JPH08251141A - Transmission output control system - Google Patents

Abstract

PURPOSE: To eliminate the waste of power concumption and to enable following on a receiving side by preventing a transmission output from unnecessarily increasing at the time of the deterioration of a line quality. CONSTITUTION: On the receiving side, a detection part 7 detects a bit error from a reception signal and a counting part 8 counts the number of bit errors for time set in advance, to obtain the number of the bit errors. A judging part 10 compares this number of the bit errors by a normal value set in advance and the last number of the bit errors stored in a storage means 9 and based on the comparing result, the control means 4 of a transmission means provided for a transmission side changes the transmission output of a transmission part 2 instantaneously and stepwisely. Particularly in a situation where the line quality is gradually deteriorated, stepwise increasing of the transmission output enables avoiding the unnecessary increase of the transmission output. Thereby, following incapability is prevented on the receiving side and the waste of power consumption is eliminated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission output control system for controlling a transmitter output according to a state of a transmission line in order to improve transmission quality in a wireless transmission line, and more particularly to a receiver for a change in transmission output. The present invention relates to a transmission output control method with improved tracking performance on the side.

[0002]

2. Description of the Related Art In order to improve the transmission quality on a wireless transmission line, various systems have been proposed as a transmission output control system for controlling a transmitter output according to the state of the transmission line. No. 193434, Japanese Patent Laid-Open No. Hei 4
There is one disclosed in Japanese Patent Publication No. 167836. Each of these methods detects a code error on the receiver side and increases the output of the transmitter when this code error exceeds a predetermined value, thereby improving the reception quality on the receiver side. It is based on the technical idea of

Further, the above-mentioned is an example in which the receiver side and the transmitter side are configured as separate stations, but the output of the transmitter of the own station is based on the reception quality of the receiver side of the own station. There is also a configuration in which the reception quality at the opposite station is improved by controlling the control signal. An example thereof is shown in FIG. Here, this is an example of a satellite communication system, and each transmitting side of the ground stations T1 and T2 that communicate via the satellite S has a modulator 21 that modulates data.
And a transmitter 22 for transmitting the modulated output from the antenna 23.
And a control unit 24 for controlling the transmission output of the transmission unit 22. The receiving side receives a signal through the antenna 23 and a demodulator 2 that demodulates the received signal.
6, a bit error detector 27 for detecting bit errors in the demodulator, a bit error counter 28 for counting the number of detected bit errors, and a count value setting unit 3
By comparing with the specified value set at 0, the transmission unit 22
Determination unit 29 for controlling the transmission output of the control unit 24 of
It has and.

In this configuration, the data is modulated by the modulator 21, the modulated output is amplified by the transmitter 22 and sent out from the antenna 23. Also, it is received by the antenna 23,
The signal amplified by the receiver 25 is demodulated by the demodulator 26. Then, a bit error detecting section 27 detects a bit error based on the received data from the demodulating section 26, and the bit error counting section 28 counts the detected bit error number. Further, the number of bit errors counted by the determination unit 29 is compared with a specified value, and the comparison result is sent to the control unit 24.
The controller 24 controls the output level of the transmitter 22. In this case, the transmission output is instantly increased when the number of bit errors exceeds the specified value. After that, when the line quality becomes good and the number of bit errors becomes smaller than the specified value, control is performed to reduce the transmission output.

[0005]

In such a conventional transmission output control system, the line quality is judged by comparing the number of bit errors with a specified value, and when it is judged that the line quality is deteriorated, transmission is performed. In order to improve the quality promptly, the transmission output is instantly increased to a preset high output. In this case, even if the number of bit errors is extremely large compared to the specified value and the line quality is extremely deteriorated, or even if the number of bit errors is slightly larger than the specified value and the line quality is not deteriorated as much as the difference. The transmission power is increased in exactly the same way. For this reason, when the line quality is slightly deteriorated, the transmission output is unnecessarily increased, resulting in unnecessary power consumption. In addition, when the increase amount of the transmission output is set to a large value, the receiving unit of the opposite station cannot immediately follow the fluctuation of the input level, and during that period, the reception becomes impossible,
Alternatively, the number of bit errors may increase.

[0006]

SUMMARY OF THE INVENTION It is an object of the present invention to prevent a transmission output from unnecessarily increasing when the line quality deteriorates, to eliminate waste of power consumption, and to enable tracking on the receiving side. To provide.

[0007]

According to the transmission output control method of the present invention, the receiving side has a bit error detecting means for detecting a bit error from a received and demodulated signal, and a bit error for a preset time. The bit error counting means for counting the number of bit errors, the storage means for storing the counted number of bit errors, the preset value for the counted bit error number and the previous bit error stored in the storage means. And a determination means for controlling the transmission output to be instantaneously or stepwise changed by the control means of the transmission means provided on the transmission side based on the comparison result.

