JP5251712B2 - Transmission power control apparatus, transmission power control method, and program - Google Patents

Description

  The present invention relates to a transmission power control apparatus, a transmission power control method, and a program for controlling transmission power of a transmission power control target terminal.

  Conventionally, in a wireless communication system, a base station apparatus controls transmission power of a mobile station apparatus so that necessary communication quality can be ensured in a changing radio wave environment. The transmission power is controlled by detecting a block error in the received signal. If an error is detected, the target value (hereinafter referred to as the target SIR) of the signal-to-interference ratio (SIR) is lowered to reduce the block error. Is not detected, it is performed by increasing the target SIR. Thereby, the error rate of a received signal is ensured and the transmission power of the mobile station apparatus is suppressed.

Hereinafter, a specific example of a transmission power control method by a base station apparatus according to a conventionally known technique will be described.
FIG. 4 is a schematic block diagram showing a configuration of a base station apparatus according to a conventional known technique.
FIG. 5 is a flowchart showing the target SIR calculation operation of the base station apparatus according to a conventional known technique.
In step S101, the target SIR control unit 906 of the base station apparatus 900, based on the target value (target BLER) of the block error rate (BLER, Block Error Rate), sets the step increase amount of the target SIR from the parameter table storage unit 907. Get block error measurement interval length. Here, the block error measurement section length indicates the number of received blocks for measuring a block error.
When a block error is detected in the received signal within the block error measurement section length, the target SIR control unit 910 sets a target value of the signal-to-interference ratio according to equation (1) in step S105. Further, when no block error is detected in the received signal within the block error measurement section length, the target SIR control unit 910 sets the target value of the signal-to-interference ratio according to equation (2) in step S108.

However, SIR _t indicates the target SIR, and SIR _t ′ indicates the previous target SIR. Further, δ represents a predetermined step increase amount. BLER _t indicates a target BLER.
When the target SIR is calculated in this way, the comparator 912 compares the target SIR with a signal-to-interference ratio (hereinafter referred to as reception SIR) of the received signal, and the transmission unit 113 supports TPC (Transmitting Power) that supports increase / decrease in power. Control: transmission power control) command is sent to mobile station apparatus 200.

FIG. 6 is a diagram illustrating a change in the target SIR in a base station apparatus according to a conventional known technique.
The vertical axis in FIG. 6 indicates the SIR value, and the horizontal axis indicates time. According to FIG. 6, the target SIR decreases intermittently and increases by δ when a block error occurs. That is, the target SIR decreases when the received SIR satisfies a signal-to-interference ratio (hereinafter referred to as required SIR) required to prevent a block error from occurring, and increases when the received SIR does not satisfy the required SIR. . Thereby, the base station apparatus 900 can control the transmission power of the mobile station apparatus so that the target BLER can be secured.

  Patent Document 1, Patent Document 2 and Patent Document 3 disclose power control methods for controlling transmission power so that a reception SIR satisfies a target SIR.

JP 2003-188815 A JP 2005-303670 A JP 2006-086716 A

  However, in the transmission power control method as described above, when there is no block error and the reception SIR exceeds the required SIR, but the reception SIR does not reach the target SIR, the base station apparatus 900 transmits the TPC increase command. Will continue. When the reception SIR exceeds the required SIR, the transmission power of the mobile station apparatus 200 satisfies the minimum power that can secure the target BLER, and therefore the TPC increase command by the base station apparatus 900 has an excessive transmission power. Indicates that an increase is requested.

  For example, the reception SIR at time τ in FIG. 6 is in a state where the power is increased by the TPC increase command after the occurrence of the block error and the required SIR is already satisfied, but there is a difference between the target SIR and the reception SIR. In addition, the TPC increase command is continuously transmitted to the mobile station apparatus 200. Therefore, the mobile station apparatus 200 increases unnecessary power, wastes power consumption, and gives interference to transmission signals of other mobile station apparatuses.

  The present invention has been made in view of the above points, and an object of the present invention is to control transmission power of a transmission power control target terminal so that a signal can be delivered without excess or deficiency with minimum power that can secure a target BLER. A power control apparatus, a transmission power control method, and a program are provided.

