JP3129285B2 - Base station transmission power control method and base station transmission power control apparatus in CDMA mobile communication system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a method and apparatus for controlling the transmission power of a base station in a mobile communication system based on a code division multiple access (CDMA) system.

[0002]

2. Description of the Related Art In the CDMA system, spread modulation using a spread code having a high transmission rate is performed after normal information modulation, and transmitted. The receiving side performs the normal demodulation by performing the spread demodulation using the same spreading code as the transmitting side to return to the original information bandwidth. Since each user is assigned a mutually orthogonal spreading code sequence, a plurality of users can simultaneously communicate within the same frequency band.

In a cellular type mobile communication system using the CDMA system, a plurality of mobile stations share the same frequency band. In the communication from the base station to the mobile station, a signal transmitted from the same base station is such that all of the desired wave signal component and the interference wave signal component contained in the signal pass through the same propagation path and are transmitted to the mobile station. To reach. For example, when a call from the same base station to the mobile station A and a call to the mobile station B are made at the same time, the mobile station A receives the call to its own station as the desired signal S _A , and receiving a transmission signal as an interference wave signal S _B. However, these received signal components S _A and S _B are received through the same transmission path from the base station to the mobile station A, and therefore have the same variation characteristics. As a result, the ratio of the desired wave reception power to the interference wave reception power at the mobile station is always constant regardless of the position of the mobile station.

However, when a mobile station receives a desired signal from a certain base station X and receives an interference signal from another base station Y, the signal component transmitted from the base station X is The mobile station arrives at the mobile station through a propagation path different from that of the transmitted signal component. As a result, since the fluctuation characteristics of those signal components are different, the mobile station located around the cell boundary is greatly affected by the interference wave signal from another base station.

[0005] In such a case, for mobile stations located near the cell boundary, the transmission power of the base station is made larger than the reference power to prevent the deterioration of the communication quality. In addition, even for mobile stations located at locations where a plurality of strong multipath signals arrive, the transmission power of the base station can be made higher than the reference power, thereby preventing the degradation of speech quality. On the other hand, for other mobile stations having good speech quality, it is necessary to reduce the transmission power of the base station from the reference power. This is to reduce the interference wave power received by another mobile station communicating with the base station. For the above reasons, transmission power control of the base station is required to obtain uniform communication quality in the service area.

An example of a conventional transmission power control method is described in A. Sal.
masi, KSGilhousen, On the System Design Aspects
of Code Division Multiple Access (CDMA) Applied to
Digital Cellular and Personal Communication Netwo
rks, IEEE VCT 1991, PP.57-62.

FIG. 8 is a diagram showing an outline of a base station transmission power control device described in this document. This device is a transmitter,
The receiving unit includes an antenna duplexer 108. The transmitting unit includes transmitting units 101 for N communication channels 1 to N, transmitting unit 102 for pilot channel, transmitting power determining unit 10
6. It is constituted by the amplifier 107.

A transmission signal (downlink transmission signal) to mobile station 113 is input to communication channel transmitting section 101 if the signal is a signal for communication, and is input to pilot channel transmitting section 102 if the signal is a pilot signal. You. Each of the channel transmitting units 101 and 102 performs information modulation and frequency conversion to a radio frequency band, and then spread-modulates the frequency-modulated signal using a spreading code corresponding to a mobile station to be transmitted. Output. Then, a signal generated by adding the output signals of all the channels is output to the amplifier 10.
7 is output. The antenna splitter 108 is an amplifier 107
The mobile station 113 transmits the amplified signal to the mobile station 113. Communication channel transmitting section 101 also sets communication channel transmission power based on notification information from transmission power determining section 106 described later.

The receiving section includes an amplifier 109, a receiving section 110 for N communication channels 1 to N, a receiving section 111 for a pilot channel, and a quality judging section 112.

An amplifier 109 amplifies a spread-modulated radio signal received from a mobile station 113 via an antenna and an antenna splitter 108. The communication channel receiver 110 and the pilot channel receiver 111 despread the radio signal amplified by the amplifier 109 to extract a radio frequency band signal, and then convert the radio frequency signal into a baseband signal. And demodulate to generate and output an analog signal. Further, the communication channel receiving section 110 transmits quality information (from the base station to the mobile station 1) attached to the radio signal received from the mobile station 113.
Information indicating the quality of the signal transmitted to the mobile station 11
3), and decodes and outputs the desired signal reception power to the interference wave reception power ratio to the quality determination unit 112.
Quality determining section 112 determines the quality of the signal transmitted from the base station to mobile station 113 based on the quality information, and notifies transmission power determining section 106 of the quality. The transmission power determination unit 106 determines the transmission power for the communication channel of the mobile station based on the quality notified from the quality determination unit 112,
The transmission power is set for each transmitting section 101.

In the base station transmission power control device having such a configuration, the transmission power of the base station is controlled based on the ratio of the desired wave reception power to the interference wave reception power measured at the mobile station. The mobile station measures the desired signal received power to interference wave received power ratio (hereinafter, SIR (Signal-to-Interference power Ration)).
Is smaller than the reference value, a request signal to increase the transmission power is transmitted to the base station. Measured SI
When R is larger than the reference value, a request signal for reducing transmission power is transmitted to the base station. The base station receives the request signal and increases or decreases the transmission power by a predetermined control step power. As the control step power, a small value such as 0.5 db is used. The range of the control amount with respect to the reference power is limited to, for example, ± 6 db.

