JP3393363B2 - Transmission power control method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to mobile radio communication, particularly code division multiplex communication system (hereinafter referred to as CDMA).
And a transmission power control method in.

[0002]

2. Description of the Related Art Conventionally, as a document related to this type of CDMA, [Andrew J. Viterbi, "CDMA Principles of Spre
ad Spectrum Communication ", Addison Wesley Publishi
ng Company]. In such CDMA, each mobile station uses the same frequency band in common, and instead, the transmission signal from each mobile station is identified by the spreading code uniquely assigned to each mobile station.

FIG. 2 is an explanatory diagram for explaining a conventional transmission power control method, and shows a configuration on the mobile station side.
In the figure, 11 is a transmitting / receiving antenna, 12 is a high frequency unit for converting a received signal from a base station into a spread band signal, 13
Is a RAKE receiving unit that decodes the output signal of the high frequency unit 12 as a base band signal, 14 is a transmission power control bit reproducing unit that extracts the transmission power control bits sent from the base station at regular intervals, and 15 is the transmission power A transmission power gain control unit for controlling the gain, 16 is a high frequency unit for using a communication channel signal as a radio band signal, and 17 is a transmission power gain control unit 1.
5 is a variable amplifier in which the transmission power is controlled by 5, and the output signal of the high frequency unit 16 is emitted by the transmission / reception antenna 11 with the transmission power.

Here, in order that the speech quality of each mobile station is the same and fair, the received power from the mobile station at the base station must be the same, but the received signal power from each mobile station is It is accompanied by fluctuations (fading) that accompany movement.

Therefore, in the conventional example shown in FIG. 2, the base station notifies the receiving power of excess or deficiency, and the mobile station adjusts the transmission power according to the instruction. Note that such control is called closed-loop transmission power control, but the transmission power control is also combined with open-loop control in which the mobile station automatically controls power without receiving an instruction from the base station.

Next, the operation of the conventional example will be described. First, in the base station, the received power of the signal transmitted from the mobile station is observed in a certain period (Tpc [sec]), and if the average power in that period is larger than a desired value, the transmission power of the mobile station is determined. 1-bit instruction information (transmission power control bit) that lowers the transmission power of the mobile station by a certain percentage if it is smaller than the desired value. The control bit) is inserted into the communication channel of the downlink (communication from the base station to the mobile station) at a fixed interval (Tpc [sec]) cycle to notify the mobile station.

After the mobile station demodulates the received signal in the RAKE receiving unit 13, the transmission power control bit reproducing unit 14 extracts the transmission power control bit from the demodulated signal from the RAKE receiving unit 13 at regular intervals and transmits it. Output to the power gain control unit 15. Then, in the transmission power gain control unit 15, if the content of the transmission power control bit is an instruction to increase the transmission power, the transmission power is increased by a fixed rate.
If the instruction is to reduce the transmission power, the variable amplifier 17 is controlled so as to reduce the transmission power by a fixed rate.

[0008]

In the conventional transmission power control method as described above, the ratio of increase or decrease of the transmission power in the mobile station (hereinafter, the ratio of the increase or decrease of the transmission power is referred to as the step size of the transmission power control). Is constant irrespective of the speed of movement and the temporal change in the rate of change in received power due to instantaneous fading. For example, when a larger increase is required, an appropriate rate of increase cannot be obtained. When the moving speed is fast, the power fluctuation of the received signal from the mobile station becomes abrupt, and the error of the received signal at the base station from the desired value increases.

