KR20000055790A - Apparatus and method for controlling transmission diversity in mobile communication system - Google Patents

Abstract

PURPOSE: An apparatus for controlling a transmit antenna diversity in a mobile communication system is provided, so that a base station can control transmit power of two antennas by weighting the transmit power, by making a terminal measure relative receiving signal strength of the two antennas, to transmit measured information to the base station through a channel such as a reverse link dedicated control channel. CONSTITUTION: An apparatus for controlling a transmit antenna diversity in a mobile communication system comprises a central controller(111), space-time transmit diversity(STTD) coders(103,105), multiplexers(104,106), a diffuser, and a transmit power controller. The central controller decides a transmit mode according to a mobile speed of a terminal and a handoff region. The STTD coders perform STTD coding processes for transmitting information in a base station. The multiplexers separate signals into at least two antenna signals. The diffuser diffuses the separated signals with orthogonal codes and scrambles the orthogonal codes. The transmit power controller controls transmit power ratios of antennas according to feedback information received from the terminal.

Description

Transmission antenna diversity control method and apparatus in mobile communication system {APPARATUS AND METHOD FOR CONTROLLING TRANSMISSION DIVERSITY IN MOBILE COMMUNICATION SYSTEM}

The present invention relates to a transmission antenna diversity control apparatus and method of a mobile communication system, and more particularly to a transmission antenna diversity control apparatus and method of the forward link (Forwardlink).

In general, the code division multiple access (CDMA) mobile communication system has been developed from the conventional mobile communication standard mainly on voice, and is an IMT-2000 standard capable of transmitting high speed data as well as voice. It has developed. In the IMT-2000 standard, services such as high quality voice, moving picture, and internet search are possible. In the CDMA mobile communication system, a communication line existing between a terminal and a base station is largely divided into a reverse link from the terminal to the base station as opposed to a forward link from the base station to the terminal.

In particular, the capacity of the forward link requires more gain for increasing traffic. It is known that there is a gain of about 1 to 7 dB when the transmission speed of the terminal in the forward link is low when using transmit antenna diversity using multiple antennas compared to the case where the transmit antenna diversity is not used. This can increase the system capacity by two to three times, and the better performance is achieved when the receiver of the terminal cannot obtain sufficient path diversity and the lower the moving speed of the terminal.

The transmit antenna diversity method is a closed-loop method in which an antenna transmits an antenna selection (hereinafter referred to as an AS) message from a terminal to a base station, allocates transmission power from a base station to a specific antenna according to the selection signal, and then loads data. ) And an open-loop method in which equal transmission power is allocated to each antenna without using a special antenna selection message and data is transmitted to each antenna using different orthogonal codes. In the following description, it is assumed that two transmission antennas exist.

In addition, there are two largely closed loop methods, one of which measures the power strength of each pilot received from two transmitting antennas at a terminal and compares the relative ratio with a threshold value. There is STD (Selection Transmit Diversity, STD) as a method of periodically sending an antenna selection signal to the base station and transmitting data only to one antenna having a good reception state between the two antennas. However, in the STD method, since the transmit power allocated to each antenna is turned on / off, a peak-to-average ratio (hereinafter referred to as a PAR) of a power amplifier of a base station is called. There is a disadvantage in that the deterioration, and the power unbalance problem of the base station transmit antenna (cannot be overcome).

The other is a transmit antenna adaptive array (hereinafter referred to as TxAA), which uses the same data and orthogonal code for each transmit antenna, but assigns different phases and amplitudes to the two antennas. to be. However, TxAA uses a pilot symbol of a forwardlink common channel, which a base station transmits to a plurality of terminals without any power control in common, and thus phase and amplitude of signals received from two antennas at the transmitting side. ) To generate weight information. Therefore, the TxAA uses several antennas, and thus, applications such as smart antennas, which are provided to a user in the form of a beam, require multiple common channels, and thus, transmit diversity cannot be realized. There is this. Accordingly, there is a need for a method capable of providing closed-loop transmit antenna diversity using pilot symbols of dedicated channels provided by power control separately for each user.

As described above, since the closed loop transmission antenna diversity method uses the reception state information of each antenna provided from the terminal, it is impossible to accurately estimate the state of the rapidly changing channel when the terminal moving speed is high. Due to the time delay in transferring information to the base station, it cannot be used when the terminal moves at high speed.