Here, in the judging means, the transmission output is instantaneously increased and counted when the counted bit error number is larger than the specified value and the difference from the previous bit error number is larger than the specified value. When the number of bit errors is larger than the specified value and the difference from the previous number of bit errors is smaller than the specified value, the transmission output is increased stepwise. Also,
When the number of counted bit errors is smaller than the specified value and the difference from the previous number of bit errors is larger than the specified value, the transmission output is instantaneously reduced, and the counted number of bit errors is larger than the specified value. It has a function of gradually reducing the transmission output when the difference from the previous bit error number is smaller than a specified value.

[0009]

When the number of bit errors is larger than the specified value and is significantly larger than the previous number of bit errors, it is determined that the line quality is suddenly deteriorated, so that the transmission output is instantaneously increased. Also, when the number of bit errors is slightly increased compared to the previous number of bit errors, it is determined that the line quality is gradually deteriorated, and therefore the transmission output is increased stepwise.
As a result, it is possible to prevent the transmission output from increasing more than necessary, to prevent the reception side from being unable to follow up, and to eliminate the waste of power consumption.

[0010]

Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of the present invention. Ground stations T1 and T2 facing each other are configured to transmit and receive signals via a satellite S via a wireless line. The configuration of the ground stations T1 and T2 is represented by the ground station T1.
The transmitting side of the ground station T1 has a modulator 1 that modulates data.
And a transmission unit 2 for transmitting the modulated output from the antenna 3 and a control unit 4 for controlling the transmission output of the transmission unit 2.

On the receiving side, the receiving section 5 for receiving a signal through the antenna 3, the demodulating section 6 for demodulating the received signal, and the bit error number are detected based on the received data from the demodulating section 6. It includes a bit error detection unit 7, a bit error counting unit 8 that counts the number of detected bit errors only for a fixed time t1, and a storage unit 9 that sequentially stores the counted number of bit errors. In addition, the number of bit errors counted by the bit error counting unit 8 is compared with a prescribed value set in advance every constant time t2, or the storage unit 9 is used.
Is provided with a determination unit 10 that determines whether the transmission output is increased or decreased based on the result of this comparison, and outputs the determination result of the determination unit 10 to the control unit 4 and It is configured to control the transmission output of the transmission unit 2. Here, the specified value for comparing the counted bit error numbers and the above-mentioned times t1 and t2 are set in the specified value setting unit 11, respectively.

The operation of the ground stations T1 and T2 having such a configuration will be described. At the time of transmission, the data is the modulator 1
The modulated output is amplified by the transmission output controlled by the transmitter 2 and is output from the antenna 3. The signal received by the antenna 3 and amplified by the receiving unit 5 is demodulated by the demodulating unit 6 and output to the bit error detecting unit 7. The bit error detection unit 7 detects the number of bit errors in the received signal and sequentially outputs them to the bit error counting unit 8.
The bit error counting unit 8 counts the number of bit errors during the time t1 set by the prescribed value setting unit 11, stores the counted value in the storage unit 9 together with the time information, and the determination unit 1
Enter 0.

In the judging section 10, the present bit error counting section 8
And the specified value setting unit 11
The specified values B1 and B2 set in advance and the previous bit error number stored in the storage unit 9, that is, the previous bit error number are respectively input, and the counted bit error number is set to the specified values B1 and B2. And the previous number of bit errors are compared. Then, a control signal is sent to the control unit 4 according to the comparison result, and the control unit 4 controls the transmission output of the transmission unit 2. Here, the prescribed values B1 and B2 set by the prescribed value setting unit 11 are set to have a relationship of B1> B2. In addition, in the specified value setting unit 11, when the maximum transmission amount b (dB) of the transmission output to be controlled is changed with respect to the normal transmission output A (dBm), the transmission output is gradually changed as described later. Change amounts a1 and a2 (dB) are also set and output to the determination unit 10. Note that a1,
Let a2 <b.

The operation of controlling the transmission output in the determination unit 10 and the control unit 4 is shown in the flowcharts of FIGS. 2 and 3.
This will be described with reference to the transmission output time chart of FIG. FIG. 2 is a diagram showing control in the case of increasing the transmission output,
The determination unit 10 first compares the number of bit errors with the specified value B1 (step S11, the same applies hereinafter)). When the number of bit errors is larger than the specified value B1, the difference between the previous number of bit errors and the present number of bit errors from the storage unit 9 is calculated, and the difference is compared with the specified value B1 (S12). When the difference is larger than the specified value B1, it is determined whether the current transmission output is larger or smaller than A + b (dBm) (S
13) If it is smaller, as shown in FIG. 4A, the transmission output is instantly set to A + b (dBm) (S14). As a result, the number of bit errors is degraded from the state set by the specified value B1, and the specified value B is set to be smaller than the previous number of bit errors by the specified value B1.
When the line quality is sharply deteriorated by being reduced by one minute, the transmission output is instantaneously increased to the set output to improve the transmission quality.

