JPS648500B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field) The present invention relates to a highly accurate wireless line monitoring and control system in a mobile communication system.

(Background Art) Conventionally, in mobile communication systems, a method of detecting the median value of the received wave level of a communication channel has been adopted as a method of monitoring the transmission quality of a voice signal after the communication channel is set. However, the accuracy of the envelope detector, which outputs a voltage proportional to the received wave level, is extremely poor at low levels that degrade the transmission quality of audio signals, making it difficult to monitor and control wireless lines with high precision. There was a drawback.

Additionally, after detecting that the median received wave level has fallen below a predetermined level, there is a method of transmitting control signals to perform various wireless line controls such as switching the call channel to another wireless zone. Techniques have been adopted in which calls are disconnected and digital signals are transmitted through the call channel. However, this method has disadvantages in that instantaneous call interruptions are unavoidable and noise is generated.

Furthermore, in the method of monitoring the transmission quality of audio signals based on the received wave level, if co-channel interference occurs, the received wave level is detected as being equal to or higher than a predetermined value. For this reason, there was a drawback that deterioration in the transmission quality of audio signals due to same-channel interference could not be detected.

(Problems to be solved by the invention) In order to eliminate these drawbacks, the present invention is characterized in that a control signal is transmitted simultaneously with the audio signal by frequency multiplexing a band-limited digital signal outside the audio signal band. By adopting an error correction code as the code format and constantly monitoring the syndrome sequences generated from the error correction code, it is possible to monitor the transmission quality of voice signals.The purpose is to perform highly accurate wireless line monitoring and control. The goal is to do the following.

(Structure and operation of the invention) FIG. 1 is an embodiment of the first invention, and is a configuration diagram in the case where a band-limited digital signal is superimposed on the lower band (0 to 0.3 kHz) of an audio signal. .
Figure 1A shows the configuration of the transmitting side, and Figure 1B shows the configuration of the receiving side, where 1 is an audio input terminal, 2 is a bandpass filter, 3 is an instantaneous amplitude limiter, 4 is a splatter filter, and 5 is an analog adder. , 6 is a digital signal input terminal, 7 is a code converter, 8 is a low-pass filter, 9 is a modulator, 10 is a transmitting antenna, 11 is a receiving antenna, 12 is a demodulator, 13 is a band-pass filter, 14 is an audio output terminal , 15 is a low-pass filter, 16 is a code converter, and 17 is a digital signal output terminal.

A bandpass filter 2 extracts a 0.3 to 3kHz component of the audio signal applied to the audio input terminal, and the extracted component is input to an instantaneous amplitude limiter 3. The instantaneous amplitude limiter 3 clips the voltage waveform that is higher than the modulator input voltage corresponding to a preset maximum frequency deviation, and the harmonic components generated by its nonlinear operation are removed by the splatter filter 4. be done.
Further, the control information is encoded into control data by an input device (not shown) and inputted to the digital signal input terminal 6. The digital signal is converted by the code converter 7 into a signal format suitable for the characteristics of the transmission path, and then by the low-pass filter 8.
The signal is band-limited so as not to affect the audio band, and is superimposed on the audio signal by the analog adder 5. The modulator 9 generates a modulated wave with a frequency shift corresponding to the input voltage, and transmits the modulated wave via the transmitting antenna 10.
Transmits radio waves. On the other hand, on the receiving side, a demodulator 12 demodulates the transmitted voltage waveform, a bandpass filter 13 extracts audio signal components, and outputs them to an audio output terminal 14. Further, components of the digital signal are extracted by a low-pass filter 15, and after being returned to the original signal format by a code converter 16, the signal is outputted to a digital signal output terminal 17.

By adopting such a configuration as a modulation/demodulation system, it becomes possible to exchange control signals between a mobile station and a base station during a call without affecting the call.