[0009]

A transmission power control method according to the present invention comprises at least one base station and a plurality of mobile stations, wherein the base station is based on the reception power of a signal transmitted from the mobile station. A transmission power control instruction signal for controlling transmission power to the mobile station is transmitted at regular intervals, and the mobile station controls the transmission power of the signal based on the transmission power control instruction signal. In a transmission power control method in a mobile station, the transmission power control instruction signal transmitted from the base station is monitored, and the transmission power control instruction signal is counted the same number of times continuously or differently. When the number of times reaches a predetermined number, the change rate of the transmission power is changed, and when the change rate of the transmission power is changed, the counted number is reset and transmitted from the base station. Based on the transmission power control instruction signal and the change rate of the transmission power, and controls the transmission power of the signal.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION The basic principle of the present invention is to appropriately change the step size of transmission power control so as to obtain better followability to fading. As such a method for appropriately changing the step size, a voice code as described in [LR Rabiner / RWSchafer, "Digital signal processing of voice by Kuki Suzuki", Corona Publishing Co., Ltd., p.235-238], etc. There is a Jayant method used in adaptive delta modulation in fields such as digitalization.

First, an outline of transmission power control by this method will be described. First, a transmission power control instruction (1 bit of information meaning increase or decrease) received from a base station in a certain cycle (for example, the nth cycle) of transmission power control is C (n) (for convenience, The transmission power is set to -1 and the decrease is set to +1), the transmission power control bit input one cycle before is set to C (n-1), and the step size used at this stage is S (n). (Unit: dB), the step size S (n + 1) for the instruction C (n) is set by the following equation.

[0012]

## EQU1 ## In the case of C (n) = C (n-1), if S (n + 1) = P.S (n) (P> 1) C (n) ≠ C (n-1), S (n + 1) = (1 / Q) .S (n) (Q> 1) However, P is a coefficient for increasing the step size S, and Q is a coefficient for decreasing the step size S.

However, with this method alone, the error of the transmission information generally shows a high value in the wireless communication unlike the wired communication, and therefore, when an error occurs in the reception of the instruction, on the contrary, an inappropriate step size is generated. May be set, and also
The step size always changes each time an instruction is received, and an appropriate step size is determined while increasing or decreasing the step size.

Therefore, in the present invention, between the determination of the difference in the instruction of the transmission power control and the execution of the step size change,
A transmission power control bit monitoring unit that monitors differences in transmission power control instructions in time series is provided, and if the instruction contents of the transmission power control bits are the same for a predetermined number of times, the step size is increased and the instruction contents of the transmission power control bit are increased. If the difference is a predetermined number of times, the step size is made smaller, and when the step size change instruction is issued, the count of the predetermined number of times is cleared so that the respective monitoring sections do not overlap. Also makes it possible to change the step size according to fading.

Further, a transmission power control bit monitoring unit for monitoring the difference in the transmission power control instructions in a time series is provided between the determination of the difference in the transmission power control instructions and the execution of the step size change. If the instruction content of the transmission power control bit is the same for a predetermined number of times including the past series, the step size is increased, and if the instruction content of the current transmission power control bit is different for the predetermined number of times including the past series, the step size is increased. , So that this does not impair the responsiveness of the step size, by overlapping the monitoring interval, the step size can be changed according to the fluctuation of the received power due to fading with a 1-bit instruction. It is more appropriate and automatic. The details will be described below.

Embodiment 1. FIG. 1 is an explanatory diagram for explaining a transmission power control method according to an embodiment of the present invention, and shows a configuration on the mobile station side. In the figure, 21 is a transmitting / receiving antenna, 22 is a high frequency unit for converting a received signal from a base station into a spread band signal, 23 is a RAKE receiving unit for decoding the output signal of the high frequency unit 22 as a base band signal, and 24 is RAKE. The output signal of the receiver 23 is input,
A transmission power control bit reproducing unit for extracting transmission power control bits sent from the base station at regular intervals, 25 monitors the transmission power control bits, and if a certain condition is satisfied, gives an instruction to update the step size. It is a transmission power control bit monitoring unit for outputting.

Reference numeral 26 is a step size determining unit for determining the step size based on the step size update instruction output from the transmission power control bit monitoring unit 25, and 27 is the transmission power output from the transmission power control bit reproducing unit 24. A transmission power gain control unit that sets the transmission power gain based on the control bit and the step size output from the step size determination unit 26, 28 is a high frequency unit that uses a communication channel signal as a radio band signal, and 29 is a transmission power gain control unit. The transmission amplifier 27 controls the transmission power, and the transmission power is used to emit the output signal of the high frequency unit 28 from the transmission / reception antenna 21.

