JP2004320254A - Transmission power controlling device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmission power controlling device which is capable of precisely measuring SIR even to an interference that breaks out suddenly. <P>SOLUTION: An instantaneous SIR measuring unit 105 computes instantaneous SIR using instantaneous RSCP and average ISCP. An SIR storage region 109 stores the instantaneous SIR, and a prediction unit 114 predicts future SIR from the SIR stored in the SIR storage region 109. A weighting coefficient calculating unit 115 calculates a weighting coefficient for a weighted average SIR calculation unit 111 using the number of effective passes determined by a unit 113 of determining the number of passes. The weighted average SIR calculation unit 111 classifies the weight of the SIR of the prescribed operation slots containing the SIR of future slots using the calculated weighting coefficient, and averages them up to calculate a weighted average SIR which is compared with a prescribed target SIR through a TPC bit calculation unit 117. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a transmission power control apparatus in mobile communication of a CDMA (Code Division Multiple Access) system.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in CDMA as an access method of a mobile communication system, a system capacity is limited by an amount of interference received by a receiving station. In order to secure system capacity, it is necessary to keep interference low, that is, to keep the transmission power of other stations as low as possible. Therefore, in CDMA, transmission power control (TPC: Transmit Power Control) for increasing or decreasing transmission power according to the quality of a received signal is an essential technology.
[0003]
In this transmission power control, a signal-to-interference ratio (SIR) is generally used as a measure for measuring the quality of a received signal. In order to minimize the interference to the system and ensure the system capacity, the SIR of the received signal is accurately measured, and the transmitting station controls the transmission power so that the value becomes constant during reception. Power control needs to be performed.
[0004]
As this transmission power control method, as disclosed in Patent Document 1, for example, a desired signal power (RSCP: Received Signal Code Power) and an interference wave power (ISCP) are known by using a known pilot signal transmitted from a transmission side. : Interference Signal Code Power). In this system, the desired reception wave power and the reception interference wave power are calculated in the following procedure.
[0005]
That is, the desired signal power is calculated by estimating a transfer function by detecting a pilot signal from a baseband received signal, inverting the phase of the estimated transfer function, multiplying the received signal by an average, and then calculating the power. To calculate the desired signal power.
[0006]
On the other hand, the received interference wave power estimates a transfer function by detecting a pilot signal from a baseband received signal, inverts the phase of the estimated transfer function, multiplies the received signal, and accumulates one slot worth of data in a buffer. The averaging process is performed together with. The difference between the average value and the power for one slot is calculated, and the power is calculated to calculate the interference wave power. The interference wave power calculated in this way is averaged over a plurality of slots. The SIR is calculated using the reception desired wave power and the interference wave power calculated as described above.
[0007]
[Patent Document 1]
JP-A-10-13364
[0008]
[Problems to be solved by the invention]
However, in the conventional transmission power control device, the average of the desired wave power and the average of the interference wave power are simply averaged over a plurality of slots, and thus have the following problems.
[0009]
That is, if the number of slots to be averaged is too small, sufficient averaging is not performed, so that the accuracy of interference power measurement is degraded and the SIR measurement accuracy is degraded. On the other hand, if the number of averaged slots is too large, accurate interference power measurement cannot be performed for suddenly occurring interference, and the SIR measurement accuracy deteriorates.
[0010]
In any case, when the SIR measurement accuracy is deteriorated as described above, the performance of the TPC performed using the SIR measurement result also changes, and the TPC error eventually increases, so that it is necessary to satisfy the reception quality. There is a problem that transmission power is increased, interference given to the wireless system is increased, and system capacity is reduced.
[0011]
The present invention has been made in view of such a point, and an object of the present invention is to provide a transmission power control device capable of accurately measuring SIR even for suddenly occurring interference.
[0012]
[Means for Solving the Problems]
(1) A transmission power control apparatus according to the present invention includes: a desired wave power calculating unit that calculates a desired wave power using the pilot signal for each slot of a received signal including a pilot signal; An interference wave power calculating unit that calculates the interference wave power using the pilot signal, an averaging unit that averages the calculated interference wave power, and the calculated desired wave power and the averaged average interference wave power. SIR calculating means for calculating the SIR, a storing means for storing the calculated SIR, a weighting coefficient calculating means for calculating a weighting coefficient using a parameter relating to the radio wave propagation environment, and Weighted average SIR calculating means for weighting and averaging each of the SIRs for the slots and calculating a weighted average SIR; A configuration and a generating means for generating a transmission power control signal using the SIR and a predetermined target SIR.
[0013]
According to this configuration, the weighting coefficient using the parameter related to the radio wave propagation environment is weighted (for example, multiplied) for each of the SIRs for the predetermined operation slots and averaged, so that the target when generating the transmission control signal is obtained. In order to calculate a weighted average SIR used as a value to be compared with the SIR, the averaging length when calculating the SIR average for a predetermined calculation slot is set to a length corresponding to the radio wave propagation environment of the pilot signal. As a result, it is possible to measure the SIR with high accuracy in response to the radio wave propagation environment even for sudden interference.
[0014]
(2) The transmission power control device of the present invention, in the above-described configuration, further includes a prediction unit that predicts an SIR of a future slot based on the SIR stored in the storage unit, and calculates the weighted average SIR. The means adopts a configuration in which the weighting factors are respectively weighted to SIRs of predetermined calculation slots including the predicted SIR of future slots, and averaged.
[0015]
According to this configuration, since the weighting factors are weighted and averaged for the SIRs of the predetermined operation slots including the predicted future slot, respectively, the weighted average is calculated as the average of the SIRs of the predetermined operation slots. The SIR measurement accuracy can be improved.