  The present invention has been made to solve the above-described problem, and is a transmission power control apparatus that controls transmission power of a transmission power control target terminal, the target value of the signal-to-interference ratio of the transmission power control target terminal. Storage means for storing a target signal-to-interference ratio indicating, receiving means for receiving a signal from the transmission power control target terminal, error detecting means for performing error detection of the signal received by the receiving means for each reception, and A signal-to-interference ratio measuring unit that measures a signal-to-interference ratio of a signal received by the receiving unit for each reception; a target signal-to-interference ratio stored by the target signal-to-interference ratio storage unit; First target signal-to-interference ratio setting means for rewriting the signal-to-interference ratio measured by the signal-to-interference ratio measuring means when not detected, and the signal-to-interference ratio measured by the signal-to-interference ratio measuring means, The target If the signal-to-interference ratio storage means stores higher than the target signal-to-interference ratio, a transmission power control command indicating a command to increase the transmission power is generated, and the signal-to-interference ratio measured by the signal-to-interference ratio measuring means is When the target signal-to-interference ratio storage means is lower than the target signal-to-interference ratio stored, the transmission power control command generating means for generating a transmission power control command indicating a command to reduce the transmission power, and the transmission power control command generating means Transmission means for transmitting the generated transmission power control command to the transmission power control target terminal.

  The present invention also includes a storage means for storing a target signal-to-interference ratio indicating a target value of a signal-to-interference ratio of the transmission power control target terminal, and a transmission power control apparatus that controls the transmission power of the transmission power control target terminal The reception means receives a signal from the transmission power control target terminal, the error detection means performs error detection of the signal received by the reception means for each reception, and performs signal pairing. The interference ratio measuring means measures the signal-to-interference ratio of the signal received by the receiving means for each reception, and the first target signal-to-interference ratio setting means is a target signal stored in the target signal-to-interference ratio storage means The interference-to-interference ratio is rewritten to the signal-to-interference ratio measured by the signal-to-interference ratio measurement unit when the error detection unit does not detect an error, and the transmission power control command generation unit is configured to transmit the signal-to-interference ratio measurement unit. Measured by When the interference-to-interference ratio is higher than the target signal-to-interference ratio stored by the target signal-to-interference ratio storage means, a transmission power control command indicating a command to increase the transmission power is generated, and the transmission power control command generation means When the signal-to-interference ratio measured by the signal-to-interference ratio measuring unit is lower than the target signal-to-interference ratio stored by the target signal-to-interference ratio storage unit, a transmission power control command indicating a command to reduce the transmission power is issued. The transmission power control command generated by the transmission power control command generation means is transmitted to the transmission power control target terminal.

  The present invention also provides a transmission power control apparatus comprising storage means for storing a target signal-to-interference ratio indicating a target value of the signal-to-interference ratio of the transmission power control target terminal, and controlling the transmission power of the transmission power control target terminal Receiving means for receiving a signal from the transmission power control target terminal, error detecting means for performing error detection of the signal received by the receiving means for each reception, and signal-to-interference ratio of the signal received by the receiving means for each reception. The signal-to-interference ratio measuring unit measures the target signal-to-interference ratio stored by the target signal-to-interference ratio storage unit when the error detecting unit detects no error. The target signal-to-interference ratio stored in the target-signal-to-interference-ratio storage means is the first target-signal-to-interference-ratio setting means for rewriting the signal-to-interference ratio. Than If the signal-to-interference ratio is measured, the signal-to-interference ratio measured by the signal-to-interference ratio measuring unit is stored in the target signal-to-interference ratio storage unit. If the ratio is lower than the ratio, the transmission power control command generating means for generating a transmission power control command indicating an instruction to reduce the transmission power, and the transmission power control command generated by the transmission power control command generating means is transmitted to the transmission power control target terminal. It is a program for making it operate | move as a transmission means to transmit.

  According to the present invention, the first target signal-to-interference ratio setting means sets the target signal-to-interference ratio stored by the target signal-to-interference ratio storage means when the error detection means does not detect an error. The signal-to-interference ratio measured by the ratio measuring means is rewritten. As a result, the difference between the target signal-to-interference ratio and the signal-to-interference ratio required to prevent signal errors can be reduced, and the transmission means can be used for the mobile station apparatus (transmission power control target terminal). Thus, a transmission power control command indicating an increase in transmission power more than necessary is not transmitted. As a result, the base station apparatus (transmission power control apparatus) can control the transmission power of the mobile station apparatus so that the signal can be received without excess or deficiency with the minimum power that can secure the target BLER.

