode.

One embodiment of the present invention includes a method implemented in a wireless communication system including one or more base stations connected to a network and one or more mobile stations that are in communication with base stations. The method includes the steps of detecting an entry or exit of a mobile station from a soft transmission mode and changing a transmission parameter for a mobile station in response to detecting an entry or exit of a mobile station from a soft transmission mode. In one embodiment, the transmission parameter includes a frame size, wherein if the mobile station is in soft transmission mode, then the frame size is set as the first size (for example, 10 milliseconds), and if the mobile station is not in soft transmission mode, then the size The frame is set as the second size (for example, 2 milliseconds). In one embodiment, the mobile station measures pilot power values for each of one or more base stations and periodically transmits pilot power measurement messages (PSMMs) to the network through one of the base stations. The network determines whether the mobile station enters or leaves soft transmission based on the received PSMMs and, if necessary, sends a soft transmission directivity (HDM) message to the base station, which transmits HDM to the mobile station. In response to the received HDM, the mobile station enters or exits soft transmission mode, as indicated by the network, and also, accordingly, sets the transmission parameter (for example, frame size). Then, the mobile station transmits a message about the completion of soft transmission to the network after entering or exiting soft transmission mode and setting the transmission parameter.

An alternative embodiment of the present invention includes a wireless communication system. The system includes a network, a base station, and a mobile station, wherein the mobile station is configured to set a transmission parameter according to whether the mobile station is in soft transmission mode or not. In one embodiment, the transmission parameter includes a frame size, and the mobile station is configured to set the frame size as a first, larger value, if the mobile station is in soft transmission mode, and set the frame size as a second, smaller value, if the mobile station is not in soft transmission mode. In one embodiment, the mobile station is configured to measure pilot power for each of one or more base stations and periodically transmit PSMMs to the network. The network in this embodiment is configured to identify a change in the number of base stations in the active set (the set of base stations with which the mobile station is communicating) for the mobile station (based on PSMMs) and instructing the mobile station to enter or exit soft transmission based on the change in the number of base stations in the active set. The network then sends a soft transfer direction (HDM) message to the mobile station. The mobile station is configured to enter or exit soft transmission mode to change the transmission parameter in response to the received HDM and then to transmit the soft transmission completion message to the network.

Numerous additional embodiments are also possible.

Brief Description of the Drawings

Various aspects and features of the invention are disclosed in accordance with the following detailed description and with reference to the accompanying drawings, where:

1 is a diagram illustrating a typical structure of base stations, corresponding sectors that serve base stations, and mobile stations in a wireless data communication system, in accordance with one embodiment;

2 is a diagram illustrating the structure of a typical wireless communication system, in accordance with one embodiment;

3 is a functional block diagram illustrating the basic structural components of a wireless transceiver system, in accordance with one embodiment;

4 is a diagram illustrating changes in pilot power values from two different base stations, as measured by a separate mobile station, in accordance with one embodiment;

5 is a flowchart illustrating a method implemented in a mobile station in accordance with one embodiment; and

6 is a flowchart illustrating a method implemented in a base station in accordance with one embodiment.

While the invention is subject to various modifications and alternative forms, specific embodiments of the present invention are shown by way of example in the drawings and are accompanied by a detailed description. This should be understood, however, the drawings and detailed description are not intended to limit the invention to the specific embodiments described herein.

The implementation of the invention

One or more embodiments of the invention are described below. It should be noted that these and any other embodiments described below are exemplary and are intended to illustrate the invention and not to limit it.

As described herein, various embodiments of the invention include systems and methods for setting parameters for transmitting data from a mobile station to a base station in a wireless communication system. One embodiment of the present invention includes a method for determining when states for a mobile station correspond to an entry state of soft transmission mode, and for setting transmission parameters for a mobile station based on whether the mobile station is in soft transmission mode or not .