[0012]

In the above-described conventional base station transmission power control apparatus, when the total value of the transmission power of the base station increases and approaches the maximum transmission power defined in advance, the mobile station is controlled. Even if a request signal for increasing the transmission power is transmitted to the base station, the base station cannot increase the power as desired by the mobile station because the total transmission power exceeds the maximum transmission power. When the shortage of the transmission power occurs, the waveform of the transmission signal of the base station is distorted, and as a result, the mobile station cannot correctly demodulate the signal, resulting in a problem that the communication quality deteriorates. In addition, a phenomenon in which the transmission power of the base station is insufficient tends to occur in, for example, a base station whose traffic has rapidly increased.

SUMMARY OF THE INVENTION It is an object of the present invention to reduce the degradation of downlink communication quality that occurs when a mobile station cannot transmit desired power due to an increase in base station total transmission power in a CDMA cellular system. It is an object of the present invention to provide a base station transmission power control method and apparatus that can perform the control.

[0014]

[0015]

[0016]

[0017]

[MEANS FOR SOLVING THE PROBLEMS] To achieve the above object
The base station transmission power control method for a CDMA mobile communication system according to the present invention includes the steps of: periodically selecting one of a plurality of communication channels as a transmission power control target channel i; The power reduction rate of the total transmission power used in the previous processing in the transmission power control processing for changing the setting of the transmission power of each communication channel so as to satisfy the predetermined communication quality is the previous reduction rate Dt-1.
And the transmission power control target channel i
For communication channels j other than the above, the value obtained by multiplying the transmission power Ptx (j) currently set for each communication channel by the previous decrease rate Dt-1 as a result of the previous transmission power control processing is the communication channel j. For the transmission power control target channel i, a value obtained by multiplying the desired transmission power Pa (i) by a predetermined function of the previous reduction rate Dt-1 is defined as When the transmission power is equal to or less than the maximum transmission power Pmax_1ch, a value obtained by multiplying the predetermined function is set as the estimated transmission power of the channel i, and the desired transmission power Pa (i) is reduced by the previous reduction rate D.
When the value obtained by multiplying the predetermined function of t-1 is larger than the specified maximum transmission power Pmax_1ch per channel, the value obtained by dividing the maximum transmission power Pmax_1ch per channel by the predetermined function is calculated. As the estimated transmission power of the transmission power control target channel i, the estimated transmission power of each communication channel is added to calculate the base station total transmission power Ptotal, and the base station total transmission power Ptotal is defined as the specified maximum total transmission power. Calculate a power reduction rate Dt that is a rate of reducing the base station total transmission power by dividing by the power Pmax, and the base station total transmission power Ptotal is the maximum total transmission power Pm
If it is larger than ax, the trial transmission power of each communication channel is divided by the power reduction rate Dt, and the divided transmission power is set as a new transmission power of each communication channel, and the base station total When the transmission power Ptotal is equal to or less than the maximum total transmission power Pmax, each of the trial transmission powers is divided by the previous decrease rate Dt-1, and the divided transmission power is newly transmitted to each of the communication channels. Power is set for each communication channel.

According to the base station transmission power control method of the present invention, the transmission power control target channel i is multiplied by a predetermined function of the previous reduction rate _Dt-1 , and the communication channel j is multiplied by the previous reduction rate _Dt-1 . By multiplying, the transmission power of the individual communication channel reduced by the previous transmission power control is returned to the value before the reduction, and the transmission power is set to the estimated transmission power, and the transmission power control is performed using the estimated transmission power. Things.

Therefore, when the base station total transmission power Ptotal does not exceed the maximum total transmission power Pmax,
Control for restoring the transmission power of each communication channel is performed.

Further, the base station transmission power control method according to another CDMA mobile communication system of the present invention, a predetermined function of said previous reduction rate D _t-1 is a function that multiply α previous reduction rate D _t-1 .

[0021]

[0022]

[0023]

[0024]

[0025]

Next, an embodiment of the present invention will be described in detail with reference to the drawings.

(First Embodiment) First, a base station transmission power control method in a CDMA mobile communication system according to a first embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of the base station transmission power control apparatus of the present embodiment. 8 denote the same components.

The transmission power control device of the present embodiment includes a transmission unit, a reception unit, and an antenna duplexer 108.

The transmitting unit includes a plurality of transmitting units 1 for communication channels.
01, a pilot channel transmission section 102, a total transmission power calculation section 103, a comparator 104, a reduction rate calculation section 105, a transmission power determination section 106, and an amplifier 107. The receiving unit includes an amplifier 109, a plurality of communication channel receiving units 110, a pilot channel receiving unit 111, and a quality determining unit 112. The transmitting unit and the receiving unit can communicate with a plurality of mobile stations 113 via the antenna splitter 108 and the antenna. The difference between the base station transmission power control device of the present embodiment and the conventional base station transmission power control device of FIG.
05, and the transmission power determination unit 106
2 in that the transmission power of the transmission unit 101 for the communication channel is determined based on the result of the determination made by No. 2 and the output of the reduction rate calculation unit 105.