It is a schematic block diagram which shows the structure of the base station apparatus by one Embodiment of this invention. It is a flowchart which shows the calculation operation | movement of target SIR by a base station apparatus. It is a figure which shows the change of target SIR in a base station apparatus. It is a schematic block diagram which shows the structure of the base station apparatus by the conventional well-known technique. It is a flowchart which shows the calculation operation | movement of the target SIR of the base station apparatus by the conventional well-known technique. It is a figure which shows the change of the target SIR in the base station apparatus by the conventional well-known technique.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a schematic block diagram showing a configuration of a base station apparatus according to an embodiment of the present invention.
The base station apparatus 100 includes a reception unit 101 (reception unit), a delay spread calculation unit 102, a demodulation unit 103, an SIR measurement unit 104 (signal-to-interference ratio measurement unit), an error correction decoding unit 105, a CRC detection unit 106, and a registration unit. 107, parameter table storage unit 108, received block number counter storage register 109, parameter storage register 110, first target SIR control unit 111 (second target SIR setting means), delay spread storage unit 112, SIR measurement value storage unit 113, SIR measurement section reception block counter storage register 114, second target SIR increase / decrease control 115 (first target signal to interference ratio setting means), target SIR storage section 116 (storage means), comparison section 117 (transmission) A power control command generation unit) and a transmission unit 118 (transmission unit).

The receiving unit 101 receives a signal from the mobile station device 200.
The delay spread calculator 102 calculates a delay spread based on the received signal. Here, the delay spread indicates a degree of spread in a time direction of a signal propagated through a multipath by reflection and refraction by an ionosphere or a building.
The demodulator 103 demodulates the received signal.
The SIR measurement unit 104 measures the signal-to-interference ratio of the received signal.
Error correction coding section 105 corrects an error in the demodulated received signal.
The CRC detection unit 106 detects a block error of the received signal by CRC (cyclic redundancy check).

The registration unit 107 registers information in the reception block number counter storage register 109, the parameter storage register 110, the delay spread storage unit 112, the SIR measurement value storage unit 113, and the SIR measurement section reception block number counter storage register 114.
The parameter table storage unit 108 stores a parameter table that stores the block error measurement section length, the step increase amount, the SIR measurement section length calculation coefficient, and the SIR averaged section length calculation table coefficient in association with the target BLER. Here, the block error measurement section length indicates the number of received blocks for measuring a block error. The SIR measurement section length calculation coefficient and the SIR averaged section length calculation table coefficient are coefficients used for calculation of a second target SIR described later.

The first target SIR control unit 111 calculates the first target SIR based on the step increase amount and the target BLER.
The second target SIR control unit 115 calculates the second target SIR based on the SIR measurement section length calculation coefficient and the SIR averaged section length calculation table coefficient.
The target SIR storage unit 116 stores the smaller one of the first target SIR and the second target SIR as the target SIR.
The comparison unit 117 compares the target SIR stored in the target SIR storage unit 116 with the received SIR, and generates a TPC command.
The transmission unit 118 transmits a TPC command to the mobile station device 200.

According to the present embodiment, in the base station device 100, the reception unit 101 receives a signal from the mobile station device 200, and the CRC detection unit 106 performs error detection on the signal received by the reception unit 101 for each reception. The SIR measurement unit 104 measures the reception SIR of the signal received by the reception unit 101 for each reception, and the second target SIR control unit 115 determines the target SIR stored in the target SIR storage unit 116 as the CRC detection unit. When 106 does not detect an error, the SIR measuring unit 104 rewrites the received SIR.
Next, when the reception SIR measured by the SIR measurement unit 104 is higher than the target SIR stored in the target SIR storage unit 116, the comparison unit 117 generates a TPC command indicating an instruction to increase the transmission power, and compares If the received SIR measured by the SIR measuring unit 104 is lower than the target SIR stored in the target SIR storage unit 116, the unit 117 generates a TPC command indicating an instruction to reduce the transmission power. The transmission unit 118 The TPC command generated by 117 is transmitted to the mobile station apparatus 200.
As a result, the base station apparatus 100 controls the transmission power of the mobile station apparatus 200 so that the signal can be received with the minimum power that can secure the target BLER without excess or deficiency.