In one embodiment, the method is implemented in a wireless data transmission system having a plurality of base stations and a plurality of mobile stations. Each of the mobile stations can move throughout the geographical area within which the base stations provide the provision of communication services. When moving each mobile station within this area, the quality of each of the communication lines between the mobile station and various base stations can change. Generally, when the mobile station is relatively close to the base station, the quality of the corresponding communication line is good, and in this case, transmission parameters for the communication line can be set to support a high data rate (for example, a shorter frame period can be used). As the mobile station approaches the border of the sector that the base station serves, the quality of the communication line usually deteriorates, and it is typically necessary to set transmission parameters for the communication line to support a lower data rate (in order to ensure an acceptable error rate (coefficient)).

One of the problems associated with trying to adjust the transmission parameters of the communication line in accordance with the quality of communication is that it is typically necessary to perform a significant number of signal transmissions between the mobile station and the base station only to have enough information for a suitable adjustment of the transmission parameters . These signal transmissions represent congestion, which reduces the bandwidth available for data transmissions. Messaging also creates interference that can reduce the bandwidth of other mobile stations. Various embodiments of the present invention can eliminate a substantial amount of this communication overload by setting transmission parameters based on states that are known to apply. These conditions are known from the overload information currently in use.

In one embodiment, it is assumed that the mobile station, which is in soft transmission mode, is located near the boundary of the sector served by the base station. Therefore, it is also assumed that the quality of the communication link between the mobile station and the base station is not sufficient to support a high data rate. Therefore, whenever the mobile station is in soft transmission mode (i.e., the mobile station is communicating with more than one base station), the frame size (i.e., the time it takes for the data frame to be transmitted) is set to the larger of the two frame sizes. This larger frame size corresponds to a lower data rate, which requires less power to achieve an acceptable error rate (coefficient). When the mobile station is not in soft transmission mode, the frame size is set to the smaller of these sizes. In one embodiment, a frame size of either 10 milliseconds (in soft transfer mode) or 2 milliseconds (not in soft transfer mode) is used.

In one embodiment, the frame size is set as part of the transmission process of the soft transfer direction messages. In this embodiment, the mobile station communicates primarily with a separate base station. The mobile station is configured to periodically determine the power of the pilot signals, which are received not only from the main base station, but also from each base station from which the pilot signals are received. The mobile station is also configured to periodically transmit pilot power measurement messages (PSMMs) of the main base station, indicating pilot power from each base station. Information about the power of the pilot signal is sent to the telephone exchange or other network to which all the base stations are connected. Based on the pilot power information, it is determined whether the mobile station should actually be in soft transmission between multiple base stations or not. Messages are then sent to the mobile station, and if necessary, cause the mobile station to enter or exit the state in which the mobile station is in soft transmission mode. While the mobile station is receiving one of these messages, the mobile station not only enters or exits soft transmission mode, but also automatically sets transmission parameters (for example, frame size) to the corresponding values for the current state of the mobile station.

Various embodiments of the present invention can provide many advantages over the prior art. For example, since the embodiment described above uses a soft transmission mode mechanism that is already present, it does not require additional message transmissions to provide the mobile station with the required information to determine whether the frame size should be set larger or smaller than two possible values. However, other advantages will be apparent to those skilled in the art.

1 is a diagram illustrating a plurality of base stations and a plurality of mobile stations in a wireless data communication system, in accordance with one embodiment. Figure 1 depicts three of the base stations 12 in the system. Also, a lot more base stations can be included in the system. Each base station 12 has a corresponding sector 14, which is simply a service area, and mobile stations in this area can exchange information with the base station. (While the sectors in the figure are clearly demarcated by dashed lines, they do not have clear boundaries, but instead have more graded boundaries, which are determined by the power of the signals communicating between the respective base and mobile stations in the sector). Mobile stations 16 are shown scattered throughout the service area of the combined sectors.

It should be noted that for the sake of clarity, not all base stations, sectors, and mobile stations in the figure are identified by corresponding reference numbers. In cases where each of these network elements is referred to herein by a corresponding reference number without a lowercase character (for example, “12”), the link is applicable to any of the identical elements. And in cases where the elements are referred to by the corresponding reference number followed by a lowercase character (for example, “12a”), the link is applicable to the specific element indicated in the figure.