[0016]
(3) The transmission power control device of the present invention stores, for each slot of a reception signal including a pilot signal, a desired wave power calculation unit that calculates a desired wave power using the pilot signal, and stores the calculated desired wave power. Weighting coefficient determining means for calculating a parameter relating to the radio wave propagation environment as a weighting coefficient, and averaging the calculated weighting coefficients by averaging them by weighting the desired wave power for a predetermined calculation slot. Weighted average desired wave power calculation means for calculating power, interference wave power calculation means for calculating interference wave power using the pilot signal for each slot of the received signal, and averaging means for averaging interference wave power SIR calculating means for calculating an SIR using the calculated weighted average desired wave power and the averaged interference wave power, A configuration and a generating means for generating a transmission power control signal using the SIR and a preset target SIR.
[0017]
According to this configuration, the weighted coefficient using the parameter related to the radio wave propagation environment is weighted (for example, multiplied) to each of the desired wave powers for the predetermined operation slots, and the weighted average desired wave power is averaged. In order to calculate the SIR to be compared with the target SIR from the ratio of the obtained interference wave power, the averaging length when calculating the average of the desired wave power for a predetermined calculation slot is determined by the radio propagation environment of the pilot signal. Therefore, the SIR can be measured with high accuracy even for suddenly occurring interference.
[0018]
(4) In the transmission power control device of the present invention, the weighted average desired wave power is calculated by predicting a desired wave power of a future slot based on the desired wave power stored in the storage means. The weighted average desired wave power calculating means weights the weighting coefficients to desired wave powers of predetermined calculation slots including a predicted future slot desired wave power, respectively. And a configuration for averaging.
[0019]
According to this configuration, the weighted coefficients are respectively weighted (for example, multiplied) with desired wave powers of predetermined operation slots including a predicted future slot, and averaged. The SIR can be calculated from the power and the average interference wave power, whereby the measurement accuracy of the SIR compared with the target SIR can be improved.
[0020]
(5) The transmission power control device according to the above configuration, wherein the parameter relating to the radio wave propagation environment is the number of effective paths, and the weighting coefficient calculation unit calculates a weighting coefficient using the number of effective paths. Take.
[0021]
According to this configuration, since the parameter used for the weighting factor is the number of effective paths, it is possible to calculate a highly accurate SIR that is weighted and averaged in accordance with the radio wave propagation environment of the pilot signal.
[0022]
(6) In the transmission power control device of the present invention, in the above configuration, the parameter relating to the radio wave propagation environment is a standard deviation of a desired wave power, and the weighting coefficient calculating unit uses the standard deviation of the desired wave power. A configuration for calculating a weighting coefficient is employed.
[0023]
According to this configuration, since the parameter used for the weighting factor is the standard deviation of the desired signal power measured from the pilot signal, a highly accurate SIR that is weighted and averaged in accordance with the radio wave propagation environment of the pilot signal is calculated. be able to.
[0024]
(7) In the transmission power control device of the present invention, in the above-described configuration, the parameter relating to the radio wave propagation environment is a standard deviation of SIR, and the weighting coefficient calculating means calculates a weighting coefficient using the standard deviation of SIR. It adopts the configuration to do.
[0025]
According to this configuration, since the parameter used for the weighting coefficient is the standard deviation of the SIR measured from the pilot signal, it is possible to calculate a highly accurate SIR that is weighted and averaged in accordance with the radio propagation environment of the pilot signal. it can.
[0026]
(8) In the transmission power control device of the present invention, in the above-described configuration, the parameter related to the radio wave propagation environment is a Doppler frequency, and the weighting factor calculation unit calculates a weighting factor using the Doppler frequency. .
[0027]
According to this configuration, since the weighting coefficient is determined according to the Doppler frequency from the pilot signal, it is possible to calculate a highly accurate SIR that is weighted and averaged in accordance with the radio wave propagation environment of the pilot signal.
[0028]
(9) In the transmission power control device of the present invention, in the above configuration, the parameter relating to the radio wave propagation environment is a long section average SIR, and the weighting coefficient calculation means calculates a weighting coefficient using the long section average SIR. It adopts the configuration to do.
[0029]
According to this configuration, since the parameter used for the weighting factor is the long-term average SIR, it is possible to calculate a highly accurate SIR that is weighted and averaged corresponding to the radio wave propagation environment of the pilot signal.
[0030]
(10) In the transmission power control device of the present invention, in the above-described configuration, the parameter relating to the radio wave propagation environment is a target SIR, and the weighting factor calculation means calculates a weighting factor using the target SIR. .
[0031]
According to this configuration, since the weight coefficient is calculated based on the target SIR, it is possible to calculate a highly accurate SIR that is weighted and averaged in accordance with the radio wave propagation environment of the pilot signal.
[0032]
BEST MODE FOR CARRYING OUT THE INVENTION
The gist of the present invention is a radio wave propagation environment such as the number of effective paths, the standard deviation of desired signal power (RSCP), the standard deviation of desired signal power to interference power ratio (SIR), Doppler frequency, long section average SIR, and target SIR. Is to control the averaging length when the SIR and RSCP calculated from the received signal are obtained by weighted averaging using the parameter corresponding to. Note that the long section average SIR is an SIR averaged in a section of about several hundred to several thousand symbols. Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0033]
(Embodiment 1)
FIG. 1 is a block diagram showing a configuration of a transmission power device 100 according to Embodiment 1 of the present invention.