The open loop method has better performance than a closed loop when the moving speed of the terminal is medium speed or high speed, and can be used in a common channel such as a broadcast channel (BCH). The closed loop method cannot process data received from different base stations in soft handover, but the open loop method can be used in soft handover. In the open loop method, there is a parallel transmit diversity (PTD) method using different orthogonal codes for two antennas and transmitting the same data. However, the above method requires two orthogonal codes to be used for one data transmission, which leads to a problem of lack of orthogonal codes. Therefore, it cannot be used when there are a large number of users.

The other is an Orthogonal Transmit Diversity (OTD) method that uses different orthogonal codes for two antennas and allocates and transmits different data to each antenna. However, the orthogonal transmit diversity method requires a special channel interleaver to optimize performance. In this case, the base station must additionally store an OTD channel interleaver separately from the channel interleaver in non-diversity mode. In addition, when a transmission signal received from a specific antenna is subjected to severe fading, there is a problem that all data is lost.

Therefore, since the closed-loop transmit antenna diversity gain at the low speed is much larger than that of the non-diversity, there is a need to improve the diversity method of the closed loop to ensure stable performance. When the moving speed of the terminal is low, the transmission path of a specific antenna may be subjected to severe fading. If a signal transmitted from one antenna is completely lost due to severe fading, 1/1 may be transmitted to one antenna. Same as transmitted with power of 2. Therefore, when the moving speed of the terminal is low, the gain of the transmission antenna diversity can be maximized by using a method of transmitting a weight to the transmission power of the transmission antenna. It measures the relative received signal strength of the two transmit antennas at the terminal and transmits this information to the base station through a channel such as a dedicated dedicated dedicated control channel, thereby allowing the base station to weight the transmit power of the two antennas. ) Can be sent. However, when the user uses a service in a super high speed train, and the moving speed of the terminal is very fast, such as 250km / h ~ 500km / h, the closed loop and open loop diversity mode has a performance degradation without additional performance improvement effect It can also bring a lot of calculations to operate a complex receiver, which brings the battery consumption of the terminal. Therefore, it is preferable to operate in a non-diversity mode in an area where transmit diversity does not provide performance improvement.

There is also a need for a method that can selectively provide the different closed loop, open loop diversity mode and non-diveristy mode with a very simple diversity transmitter structure. In addition, by using the method of alternately transmitting the same data symbols to the two antennas without additionally assigning orthogonal codes, it is possible to provide excellent performance without a lack of orthogonal codes or additional channel interleaver.

Accordingly, an object of the present invention is to provide a transmission power control apparatus and method for placing a weight on the transmission power strength of each transmission antenna in a mobile communication system using transmission antenna diversity.

Another object of the present invention is to provide an apparatus and method for selectively adopting an antenna transmission mode in a mobile communication system using a transmission antenna diver sheet.

A base station apparatus of a mobile communication system for achieving the above objects includes: a control device for determining a transmission mode according to a moving speed of a terminal and whether there is a handoff region; an encoder for STTD encoding information to be transmitted from a base station; A multiplexer for splitting into two antenna signals, a spreader for spreading and scrambled the separated signal with an orthogonal code, and a transmission power regulator for adjusting the transmission power ratio of the antennas according to feedback information received from the terminal.

1 is a diagram illustrating a transmission antenna power control method according to the present invention.

2 is a view showing the role of the STTD encoder in FIG.

3A and 3B illustrate the structure of a receiver of a terminal according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. First, in adding the reference numerals to the components of each drawing, the same components have the same reference numerals as much as possible even if displayed on different drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a diagram illustrating a structure of a base station transmitter for controlling the transmission power strength of a transmission antenna in a mobile communication system using the transmission antenna diversity according to the present invention. In the following description, the transmitter structure describes an example of a structure using STTD (Space-Time Transmit Diversity), and assumes two transmission antennas. However, the number of transmission antennas may be two or more.