2 is a diagram illustrating the structure of a typical wireless communication system. As depicted in this drawing, system 200 includes a base station 210 that is configured to communicate with a plurality of mobile stations 220. For example, mobile stations 220 may be cell phones, personal information systems (electronic notebooks or “handheld” computers) or other Configured for wireless communications. It should be noted that these devices did not actually have to be “mobile,” but simply could communicate with the base station 210 via a wireless link. Base station 210 transmits data to mobile stations 220 through corresponding forward link (FL) channels, while mobile stations 220 transmit data to base station 210 through corresponding reverse link (RL) channels.

It should be noted that for the purposes of this disclosure, the same elements in the figures may be denoted by the same reference numbers, followed by a lowercase character, for example 220a, 220b, and so on. Elements can be collectively referred to here simply by reference number.

Base station 210 is also connected to a telephone exchange 230 via a wired line. A telephone exchange line 230 allows the base station 210 to communicate with various other system components, such as a data server 240, a public switched telephone network 250, or the Internet 260. It should be noted that the mobile stations and system components in this figure are typical, and others systems may include other types and other combinations of devices.

While the practically specific designs of the base station 210 and the mobile stations 220 can vary significantly, each serves as a wireless transceiver for communication on the forward and reverse links. Therefore, the base station 210 and the mobile stations 220 have the same common structure. This structure is illustrated in FIG.

3 is a functional block diagram illustrating the basic structural components of a wireless transceiver system, in accordance with one embodiment. As depicted in this figure, the system includes a transmission subsystem 322 and a reception subsystem 324, each of which is connected to an antenna 326. The transmission subsystem 322 and the reception subsystem 324 may be collectively referred to as a transceiver subsystem. The transmission subsystem 322 and the reception subsystem 324 access the forward and reverse links through the antenna 326. The transmission subsystem 322 and the reception subsystem 324 are also connected to a processor 323, which is configured to control the transmission and reception subsystems 322 and 324. The memory 330 is connected to the processor 328 to provide a work area and local storage for the processor. A data source 332 is coupled to a processor 328 to provide data transmitted by the system. The data source 332 may, for example, include a microphone or input from a network device. Data is processed by processor 328 and then transmitted to transmission subsystem 322, which transmits data through antenna 326. Data received by reception subsystem 324 through antenna 326 is transmitted to processor 328 for processing and then to information output 334 for presentation to the user. Information output 334 may include devices such as a speaker (speaker), display device, or output to a network device.

Considering the structure of FIG. 3, as implemented in a mobile station, system components can be considered as a transceiver subsystem connected to a processing subsystem, the transceiver subsystem responsible for receiving and transmitting data over a wireless channel, and the processing subsystem responsible for preparing and providing data to the transceiver subsystem for receiving, transmitting and processing data received from the transceiver subsystem. The transceiver subsystem can be considered as including the transmission subsystem 322, the reception subsystem 324 and the antenna 326. The processing subsystem can be considered as including the processor 328, memory 330, data source 332 and information output 334.

The base station and mobile station transceiver subsystems allow them to communicate via a wireless link. This wireless link may include multiple forward link channels that are used to transmit data from the base station to the mobile station, as well as multiple reverse link channels that are used to transmit data from the mobile station to the base station.

The quality of the wireless link between the base station and the mobile station may depend on many factors, many of which are constantly changing. For example, the quality of the communication line may vary with atmospheric conditions, geographical features, obstacles (interference), the distance between the base station and the mobile station, and so on. Each of these factors can cause a change in the quality of the communication line, such as a change in the position of the mobile station, sometimes improving the quality of the communication line, and sometimes worsening it. Typically, it is necessary to take into account that for a mobile station, the final quality of the communication line depends on determining the parameters that will be used to transfer data from the mobile station to the base station to achieve an acceptable error rate (coefficient) for data transmitted over the communication line.

The factors mentioned above and their effect on the communication line as a whole are very difficult to predict or prevent. Therefore, typically, it is necessary to directly determine the quality of the communication line, and then set the transmission parameters of the mobile station in accordance with the quality of the communication line. This may require some additional messaging from and to between the mobile station and the base station. Thus, some of the resources of the system (for example, the power of the mobile station and the bandwidth of the communication line) should be used preferably for overhead signals, and not for data transmission.