Next, the operation of this embodiment will be described. First, in the high frequency unit 22, the reception signal received by the transmission / reception antenna 21 is converted into a spread band signal and RAK is performed.
The E reception unit 23 decodes the output signal of the high frequency unit 22 as a baseband signal. Then, the transmission power control bit reproducing unit 24 reproduces the transmission power control bit transmitted from the base station at every constant period Tpc [sec] based on the demodulated signal decoded by the RAKE receiving unit 23.

Then, the transmission power control bit monitoring unit 25 monitors the instruction content of the transmission power control bit output from the transmission power control bit reproducing unit 24 and indicates the currently input transmission power control bit C (n). If the content is the same as the instruction content of the transmission power control bit C (n-1) input in the immediately preceding cycle M times consecutively, an instruction to increase the step size is issued. The instruction content of the transmission power control bit C (n) that is output to the determining unit 26 and is currently input is different from the instruction content of the transmission power control bit C (n-1) that was input in the immediately preceding cycle. When N occurs consecutively N times, an instruction to reduce the step size is output to the step size determination unit 26. At this time, at the time when the instruction to change the step size is output and at the time when the step size is interrupted without being continuous, the count of the continuous number is cleared and the counting is started again. The values of M and N are set in advance by simulation so that the variance of the difference between the power received at the base station and the desired value power becomes small.

Then, in the step size determining section 26,
The step size currently used is S (n) (unit: dB)
As a result, a new step size S (n + 1) is set by the following equation, and the set step size S (n + 1) is output to the transmission power gain controller 27.

[0021]

[Equation 2]   To increase the step size: S (n + 1) = P · S (n)   To reduce the step size: S (n + 1) = (1 / Q) S (n)

It should be noted that the coefficients P and Q are set in advance to the best P and Q values at each frequency by simulation. Then, the transmission power gain control unit 27 controls the variable amplifier 29 so that the transmission power becomes Pout as shown in the following equation.

[0023]

[Equation 3] Here, Po is the initial transmission power.

In this embodiment, the mobile station monitors the transmission power control bit transmitted from the base station, and if the instruction contents of the transmission power control bit are the same for a predetermined number of times, increase the step size, If the instruction content of the transmission power control bit is different a predetermined number of times, the step size is made smaller, and when the instruction to change the step size is issued, the count of the predetermined number of times is cleared so that the respective monitoring sections do not overlap. Therefore, even if the moving speed of the mobile station is high or there is an error in communication information that occurs in wireless communication, it is possible to reduce the deviation from the desired power of the transmission power control according to the moving speed of the mobile station, and It becomes possible to provide more fair call quality to the user.

Embodiment 2. In this embodiment, the monitoring section of the transmission power control bit in the transmission power control bit monitoring unit 25 of the first embodiment is overlapped, and the configuration on the mobile station side is the same as that of the first embodiment. Is.

Next, the operation of this embodiment will be described. First, in the high frequency unit 22, the reception signal received by the transmission / reception antenna 21 is converted into a spread band signal and RAK is performed.
The E reception unit 23 decodes the output signal of the high frequency unit 22 as a baseband signal. Then, the transmission power control bit reproducing unit 24 reproduces the transmission power control bit transmitted from the base station at every constant period Tpc [sec] based on the demodulated signal decoded by the RAKE receiving unit 23.

Then, in the transmission power control bit monitoring unit 25, the instruction content of the transmission power control bit C (n) currently input is changed to the transmission power control bit C (n-1) input in the immediately preceding cycle. ) Is the same as the instruction content of), the instruction content of the transmission power control bit sequence of the past I times is checked, and the instruction content may be the same including the past sequence I times. For example, an instruction to increase the step size is output to the step size determination unit 26. That is, assuming that the current transmission power control bit is C (0), C (0) = C (-1) = C
(-2) ... C (-I + 1) = C (-I) is satisfied.