On the other hand, when the difference is smaller than the specified value B1 in step S12, it is determined that the line quality is gradually deteriorated as compared with the previous determination.
Therefore, in this case, the current transmission output is A + b (dB
It is determined whether it is larger or smaller than m) (S15), and if smaller, the transmission output is increased by + a1 (dB) (S16). Furthermore, after an arbitrary time has passed (S17),
The steps S15 and S16 are performed again. That is, it is determined whether the current transmission output is larger or smaller than A + b (dBm) (S15), and if smaller, the transmission output is + a1.
By increasing by (dB) (S16) and repeating this until the transmission output finally reaches A + b (dBm),
As shown in FIG. 4B, the transmission output is gradually increased to the set output, and the transmission quality is improved.

Further, FIG. 3 is a diagram showing the control in the case of reducing the transmission output, and the judging section 10 first compares the number of bit errors with the specified value B2 (step S21, the same applies hereinafter)). When the number of bit errors is smaller than the specified value B2, the difference between the previous number of bit errors and the present number of bit errors from the storage unit 9 is calculated, and the difference is compared with the specified value B2 (S22). Then, when the difference is larger than the specified value B2, it is determined whether or not the current transmission output is larger or smaller than A (dBm) (S23).
As shown in (c), the transmission output is instantly set to A (dBm) (S24). As a result, the number of bit errors is the specified value B.
The transmission output is instantly reduced to the set output when the line quality is improved more than the state set by 2 and reduced by the specified value B2 from the previous bit error number and the line quality is rapidly improved.

On the other hand, when the difference is smaller than the specified value B2 in step S22, it is determined that the line quality is gradually improved as compared with the previous determination.
Therefore, in this case, -a2 (d
It is determined whether the Bm) output is larger or smaller than A (dBm) (S25), and if it is larger, the transmission output is -a.
It is reduced by (dB) (S26). Furthermore, after an arbitrary time has passed (S27), the steps S25 and S2 are again performed.
Do 6. That is, from the current transmission output, -a2 (dBm)
It is determined whether the output power is larger or smaller than A (dBm) (S25), and if it is larger, the transmission output is -a2 (d).
Only B) is reduced (S26), and this is repeated until the transmission output finally becomes smaller than A (dBm) as shown in FIG. 4D, whereby the transmission output is gradually reduced to the set output.

Here, in the process of steps S15 to S17 of FIG. 2, that is, in the middle of the control for stepwise increasing the transmission output,
When the line quality is recovered and the number of bit errors becomes smaller than the specified value B2, the transmission output is reduced even before the transmission output reaches A + b (dBm). Steps S25 to S27 in FIG. To do. On the contrary, when the line quality deteriorates and the number of bit errors becomes larger than the specified value B1 in the process of steps S25 to S27 of FIG. 3, that is, in the middle of the control for gradually reducing the transmission output, Even before the transmission output reaches A (dBm),
As shown in FIG. 4E, steps S15 to S17 of FIG. 2 for increasing the transmission output are performed. In this figure, a1 = a2 is an example.

In this case, since the specified value B1 when increasing the transmission output and the specified value B2 when decreasing the transmission output have the relationship of B1> B2 as described above, the transmission output is There is hysteresis when increasing and decreasing, and when the bit error count value changes near the specified value, control such as increasing or decreasing the transmission output within a short time becomes unstable. Can be avoided.

As described above, in this embodiment, when the line quality is suddenly deteriorated or abruptly improved, the transmission output is instantly increased to the preset transmission output or is reduced to the original transmission output. This immediately improves the transmission quality. However, in this case, when the transmission output is instantaneously increased, it is inevitable that there may be a problem in tracking on the receiving side, which has been a problem in the past.

However, when the line quality is gradually deteriorated or gradually improved, the transmission output is increased stepwise up to a preset transmission output or is gradually reduced to the original transmission output. As a result, it is possible to avoid an instantaneous increase in the transmission output while improving the transmission quality, and prevent a problem caused by the inability to follow on the receiving side. Further, when the line quality is improved during the stepwise increase of the transmission output, the increase of the transmission output is stopped and the transmission output is decreased conversely, or conversely, the transmission output is decreased stepwise. When the line quality is deteriorated, the reduction of the transmission output is stopped and the transmission output is increased conversely. Therefore, the transmission output is changed to the transmission output at a certain stage while alternately increasing and decreasing the transmission output. It is possible to maintain the transmission quality, and to maintain suitable transmission quality in this transmission output state. Therefore, it is possible to prevent the transmission output from being increased more than necessary, and wasteful power consumption is improved.