[0030] Total transmission power calculation section 103 calculates the total transmission power of communication channels 1 to N. The comparator 104
The total transmission power calculated by total transmission power calculation section 103 is compared with a predetermined value, and whether or not the base station transmission power is insufficient (whether or not the total transmission power is greater than the predetermined value) is determined. judge. When the comparator 104 determines that the base station transmission power is insufficient, the reduction rate calculation unit 105 calculates a power reduction rate that is a rate at which the transmission power is reduced. Transmission power determining section 106 determines transmission power using the power reduction rate calculated by reduction rate calculating section 105, and resets the transmission power in all communication channel transmitting sections 101.

Next, the operation of the base station transmission power control device in the CDMA mobile communication system of the present embodiment will be described.

The downlink transmission signal is output to a communication channel transmitting section 101 in the case of a communication signal, and is output to a pilot channel transmitting section 102 in the case of a pilot signal. In communication channel transmitting section 101, transmission power is set based on the notification information from transmission power determining section 106. In each of channel transmitting sections 101 and 102, analog signal modulation, frequency conversion to a radio frequency band, and spread modulation are performed, and a signal obtained by adding all channel signals is output to amplifier 107. The signal amplified by the amplifier 107 is transmitted to the mobile station 113 via the antenna splitter 108.

On the other hand, the information of the transmission power set by each communication channel transmitting section 101 includes a total transmission power calculating section 103.
Is output to Total transmission power calculation section 103 calculates the total transmission power of communication channels 1 to N. Then, the calculation result of the total transmission power calculated by total transmission power calculation section 103 is output to comparator 104. The comparator 104
The total transmission power is compared with a predetermined maximum total transmission power of the base station, and the comparison result is used as the reduction rate calculation unit 10
Notify 5 Reduction rate calculation section 105 calculates a power reduction rate from the total transmission power calculated by total transmission power calculation section 103 and the maximum total transmission power of a base station defined in advance based on the comparison result from comparator 104. I do. Then, this power reduction rate is notified to transmission power determination section 106.

On the other hand, from the mobile station 113, the antenna duplexer 1
08, the signal received via the amplifier 109 is output to the receiving units 110 and 111 for each channel, where despreading modulation, frequency conversion to a baseband signal, and demodulation are performed. The quality determination unit 112 extracts quality information of the downlink communication channel from the signal demodulated by each reception unit 110,
This result is notified to transmission power determination section 106. The transmission power determining unit 106 calculates the transmission power using the quality reduction information notified from the quality determination unit 112 and the power reduction rate notified from the reduction rate calculation unit 105, and notifies the transmission unit 101 for each communication channel. I do. The transmission unit 101 for the communication channel can change the transmission power up or down based on the notification information from the transmission power determination unit 106.

Next, the operation procedure of the first embodiment of the present invention will be described with reference to FIG.

The transmission power determination section 106 of the base station selects one of the communication channels 1 to N at a constant cycle, and sets a desired transmission power Pa (i) of the communication channel i.
Is determined (step A1). The desired transmission power is determined such that the communication quality of the downlink communication channel determined by the quality determination unit 112 satisfies a preset target communication quality. The procedure of the present embodiment shown in FIG. 2 is a transmission power reset procedure for determining a desired transmission power Pa (i) of a communication channel i at a regular time point t. The total transmission power calculator 103 is notified of the transmission power Ptx (j) of each communication channel j other than the channel i. For the communication channel i, the desired transmission power Pa (i) is notified. Total transmission power calculation unit 1
03 adds these notified transmission powers to calculate the total transmission power Ptotal (step A2). Next, the comparator 104 compares the total transmission power Ptotal with a preset communication channel maximum total transmission power Pmax of the base station (step A3). If the comparison result satisfies the following equation (1), that is, the transmission power of communication channel i is reduced to the desired transmission power because the transmission power of the base station is insufficient.
If Pa (i) cannot be set, reduction rate calculation section 105 calculates a reduction rate, which is a ratio of insufficient transmission power.

Ptotal> Pmax (1) The ratio of desired wave power to interference wave power received by the mobile station 113 by reducing the transmission power of all communication channels by the ratio of the insufficient power. Can be controlled so that the total transmission power does not exceed the maximum value while keeping the constant. The transmission power reduction rate _Dt is obtained by the following equation (2) (step A4).

D _t = Ptotal / Pmax (2) In the case of the following equation (3), that is, when the transmission power of the base station is not insufficient, the power reduction rate
The transmission power is not reduced by setting D _t to 1 (step A).
5).

[0039] Ptotal <Pmax ········ (3) was calculated by reduction rate calculator 105 power reduction rate D _t is notified to transmitting power decision unit 106. The transmission power determination unit 106
Calculate the transmission power of each communication channel (step A
6). The transmission power Ptx (i) of the communication channel i is a value obtained by dividing the desired transmission power Pa (i) by the power reduction rate Dt, as shown in the following equation (4).