Next, the operation of base station apparatus 100 will be described.
FIG. 2 is a flowchart showing the target SIR calculation operation by the base station apparatus.
First, when the base station apparatus 100 is activated, the registration unit 107 calculates the SIR step increment δ corresponding to the target BLER indicating the required quality in the base station apparatus 100, the block error measurement section length T, and the SIR measurement section length calculation. The coefficient α and the SIR average section length calculation coefficient β are acquired from the parameter table stored in the parameter table storage unit, and are registered in the parameter storage register 110 (step S1).

  When registering the parameter in the parameter storage register 110, the registration unit 107 resets the reception block number counter stored in the reception block number counter storage register to zero (step S2). At the first activation, all the information stored in the reception block number counter storage register 109, the parameter storage register 110, the delay spread storage unit 112, the SIR measurement value storage unit 113, and the SIR measurement section reception block number counter storage register 114 is all stored. It is zero.

  When the registration unit 107 resets the reception block number counter in step S2, the delay spread calculation unit 102 calculates a delay spread of the received signal from a signal such as a preamble signal received by the reception unit 101 from the mobile station device 200 ( Step S3). At this time, the registration unit 107 registers the delay spread calculated by the delay spread calculation unit 102 in the delay spread storage unit 112. The delay spread is calculated by equation (3).

However, P _i denotes a path level of an i-th path. Τ _i indicates the arrival timing of the i-th path. N indicates the number of paths. Further, ^τ￣ indicates the average arrival timing of the path, and is calculated by the equation (4).

  As shown in Expression (3), the delay spread indicates the influence of multipath, and it is known that the SIR cannot be obtained with high accuracy by interference power when the number of paths is large. In determining whether the delay spread calculated here satisfies a required SIR, which will be described later, in order to increase the number of received SIR samples and increase the accuracy of the determination by providing a longer measurement section when the delay spread is large. Use.

When the delay spread calculation unit 102 calculates the delay spread in step S3, the reception unit 101 receives a transfer block (TB, Transport Block) storing communication data from the mobile station device 200 (step S4). When the mobile station apparatus 200 receives the transfer block, the demodulation unit 103 performs demodulation processing on the transfer block received, and the SIR measurement unit 104 measures the reception SIR of the transfer block (step S5). At this time, the registration unit 107 additionally registers the measured received SIR in the SIR measurement value storage unit 113.
When the SIR measurement unit 104 calculates the received SIR, the error correction decoding unit 105 performs error correction processing on the transfer block, and the CRC detection unit 106 detects an error in the transfer block based on the CRC code assigned to the transfer block. It is determined whether or not there is (step S6).

  When the CRC detection unit 106 determines that there is an error in the transfer block (step S6: NO), the registration unit 107 turns on the error occurrence flag stored in the parameter storage register 110 (step S7). Here, the error occurrence flag is a flag indicating whether or not the CRC detection unit 106 has detected an error at the time of reception of the previous transfer block, and indicates that an error has been detected when ON, and when it is OFF. Indicates that no error was detected.

When the error occurrence flag is turned ON in step S7, the registration unit 107 resets the SIR measurement reception block counter stored in the SIR measurement reception block counter storage register 114 to zero (step S8).
Next, the first target SIR control unit 111 performs a calculation for increasing the first target SIR by the equation (1), and registers the calculated first target SIR in the target SIR storage unit 116 (step S9). ). When the first target SIR control unit 111 registers the target SIR, the comparison unit 117 compares the reception SIR measured by the SIR measurement unit 104 with the target SIR stored in the target SIR storage unit 116, and the reception SIR is the target SIR. If the received SIR is lower than the target SIR, a TPC command indicating an instruction to decrease the transmission power is generated. Then, the transmission unit 118 transmits the TPC command generated by the comparison unit 117 to the mobile station device 200 (step S10).
When transmitting section 118 transmits a TPC command, the base station apparatus ends the processing for the received signal and starts processing the next received signal.

  On the other hand, when the CRC detection unit 106 determines in step S6 that there is no error in the transfer block (step S6: YES), the registration unit 107 receives the reception block number counter stored in the reception block number counter storage register 109, The received transfer block number is added to the SIR measurement reception block counter stored in the SIR measurement reception block counter storage register 114 (step S11).