While it is generally difficult, if not impossible, to prevent changes in factors that affect the quality of the communication line and set transmission parameters accordingly, some generalizations can be made regarding some of the factors. For example, with respect to the distance between the base station and the mobile station, it may be assumed that as the distance between the base station and the mobile stations increases, the quality of the communication line will deteriorate (since the received transmit power of the signal typically decreases with distance). Therefore, it may be reasonable to assume that when the mobile station is near the base station, then the communication line will be able to maintain higher throughput than when the mobile station is far from the base station. As a practical matter, this means that the mobile station can use a shorter frame length (duration) or a higher data rate to transmit data to the base station. When the mobile station is near the base station, it is also less likely that data transmission at a higher speed (and correspondingly higher power level) creates interference that significantly affects communication between the mobile stations and other base stations. On the other hand, when the mobile station is far from the base station, it may be necessary to use a larger frame to achieve an acceptable error rate (coefficient) and to minimize interference with mobile stations in other sectors.

Therefore, the area within the sector of the base station can be divided into sections where, in the “near” section, the communication line is able to support a higher level of throughput and in the “far” section where the communication line is able to maintain a lower level of throughput. Therefore, when the mobile station is in the “near” section, parameters for transmitting data from the mobile station to the base station can be set in accordance with a higher level of throughput. When the mobile station is in a “distant” section, transmission parameters can be set in accordance with a lower level of throughput.

For example, in one embodiment, the mobile station may use either a frame size of 10 milliseconds or a frame size of 2 milliseconds. When using a frame size of 10 milliseconds, the data frame is transmitted with a frame duration of 10 milliseconds. When a frame size of 2 milliseconds is used, then the same amount of data is transmitted with a duration of 2 milliseconds. Therefore, data transmitted in a 2-millisecond frame must be transmitted at a data rate that is five times less than the data rate used with a 10-millisecond frame. This higher data rate corresponds to a higher power level. Therefore, in this embodiment, the mobile station is configured to use a frame size of 2 milliseconds when the mobile station is in a "close" sector of the sector, and to use a frame size of 10 milliseconds when the mobile station is in " far "plot.

In a preferred embodiment, the selection of an appropriate frame size for data transmission from the mobile station is performed in conjunction with the soft transfer mode execution process. As described above, mobile stations may be in communication with more than one base station. Although the mobile station connects primarily to one of the base stations, the mobile station may begin to connect (for example, intercepting) with other base stations in preparation for the possibility that the quality of the communication link to the first base station may deteriorate to the value with which the mobile station should communicate primarily with another of the base stations. When a mobile station communicates with multiple base stations, the mobile station is in soft transmission mode.

This can be illustrated by means of the diagram in FIG. 4. This figure illustrates changes in pilot power values from two different base stations, as measured by a separate mobile station. In this figure, curve 410 represents the pilot power from the first base station as a function of time. Curve 420 represents pilot power from a second base station. Line 430 indicates the threshold power of the pilot signal. When the pilot signal power of the base station is greater than the threshold level, the communication link to this base station is strong enough for the base station to become part of the active set (the set of base stations with which the mobile station can communicate). Thus, until time t _0, only one of the base stations (the first base station) is above a threshold value. The pilot power from the second base station is below the threshold at this time, but it is increasing. At time t _{0, the} pilot of the second base station reaches a threshold level. Therefore, the mobile station may be in soft transmission with two base stations after time t ₀ until the pilot signal strength of one of the base stations decreases below a threshold level.

It should be noted that while the above example describes the interaction of a mobile station with only two base stations, much more base stations can be involved. The mobile station monitors the power values of the pilot signal of each of the base stations from which the pilot signal is received. A base station whose pilot power value is above a threshold level is typically included in an active set for a mobile station.

The significance of the soft transmission mode with respect to various embodiments of the present invention is that, in essence, the soft transmission mode takes place at a time when the mobile station is in a “distant” sector of the sector that the first base station serves. In other words, because the sectors served by other base stations partially overlap at the boundaries of sectors far from the respective base stations (see FIG. 1), the mobile station which is in soft transmission will be near the boundary of the sector, which, in overall, coincides with the “distant” sector of the sector.