FIG. 2 shows an embodiment of the second invention, in which the portion surrounded by dotted lines is a modulation/demodulation system similar to the structure of the transmitting and receiving sides shown in FIG. 1 is a control data input terminal, 2 is an error correction code encoder, 3 is an audio input terminal, 4 is a digital signal input terminal, 5 is the transmitting device shown in FIG. 1, 6 is a transmitting antenna, 7
is a receiving antenna, 8 is a receiving device shown in FIG. 1,
9 is an audio output terminal, 10 is a digital signal output terminal, 11 is an error correction code decoder, 12 is a control data output terminal, 13 is a syndrome series output terminal,
14 is the reproduction clock output terminal, 15 is “High”
The probability side determiner 16 is a "High" probability measurement value output terminal. FIG. 2C shows a configuration example of a system for determining whether the transmission quality of an audio signal has deteriorated below a predetermined quality, and 17 is data of the syndrome "High" probability corresponding to the predetermined quality. Input terminal 18 is a comparator, 19 is a judgment data output terminal, and Sref is predetermined "High" probability data.

The control information is encoded into control data by an input device (not shown) and applied to the control data input terminal 1. The error correction code encoder 2 encodes the control data into an error correction code and sends it to the digital signal input terminal. On the other hand, the digital signal reproduced on the receiving side is decoded into the original control data by the error correction code decoder 11 and output to the device data output terminal 12. Error correction code decoder 11
generates a syndrome sequence from the signal sequence of the error correction code and outputs it to the syndrome sequence output terminal 13, and also outputs a clock pulse synchronized with the control data sequence and the syndrome sequence to the reproduced clock output terminal. The “High” probability measuring device 15 is
It counts pulses corresponding to a predetermined time length, measures how many times the syndrome sequence becomes "High" during that time, and outputs that number to the "High" probability measurement value output terminal 16. As a “High” probability measuring device, (1) It counts clock pulses and syndrome series pulses independently, and every time it finishes counting a predetermined number of clock pulses, it counts the number of syndrome series pulses within that time. Obtained from the output of

(2) A shift register with a number of stages equal to the number of clock pulses corresponding to the measurement time length is provided, and the number of pulses in a given time length of the syndrome series is continuously counted using the shift register and an up-down counter.

For the method (2), it is possible to use the method disclosed in Japanese Patent Application Laid-Open No. 56-46483.

The “High” probability measure of a syndrome series is
It is input to the comparator 18 and compared with "High" probability data Sref of the syndrome series corresponding to a predetermined estimated value of audio transmission quality, and it is determined that the "High" probability measurement value is higher than the predetermined value of the "High" probability. When it becomes larger, it is assumed that the audio transmission quality has deteriorated below a predetermined value, and the information is outputted to the judgment data output terminal 19.

If an error correction code is adopted as the code format of the control signal transmitted using a band outside the voice band, and the syndrome sequence generated from it is monitored,
The higher the “High” probability of the syndrome series, the more
The received wave level is low, and the transmission quality of the audio signal can be estimated from the correspondence.

Figure 2D is an example of a measurement of the relationship between the received wave level and the syndrome sequence "High" probability (carrier frequency 920 MHz, signal transmission rate 100 b/s split phase, information transmission rate 50 b/s, 6-bit burst). error correction Iwadare code, digital signal modulation depth 1kHz, fading frequency 40Hz). Monitoring of audio transmission quality by measuring the conventional received wave level is now possible.
By measuring the "high" probability of the syndrome, it can be seen that highly accurate monitoring is possible even at reception levels below 0 dBμ, at which the accuracy of the reception wave level detector is extremely degraded.