Next, the first target SIR control unit 111 determines whether the value of the reception block number counter stored in the reception block number counter storage register 109 is equal to or greater than the block error measurement interval length T stored in the parameter storage register 110. It is determined whether or not (step S12).
When the first target SIR control unit 111 determines that the value of the received block number counter is less than the block error measurement interval length T (step S12: NO), the process returns to step S3 to detect the delay spread and perform the next transfer. Receive block.

On the other hand, when the first target SIR control unit 111 determines that the value of the received block number counter is equal to or greater than the block error measurement section length T (step S12: NO), the first target SIR control unit 111 is represented by equation (2). Is calculated, and the calculated first target SIR is registered in the target SIR storage unit 116 (step S13).
When the first target SIR control unit 111 calculates the first target SIR, the second target SIR control unit 115 determines whether or not the error occurrence flag stored in the parameter storage register 110 is ON ( Step S14).

Second target SIR control unit 115, if it is determined that the error occurrence flag is ON (step S14: YES), calculates the SIR measurement period TSIR and SIR averaging interval length TSIR _a (step S15). Here, the SIR measurement section length TSIR indicates the number of received blocks for measuring the received SIR. The SIR averaging section length TSIR _a indicates the number of received blocks used for calculating the average value of received SIR. The SIR measurement section length TSIR is calculated by multiplying the SIR measurement section length calculation coefficient α stored in the parameter storage register 110 by the delay spread σ stored in the delay spread storage unit 112. Further, SIR averaging interval length TSIR _a is calculated by multiplying the coefficient for the SIR averaging interval length calculation β on the calculated SIR measurement period TSIR.
The SIR average section length calculation coefficient β takes a value of 1 ≧ β> 0, and the SIR average section length TSIR _a is a value equal to or smaller than the SIR measurement section length TSIR. This is because the received SIR immediately after the occurrence of an error is unlikely to satisfy the required SIR, so that when the average of the received SIR is calculated by the processing described later, the received SIR immediately after the occurrence of the error is not included in the population. It is to make it.

When the second target SIR control unit 115 determines in step S14 that the error occurrence flag is OFF (step S14: NO), or in step S15, the second target SIR control unit 115 determines the SIR measurement section length. When the TSIR and the SIR averaging section length TSIR _a are calculated, the second target SIR control unit 115 calculates the SIR measurement reception block number counter stored in the SIR measurement reception block number counter storage register 114 in step S13. It is determined whether or not the SIR measurement section length TSIR is less than or equal to (step S16).

When the second target SIR control unit 115 determines that the SIR measurement reception block number counter is larger than the SIR measurement section length TSIR (step S16: NO), the error occurrence flag stored in the parameter storage register is ON. Whether or not (step S17).
When the second target SIR control unit 115 determines that the error occurrence flag is ON (step S17: YES), the SIR average section length is traced back to the past from the received SIR stored in the SIR measurement value storage unit. The average value of the received SIRs in TSIR _a is calculated as the second target SIR (step S18). After calculating the second target SIR, the second target SIR control unit 115 turns off the error occurrence flag stored in the parameter storage register 110 (step S19).

  If the second target SIR control unit 115 determines in step S16 that the error occurrence flag is OFF (step S17: NO), or the second target SIR control unit 115 turns off the error occurrence flag in step S19. In this case, the smaller one of the first target SIR calculated by the first target SIR control unit 111 in step S13 and the second target SIR calculated by the second target SIR control unit 111 in step S18. Is registered in the target SIR storage unit 116 as a target SIR (step S20).

When the second target SIR control unit 115 determines in step S16 that the SIR measurement received block number counter is equal to or shorter than the SIR measurement section length TSIR (step S16: YES), or in step S20, the target SIR is changed to the target SIR. When registered in the storage unit 116, the comparison unit 117 compares the received SIR measured by the SIR measurement unit 104 with the target SIR stored in the target SIR storage unit 116, and if the received SIR is higher than the target SIR, the transmission power When the received SIR is lower than the target SIR, a TPC command indicating an instruction to decrease the transmission power is generated. Then, the transmission unit 118 transmits the TPC command generated by the comparison unit 117 to the mobile station device 200 (step S21).
When transmitting section 118 transmits a TPC command, base station apparatus 1100 ends the processing for the received signal and starts processing the next received signal.