On the contrary, the instruction content of the transmission power control bit C (n) currently input may differ from the instruction content of the transmission power control bit C (n-1) input in the immediately preceding cycle. For example, if the instruction content of the transmission power control bit sequence of the last J times is checked and the instruction content is continuously different J times, including the past sequence, the instruction to reduce the step size is stepped. It is output to the size determination unit 26. That is, if the current transmission power control bit is C (0), then C
This is a case where (0) ≠ C (-1) ≠ C (-2) ... C (-J + 1) ≠ C (-J).

However, the monitoring section of the transmission power control bit is provided with K (K <I, J) overlapping sections with the next monitoring section, and the condition is satisfied until the overlapping of the monitoring sections becomes K or less. Even if the above condition is satisfied, the step size changing instruction is not output to the step size determining unit 26. The values of I, J, and K are set in advance by simulation so that the variance of the difference between the power received by the base station and the desired value power becomes small.

For example, first, assuming that the current transmission power control bit is C (0), C (0) = C (-1) = C (-2) ... C (-I + 1) =
It is assumed that C (-I) is satisfied and an instruction to increase the step size is output to the step size determination unit 26. Then, let C (1) be the next transmission power control bit, and C (1) =
If C (0) = C (-1) ... C (-I + 2) = C (-I + 1) is satisfied, the condition for outputting an instruction to increase the step size to the step size determination unit 26 is satisfied. It means that However, in this case, in the two monitoring sections,
C (0), C (-1), C (-2), ..., C (-I + 2), C (-I + 1) are overlapped, and these overlaps. The instruction to increase the step size is not output to the step size determination unit 26 until the number becomes K or less, even if the condition is satisfied.

Similarly, assuming that the current transmission power control bit is C (0), C (0) ≠ C (-1) ≠ C (-2) ... C (-J + 1) ≠
It is assumed that C (-J) is satisfied and an instruction to reduce the step size is output to the step size determination unit 26. Then, assuming that the next transmission power control bit is C (1), C (1) ≠
If C (0) ≠ C (-1) ... C (-J + 2) ≠ C (-J + 1) is satisfied, the condition for outputting an instruction to reduce the step size to the step size determination unit 26 is satisfied. It means that However, in this case, in the two monitoring sections,
C (0), C (-1), C (-2), ..., C (-J + 2), C (-J + 1) are overlapped, and this overlap is made. Until the number becomes K or less, even if the condition is satisfied, an instruction to reduce the step size is not output to the step size determination unit 26.

Further, since fading causes a sharp rise and fall in received power, it is preferable to increase the degree of overlap with respect to increasing the step size. Therefore, the relationship between I and J is I ≦ J. Trying to meet.

Then, in the step size determining section 26,
The step size currently used is S (n) (unit: dB)
As a result, a new step size S (n + 1) is set by the following equation, and the set step size S (n + 1) is output to the transmission power gain controller 27.

[0034]

[Equation 4]   To increase the step size: S (n + 1) = P · S (n)   To reduce the step size: S (n + 1) = (1 / Q) S (n)

It should be noted that the coefficients P and Q are set in advance to the optimum values at each frequency. Then, the transmission power gain control unit 27 controls the variable amplifier 29 so that the transmission power becomes Pout as shown in the following equation.

[0036]

[Equation 5] Here, Po is the initial transmission power.

In this embodiment, the mobile station monitors the transmission power control bit transmitted from the base station, and if the instruction content of the current transmission power control bit is the same for a predetermined number of times including the past sequence. For example, if the instruction content of the current transmission power control bit is different for a predetermined number of times including the past series, the step size is reduced so that the responsiveness of the step size is not impaired. Since the monitoring section is made to overlap, even if the moving speed of the mobile station is high or there is an error in the communication information that occurs in wireless communication, the desired power of the transmission power control is adjusted according to the moving speed of the mobile station. It is possible to reduce the gap between the two and to provide more fair call quality to a large number of users.