[0034]
1 includes an instantaneous RSCP measuring unit 101, an instantaneous ISCP measuring unit 103, an instantaneous SIR measuring unit 105, an averaging unit 107, an SIR storage area unit 109, a weighted average SIR calculating unit 111, and a path number determining unit. 113, a prediction unit 114, a weighting coefficient calculation unit 115, and a TPC bit calculation unit 117.
[0035]
Instantaneous RSCP measuring section 101 measures the power of the desired signal component (RSCP) of the known pilot signal included in the received signal for each slot of the received signal, and calculates the instantaneous SIR measuring section 105. In FIG. 1, the received pilot signal is referred to as “received pilot signal”.
[0036]
Instantaneous ISCP measuring section 103 measures the instantaneous interference wave component power (ISCP) of the received signal and outputs the result to averaging section 107. The averaging unit 107 calculates an average ISCP as an average value of the power of the interference wave component input from the instantaneous ISCP measuring unit 103 in a predetermined section.
[0037]
The instantaneous SIR measuring section 105 calculates the instantaneous desired signal power based on the instantaneous desired signal power measured by the instantaneous RSCP measuring section 101 and the average value (average ISCP) of the interference signal power averaged by the averaging section 107. The power ratio to interference wave (SIR) is calculated and output to the SIR storage area unit 109 and the weighted average SIR calculation unit 111.
[0038]
The instantaneous SIR measurement unit 105 calculates the SIR using the following equation.
SIR = desired wave power / interference wave power
[0039]
The SIR storage area unit 109 stores the instantaneous SIR input from the instantaneous SIR measurement unit 105. The SIR storage area 109 stores the instantaneous SIR and the SIR of a past slot that is continuous with the slot in which the instantaneous SIR was measured.
[0040]
Based on the instantaneous SIR and past SIR held in the SIR storage area 109, the prediction unit 114 calculates the value of the next measured SIR, that is, the SIR of a future slot that is continuously input to the current slot. Predicted and output to the weighted average SIR calculation unit 111.
[0041]
The number-of-paths determination unit 113 includes a plurality of fingers assigned to the path of the received signal, measures the number of effective paths from the number of effective fingers assigned to the effective path of the received signal, and weights the measured number of effective paths to a weighting factor. Output to calculation section 115.
[0042]
The weighting coefficient calculation unit 115 is weighted by the weighted average SIR calculation unit 111 over the SIRs of a plurality of slots continuous to the measured slot, based on the number of paths input by the path number determination unit 113. The weighting coefficient is calculated and output to the weighted average SIR calculation unit 111.
[0043]
In detail, the weighting coefficient calculation unit 115 includes a table in which the number of paths and the weighting coefficient for weighting the slot are associated with each other. And outputs a weighting coefficient associated with the input number of paths to the weighted average SIR calculation unit 111.
[0044]
Here, FIG. 2 shows an example of a table in which the number of paths provided in the weighting coefficient calculation unit 115 and the weighting coefficients are related. In FIG. 2, A ₁ , B ₁ , C ₁ , D ₁ Represents the preset number of paths, and W (i) represents the weight for the slot number i.
[0045]
In the table of FIG. 2, the predetermined number of paths A is set in advance. ₁ , B ₁ , C ₁ , D ₁ And weighting coefficients corresponding to the number of paths satisfying these conditions are stored. For example, the number of paths A from which the number of paths from the number-of-paths determination unit 113 is the threshold stored in the table ₁ If the number is larger than the number of paths, the number of paths is greater than the number of paths> A. ₁ And 0.8, 0.9, 1, 0.9, 0.8 are weighted average SIRs as weighting factors for weighting SIRs of the current slot and a plurality of continuous slots before and after the current slot. The calculation is performed by the calculation unit 111.
[0046]
The weighted average SIR calculation unit 111 calculates the instantaneous SIR input from the instantaneous SIR measurement unit 105, the SIR of the past slot input from the SIR storage area unit 109, the SIR of the future slot input from the prediction unit 114, , The SIR of a slot that is continuous with the past and the future is multiplied by the weighting coefficient calculated by the weighting coefficient calculation unit 115, and the weighted and averaged value is calculated by the TPC bit calculation unit 117.
[0047]
TPC bit calculation section 117 compares the SIR input from weighted average SIR calculation section 111 (hereinafter referred to as “weighted average SIR”) with a preset target SIR, and the weighted average SIR is smaller than target SIR. In this case, a TPC bit for increasing the transmission power is generated. Conversely, when the weighted average SIR is larger than the target SIR, a TPC bit for decreasing the transmission power is generated. For example, when the TPC bit is “0”, the transmission power is reduced by 1 dB, and when the TPC bit is “1”, the transmission power is increased by 1 dB.
[0048]
Next, the operation of the transmission power control device 1 having the above configuration will be described.
When transmission power control apparatus 1 receives a known signal included in a received signal, here, a received pilot signal, for each slot of the received signal, instantaneous RSCP measuring section 101 measures instantaneous RSCP and outputs it to instantaneous SIR measuring section 105. . Further, instantaneous ISCP measuring section 103 measures the instantaneous ISCP, averages the measured instantaneous ISCP in averaging section 107, and outputs the averaged ISCP to instantaneous SIR measuring section 105.
[0049]
The instantaneous SIR measurement unit 105 calculates an instantaneous SIR, which is a ratio between the instantaneous RSCP and the average ISCP, and outputs the calculated instantaneous SIR to the SIR storage area unit 109 and the weighted average SIR calculation unit 111.
[0050]
The SIR storage area unit 109 outputs to the weighted average SIR calculation unit 111 the SIR of the past slot that is already stored and that is continuous to the slot in which the instantaneous SIR was measured, and stores the SIR of the past slot in the instantaneous SIR. Output to the prediction unit 114 together with the instantaneous SIR input from the measurement unit 105.