[0040] Ptx (i) = Pa (i ) / D t ······ (4) When all communication channels other than communication channel i and j, the transmission power Ptx of a communication channel j (j), the following as shown in equation (5), a value obtained by dividing transmitting power Ptx a (j) by the power reduction rate D _t.

[0041] In Ptx (j) = Ptx (j ) / D t ······ (5) transmitting section 101 for each communication channel is changed to a value which determines the configuration of the transmission power by the transmission power determination unit 106 . With the above steps, the transmission power of all communication channels can be reduced on average at a uniform rate at the ratio of the insufficient transmission power, so that the downlink transmission signal transmitted from the base station with the insufficient transmission power Of the telephone call quality can be reduced.

Next, the operation of this embodiment will be described using specific values.

FIG. 3 is a diagram showing an example of the arrangement of base stations and mobile stations. Referring to FIG. 3, the CDM of the present embodiment
The A mobile communication system includes base stations 201 and 202 and mobile stations 203, 204, 205, 206, and 207. The base station 201 is a mobile station 203, 204,
The base station 201 is connected to communication channels 208, 209, 21 for each mobile station.
It is assumed that a call is being made using 0 and 211. Base station 20
2 is connected to the mobile station 207 and the communication channel 212
Suppose you are on a call using.

Here, the case where the desired transmission power Pa (i) of the communication channel 208 is determined at a certain point in time when the transmission power control is performed periodically will be described.

It is assumed that the transmission power of each of the communication channels 208 to 211 immediately before the transmission power control of the communication channel 208 is a value shown in Table 1 below, and that the base station 20
The maximum total transmission power of one communication channel is 100.0 milliwatts.

[0046]

[Table 1]

[0047]

[Table 2] Here, assuming that the desired transmission power for the communication channel 208 to satisfy the target quality is 22.0 milliwatts (Step A1 in FIG. 2), the total transmission power of the communication channel obtained by the total transmission power calculation unit 103 is 110.0. Milliwatts (step A2), and the total transmission power exceeds the maximum total transmission power 100.0 of the base station 201 (step A3).
Therefore, the power reduction rate is calculated by the reduction rate calculation unit 105 (step A4), and the power reduction rate _Dt = 110/100 = 1.1 is obtained. Then, the new transmission power of each communication channel reset by the transmission power determination unit 106 has a value shown in Table 2 (Step A6).

In this embodiment, the base station total transmission power Ptotal when the desired transmission power Pa (i) is set as the transmission power of the transmission power control target channel i is calculated, and the value exceeds the maximum total transmission power Pmax. If it is, the transmission power of the base station by the transmission power be reduced at a constant rate for all communication channels does not exceed the maximum total transmitting power Pmax by using power reduction rate D _t.

In this embodiment, the desired transmission power Pa
(i) A transmission power of a value lower than that of the transmission power control target channel i is set. However, since the transmission power of the other communication channels is reduced at the same rate, And the amount of interference from Therefore, the deterioration of the desired signal reception power to interference wave reception power ratio (SIR) is not so large.

(Second Embodiment) Next, a second embodiment of the present invention will be described with reference to the drawings.

FIG. 4 is a block diagram of a second embodiment of the present invention. The base station transmission power control device of FIG. 4 is different from the first embodiment shown in FIG. 1 in that a plurality of power multiplication units 301 provided for each of communication channels 1 to N are connected to each power multiplication unit. The difference is that a comparison unit 302, a reduction rate calculation unit 303, and a reduction rate storage unit 304 are newly provided, and the transmission power determination unit 106 is replaced with a transmission power determination unit 305. Transmission power determination section 305
For the transmission power determination unit 106, a quality determination unit 112,
The difference is that the transmission power is determined based on the output of the reduction rate calculation unit 303, the reduction rate storage unit 304, and the comparison unit 302.

The reason why the reduction rate storage unit 304 is provided in the present embodiment is that the power reduction rate calculated by the reduction rate calculation unit 303 is stored and the power reduction rate of the next communication channel is calculated. This is for use.

Power multiplying section 301 receives the transmission power information set by communication channel transmitting section 101 and multiplies it by the previous power reduction rate notified from reduction rate storage section 304. The multiplied power is output to comparison section 302. Comparing section 302 compares the multiplied power with a preset maximum transmission power per communication channel. The power output from the comparison unit 302 for each communication channel is added by the total transmission power calculation unit 103 to calculate the total transmission power.

The comparator 104 compares the total transmission power with a preset maximum transmission power of the base station, and notifies the reduction result calculator 303 of the comparison result. Reduction rate calculation section 303 calculates the power reduction rate of the communication channel, and this power reduction rate is reported to transmission power determining section 305 and reduction rate storage section 304. The transmission power determination unit 305 includes the quality information notified from the quality determination unit 112, the power reduction rate notified from the reduction rate calculation unit 303, and the reduction rate storage unit 3.
04 and the comparison unit 302
The transmission power is calculated using the power outputted from the communication channel, and is notified to the transmission unit 101 for each communication channel.

Next, the operation procedure of the present embodiment will be described with reference to FIG.