[0038]

As described above, according to the present invention, the mobile station monitors the transmission power control instruction signal transmitted from the base station, and the transmission power control instruction signal is continuously the same or continuous. Then, the number of different times is counted, and when the counted number reaches a predetermined number, the change rate of the transmission power is changed, and when the change rate of the transmission power is changed, the counted number is reset and the base Since the transmission power of the signal is controlled based on the transmission power control instruction signal transmitted from the station and the change rate of the transmission power, an error in the communication information that occurs when the moving speed of the mobile station is high or in wireless communication Even if
It is possible to reduce the deviation of the transmission power control from the desired power according to the moving speed of the mobile station, and it is possible to provide more fair call quality to a large number of users.

[Brief description of drawings]

FIG. 1 is an explanatory diagram illustrating a transmission power control method according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram for explaining a conventional transmission power control method.

[Explanation of symbols]

11 transmitting and receiving antenna 12 High frequency part (reception) 13 RAKE receiver 14 Transmission power control bit regeneration unit 15 Transmission power gain controller 16 High frequency part (transmission) 17 Variable amplifier 21 transmitting and receiving antenna 22 High frequency part (reception) 23 RAKE receiver 24 Transmission power control bit regeneration unit 25 Transmission power control bit sequence monitoring unit 26 Step size determination unit 27 Transmission power gain controller 28 High frequency part (transmission) 29 Variable amplifier

─────────────────────────────────────────────────── ─── Continuation of the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04B ^7/ 24-7/26 102 H04Q ^7/ 00-7/38

Claims (3)

(57) [Claims] 1. At least one base station and a plurality of mobile stations
The mobile station is composed of
Transmit power to the mobile station based on the received power of the signal
Transmits a transmission power control instruction signal to control
The mobile station based on the transmission power control instruction signal.
Of a wireless communication system for controlling signal transmission power by
In a transmission power control method in a mobile station, a transmission power control instruction signal transmitted from the base station is transmitted.
The transmission power control instruction signal is continuously monitored to be the same or
Counts different times consecutively, and the counted number is a predetermined number
Change to the transmission power change rate,
When the force change rate is changed, the counted number is reset.
Set and transmit power control instruction transmitted from the base station
Signal transmission based on the signal and the rate of change of the transmission power
A transmission power control method characterized by controlling power. 2. The transmission power control method according to claim 1.
The transmission power control instruction signal transmitted from the base station.
The transmission power control instruction signal is continuously monitored to be the same.
Within the instruction of the transmission power control instruction signal
When the contents are the same for the first predetermined number of times, the transmission power change rate
By a first ratio to change the transmission power change rate.
When the transmission power control instruction signal is continuously
Reset the number of times it becomes the same
Based on the transmission power control instruction signal and the transmission power change rate.
Based on the above, the transmission power of the signal is controlled.
Transmission power control method. 3. A transmission power control method in a wireless communication system for performing communication between at least one base station and a plurality of mobile stations, wherein the base station is based on the reception power of a signal transmitted from the mobile station. , A transmission power control instruction signal for controlling the transmission power to the mobile station is transmitted together with the transmission signal at regular intervals, and the mobile station monitors the transmission power control instruction signal transmitted from the base station, The number of times the transmission power control instruction signal becomes the same and the number of times the transmission power control instruction signal continuously differ are counted, and the instruction content of the transmission power control instruction signal is the first.
Of the same number of times, the transmission power change rate is increased by a first rate, and the instruction content of the transmission power control signal is set to the second rate.
, The transmission power change rate is reduced by a second ratio, and at the time when the transmission power change rate is changed, the transmission power control instruction signal becomes the same number of times and continuously. And resetting the count of different numbers of times, and controlling the transmission power of the signal based on the transmission power control instruction signal transmitted from the base station and the change rate of the transmission power.