[0051]
The prediction unit 114 predicts, based on the instantaneous SIR and the past SIR, the SIR of a future slot that is continuous with the current slot in which the instantaneous SIR was measured, and the future SIR is calculated by the weighted average SIR calculation unit 111. You.
[0052]
On the other hand, the number of paths is determined by path number determining section 113 based on the received pilot signal and output to weighting coefficient calculating section 115.
[0053]
In the weighting coefficient calculation unit 115, a weighting coefficient is calculated by the weighted average SIR calculation unit 111 based on the stored table.
[0054]
FIG. 3 is a diagram for explaining the calculation of the weighted average SIR in the weighted average SIR calculation unit 111. In FIG. 3, the slot measured by the instantaneous SIR measurement unit is the current slot slot #n. By calculating the average SIR over the number of consecutive slots before and after this slot #n, the average length of the SIR can be changed.
[0055]
As shown in FIG. 3, the weighted average SIR calculation unit 111 includes an instantaneous SIR (SIR (n) shown in FIG. 3) input from the instantaneous SIR measurement unit 105 and a past SIR (SIR (n) shown in FIG. Weighting coefficient calculation is performed on each of SIR (n-1) and SIR (n-2) shown in FIG. 3 and future SIRs (SIR (n + 1) and SIR (n + 2) shown in FIG. 3) input from prediction section 114. A weighting coefficient W (n−2), W (n−1), W (n), W (n + 1), W (n + 2) corresponding to the number of paths calculated by the unit 115 is multiplied, and these weighted SIRs are calculated. Calculate the average of
[0056]
For example, the number of paths input to weighting coefficient calculation section 115 from number-of-paths determination section 113 is equal to the number of paths A serving as a threshold in the table. ₁ If it is larger, the weighted average SIR calculator 111 ₁ The weighting factors for the larger case, ie, SIR (n-1), SIR (n-2), SIR (n), SIR (n + 1), SIR (n + 2) shown in FIG. The weighted average SIR is calculated by multiplying by 0.9, 1, 0.9, and 0.8, respectively, and weighting and averaging.
[0057]
As described above, the weighted average SIR calculation unit 111 calculates the SIR after the weighted average in the n-th slot (weighted average SIR (n)) using the following equation.
[0058]
Weighted average SIR (n) = ΣW (i) × SIR (i) / ΣW (i)
Here, i is the slot number, SIR (i) is the instantaneous SIR at the i-th slot, and W (i) is the weight at the i-th slot.
[0059]
According to the above embodiment, the SIR in the TPC bit calculation unit, which is compared with the target SIR to output the transmission control signal, is obtained by dividing the weighting coefficient using the number of paths as a parameter related to the radio wave propagation environment for a predetermined calculation slot. Are weighted, that is, multiplied and averaged. As a result, the length of averaging when calculating the SIR average for a predetermined calculation slot can be set to a length corresponding to the radio wave propagation environment of the received pilot signal. Therefore, even for the interference that occurs suddenly when measuring the SIR, the SIR measurement can be accurately performed in accordance with the radio wave propagation environment at that time.
[0060]
In the first embodiment, the number of paths input from the number-of-paths determination unit 113 is used as a parameter related to the radio wave propagation environment for the weighting coefficient calculation unit 115 to calculate the weighting coefficient. Parameters other than the number of paths, such as the standard deviation of RSCP, the standard deviation of SIR, the Doppler frequency, the long-term average SIR, and the target SIR, may be used as parameters.
[0061]
Hereinafter, with reference to FIGS. 4 to 13, a description will be given of a transmission power control apparatus in a case where a parameter related to a radio wave propagation environment for calculating a weighting coefficient is changed as Modification Examples 1 to 5. In FIGS. 4 to 13, portions common to FIGS. 1 and 2 are denoted by the same reference numerals as those in FIGS. 1 and 2, and detailed description is omitted.
[0062]
FIG. 4 is a block diagram showing the configuration of a transmission power control device 100a as a first modification of the first modification in which the parameter relating to the radio wave propagation environment for calculating the weighting coefficient is set to the standard deviation of the desired signal power (RSCP) instead of the number of paths. It is.
[0063]
4 includes an instantaneous RSCP measuring unit 101, an instantaneous ISCP measuring unit 103, an instantaneous SIR measuring unit 105, an averaging unit 107, an SIR storage area unit 109, a weighted average SIR calculating unit 111, and a predicting unit 114. , A TPC bit calculation unit 117, an RSCP standard deviation measurement unit 120, and a weighting coefficient calculation unit 130. That is, transmission power control apparatus 100a has a configuration in which RSCP standard deviation measurement section 120 that measures the standard deviation of RSCP from the received pilot signal is used instead of path number determination section 113 in comparison with the configuration of transmission power apparatus 100. ing.
[0064]
RSCP standard deviation measurement section 120 outputs the standard deviation value of RSCP measured from the received pilot signal to weighting coefficient calculation section 130.
[0065]
Weighting coefficient calculating section 130 calculates a weighting coefficient corresponding to the standard deviation of RSCP input from RSCP standard deviation measuring section 120 and outputs the weighting coefficient to weighted average SIR calculating section 111. I do.
[0066]
FIG. 5 shows an example of a table included in the weighting coefficient calculation section 130 in the transmission power control device of the first modification.
[0067]
The table shown in FIG. 5 is different from the table of FIG. 2 in that the threshold value for comparing with the parameter relating to the input radio wave propagation environment is the standard deviation of RSCP instead of the number of paths, and other values are the same. It is. Therefore, the calculation of the weighting coefficient in weighting coefficient calculating section 130 is different from weighting coefficient calculating section 115 only in the input parameters, and the other steps are performed in the same manner. It has the same function and effect as 100.