The transmission power determination unit 305 of the base station periodically determines the desired transmission power Pa (i) of the communication channel (step A1). The desired transmission power Pa (i) is based on the communication quality of the communication channel determined by the quality determination unit 112,
The power is calculated as satisfying the predetermined target communication quality of the downlink communication channel.

The operation procedure shown in FIG. 5 is a transmission power control procedure for determining a desired transmission power Pa (i) of a communication channel i at a regular time t.

Each communication channel transmitting section 101 notifies the power multiplying section 301 of information on the transmission power. Power multiplier 30
1 is notified from the reduction rate storage unit 304 to the transmission power Pt at the current time t, which is notified from each transmission unit 101;
The time point t-1 is multiplied by the calculated reduction rate _Dt-1 . Here, time point t-1 is the time point when the transmission power control procedure was executed last time. The process of multiplying the transmission power Pt by the reduction rate _Dt-1 is performed in a different procedure in the communication channel i and the communication channel j (j indicates any communication channel except i).

For the communication channel i, as shown in the following equation (6), the power multiplication unit 3 for the communication channel i
At 01, the desired transmission power Pa (i) is multiplied by a value _Dt- 1-1α obtained by raising the previous reduction rate _Dt-1 to the power of α.

Pa (i) × D _t-1 ＾ α (6) where α is a value in the range of 0 ≦ α ≦ 1. for that reason,
When α is set to 0, D _t−1 ＾ α becomes 1, and when α is set to 1, D _t−1 ＾ α becomes D _t−1 . Therefore, D _t-1 ＾ α
Is a value in the range of 1 ≦ D _t−1 ＾ α ≦ D _t−1 .

The comparison unit 302 for the communication channel i compares the calculation result of the power multiplication unit 301 with the maximum transmission power Pmax_1ch per communication channel (step B).
1). When the calculation result of power multiplication section 301 is larger, comparison section 302 for communication channel i determines desired transmission power Pa
(i) is changed to a value represented by the following equation (7) (step B2).

Pa (i) = Pmax_1ch / (D _t−1 ＾ α) (7) Then, the comparison unit 302 for the communication channel i sets the Pa
A value obtained by multiplying (i) by D _t−1 ∧α is output to total transmission power calculation section 103 as trial transmission power. If the calculation result of the power multiplication unit 301 is smaller, the comparison unit 302 for the communication channel i calculates the calculation result Pa (i) × D _t-1 ＾ α of the power multiplication unit 301 for the communication channel i as it is. Output to total transmission power calculation section 103 as transmission power.

[0063] The communication channel j, the power multiplier 301 for communication channel j, as shown by the following equation (8), a decrease rate Ptx (j) is the transmission power of a communication channel j D _t- Multiply by ₁ to obtain the estimated transmission power.

Ptx (j) × D _t−1 (8) The comparison unit 302 for the communication channel j is a power multiplier 301
The calculated power is output as it is to the total transmission power calculation section 103 as the trial transmission power.

The total transmission power calculation section 103 calculates the total transmission power Ptotal by summing the trial transmission powers of all communication channels (step B3), and the comparator 104 calculates the total transmission power Ptot.
al is compared with a preset communication channel maximum total transmission power Pmax of the base station (step A3). Comparator 10
As a result of the comparison in 4, when the relationship represented by the following equation (9) is established, that is, when the transmission power of the base station is insufficient, the reduction rate calculation unit 303 is the ratio of the insufficient power. The transmission power reduction rate _Dt is calculated (step A4).
This shows the formula for calculating the transmission power reduction rate D _t of the communication channels in the formula (10).

Ptotal> Pmax (9) D _t = Ptotal / Pmax (10) As a result of comparison by the comparator 104, the following equation (11) is obtained.
If in the relationship shown is satisfied, that is, the transmission power of the base station is not low, as shown in equation (12), the power reduction rate D _t of the power reduction rate D _t in the previous time point t-1 _-1 (Step B4).

Ptotal <Pmax (11) D _t = D _{t -1} (12) The power reduction rate calculated by the reduction rate calculation unit 303 is stored as a reduction rate. The information is stored in the unit 304. Transmission power determining section 106
Calculates the transmission power of each communication channel (step A
6). The transmission power Ptx (i) of the communication channel i is obtained by multiplying the desired transmission power Pa (i) by the power reduction rate D _t−1 at the previous time point _t−1 as α, as shown in the following equation (13). It determined a value obtained by multiplying a value from the value obtained by dividing the power reduction rate D _t.

Ptx (i) = Pa (i) × D _t−1 ∧α / D _t (13) The transmission power Ptx (j) of the communication channel j is calculated by the following equation (14).
As shown in, it is determined from the value obtained by dividing the value obtained by multiplying the power reduction rate D _t-1 at the previous time point t-1 to the transmission power Ptx (j) by power reduction rate D _t (step B5).

Ptx (j) × D _t−1 / D _t (14) The feature of the present embodiment is that the calculation of the power reduction rate D _{t at} the time point t is performed at the previous time point t The point is that the calculation is performed using the power reduction rate D _t−1 of −1. In the above-described first embodiment, the transmission power of the communication channel j other than the communication channel for which the desired transmission power is to be calculated is repeatedly reduced each time the base station transmission power becomes insufficient, and the total transmission power of the base station is reduced. Even when the power Ptotal does not exceed the maximum value Pmax, control to return to the original transmission power is not performed again. Therefore, the transmission power of the communication channel j continues to decrease until the communication channel becomes a target of the desired transmission power calculation (step A1), and the transmission power becomes minimum immediately before the communication channel becomes the target channel.