FIG. 3 is a diagram illustrating changes in the target SIR in the base station apparatus.
According to FIG. 3, after the occurrence of an error, the TPC command is generated using the conventional target SIR calculation algorithm (first target SIR) until the time τ ′ at which the number of blocks having the length of the SIR measurement interval is received. The second target SIR is calculated at time τ ′, and thereafter, the TPC command is generated using the second target SIR. By setting the second target SIR as the target SIR, the target SIR decreases, and the TPC increase command that has been sequentially transmitted until time τ in the conventional method is suppressed. Therefore, the transmission power of mobile station apparatus 200 is not increased excessively. Further, since the second target SIR exceeds the first target SIR at time τ ″, the first target SIR is set as the target SIR thereafter. Thereby, the block error rate in the base station apparatus 100 is determined. Can be brought close to the target BLER.

  As described above, according to the present embodiment, the second target SIR control unit 115 determines the target SIR stored in the target SIR storage unit 116 when the CRC detection unit 106 does not detect an error. Is rewritten to the measured reception SIR. Therefore, the difference between the target SIR and the required SIR can be reduced, and the transmission unit 118 does not transmit a TPC command indicating an increase in transmission power more than necessary to the mobile station apparatus 200. Thereby, the base station apparatus 100 can control the transmission power of the mobile station apparatus 200 so that the signal can be delivered with the minimum power that can secure the target BLER without excess or deficiency.

As described above, the embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to the above, and various design changes and the like can be made without departing from the scope of the present invention. It is possible to
For example, in the present embodiment, the case where the CRC detection unit 106 detects a block error based on the CRC code of the transfer block has been described. However, the present invention is not limited to this, and the block error is detected using another error detection code. May be.

  The above-described base station apparatus 100 has a computer system inside. The operation of each processing unit described above is stored in a computer-readable recording medium in the form of a program, and the above processing is performed by the computer reading and executing this program. Here, the computer-readable recording medium means a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like. Alternatively, the computer program may be distributed to the computer via a communication line, and the computer that has received the distribution may execute the program.

  The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

  DESCRIPTION OF SYMBOLS 100 ... Base station apparatus 101 ... Reception part 102 ... Delay spread calculation part 103 ... Demodulation part 104 ... SIR measurement part 105 ... Error correction decoding part 106 ... CRC detection part 107 ... Registration part 108 ... Parameter table memory | storage part 109 ... Number of received blocks Counter storage register 110 ... Parameter storage register 111 ... First target SIR control unit 112 ... Delay spread storage unit 113 ... SIR measurement value storage unit 114 ... SIR measurement reception block number counter storage register 115 ... Second target SIR control unit 116: Target SIR storage unit 117 ... Comparison unit 118 ... Transmission unit 200 ... Mobile station apparatus

Claims (8)