[0068]
For example, even when the standard deviation of the desired signal power increases and the difference between the measured value and the expected value of the SIR increases, the averaging length for calculating the SIR is varied by controlling the weighting coefficient, and the SIR measurement is performed. Accuracy can be improved.
[0069]
FIG. 6 is a block diagram illustrating a configuration of a transmission power control device as a second modification in which a parameter relating to a radio wave propagation environment for calculating a weighting coefficient is a standard deviation of SIR instead of the number of paths.
[0070]
6 includes an instantaneous RSCP measuring section 101, an instantaneous ISCP measuring section 103, an instantaneous SIR measuring section 105, an averaging section 107, an SIR storage area section 109, a weighted average SIR calculating section 111, and a TPC bit calculating section. It has a unit 117, a prediction unit 114, an SIR standard deviation measurement unit 140, and a weighting coefficient calculation unit 145.
[0071]
That is, transmission power control apparatus 100b has a configuration in which SIR standard deviation measurement section 140 that measures the SIR standard deviation from the received pilot signal is used instead of path number determination section 113 in comparison with the configuration of transmission power apparatus 100. ing.
[0072]
SIR standard deviation measurement section 140 outputs the standard deviation value of the SIR measured from the received pilot signal to weighting coefficient calculation section 145.
[0073]
The weighting coefficient calculating section 145 calculates a weighting coefficient corresponding to the standard deviation of the SIR input from the SIR standard deviation measuring section 140 and outputs the weighting coefficient to the weighted average SIR calculating section 111. I do.
[0074]
FIG. 7 illustrates an example of a table included in the weighting coefficient calculation unit 145 in the transmission power control device according to the second modification.
[0075]
The table shown in FIG. 7 is different from the table of FIG. 2 in that the threshold value to be compared with the parameter relating to the input radio wave propagation environment is the standard deviation of SIR instead of the number of paths, and other values are the same. Things. Therefore, the calculation of the weighting coefficient in weighting coefficient calculation section 145 is performed in the same manner as in weighting coefficient calculation section 115, except for the input parameters, and transmission power control apparatus 100b operates in the same manner as transmission power control apparatus 100b. It has the same function and effect as 100.
[0076]
For example, since the standard deviation of the SIR increases when the target SIR is small, the difference between the measured SIR value and the target SIR at the time of the measurement may increase. In this case as well, the weighting coefficient based on the target SIR is compared with the case where the target SIR is large, the length of averaging for calculating the SIR is increased, the dispersion of the measurement is reduced, and the measurement accuracy is improved. Can be achieved.
[0077]
FIG. 8 is a block diagram showing a configuration of a third modification of the transmission power control device according to the present invention.
[0078]
8 includes an instantaneous RSCP measuring section 101, an instantaneous ISCP measuring section 103, an instantaneous SIR measuring section 105, an averaging section 107, an SIR storage area section 109, a weighted average SIR calculating section 111, and a TPC bit calculating section. It has a unit 117, a prediction unit 114, a Doppler frequency measurement unit 150, and a weighting coefficient calculation unit 155. That is, transmission power control apparatus 100c has a configuration in which Doppler frequency measurement section 150 that measures a Doppler frequency from a received pilot signal is used instead of path number determination section 113 in comparison with the configuration of transmission power apparatus 100.
[0079]
Doppler frequency measuring section 150 measures the Doppler frequency from the received pilot signal and outputs the result to weighting coefficient calculating section 155.
[0080]
Weighting coefficient calculation section 155 calculates a weighting coefficient corresponding to the Doppler frequency input from Doppler frequency measurement section 150 and outputs the calculated weighting coefficient to weighted average SIR calculation section 111.
[0081]
FIG. 9 shows an example of a table held by the weighting coefficient calculation section 155 in the transmission power control device of the third modification.
[0082]
The table shown in FIG. 9 is different from the table of FIG. 2 in that the threshold value to be compared with the parameter relating to the input radio wave propagation environment is Doppler frequency instead of the number of paths, and the other values are the same. is there. Therefore, the calculation of the weighting coefficient in the weighting coefficient calculation unit 155 is different from that of the weighting coefficient calculation unit 115 only in the input parameters, and is otherwise performed in the same manner. That is, the transmission power control device 100c has the same operation and effect as the transmission power control device 100.
[0083]
For example, when the Doppler frequency from the pilot signal is high, the averaging length for calculating the SIR is longer than that in the case where the Doppler frequency is low in order to follow the fluctuation level, and the measurement accuracy is improved. be able to.
[0084]
FIG. 10 is a block diagram showing a configuration of a fourth modification of the transmission power control device according to the present invention.
[0085]
Transmission power control apparatus 100d shown in FIG. 10 includes instantaneous RSCP measuring section 101, instantaneous ISCP measuring section 103, instantaneous SIR measuring section 105, averaging section 107, SIR storage area section 109, weighted average SIR calculating section 111, and TPC bit calculation. It has a section 117, a prediction section 114, a long section average SIR measurement section 160, and a weighting coefficient calculation section 165. That is, transmission power control apparatus 100d has a configuration in which, instead of configuration of transmission power apparatus 100, long interval average SIR measurement section 160 that measures long interval average SIR from a received pilot signal is used instead of path number determination section 113. ing.
[0086]
The long section average SIR measurement section 160 measures the SIR over a long section, and outputs the value obtained by averaging the long sections to the weighting coefficient calculation section 165 as the long section average SIR.