Referring to FIG. 1, the channel encoder 101 encodes and outputs data to be transmitted. The channel encoder may use a convolutional coder, a turbo coder, or the like. The interleaver 102 interleaves and outputs the symbols output from the iterator 402 in order to prevent occurrence of a burst error. The first multiplexer 104 multiplexes and outputs a power control bit (hereinafter referred to as a TPC), frame rate information and data interleaved in the interleaver 102. The second STTD encoder 105 encodes the output of the first multiplexer 104 and outputs the first and second antenna symbols. The first STTD encoder 103 encodes the pilot data, and separates the pilot data into a first antenna and a second antenna symbol. Operation of the first STTD encoder 103 and the second STTD encoder 106 will be described in more detail with reference to FIG. 2. The second multiplexer 106 multiplexes the outputs of the first STTD encoder 103 and the second STTD encoder 105 and divides the output into a first antenna and a second antenna symbol.

The channel quadrature code (Cm) generator 107 generates and outputs an orthogonal code. The multipliers 121-1 and 121-2 multiply and output the corresponding inputs by multiplying orthogonal codes provided by the channel orthogonal codes 107. The scrambling code (Lc) generator 108 generates and outputs a scrambling code. The multiplier 121-3 and the multiplier 121-4 multiply the outputs of the corresponding multiplier 121-1 and the multiplier 121-2 by scrambling the scrambling code generated by the scrambling code generator 108 to output the scrambling code. The central control unit 111 selects the antenna transmission mode in consideration of the moving speed of the terminal, whether the terminal is in the handover area and the state of the transmission channel, and outputs the selection signal to the weight decoder 110.

This orthogonal coded and scrambled data is transmitted through an antenna, where the transmit power of each transmit antenna is adjusted by a transmit power regulator. Look at the configuration of the transmission power regulator below. The control channel decoder 109 decodes and transmits a control signal included in a reverse common control channel received from the reception antenna to the central controller 111, and controls the transmission power of the transmission antennas in the control signal. The feedback information (= weight information) is extracted and transmitted to the weight decoder 110. When the selection signal indicates the open loop mode, the weight decoder 110 outputs the same weight value to the multiplier 121-5 and the multiplier 121-6 such that the two antennas have the same transmit power strength. When the selection signal indicates the closed loop mode, the weight decoder 110 outputs a weight value corresponding to the weight information provided from the control channel decoder 109 to the multiplier 121-5 and the multiplier 121-6. When the selection signal indicates a non-diversity mode, the weight decoder 110 outputs a weight value '1' to a corresponding multiplier to transmit data through only one antenna, and outputs a weight value '0'. do. The multipliers 121-5 and multipliers 121-6 multiply outputs of the corresponding multipliers 121-3 and multipliers 121-4 by the weight values provided by the weight decoder 110 and output the multipliers to the corresponding transmission antennas.

Hereinafter, an operation of the transmitter according to the present invention based on the configuration of FIG. 1 will be described.

First, data to be transmitted is passed through the channel encoder 101 and then scrambling in the interleaver 102. When a power control bit (hereinafter referred to as a TPC) and multiple data frames are multiplexed, frame merge information (Transport Format Combination Indicator, TFCI) is used to store rate information of each data frame. Is multiplexed with the interleaved data in the first multiplexer 104. The TPC, TFCI, and data are passed through the first multiplexer 104, encoded by the second STT encoder 105, and then separated into symbols for transmission to the first transmitting antenna and the second transmitting antenna, and sent to the second multiplexer 106. On the other hand, the pilot (Pilot) after passing through the first STTD encoder 103 is divided into symbols for sending to the first transmitting antenna and the second transmitting antenna is sent to the second multiplexer. The outputs of the first SSTD encoder 103 and the second SSTD encoder 105 are divided into symbols to be sent to the first transmitting antenna and the second transmitting antenna after being multiplexed by the second multiplexer 106. The second multiplexer 106 lists pilots, TPCs, TFCIs, and data symbols input for the first transmission antenna and the second transmission antenna in a predetermined order, and the order is pilot, TPC, TFCI, It may be an order of data. The output of the second multiplexer is multiplied by the channel orthogonal code generated by the channelization orthogonal code generator 107 in the multiplier 121-1 and the multiplier 121-2, and then in the multiplier 121-3 and the multiplier 121-4. It is multiplied by the scrambling code generated by the scrambling code generator 108. Meanwhile, the control channel decoder 109 decodes a control signal included in a reverselink common control channel received from a receiving antenna, and then sends the control signal to the central control unit 11, and also the weight transmitted from the terminal. ) Sends the information to the weight decoder 110. The weight decoder 110 generates a weight value for each transmission antenna. The central control unit 111 determines the transmission mode of the transmitting antenna using the control signal provided by the control channel decoder 109, the moving speed of the terminal, whether the terminal is in the handover region, and the state of the transmission channel. The mode selection signal is output to the weight decoder 110.