As shown in FIG. 1, the mobile station 16a is an example of a mobile station that is not in soft transmission mode. The mobile station 16a is served by the base station 12a. The mobile station 16a is far enough from the base stations 12b and 12c, and the signal power from each of these base stations will be low, and the mobile station 16a will not be required to communicate with any of these base stations. Mobile station 16b, on the other hand, is an example of a mobile station that is most likely in soft transmission mode. While the mobile station 16b can still be served primarily by the base station 12a, which is close enough to the base station 12b, it may be prescribed to communicate with both of these base stations (i.e. 12a and 12b).

In one embodiment, the soft transmission mode mechanism for a mobile station includes monitoring pilot signals from various base stations and instructing the mobile station to enter or exit the soft transmission mode state depending on various pilot strengths. Then, when the mobile station is instructed to enter or exit the soft transmission mode state, the mobile station not only enters or exits the soft transmission mode, but also sets the parameters for transmissions to the base station based on whether the mobile station is in soft transmission mode or not.

5 is a flowchart illustrating a method implemented in a mobile station in accordance with one embodiment of the present invention. As shown in this figure, the mobile station measures the power of the pilot signals received from various base stations (block 510), and periodically sends messages about the measurement of the pilot power signal (PSMMs) of the network (block 520). As will be described in more detail below, the mobile station may receive messages on the direction of soft transmission (HDM) from the network (block 530). HDM may instruct the mobile station to enter soft mode or exit it. Therefore, the mobile station enters or leaves soft transmission mode as prescribed by HDM (block 540). Also, the mobile station sets transmission parameters based on whether the mobile station is instructed by the HDM to enter or exit soft transmission mode (block 550). When the mobile station has finished entering or exiting soft transmission mode and has set the appropriate transmission parameters, it sends the soft transmission complete (HCM) message back to the network (block 560).

6 is a flowchart illustrating a method implemented in a base station in accordance with one embodiment of the present invention. As shown in the figure, the network first receives one of the PSMMs (block 610). If the mobile station was previously in soft transmission mode (block 620), then the network checks the measurement information of the pilot power in the PSMM and determines if only one base station is present for which the corresponding pilot power remains above the threshold level (block 630 ) If there are many base stations for which the corresponding pilot power values are above a threshold value, in this case the mobile station should remain in soft transmission mode, so no action is taken by the network. If there is only one base station for which the corresponding signal power is above a threshold value, in this case the mobile station should no longer remain in soft transmission mode, therefore, the network sends an HDM to the mobile station instructing the mobile station to exit soft transmission mode (block 640) .

If the mobile station has not previously been in soft transmission mode (block 620), then the network checks the measurement information of the pilot power in the PSMM and determines if there are many base stations for which the corresponding pilot power values are above the threshold level (block 650 ) If there is only one base station for which the corresponding pilot power is above a threshold value, in this case the mobile station should remain out of soft transmission mode, so no action is taken by the network. If there are many base stations for which the corresponding pilot power values are above a threshold value, in this case the mobile station should go into soft transmission mode, therefore, the network sends an HDM to the mobile station instructing the mobile station to enter soft transmission mode (block 660) .

It should be noted that the use of the pilot threshold power level, as described above, to determine whether the various base stations should actually be in the active set of the mobile station or not, is exemplary. The threshold value can be set at a constant level, or it can vary depending on the specific circumstances that arise at a particular time. For example, the threshold value may be set at a level that is less than the level of the strongest pilot signal. Alternatively, the threshold value may include a number of threshold conditions. For example, there may be an absolute threshold value below which no base station can be in the active set, and a variable threshold value that can be set at a level that allows no more than a predetermined number of base stations to be in the active set. Many other variations are also possible.

The embodiments described above use an existing mechanism for setting parameters for transmitting data from a mobile station to a base station. In particular, the soft transmission mode state is used to set the frame size for transmissions from the mobile station to the base station. Using this mechanism makes it possible to control the frame size based on a rough estimate of the location of the mobile station (for example, near the border of a sector where soft transmission typically occurs), without adding overhead from an explicit message about the location of the mobile station. In other embodiments, using these mechanisms, it may be possible to use other existing mechanisms and control other transmission parameters.