[0087]
The weighting coefficient calculation section 165 calculates a weighting coefficient corresponding to the input long section average SIR based on the long section average SIR input from the long section average SIR measurement section 160, and outputs the weighted coefficient to the weighted average SIR calculation section 111. Output.
[0088]
FIG. 11 illustrates an example of a table included in the weighting coefficient calculation unit in the transmission power control device according to the fourth modification.
[0089]
The table shown in FIG. 11 is different from the table of FIG. 2 in that the threshold value to be compared with the parameter related to the input radio wave propagation environment is a long section average SIR instead of the number of paths, and other values are the same. Things. Therefore, the calculation of the weighting coefficient in the weighting coefficient calculation unit 165 is different from that of the weighting coefficient calculation unit 115 only in the parameters to be input, and is otherwise performed in the same manner. Therefore, the transmission power control device 100d has the same operation and effect as the transmission power control device 100.
[0090]
For example, when the average SIR of the long section is lower than the average SIR of the short section (about several symbols to several tens of symbols), the standard deviation of the SIR increases, and the difference between the measured SIR and the target SIR increases. Even if there is, the averaging length for calculating the SIR can be increased as compared with the case where the long section average SIR is high, and the SIR measurement accuracy can be improved.
[0091]
FIG. 12 is a block diagram illustrating a configuration of a transmission power control apparatus 100e as a fifth modification example in which a parameter relating to the radio wave propagation environment for calculating the weighting coefficient is set to the target SIR instead of the number of paths.
[0092]
Transmission power control apparatus 100e shown in FIG. 12 includes instantaneous RSCP measuring section 101, instantaneous ISCP measuring section 103, instantaneous SIR measuring section 105, averaging section 107, SIR storage area section 109, weighted average SIR calculating section 111, and TPC bit calculation. It has a unit 117, a prediction unit 114, a target SIR determination unit 170, and a weighting coefficient calculation unit 175. That is, transmission power control apparatus 100e has a configuration in which target SIR determining section 170 that determines a target SIR from a received pilot signal instead of path number determining section 113 in comparison with the configuration of transmission power apparatus 100.
[0093]
Target SIR determining section 170 determines a target SIR based on the received pilot signal, and outputs the target SIR to TPC bit calculating section 117 and to weighting coefficient calculating section 145.
[0094]
Weighting coefficient calculation section 175 calculates a weighting coefficient corresponding to the input target SIR based on the target SIR input from target SIR determination section 170, and outputs the calculated weighting coefficient to weighted average SIR calculation section 111.
[0095]
FIG. 13 shows an example of a table included in the weighting coefficient calculation section 175 in the transmission power control device of the fifth modification.
[0096]
The table shown in FIG. 13 is different from the table of FIG. 2 in that the threshold value to be compared with the parameter relating to the input radio wave propagation environment is the target SIR instead of the number of paths, and the other values are the same. . Therefore, the calculation of the weighting coefficient in weighting coefficient calculation section 175 is different from weighting coefficient calculation section 115 only in the input parameters. Thus, the transmission power control device 100e has the same operation and effect as the transmission power control device 100.
[0097]
For example, since the standard deviation of the SIR increases when the target SIR is small, the difference between the measured SIR value and the target SIR at the time of the measurement may increase. In this case as well, the weighting coefficient based on the target SIR is compared with the case where the target SIR is large, the length of averaging for calculating the SIR is increased, the dispersion of the measurement is reduced, and the measurement accuracy is improved. Can be achieved.
[0098]
(Embodiment 2)
FIG. 14 is a block diagram showing a configuration of transmission power control apparatus 200 according to Embodiment 2 of the present invention. However, in FIG. 14, portions common to FIG. 1 are denoted by the same reference numerals as in FIG. 1, and detailed description is omitted.
[0099]
A feature of the transmission power control device 200 shown in FIG. 14 is that, compared to the transmission power control device 100 of FIG. 1, an object to be weighted by a parameter related to a radio wave propagation environment is instantaneous RSCP instead of SIR over a plurality of slots. This is the instantaneous RSCP measured by the measurement unit 101.
[0100]
Transmission power control apparatus 200 shown in FIG. 14 includes instantaneous RSCP measuring section 101, instantaneous ISCP measuring section 103, SIR measuring section 205, averaging section 107, RSCP storage area section 209, predicting section 214, number of paths determining section 113, TPC It comprises a bit calculator 117, a weighted average RSCP calculator 211, and a weighting coefficient calculator 222.
[0101]
In transmission power control apparatus 200, instantaneous RSCP measuring section 101 measures the power of the desired wave component of the received signal, and calculates it in RSCP storage area section 209 and weighted average RSCP calculating section 211.
[0102]
The RSCP storage area unit 209 stores the instantaneous RSCP input from the instantaneous RSCP measurement unit 101. That is, the RSCP storage area 209 stores the instantaneous RSCP and the RSCP of the past slot that is continuous to the slot in which the instantaneous RSCP was measured.
[0103]
The prediction unit 214 predicts, based on the instantaneous RSCP and the past RSCP held in the RSCP storage area unit 209, the value of the next measured RSCP, that is, the RSCP of the future slot that is continuous with the current slot, and assigns a weight. Output to average RSCP calculation section 211.
[0104]
The weighting coefficient calculating section 222 calculates a weighting coefficient to be weighted over the RSCPs of a plurality of slots by the weighted average RSCP calculating section 211 based on the number of paths input by the path number determining section 113. Note that the weighting coefficient calculation unit 222 includes a table indicating the relationship between the number of paths and the weighting coefficient as in the case of the weighting coefficient calculation unit 115. In the weighting coefficient calculation section 222, the weighting coefficients calculated by the weighted average RSCP calculation section 211 are calculated for a plurality of slots continuous to the current slot to be weighted by the weighted average RSCP calculation section 211.