When the mode selection signal indicates the open loop mode, the multipliers 121-5 and 121-6 multiply the same weight value. That is, when the channel environment is excellent or the moving speed of the terminal is high, it may be meaningless to adjust the weight of the transmission antenna. In this case, each weight value may be equally set as a default. Therefore, an equal transmission power is allocated to each transmission antenna. The outputs of the multiplier 121-5 and the multiplier 121-6 are output through the first transmitting antenna and the second transmitting antenna, respectively.

When the mode selection signal indicates the closed loop mode, the weight decoder 110 multiplies the multipliers 121-5 and 121-6 by the weight values corresponding to the weight information received from the terminal. The outputs of the multiplier 121-5 and the multiplier 121-6 are output through the first transmitting antenna and the second transmitting antenna, respectively. The weight information may be provided to the base station using a reverse control channel at a ratio according to the relative strength of signals received from two transmission antennas measured by the terminal, and the weight information is a control bit used for transmission from the terminal to the base station. This is called feedback information (hereinafter referred to as FBI). The FBI may be provided from the terminal to the base station through the reverse control channel, the FBI may be configured by one bit or multiple bits.

Here, when the FBI consists of 1 bit, the transmission power ratio of the first transmission antenna and the second transmission antenna may be a fixed value. For example, if the weight value is 1, the transmission power of the first transmission antenna of the data portion is set to 60%, and the transmission power of the second transmission antenna is set to 40%. If the weight value is 0, the transmission power of the first transmission antenna is set to 60%, and the transmission power of the second transmission antenna is set to 40%. The FBI is provided by the terminal to the base station according to the channel environment, and the period may be variable. Meanwhile, in the above example, the weight decoder 110 accumulates the weight value and sets the transmit power of the first transmit antenna to 80% and the transmit power of the second transmit antenna to 20% when the FBI is 1 or more times three times in a row. It may be. In this case, the reference value is three. That is, when the continuous value of the FBI is larger than the reference value compared to the preset reference value, the transmission power ratio of the two antennas may be changed differently from the preset value. The transmission power ratio may be 100% of the transmission power of the first transmission antenna and 0% of the transmission power of the second transmission antenna. In this case, the change of the transmission power is limited to the data portion. Even if the transmission power is 0%, the pilot is continuously transmitted through the second transmission antenna, and the terminal estimates the channel of each antenna path using the pilot.

When the FBI is configured with two or more bits, the weight value may be various. For example, if the FBI is 2 bits, if the FBI is 00, transmit power is allocated 0% to the first transmit antenna and 100% to the second transmit antenna, and if it is 01, 30% / 70% is allocated. 10 can be used to assign 70% / 30% and 11 to 100% / 0%. Even when the FBI is 2 bits or more, the transmission power ratio may be different from the preset value by comparing the continuous value of the FBI with a preset reference value.

In addition, when the mode selection signal indicates a non-diversity mode, the weight decoder 110 transmits a weight value to the multiplier 121-5 and the multiplier 121-6 such that data is transmitted only to one transmission antenna of any one of the transmission antennas. give. For example, when data is to be transmitted through the first transmission antenna, the multiplier 121-5 multiplies the weight value '1', and the multiplier 121-6 multiplies the weight value '0'. In this case, the non-diversity mode may be a handover or the like.

2 is a view for explaining the role of the STTD encoder in the configuration of FIG. Hereinafter, in the present invention, for simplicity, two symbol intervals in one slot will be described. However, it should be noted that the STTD encoder encodes an entire slot.

In FIG. 2, S denotes a symbol, T denotes a symbol duration, and when chip time is T _C and spreading gain is M, T _C = It has a relationship of T / M. N _pilot and N _data mean pilot information and data having N symbols respectively. The STTD encoder 201 receives the symbols S ₁ and S ₂ , and outputs S ₁ and S ₂ on one transmission antenna side, and converts the input symbols to -S ₂ * and S ₁ * on the other transmission antenna side. Output Where * means conjugate. The signal transmitted through the first transmitting antenna reaches the receiving antenna through multipath fading, where the degree of fading is determined. Suppose The output through the matched filter and the A / D converter of the received signal for the j-th path of the i-th chip time transmitted during the [0, T) time interval is expressed by Equation 1 below.

here, Indicates a propagation delay, Denotes a fading factor. Indicates a received signal, Denotes additive white noise (AWGN). Similarly, the output through the matching filter and the A / D converter of the received signal during the time interval of [T, 2T) is shown in Table 2 below.