It should be noted that in the embodiments described above, the steps of the method can be exchanged without departing from the essence of the invention. The steps of the method described above may be implemented in hardware, software, firmware, or in any such combinations. The steps of the method may include instructions (instructions) configured to cause the processor to execute the corresponding method, and instructions may be implemented in a medium readable by a data processor, such as random access memory (RAM), read only memory (ROM), flash memory Erasable Programmable Read-Only Memory (EPROM), Electrically Erasable Programmable Read-Only Memory (EEPROM), registers, hard drives, removable disks, CD-ROM drives or yubogo other storage medium known in the art. The storage medium may be an integral part of the processor or may be external.

While some of the above options make reference to signals, parameters and procedures associated with specific standards (eg, CDMA2000), the invention is not limited to embodiments that conform to these standards. Those skilled in the art will understand that the generalized options described above are applicable to systems and methods that meet other standards, and that such alternative embodiments are within the scope of the invention.

It will also be clear to those skilled in the art that the information and signals described above can be represented using any variety of other technologies and techniques. For example, data, instructions, instructions, bits, symbols, chips, and various other information and signals may be represented by electric voltages, currents, electromagnetic waves, magnetic fields, optical fields, or the like.

Those skilled in the art will also understand that various logical or functional blocks, modules, circuits, components, algorithm steps, and the like, which are described in connection with the previous embodiments, can be implemented as hardware, software, software hardware or a combination thereof. Further, each of these logical or functional blocks, etc. can be independently implemented in a variety of different configurations. For example, one or more logical or functional blocks may be implemented or executed with a data processor, which may include a universal processor, microprocessor, microcontroller, state machine, digital signal processor (DSP), specialized integrated circuit (ASIC), programmable valve matrix (FPGA) or other programmable logic devices, discrete circuits or transistor logic circuits, discrete hardware components, or any of a combination thereof.

Various aspects and features of the present invention have been described above with respect to specific embodiments. As used herein, the terms “includes,” “including,” or any other variations of this term are intended to be interpreted as inseparable, including elements or restrictions that follow those terms. Accordingly, a system, method, or other embodiment that includes a number of elements is not limited to these elements only and may include other elements not explicitly listed or inherent in the desired embodiment.

While the present invention has been described with reference to specific embodiments, it should be understood that these embodiments are illustrative and that other embodiments are possible. Many changes, modifications, additions and enhancements to the above described embodiments are possible. This implies that these changes, modifications, additions and improvements are within the scope of the invention, as described in detail in the attached claims.

Claims (30)