[0022]

As described above, according to the present invention, on the receiving side, a bit error is detected from a received signal, the number of bit errors is counted, and the counted number of bit errors is set as a preset specified value. A control for performing a comparison on the basis of the number of previous bit errors stored in the storage means, and changing the transmission output instantaneously or stepwise by the control means of the transmission means provided on the transmission side based on the comparison result. Therefore, it becomes possible to increase and decrease the necessary and sufficient transmission output according to the deterioration or improvement of the line quality, waste of power consumption can be eliminated, and the followability on the receiving side can be secured.

Here, when the counted number of bit errors is larger than the specified value and the difference from the previous number of bit errors is larger than the specified value, the transmission output is instantaneously increased, whereby the line quality is rapidly deteriorated. It is possible to control the transmission output corresponding to.
Also, the number of counted bit errors is larger than the specified value,
When the difference from the previous number of bit errors is smaller than the specified value, the transmission output is increased stepwise to secure the necessary and sufficient transmission output in response to the gradual deterioration of the line quality, Eliminates waste of power consumption and ensures followability on the receiving side.

Further, when the counted bit error number is smaller than the specified value and the difference from the previous bit error number is larger than the specified value, the transmission output is instantaneously reduced, and the counted bit error number is specified. If the difference is larger than the value and the difference from the previous number of bit errors is smaller than the specified value, the transmission output is reduced stepwise, so that sudden improvement of the line quality can be achieved instantaneously and gradually. With respect to the improvement, the transmission output is gradually reduced according to the degree of improvement, so that the waste of power consumption is eliminated while ensuring the required transmission quality.

In particular, the determination means preferably compares the transmission output based on the comparison result at a predetermined fixed time interval, and accordingly controls the variation of the line quality that changes moment by moment. It is possible to control the transmission output.

Further, the maximum output and the normal output of the transmission output are set in advance, the transmission output is increased until the maximum output is reached, and the transmission output is reduced until the normal output is reached. It is possible to avoid a transmission output or a low transmission output that makes transmission impossible, and it is possible to secure transmission quality within a certain range.

[Brief description of drawings]

FIG. 1 is a block diagram showing an internal configuration of a ground station according to an embodiment of the present invention.

FIG. 2 is a flowchart showing steps in increasing transmission power.

FIG. 3 is a flowchart showing steps in reducing transmission power.

FIG. 4 is a timing chart showing control of increase and decrease of transmission power.

FIG. 5 is a block diagram showing an internal configuration of an example of a ground station adopting a conventional transmission output control method.

[Explanation of symbols]

 S Satellite T1, T2 Ground station 1 Modulator 2 Transmitter 4 Controller 5 Receiver 6 Demodulator 7 Bit error detector 8 Bit error counter 9 Memory 10 Judgment unit 11 Specified value setting unit

Claims (5)

[Claims] 1. The transmitting side has a transmitting means for transmitting the modulated data and a control means for controlling the transmission output of the transmitting means, and the receiving side has a bit from the received and demodulated signal. A bit error detecting means for detecting an error; a bit error counting means for counting the number of bit errors during a preset time; a storage means for storing the counted bit error number; and a counted bit error number. A control for performing a comparison based on a preset specified value and the previous number of bit errors stored in the storage means, and controlling the transmission output instantaneously or stepwise by the control means based on the comparison result. A transmission output control method comprising: 2. The judging means instantaneously increases the transmission output when the counted bit error number is larger than a specified value and the difference from the previous bit error number is larger than the specified value, and the counted bit is counted. The transmission output control method according to claim 1, wherein the transmission output is increased stepwise when the number of errors is larger than a specified value and the difference from the previous bit error number is smaller than the specified value. 3. The determination means instantaneously reduces the transmission output when the counted bit error number is smaller than a specified value and the difference from the previous bit error number is larger than the specified value, and the counted bit is counted. 3. The transmission output control method according to claim 1, wherein the transmission output is reduced stepwise when the number of errors is larger than a specified value and the difference from the previous bit error number is smaller than the specified value. 4. The transmission output control method according to claim 1, wherein the determination means performs the comparison at preset constant time intervals, and controls the change of the transmission output based on the comparison result. 5. The maximum output and the normal output of the transmission output are set in advance, the transmission output is increased until the maximum output is reached, and the transmission output is reduced until the normal output is reached. Transmission output control method.