Here, it is assumed that the transmission delay reaching the terminal reception antenna in the first transmission antenna and the second transmission antenna is the same. The receiver structure for signals transmitted in the first and second transmission antennas can be clearly understood by the following description.

3A and 3B are diagrams illustrating a terminal receiver structure according to the present invention.

First, referring to FIG. 3A, the scrambling code generator 301 generates and outputs a corresponding scrambling code. The multiplier 311-1 multiplies the received signal by the scrambling code provided by the scrambling code generator 301 and outputs the multiplied scrambling code. The channel orthogonalization code generator 302 generates and outputs an orthogonal code. The multiplier 311-2 multiplies the output of the multiplier 311-1 by an orthogonal code provided by the channel orthogonal code generator 302. The symbol accumulator 303 accumulates and outputs the outputs of the multiplier 311-2 by one symbol interval. Here, when the spreading gain is M, the symbol accumulator accumulates M input data. The delay unit 304 delays the output of the symbol accumulator 303 for one symbol and outputs the delay. Where the output of the symbol accumulator 303 And output of the delay 304 Is multiplied by the channel estimation coefficient and passed to the rake receiver (FIG. 3b) and simultaneously to the pilot symbol separator 305. Where above Denotes a received signal from the first antenna in the transmitter, Denotes a received signal from the second antenna. The pilot symbol separator 305 extracts and outputs a pilot symbol portion from the two received signals. The channel estimator 306 multiplies the pilot symbol output from the pilot symbol separator 305 by the channel estimation value. The weight encoder 306 measures the relative intensities of the first transmitting antenna and the second transmitting antenna pilot symbol in the channel estimator 306 to generate backward information (FBI) and provides it to the control channel encoder 308. The control channel encoder 308 transmits the reverse information to the reverse control channel to give weight to each transmission antenna. The base station transmitter then controls the power of each transmission antenna using the reverse information. In this case, the reverse channel information is loaded on the control channel, and a method of puncturing 1 bit of the TPC in the reverse channel and inserting the reverse information at the position thereof, and a new one bit for the reverse information without performing the puncturing There may be a way to use for FBI by adding. If the puncturing is not performed, the amount of control data that can be originally transmitted is reduced by the number of FBI bits added. The control channel encoder 308 also carries information used to select a transmission mode of a base station transmission antenna on the reverse control channel. The transmission mode includes a closed loop mode for controlling the transmission power of each transmission antenna in accordance with the reverse information transmitted from the terminal, and an open loop mode for the base station independently controlling the transmission power of each transmission antenna.

In addition, the output of the symbol accumulator 303 And output of the delay 304 Are transferred to FIG. 3b, and channel estimation coefficients, respectively. And It is multiplied by and passed to the rake receiver. Referring to FIG. 3B, the multiplier 312-1 receives the received signal. Channel Estimation Factor Multiply by and add to the adder 313-2. Conjugator (cunjugator) 31-1 is the received signal Conjugate complex and output. The multiplier 312-2 has a channel estimation coefficient at the output of the conjugate 311-1. Multiply by and add to the adder 313-1. Multiplier 312-3 receives the received signal. The channel estimation coefficient at Multiply by and add the result to the adder 313-1. The conjugate 311-2 receives the received signal. Conjugate complex and output. The multiplier 312-4 outputs the channel estimation coefficient to the output of the conjugate 311-2. Multiply by and add the result to the adder 313-2. The adder 313-2 adds the output of the multiplier 312-1 and the output of the multiplier 312-4 to output the result to the first lake receiver 314-1. The adder 313-1 inverts the output of the multiplier 312-1 and adds the output of the multiplier 312-4 to the second lake receiver 314-2. The first lake receiver 314-1 and the second lake receiver 314-2 combine all the multipath values of symbols S ₁ and S ₂ and output the result as one soft decision value.

Hereinafter, an operation of the receiver according to the present invention based on the configuration of FIGS. 3A and 3B will be described.