[0105]
The weighted average RSCP calculation unit 211 calculates the instantaneous RSCP input from the instantaneous RSCP measurement unit 101, the RSCP of the past slot input from the RSCP storage area unit 209, the RSCP of the future slot input from the prediction unit 214, The weighted averaged RSCP (weighted average RSCP) obtained by multiplying the RSCP of the slot continuous to the past and the future by the weighting coefficient calculated by the weighting coefficient calculation unit 222 to obtain an averaged value is used as the SIR measurement unit. Output to 205.
[0106]
The SIR measurement unit 205 calculates a ratio between the weighted average RSCP measured by the weighted average RSCP calculation unit 211 and the average value (average ISCP) of the interference wave power averaged by the averaging unit 107, that is, SIR = desired wave power / SIR is calculated using the equation of / interference wave power and output to TPC bit calculation section 117.
[0107]
FIG. 15 is a diagram for explaining the calculation of the weighted average RSCP in the weighted average RSCP calculation unit 211. In FIG. 15, the slot measured by the instantaneous RSCP measurement unit 101 is the current slot, and the slot is #n.
[0108]
As shown in FIG. 15, the weighted average RSCP calculation unit 211 calculates the instantaneous RSCP (RSCP (n) shown in FIG. 15) input from the instantaneous RSCP measurement unit 101 and the past RSCP (RSCP (n) input from the RSCP storage area unit 209). Weighting coefficient calculation is performed on each of RSCP (n-1) and RSCP (n-2) shown in FIG. 3 and future RSCP (RSCP (n + 1) and RSCP (n + 2) shown in FIG. 3) input from prediction section 214. The weighted coefficients W (n−2), W (n−1), W (n), W (n + 1) and W (n + 2) calculated by the unit 115F are multiplied, and the average of these weighted RSCPs is measured by SIR. The calculation is performed by the unit 205.
[0109]
Therefore, the equation for calculating the weighted average RSCP (weighted average RSCP (n)) in the n-th slot is:
Weighted average RSCP (n) = ΣW (i) × RSCP (i) / ΣW (i)
It becomes. Here, i is the slot number, RSCP (i) is the instantaneous RSCP in the i-th slot, and W (i) is the weight in the i-th slot.
[0110]
Then, the SIR measuring section 205 calculates an SIR (hereinafter referred to as a measured SIR) using the weighted average RSCP from the weighted average RSCP calculating section 211 and the average ISCP from the averaging section 107, and sends it to the TPC bit calculating section 117. Output.
[0111]
The TPC bit calculator 117 compares the input measurement SIR with a preset target SIR, and generates a TPC bit indicating that the transmission power is increased when the measurement SIR is smaller than the target SIR. Conversely, when the weighted average SIR is larger than the target SIR, a TPC bit to reduce the transmission power is generated.
[0112]
As described above, according to transmission power control apparatus 200 of Embodiment 2, weighted average RSCP calculating section 211 performs continuous RSCP calculation before and after current slot #n, that is, RSCP calculation over past and future slots including the current slot. The averaging length can be calculated, and this averaging length can be changed, and the same operation and effect as those of the transmission power control device 1 according to the first embodiment in which the SIR average length is changed can be obtained.
[0113]
According to the second embodiment, a parameter relating to a radio wave propagation environment, that is, a weighting coefficient using the number of paths measured from a received pilot signal is weighted, that is, multiplied by each desired wave power for a predetermined calculation slot. And average. Then, since the SIR to be compared with the target SIR is calculated from the ratio of the averaged desired wave power obtained by weighted averaging to the average interference wave power, the average of the desired wave power for a predetermined calculation slot is calculated. The length of averaging can be set to a length corresponding to the radio wave propagation environment of the received pilot signal, so that SIR measurement can be performed with high accuracy even for sudden interference.
[0114]
In addition, since the weighting coefficient relating to the number of paths is weighted, that is, multiplied and averaged by the desired wave power for a predetermined operation slot including the predicted future slot, the measurement accuracy of the SIR compared with the target SIR is calculated. Improvements are being made.
[0115]
In the first embodiment, the number of paths input from the number-of-paths determination unit 113 is used as a parameter related to the electric field propagation environment for the weighting coefficient calculation unit 115 to calculate the weighting coefficient. The standard deviation, the standard deviation of the SIR, the Doppler frequency, the long-term average SIR, and the target SIR may be used.
[0116]
That is, in the transmission power control device 200, as described in the first to fifth modifications, the RSCP standard deviation measurement unit 120 and the SIR standard deviation measurement are used instead of the path number determination unit 113 that outputs a parameter to the weighting coefficient calculation unit 222. A configuration may be adopted as the section 140, the Doppler frequency measurement section 150, the long section average SIR measurement section 160, and the target SIR determination section 170. It is.
[0117]
Further, the base station apparatus used in the mobile communication system using the transmission power control apparatus according to Embodiment 1, Modifications 1 to 5 and Embodiment 2 and a communication terminal apparatus performing wireless communication with the base station apparatus It can be mounted on When mounted, it is possible to improve the accuracy of transmission power control performed by the base station device and the communication terminal device according to SIR.
[0118]
【The invention's effect】
As described above, according to the present invention, it is possible to accurately measure the SIR even for sudden interference.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a transmission power device according to Embodiment 1 of the present invention.