For example, the transmission power of the communication channel i becomes minimum after the control at the previous time point t-1. Such a phenomenon is more likely to occur as the period for periodically calculating the desired transmission power of each communication channel based on the communication quality, that is, the transmission power control period becomes longer. Therefore, in the present embodiment, the transmission power Ptx (j) of the communication channel i is calculated by using a value obtained by multiplying the transmission power Ptx (j) by the power reduction rate _Dt-1 at the previous time point t-1. When the total transmission power Ptotal of the base station decreases, it is possible to control to return the transmission power of each communication channel to the original transmission power before the reduction.

However, if the calculation is performed using the value obtained by multiplying the power reduction rate D _t−1 , for the communication channel i, the calculation is performed using the increased interference wave power. It is necessary to increase the desired transmission power Pa (i) of the communication channel i. Therefore, the communication channel i
Is calculated by multiplying the desired transmission power Pa (i) by D _t-1 ＾ α to obtain D
Calculate _t . The coefficient α is not limited to a fixed value, but is a value that can be adaptively changed according to the traffic volume during service, the environment, and the like.

Next, the operation of this embodiment will be described using specific values. This description is also made with reference to FIG. 3 used in the first embodiment.

Here, a case will be described in which the desired transmission power Pa (i) of communication channel 208 is determined at a certain point in time when transmission power control is performed periodically.

The transmission power of each of the communication channels 208 to 211 immediately before performing the transmission power control of the communication channel 208 is assumed to be a value shown in Table 3 below.
The maximum total transmission power of one communication channel is 100.0 milliwatts. The maximum transmission power per communication channel is 50.0 milliwatts, and the coefficient α is 0.5. The power reduction rate Dt-1 at the previous time point t _-1 is 1.20.

[0075]

[Table 3]

[0076]

[Table 4] Here, the desired transmission power for the communication channel 208 to satisfy the target quality is 15.0 milliwatts (step A).
1). Since the value 16.4 milliwatts obtained by multiplying the power reduction rate 1.20 at the previous time by the value of the power of α is smaller than the maximum transmission power 50 milliwatts per communication channel (step B).
1) Then, the communication channel total transmission power of the base station 201 is calculated (step B3). Total transmission power calculation section 103
, The total transmission power of the communication channel obtained is 112.43.
Milliwatts, and the maximum total transmission power of the base station 201 is 1
It exceeds 00.0 (step A3). Therefore, when calculating the power reduction rate D _t at reduction rate calculator 303 (Step A4), obtaining a power reduction rate 1.12. Transmission power determination unit 3
05 The new transmission power of each communication channel to be reset has the value shown in Table 4 (step B5).

In this embodiment, as in the first embodiment, the transmission power of all communication channels is reduced at a fixed rate using the power reduction rate _{Dt, so} that the transmission power of the base station is equal to the maximum total transmission power. The power does not exceed Pmax. Also, the transmission power control target channel i is multiplied by a value obtained by raising the power reduction rate D _t−1 to the power of α, and the communication channel j is multiplied by the previous reduction rate D _t−1 to obtain the previous transmission power control. The transmission power of the reduced individual communication channel is returned to the value before the reduction, and is used as the estimated transmission power, and the transmission power is controlled using the estimated transmission power. Therefore, when the base station total transmission power Ptotal does not exceed the maximum total transmission power Pmax, control is performed to restore the transmission power of each communication channel to the original.

(Third Embodiment) Next, a third embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 6 is a block diagram showing a third embodiment of the base station transmission power control apparatus of the present invention. The transmission power control device of the present embodiment, in which the same numbers as those in FIG. 1 indicate the same components, is different from the transmission power control device of the first embodiment in FIG. Rate calculator 10
5 is different from that of FIG.

Total transmission power calculation section 103 calculates total transmission power Ptotal of the communication channel, and outputs the calculation result to conversion rate calculation section 401. Conversion rate calculation unit 401 calculates the power conversion rate C _t of the communication channels, the calculated power conversion rate
C _t is notified to transmission power determining section 106.

Next, the operation procedure of this embodiment will be described with reference to FIG.

First, the transmission power determination unit 106 determines the desired transmission power Pa (i) of the communication channel i at a regular time t (step A1), and the transmission unit 102 for each communication channel.
Each transmission power notified from the
The same procedure as in the first embodiment is performed up to the addition at 03 and the calculation of the total transmission power Ptotal (step A2). Next, the calculated total transmission power Ptotal is used as the conversion rate calculation unit 401.
Notify. The feature of the third embodiment is that the conversion rate calculator 4
01 is the power conversion rate C _t such that the total transmission power Ptotal is always equal to the communication channel maximum total transmission power Pmax of the base station.
Is the point at which That is, the power conversion rate _Ct is obtained by the following equation (15) (step C1).