First, the signal received by the receiving antenna Is the output of the scrambling code generator 301 from the multiplier 31-1 After being multiplied by, the output of channel orthogonal code generator 302 in multiplier 311-2 Multiplied by to despread. The symbol accumulator 303 accumulates the symbol values for one symbol interval, and performs the accumulation operation M times as shown in Equation 3 below when the spreading gain is M.

The output of the symbol accumulator 303 is delayed for one symbol time through the symbol delay unit 304 and then received. Signal that has not been subjected to symbol delay Is outputted to the channel phase rotator of the STTD receiver. The pilot symbol separator 305 receives a signal from the first transmitting antenna. And a received signal from the second transmitting antenna The pilot symbol part is extracted from the multiplier, and the channel estimator 306 multiplies the channel estimation value. In the weight encoder 307, the relative strengths of the first transmitting antenna and the second transmitting antenna pilot symbol are measured to generate an FBI, the FBI is transmitted to the control channel encoder 308, and the FBI is transmitted to the base station using the reverse control channel. As shown in FIG. 1, the base station controls the power ratio of two transmission antennas using the FBI.

In this case, for the transmission of the FBI, the TPC in the reverse control channel may be punctured by one bit if necessary, and the FBI bit may be inserted at the location and sent from the terminal to the base station. It is also possible to add a new one bit for the FBI without puncturing the TPC bit in the reverse control channel and use it for the FBI. In this case, the FBI bit for the FBI should be placed in the reverse control channel.

And the received signal output in Figure 3a and Are channel estimation coefficients, respectively. And It is multiplied by and passed to the rake receiver. Referring to Figure 3b, the received signal Is the channel estimation coefficient in multiplier 312-1 After multiplying by and outputting to the adder 313-2. In addition, the received signal After passing through nucleator 311-1, the channel estimation coefficient in multiplier 312-2 Multiply by and add it to the adder 313-1. The received signal Is the channel estimation coefficient in the multiplier 312-3 Multiply by and add it to the adder 313-1. In addition, the received signal After passing through nucleophile 311-2, the channel estimation coefficient in multiplier 312-4 Multiply by and add it to the adder 313-2. The adder 413-1 inverts the sign of the output of the multiplier 312-2, adds it to the output of the multiplier 312-3, and transfers the result to the S ₂ rake receiver 314-2. The adder 313-2 adds the output of the multiplier 312-1 and the output of the multiplier 312-4 and transfers the result to the S ₁ rake receiver 314-1. The rake receivers 314-1 and 314-2 merge all multipath values of symbols S ₁ and S ₂ and output the result as one soft decision value.

As described above, in the transmission antenna diversity method according to the present invention, the same number of orthogonal codes as in the case of not applying diversity may be used, and in the case of an open loop, the terminal may have a soft handover. Applicable even when in the area. In addition, a different pilot pattern may be set for each antenna and may be used as information for antenna verification for verifying which antenna of the first transmitting antenna and the second transmitting antenna is a signal at the receiving side. That is, the pilot symbols of the first transmission antenna and the pilot symbols of the second transmission antenna may be set differently.

In addition, the base station uses a variety of information for the open-loop, closed-loop diversity and non-diversity mode conversion, the mode conversion information is the movement speed of the terminal, whether or not the position of the terminal in the handover area and transmission It may be the state of the channel. If, in the closed loop diversity mode, the transmission channel is very poor even though the moving speed of the terminal is low, the antenna selection information transmitted by the terminal to the base station causes an error, it is more preferable to use the open loop rather than the closed loop. It can be efficient. When each transmitting antenna uses a different pilot symbol pattern, the terminal may perform antenna verification by comparing the signal transmitted from the first transmitting antenna with the pilot signal pattern used in the first transmitting antenna. For example, even though the terminal requests to transmit data using the first transmission antenna, if the transmission channel is very poor, the FBI causes an error during transmission to the base station, and the base station uses the second transmission antenna to transmit data. Will be sent. In this case, the terminal may check the pilot symbol pattern of the received signal to determine whether the pattern is a signal of the first transmission antenna or a signal of the second transmission antenna. In addition, if the antenna verification error accumulates three or more times in a terminal by accumulating the results of the antenna verification, the closed loop mode may rather degrade the system performance. Can be. That is, when the error frequency of the antenna verification when operating in the closed loop mode is greater than or equal to a preset reference value, the transmission antenna diversity mode can be switched to the open loop even if the moving speed of the terminal is low.