FIG. 2 is a diagram showing an example of a table in which a number of paths and a weighting coefficient are associated with each other and which is included in a weighting coefficient calculation unit in FIG. 1;
FIG. 3 is a diagram for explaining the operation of a weighted average SIR calculation unit in FIG. 1;
FIG. 4 is a block diagram showing a configuration of a transmission power control device according to a first modification of the first embodiment of the present invention.
FIG. 5 is a diagram showing an example of a table included in a weighting coefficient calculator of FIG. 4;
FIG. 6 is a block diagram showing a configuration of a transmission power control device according to a second modification of the first embodiment of the present invention.
FIG. 7 is a diagram showing an example of a table included in the weighting coefficient calculator of FIG. 6;
FIG. 8 is a block diagram showing a configuration of a transmission power control device according to a third modification of the first embodiment of the present invention.
9 is a diagram illustrating an example of a table included in the weighting coefficient calculation unit in FIG. 8;
FIG. 10 is a block diagram showing a configuration of a transmission power control apparatus according to a fourth modification of the first embodiment of the present invention.
FIG. 11 is a diagram showing an example of a table included in the weighting coefficient calculator of FIG. 10;
FIG. 12 is a block diagram showing a configuration of a transmission power control device according to a fifth modification of the first embodiment of the present invention.
FIG. 13 is a diagram showing an example of a table included in the weighting coefficient calculator of FIG.
FIG. 14 is a block diagram showing a configuration of a transmission power control device according to Embodiment 2 of the present invention.
FIG. 15 is a diagram for explaining the operation of the weighted average RSCP calculator of FIG. 14;
[Explanation of symbols]
100, 100a, 100b, 100c, 100d, 100e, 200 Transmission power control device
101 Instantaneous RSCP measurement unit
103 Instantaneous ISCP measurement unit
105 Instantaneous SIR measurement unit
109 SIR storage area
111 Weighted average SIR calculator
113 pass number determination unit
114, 214 prediction unit
115,130,145,155,165,175,222 Weighting coefficient calculator
117 TPC bit calculation unit
120 RSCP standard deviation measurement unit
140 SIR standard deviation measurement unit
150 Doppler frequency measurement unit
160 Long section average SIR measurement section
170 Target SIR determination unit
205 SIR measurement unit
209 RSCP storage area
211 Weighted average RSCP calculator

Claims (10)

For each slot of the received signal including the pilot signal, desired wave power calculation means for calculating the desired wave power using the pilot signal,
For each slot of the received signal, interference wave power calculation means for calculating interference wave power using the pilot signal,
Averaging means for averaging the calculated interference wave power,
SIR calculation means for calculating SIR using the calculated desired wave power and averaged average interference wave power,
Storage means for storing the calculated SIR;
Weighting coefficient calculating means for calculating a weighting coefficient using a parameter related to a radio wave propagation environment,
Weighted average SIR calculating means for weighting the calculated weighting coefficients to respective SIRs for predetermined operation slots and averaging them, and calculating a weighted average SIR;
Generating means for generating a transmission power control signal using the weighted average SIR and a predetermined target SIR. A prediction unit that predicts an SIR of a future slot based on the SIR stored in the storage unit,
2. The transmission power according to claim 1, wherein the weighted average SIR calculation means weights and averages the weighting coefficients to SIRs of predetermined operation slots including a predicted future slot SIR. Control device. For each slot of the received signal including the pilot signal, desired wave power calculation means for calculating the desired wave power using the pilot signal,
Storage means for storing the calculated desired wave power,
Weighting factor determining means for calculating a parameter relating to the radio wave propagation environment as a weighting factor,
A weighted average desired wave power calculating means for weighing the calculated weighting coefficients and averaging the desired wave powers for the predetermined calculation slots, respectively, and calculating a weighted average desired wave power,
For each slot of the received signal, interference wave power calculation means for calculating interference wave power using the pilot signal,
Averaging means for averaging the interference wave power;
SIR calculating means for calculating SIR using the calculated weighted average desired wave power and averaged interference wave power,
Generating means for generating a transmission power control signal using the calculated SIR and a preset target SIR. Based on the desired wave power stored in the storage means, further comprising prediction means for predicting a desired wave power of a future slot and outputting it to the weighted average desired wave power calculation means,
The weighted average desired wave power calculating means weights and averages the weighting coefficients to desired wave powers of predetermined calculation slots including a predicted future slot desired wave power. Item 4. The transmission power control device according to item 3. The transmission according to any one of claims 1 to 4, wherein the parameter relating to the radio wave propagation environment is the number of effective paths, and the weighting coefficient calculation unit calculates a weighting coefficient using the number of effective paths. Power control device. The parameter relating to the radio wave propagation environment is a standard deviation of a desired wave power,
The transmission power control device according to any one of claims 1 to 4, wherein the weighting coefficient calculation means calculates a weighting coefficient using a standard deviation of the desired signal power. The parameter relating to the radio wave propagation environment is a standard deviation of SIR,
The transmission power control device according to any one of claims 1 to 4, wherein the weighting coefficient calculation means calculates a weighting coefficient using a standard deviation of the SIR. The parameter related to the radio wave propagation environment is Doppler frequency,
The transmission power control device according to any one of claims 1 to 4, wherein the weighting coefficient calculation unit calculates a weighting coefficient using the Doppler frequency. The parameter relating to the radio wave propagation environment is a long section average SIR, and the weighting coefficient calculation means calculates a weighting coefficient using the long section average SIR. 3. The transmission power control device according to 1. The parameter relating to the radio wave propagation environment is a target SIR,
The transmission power control device according to any one of claims 1 to 4, wherein the weighting coefficient calculation means calculates a weighting coefficient using the target SIR.

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