C _t = Ptotal / Pmax (15) Here, the power conversion rate C _t becomes a value of 1 or more when the total transmission power Ptotal is larger than the maximum total transmission power Pmax. The rate C _t is the total transmission power Ptotal is the maximum total transmission power Pm
If it is smaller than ax, the number is 1 or less. Then, when the power conversion rate _Ct is a value of 1 or more, the power value of each communication channel is set to a value smaller than the estimated power, and when the power conversion rate _Ct is a value of 1 or less, The power value of each communication channel is set to a value larger than the estimated power.

Power conversion rate calculated by conversion rate calculation section 401
Ct is notified to transmission power determination section 106. The transmission power determination unit 106 calculates the transmission power Ptx (i) of the communication channel i by the following equation (16) (step C2).

Ptx (i) = Pa (i) / C _t (16) Further, the transmission power Ptx (j) of the communication channel j (j indicates an arbitrary communication channel except i) is calculated as follows. The value is changed to the value obtained by the following equation (17).

Ptx (j) = Ptx (j) / C _t (17) By the above procedure, when the transmission power of the base station is insufficient, the transmission power of all communication channels is reduced at the same rate. , The total transmission power Ptotal of the base station can be controlled to be equal to the maximum transmission power Pmax. On the other hand, the traffic volume decreases, the shortage of the base station transmission power is resolved, and the following equation (1) is obtained.
When the state shown in 8) is reached, the transmission power of all communication channels is increased at the same rate,
Control can be performed such that the total transmission power Ptotal of the base station is equal to the maximum transmission power Pmax. Ptotal <Pmax (18) As a result, the total transmission power Ptotal of the base station is controlled to always be a constant value (maximum transmission power Pmax) without depending on the traffic volume.

Next, the operation of this embodiment will be described using specific values. This description is also made with reference to FIG. 3 used in the first embodiment.

Here, the case where the desired transmission power Pa (i) of the communication channel 208 is determined at a certain point in the transmission power control that is periodically executed will be described.

It is assumed that the transmission power of each of communication channels 208 to 211 immediately before performing the transmission power control of communication channel 208 has a value shown in Table 5 below.
The maximum total transmission power of one communication channel is 100.0 milliwatts.

[0090]

[Table 5]

[0091]

[Table 6] As a result of the calculation by the transmission power determining unit 106, the communication channel 2
08 is the desired transmission power for satisfying the target quality is 10.0.
Assuming that the total transmission power is milliwatts (step A1), the total transmission power of the communication channel calculated by the total transmission power calculation unit 103 becomes 90.0 milliwatts (step A
2), the total transmission power is smaller than the maximum total transmission power 100.0 of the base station 201. Therefore, the conversion rate calculation unit 40
When the power conversion rate Ct is calculated at 1 (step C1), the power
A conversion of 0.9 is obtained. The new transmission power of each communication channel determined by transmitting power decision unit 1 06 is a value shown in Table 6 (step C2).

[0092] The present embodiment uses power conversion rate C _t in place of power reduction rate D _t used in the above-described first embodiment,
When the total transmission power Ptotal of the base station exceeds the maximum transmission power Pmax, the transmission power of each communication channel is reduced so that the transmission power of the base station does not exceed the maximum total transmission power Pmax. . Further, in the present embodiment, the total transmission power Ptotal of the base station is equal to the maximum transmission power Pm
Even if ax smaller, so that the value of the total transmission power is always equal to the maximum transmission power of the base station by multiplying the power conversion rate C _t to a transmission power being set. Therefore, the transmission power of the base station is always constant, and the amount of interference from the base station does not depend on the amount of traffic, thereby facilitating device design of the base station.

[0093]

As described above, according to the present invention, the total transmission power when the desired transmission power of each channel is transmitted is calculated, and when the total transmission power exceeds the maximum total transmission power of the base station. Has the effect that the total transmission power of the base station does not exceed the maximum transmission power by reducing the transmission power.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a base station transmission power control device according to a first embodiment of the present invention.

FIG. 2 is a flowchart showing an operation of the base station transmission power control device of FIG.

FIG. 3 is a system configuration diagram for explaining an operation of the base station transmission power control device of FIG. 1;

FIG. 4 is a block diagram illustrating a configuration of a base station transmission power control device according to a second embodiment of the present invention.

FIG. 5 is a flowchart showing an operation of the base station transmission power control device of FIG. 4;

FIG. 6 is a block diagram illustrating a configuration of a base station transmission power control device according to a third embodiment of the present invention.

FIG. 7 is a flowchart showing an operation of the base station transmission power control device of FIG. 6;

FIG. 8 is a block diagram showing a configuration of a conventional base station transmission power control device.