1. A wireless communication system comprising:
network;
a first base station connected to a network; and
a mobile station connected to the base station via a wireless link;
moreover, the network is configured to induce the mobile station to enter or exit the soft transmission mode state based on the received pilot power measurement messages (PSMM messages); and
moreover, the mobile station is configured to change the transmission parameter in response to the network instructing the mobile station to enter or exit soft transmission, the transmission parameter includes the frame size, and if the mobile station is prompted to enter soft transmission, the frame size is set as the first size, and if the mobile station is prompted to exit soft transmission, the frame size is set as the second size. 2. The wireless communication system according to claim 1, in which the first size is larger than the second size. 3. The wireless communications system of claim 2, wherein the first size is 10 ms and the second size is 2 ms. 4. The wireless communications system of claim 1, wherein the mobile station is configured to measure pilot power for each of one or more base stations, the one or more base stations including a first base station and periodically transmitting one or more messages about measuring the power of the pilot signal in the network. 5. The wireless communication system according to claim 4, in which the network is configured to identify changes in the number of base stations in the active set for the mobile station based on messages about measuring the power of the pilot signal and to prompt the mobile station to enter or exit soft transmission based on changes in the number of base stations in the active set. 6. The wireless communication system of claim 5, wherein the network is configured to cause the mobile station to enter or exit soft transmission mode by sending a soft transmission direction (HDM) message to the mobile station. 7. The wireless communication system according to claim 6, in which the mobile station is configured to change the transmission parameter in response to the received HDM from the network. 8. The wireless communication system according to claim 7, in which the mobile station is configured to send a message about the completion of soft transmission to the network after receiving HDM. 9. A mobile station configured to operate in a wireless communication system, comprising:
processing subsystem and transceiver subsystem;
wherein the processing subsystem includes a processor, memory, data source, and information output, and is configured to set a transmission parameter for the transceiver subsystem in response to detecting that the mobile station is entering or leaving soft transmission mode;
the transceiver subsystem includes a transmission subsystem and a reception subsystem, the memory is connected to the processor to provide a working area and local storage for the processor, the data source is connected to the processor to provide data transmitted by the system, the data is processed by the processor and then transmitted to the transmission subsystem, and the data received by the receiving subsystem via the antenna is transmitted to the processor for processing. 10. The mobile station according to claim 9, in which the processing subsystem is configured to detect whether the mobile station enters or leaves the soft transmission mode based on the received soft transmission direction message (HDM). 11. The mobile station of claim 10, in which the processing subsystem is configured to set the transmission parameter to the first value if the HDM prompts the mobile station to enter soft transmission mode, and set the transmission parameter to the second value if the HDM prompts the mobile station to exit soft transfer mode. 12. The mobile station of claim 11, wherein the transmission parameter includes a frame size. 13. The mobile station of claim 12, wherein the first size is larger than the second size. 14. The mobile station of claim 13, wherein the first size is 10 ms and the second size is 2 ms. 15. The mobile station of claim 10, which also provides a measurement of the power of the pilot signal for each of one or more base stations and periodic transmission of one or more messages about the measurement of the power of the pilot signal to the network connected to the base stations. 16. The mobile station according to clause 15, which also provides the transmission of a message about the completion of soft transmission to the network after receiving HDM. 17. A method for detecting soft transmission mode for a mobile station in a wireless communication system, the method comprising:
detecting a mobile station entering or leaving soft transmission mode by identifying a change in the number of base stations in the active set for the mobile station based on the received pilot power measurement messages (PSMM messages); and
changing the transmission parameter for the mobile station in response to the detection of the mobile station entering or exiting soft transmission, the transmission parameter includes the frame size, and if the mobile station is detected entering the soft transmission mode, the frame size is set to the first size and, if the mobile station is detected exiting soft transmission mode, then the frame size is set equal to the second size. 18. The method according to 17, in which the first size is larger than the second size. 19. The method of claim 20, wherein the first size is 10 ms and the second size is 2 ms. 20. The method according to 17, in which the mobile station measures the power of the pilot signal for each of one or more base stations and periodically transmits one or more messages about measuring the power of the pilot signal to the network. 21. The method according to 17, which also includes sending a message about the direction of soft transmission (HDM) from the network to the mobile station in response to detecting a change in the number of base stations in the active set. 22. The method according to item 21, in which change the transmission parameter for the mobile station in response to receiving HDM from the network. 23. The method according to item 22, which also includes transmitting a message about the completion of soft transmission from the mobile station to the network after receiving HDM. 24. A method for detecting a soft transmission mode for a mobile station, the method comprising:
detecting that the mobile station enters or leaves soft transmission mode by receiving a soft transmission direction (HDM) message from the network; and
changing the transmission parameter for the mobile station, wherein the transmission parameter includes a frame size, and
if the mobile station enters soft transmission mode, then the transmission parameter is set to a first value; and
if the mobile station leaves soft transmission mode, then the transmission parameter is set to a second value. 25. The method according to paragraph 24, which also includes measuring the power of the pilot signal for each of one or more base stations and periodically transmitting one or more messages about measuring the power of the pilot signal to the first of the base stations. 26. The method according A.25, which also comprises transmitting a message about the completion of soft transmission to the first of the base stations after receiving HDM. 27. The method according to paragraph 24, in which the first value is greater than the second value. 28. The method according to item 27, in which the first value is 10 ms, and the second value is 2 ms. 29. A computer-readable medium containing instructions for execution by a processor for implementing a method for detecting a soft transmission mode for a mobile station in a wireless communication system according to any one of claims 17-23. 30. A machine-readable medium containing instructions for execution by a processor for implementing a method for detecting soft transmission mode for a mobile station in a wireless communication system according to any one of paragraphs.24-28.

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