A transmission power control apparatus for controlling transmission power of a transmission power control target terminal,
Storage means for storing a target signal-to-interference ratio indicating a target value of the signal-to-interference ratio of the transmission power control target terminal;
Receiving means for receiving a signal from the transmission power control target terminal;
Error detecting means for performing error detection of the signal received by the receiving means for each reception;
Signal-to-interference ratio measuring means for measuring the signal-to-interference ratio of the signal received by the receiving means for each reception;
The target signal-to-interference ratio stored in the target signal-to-interference ratio storage means is rewritten to the signal-to-interference ratio measured by the signal-to-interference ratio measuring means when the error detecting means does not detect an error. Target signal-to-interference ratio setting means;
When the signal-to-interference ratio measured by the signal-to-interference ratio measuring unit is higher than the target signal-to-interference ratio stored in the target signal-to-interference ratio storage unit, a transmission power control command indicating a command to increase the transmission power is generated When the signal-to-interference ratio measured by the signal-to-interference ratio measuring unit is lower than the target signal-to-interference ratio stored by the target signal-to-interference ratio storage unit, a transmission power control command indicating a command to reduce the transmission power Transmission power control command generation means for generating
Transmitting means for transmitting the transmission power control command generated by the transmission power control command generating means to the transmission power control target terminal;
A transmission power control apparatus comprising: When the error detection means detects an error, the value of the target signal-to-interference ratio stored by the storage means is increased, and when the error detection means does not detect an error, the target signal pair stored by the storage means A second target signal-to-interference ratio setting means for reducing the value of the interference ratio;
The first target signal-to-interference ratio setting unit is configured to receive the signal during a predetermined signal-to-interference ratio measurement time from a time when the second target signal-to-interference ratio setting unit increases the target signal-to-interference ratio. The signal measured by the signal-to-interference ratio measuring unit measures the target signal-to-interference ratio stored by the target signal-to-interference ratio storing unit when the error detecting unit does not detect an error with respect to the signal received by the unit. Rewrite to interference ratio,
The transmission power control apparatus according to claim 1.   The transmission power control apparatus according to claim 2, wherein the signal-to-interference ratio measurement time is determined based on a parameter indicating a signal propagation environment.   The transmission power control apparatus according to claim 3, wherein the parameter indicating the propagation environment is a delay spread of a signal received by the reception unit. The first target signal to interference ratio setting means includes:
The target signal-to-interference ratio stored in the target signal-to-interference ratio storage means is measured for a predetermined average signal-to-interference ratio from the time when the second target signal-to-interference ratio setting means increases the target signal-to-interference ratio. Rewriting the average value of the signal-to-interference ratio measured by the signal-to-interference ratio measuring means over time,
The transmission power control apparatus according to any one of claims 2 to 4, wherein the transmission power control apparatus is characterized in that: The average value of the signal-to-interference ratio measured by the signal-to-interference ratio measuring unit during the predetermined signal-to-interference ratio average measuring time is calculated by the signal-to-interference ratio measuring unit immediately after the error detecting unit detects an error. Calculate without including the measured signal-to-interference ratio,
The transmission power control apparatus according to claim 5. Transmission power control using a transmission power control device that includes a storage unit that stores a target signal-to-interference ratio indicating a target value of a signal-to-interference ratio of a transmission power control target terminal, and controls the transmission power of the transmission power control target terminal A method,
The receiving means receives a signal from the transmission power control target terminal,
The error detection means performs error detection of the signal received by the receiving means for each reception,
The signal-to-interference ratio measuring means measures the signal-to-interference ratio of the signal received by the receiving means for each reception,
The first target signal-to-interference ratio setting means uses the target signal-to-interference ratio stored in the target signal-to-interference ratio storage means when the error detection means does not detect an error. Rewrites the measured signal-to-interference ratio,
The transmission power control command generating means is a command for increasing the transmission power when the signal-to-interference ratio measured by the signal-to-interference ratio measuring means is higher than the target signal-to-interference ratio stored in the target signal-to-interference ratio storage means. The transmission power control command generation means indicates the target signal pair stored in the target signal-to-interference ratio storage means by the signal-to-interference ratio measured by the signal-to-interference ratio measuring means. If it is lower than the interference ratio, generate a transmit power control command indicating an instruction to decrease the transmit power,
The transmission means transmits the transmission power control command generated by the transmission power control command generation means to the transmission power control target terminal.
A transmission power control method characterized by the above. A transmission power control apparatus that includes a storage unit that stores a target signal-to-interference ratio indicating a target value of a signal-to-interference ratio of the transmission power control target terminal, and that controls transmission power of the transmission power control target terminal,
Receiving means for receiving a signal from the transmission power control target terminal;
Error detecting means for performing error detection of the signal received by the receiving means for each reception;
A signal-to-interference ratio measuring means for measuring a signal-to-interference ratio of a signal received by the receiving means for each reception;
The target signal-to-interference ratio stored in the target signal-to-interference ratio storage means is rewritten to the signal-to-interference ratio measured by the signal-to-interference ratio measuring means when the error detecting means does not detect an error. Target signal to interference ratio setting means,
When the signal-to-interference ratio measured by the signal-to-interference ratio measuring unit is higher than the target signal-to-interference ratio stored in the target signal-to-interference ratio storage unit, a transmission power control command indicating a command to increase the transmission power is generated When the signal-to-interference ratio measured by the signal-to-interference ratio measuring unit is lower than the target signal-to-interference ratio stored by the target signal-to-interference ratio storage unit, a transmission power control command indicating a command to reduce the transmission power Transmission power control command generation means for generating
Transmitting means for transmitting the transmission power control command generated by the transmission power control command generating means to the transmission power control target terminal;
Program to operate as.

Images