[Explanation of symbols]

 Reference Signs List 101 transmission unit (for communication channel) 102 transmission unit (for pilot channel) 103 total transmission power calculation unit 104 comparator 105 reduction rate calculation unit 106 transmission power determination unit 107, 109 amplifier 108 antenna duplexer 110 reception unit (communication channel) 111) Receiving unit (for pilot channel) 112 Quality judging unit 113 Mobile station 201, 202 Base station 203-207 Mobile station 208-212 Downlink communication channel 301 Power multiplying unit 302 Comparator 303 Reduction rate calculation unit 304 Reduction rate storage unit 305 Transmission power determination unit 401 Power conversion unit A1 to A6 step B1 to B5 step C1, C2 step

Claims (4)

(57) [Claims] 1. One of a plurality of communication channels is periodically selected as a transmission power control target channel i, and each of the communication channels is selected such that the transmission power control target channel i satisfies a predetermined communication quality. The power reduction rate of the total transmission power used in the previous processing in the transmission power control processing for changing the setting of the transmission power is stored as the previous reduction rate Dt-1, and communication other than the transmission power control target channel i is performed. Channel j
The value obtained by multiplying the transmission power Ptx (j) currently set for each communication channel by the previous reduction rate Dt-1 as the result of the previous transmission power control processing is used as the estimated transmission power of the communication channel j. For the transmission power control target channel i, a value obtained by multiplying the desired transmission power Pa (i) by a predetermined function of the previous reduction rate Dt−1 is a specified maximum transmission power Pmax per channel.
_1ch or less, the value multiplied by the predetermined function is used as the estimated transmission power of the channel i, and the desired transmission power Pa
(i) multiplied by a predetermined function of the previous decrease rate Dt-1 is a specified maximum transmission power Pmax_1ch per channel.
If it is larger, the value obtained by dividing the maximum transmission power Pmax_1ch per channel by the predetermined function is used as the estimated transmission power of the transmission power control target channel i, and the estimated transmission power of each communication channel is added. The base station total transmission power Ptotal is calculated, and the base station total transmission power Ptotal is divided by a specified maximum total transmission power Pmax to reduce the base station total transmission power Ptotal. When the base station total transmission power Ptotal is larger than the maximum total transmission power Pmax, the estimated transmission power of each communication channel is divided by the power reduction rate Dt, and the divided transmission power is calculated. Is set as a new transmission power of each communication channel.If the base station total transmission power Ptotal is equal to or less than the maximum total transmission power Pmax, each of the estimated transmission powers is A base station transmission power control method in a CDMA mobile communication system in which the previous divided transmission power is divided by the previous decrease rate Dt-1 and the divided transmission power is set as a new transmission power of each communication channel in each communication channel. 2. The CD according to claim 1, wherein the predetermined function of the previous decrease rate Dt-1 is a function obtained by raising the previous decrease rate Dt-1 to the power of α.
A base station transmission power control method in an MA mobile communication system. 3. Periodically among a plurality of communication channels
One channel is selected as the transmission power control target channel i.
And the transmission power control target channel i is a predetermined communication product.
Change the transmission power setting of each communication channel to meet the quality.
Used for the previous processing in the transmission power control processing
The power reduction rate of the total transmitted power obtained as the previous reduction rate Dt-1
Reduction rate storing means for storing, and a communication channel j other than the transmission power control target channel i
For the current transmission power control process.
The transmission power Ptx (j) set for each communication channel
The value multiplied by the reduction rate Dt-1 is transmitted as a trial calculation for the communication channel j.
And the transmission power control target channel i
Is a predetermined transmission power Pa (i) of the previous reduction rate Dt-1
The product multiplied by the function is the specified maximum per channel
If the transmission power is less than Pmax_1ch, multiply by the given function
The above values are used as the estimated transmission power of the channel i.
A plurality of power multiplying means provided for each signal channel, which is connected to each power multiplying means, the communication Cha
If the channel is not the transmission power control target channel i,
Output from the power multiplication means
And the communication channel is the transmission power control target channel i.
, The previous transmission power is reduced to the desired transmission power Pa (i).
A value obtained by multiplying a predetermined function of the fractional rate Dt-1 is a specified one chip.
If greater than the maximum transmit power Pmax_1ch per Yaneru, the maximum transmission power Pmax_1ch per the 1 channel
The value obtained by dividing the value by the predetermined function is
And a plurality of first comparing means for calculating the estimated transmission power of the i, and summing the outputs of the first comparing means to transmit the base station total.
Total transmission power calculation means for setting the power Ptotal; and a total transmission power Ptotal defined in advance as the total transmission power Ptotal.
Second comparison means for comparing the total transmission power Pmax with the base station total
Transmission power Ptotal is greater than the maximum total transmission power Pmax
Indicates that the base station total transmission power Pt
Power reduction, a value for reducing otal at a fixed rate
A decrease rate calculating means for calculating a rate Dt, and the base station total transmission power Ptotal is the maximum total transmission power.
If the force is greater than Pmax, a trial calculation of each communication channel
The transmission power is divided by the power reduction rate Dt, and the divided
The new transmission power of each communication channel is used as the new transmission power.
And the base station total transmission power Ptotal is
If the maximum total transmission power is less than Pmax,
Divide the transmission power by the previous reduction rate Dt-1 and divide it by
The calculated transmission power is used as the new transmission power for each of the communication channels.
Transmission power determining means to set each communication channel as power
In a CDMA mobile communication system comprising
Base station transmission power control device. 4. The predetermined function of the previous reduction rate Dt-1 is
4. The CD according to claim 3, which is a function obtained by raising the reduction rate Dt-1 to the power of α.
Base station transmission power control device in MA mobile communication system
Place.