The movement speed of the terminal may be estimated by a method of measuring a Doppler frequency shift of a signal transmitted by the terminal from the base station, and the movement speed of the terminal may be estimated by measuring the fading rate of the channel. There are several methods and a suitable method can be used depending on the channel situation and the reliability of each method. The base station in the open loop mode using the moving speed of the terminal. It can be used to switch between closed loop mode and non-diversity mode. That is, for example, the closed loop mode when the movement speed of the terminal is less than 30km / h, the open loop mode when the channel is poor at 30km / h or less, and open loop mode when the distance is 30km / h ~ 250km / h In the case of 250 km / h or more, the non-diversity mode may be used. The moving speed reference value of the terminal used for the transmission diversity mode conversion is a system parameter that changes according to the location of the base station and the type of service. In addition, the base station may operate in the open loop mode or in the non-transmit diversity mode when the corresponding terminal needs to handover.

As described above, according to the present invention, in a mobile communication system using transmit antenna diversity, a terminal measures a relative received signal strength of two transmit antennas, and transmits this information to a channel such as a dedicated dedicated dedicated control channel. By transmitting to the base station through the base station, the base station can control the transmission power by placing weights on the transmission power of the two antennas. This is an advantage of maximizing the gain of the transmission antenna diversity by transmitting a weight to the transmission power of the transmission antenna when the moving speed of the terminal is low. In addition, the present invention has the advantage that it is possible to set the optimal transmission mode for the current situation by selectively determining the transmission mode of the antenna.

Claims (10)

A base station apparatus of a mobile communication system, A control device for determining a transmission mode according to the movement speed of the terminal and the presence of the handoff area; An encoder for STTD encoding information to be transmitted from a base station, A multiplexer that separates at least two antenna signals, A spreader that spreads and scrambles the separated signal with an orthogonal code; And a transmission power regulator for adjusting transmission power ratios of the antennas according to feedback information received from a terminal. The method of claim 1, And when the feedback information is continuously received at the same value, the base station variably sets the transmission power ratio of the antennas. The method of claim 1, And the feedback information is received through a reverse control channel. The method of claim 3, And the feedback information punctures a specific bit of the reverse control channel message, is inserted in its place, and is transmitted. The method of claim 3, And the feedback information is transmitted in addition to the reverse control channel message. The method of claim 3, And the feedback information is at least one bit or more. The method of claim 3, wherein the transmission power regulator, A control channel decoder which decodes a control signal in the received reverse control channel and provides the control signal to the central controller, extracting feedback information from the control signal, and transferring the feedback information to a weight decoder; When the transmission mode is the closed loop mode, the transmission power of each transmission antenna is controlled to another weight according to the extracted feedback information, When the transmission mode is the open loop mode, the transmission power of each transmission antenna is controlled to the same weight, And a weight decoder configured to control a weight so that data is transmitted to only one transmit antenna when the transmission mode is a non-diversity mode. In the terminal receiver of a mobile communication system, A despreader for descrambling and orthogonal despreading on a signal received from an antenna, A pilot symbol separator for separating a pilot signal from a pilot signal among the despread signals; A channel estimator for multiplying the separated pilot symbol by a channel estimation coefficient and outputting the multiplied channel estimation coefficient; A transmitter for generating and transmitting feedback information from an output of the channel estimator, And a base station controls the transmission power ratio of the transmission antennas using the feedback information. In the transmission antenna diversity control method of a mobile communication system, Determining a transmission mode according to the movement speed of the terminal and the presence of the handoff region; STTD encoding the information to be transmitted from the base station, Separating the encoded data into at least two antenna signals; Spreading the scrambled signal with an orthogonal code, scrambled, and transmitting the scrambled signal to an antenna; Transmitting antenna diversity control method of a mobile communication system, characterized in that the step of adjusting the transmission power ratio of the antennas according to the feedback information received from the terminal. In the transmission antenna diversity control method of a mobile communication system, Descrambling and orthogonal despreading from a signal received from an antenna; Separating a pilot symbol from a pilot signal among the despread signals; Outputting by multiplying the separated pilot symbol by a channel estimation coefficient; And generating and transmitting feedback information from the pilot symbol multiplied by the channel estimation coefficient. The base station controls the transmission power ratio of the transmission antennas using the feedback information.