FIG. 3 is an embodiment of the third invention, and is a second embodiment of the invention.
A receiving device is used by adding a received wave level output (envelope detection output) to the receiving system shown in FIG. B. FIG. 3A shows an example of the configuration of the receiving side, where 1 is a receiving antenna, 2 is a receiving device in which a received wave level output is added to the receiving system in FIG. 2B, 3 is an audio output terminal, 4 is a control data output terminal, 5 is a syndrome series "High" probability measurement value output terminal, 6 is a predetermined syndrome series "High" probability data input terminal, 7 is a comparator, 8 is a judgment data output terminal, 9 is a received wave level output terminal, 10 is the center A value detector, 11 is a median output terminal, 12 is a voltage input terminal corresponding to a predetermined reception level, 13 is an analog comparator, 14 is an analog comparator output terminal, 15 is an AND gate, and 16 is an output terminal. Further, Vref is a voltage corresponding to a predetermined received wave level, and Sref is predetermined “High” probability data. Similarly to the second invention, an audio signal, control data, and determination data are output to the audio output terminal 3, the control data output terminal 4, and the determination data output terminal. Further, from the voltage corresponding to the received wave level outputted to the received wave level output terminal, the median value within a predetermined time is detected by the median value detector 10, and the voltage corresponding to the median value is detected as the median value. Output to the output terminal. The voltage corresponding to the median value is compared with the analog comparator reference voltage Vref by the analog comparator 13. If the voltage corresponding to the median value is higher, the “High” level is set, and if the voltage corresponding to the median value is higher, the “Low” level is set. Comparator output terminal 14
is output to. The analog comparator reference voltage Vref is
The voltage is set to a voltage corresponding to the median received wave level that is sufficiently high that almost no pulse appears in the syndrome series, and is inputted from the voltage input terminal 12 corresponding to a predetermined received wave level. The output terminal 16 is output when the median reception level is higher than the level corresponding to Vref and the syndrome is “High”.
A “High” level appears when the probability that Sref is higher than a predetermined “High” probability Sref. The state in which the received wave level is sufficiently high and the probability of the syndrome becoming "High" is high is when co-channel interference is occurring, so the present invention enables monitoring of co-channel interference, which was previously impossible. becomes possible. Figure 3B is an example of a measurement of the relationship between the carrier wave power to interference wave power ratio (CIR) and the syndrome “High” probability (carrier wave frequency 920 MHz, interference wave frequency 920 MHz, signal transmission rate 100 b/s split phase). , information transmission rate 50 b/s, 6-bit burst error correction Iwadare code, digital signal modulation degree 1 kHz, fading frequency 40 Hz, carrier wave level median 30 dBμ). From this figure, from the measured value of the syndrome series “High” probability,
CIR can be estimated.

(Effect of the invention) As explained above, in the first invention,
This has the advantage that control signals can be exchanged between a mobile station and a base station during a call without affecting the call, and highly accurate radio channel monitoring and control can be performed.

Furthermore, in the second invention, the transmission quality of the audio signal, which was conventionally carried out by measuring the level of the received wave, is monitored by measuring the probability of "High" in the syndrome series. Even at low received wave levels where the accuracy of the wave level detector is extremely degraded, highly accurate monitoring is possible. Therefore, the present invention has the advantage that it is possible to perform highly accurate wireless line monitoring and control.

Furthermore, in the third invention, by using both the "High" probability information of the syndrome series and the received wave level information, it becomes possible to monitor co-channel interference, which was previously impossible. Therefore, the present invention has the advantage that highly accurate wireless line control is possible.

[Brief explanation of drawings]

Figures 1A and B are diagrams showing a first embodiment of the present invention, Figures 2A, 2B, and 2C are configuration examples of a second embodiment of the present invention, and Figure 2D FIG. 3A is an example of measuring the received wave level and syndrome sequence “High” probability in the second embodiment, and FIG.
FIG. 3B is a diagram showing an example of measurement of IR and syndrome series "High" probability in the third embodiment. In FIG. 1, 1...audio input terminal, 2...
Bandpass filter, 3... Instantaneous amplitude limiter, 4
... Splatter filter, 5 ... Analog adder, 6 ... Digital signal input terminal, 7 ... Code converter, 8 ... Low pass filter, 9 ... Modulator, 10 ... Transmission antenna, 11 ... Reception Antenna, 12... Demodulator, 13... Band pass filter, 14... Audio output terminal, 15... Low pass filter, 16... Code converter, 17... Digital signal output terminal. In Figure 2, 1...
Control data input terminal, 2...Error correction code encoder, 3...Audio input terminal, 4...Digital signal input terminal, 5...Transmission device shown in FIG. 1, 6...
...Transmitting antenna, 7...Receiving antenna, 8...Receiving device shown in Fig. 1, 9...Audio output terminal, 1
0...Digital signal output terminal, 11...Error correction code decoder, 12...Control data output terminal, 1
3...Syndrome series output terminal, 14...Regenerated clock output terminal, 15..."High" probability measuring device, 16..."High" probability measurement value output terminal, 1
7... Data output terminal of syndrome "High" probability corresponding to predetermined quality, 18... Comparator, 19... Judgment data output terminal, Sref... Predetermined "High" probability data. In Figure 3,
DESCRIPTION OF SYMBOLS 1... Receiving antenna, 2... Receiving device with received wave level output (envelope detection output) added to the receiving system shown in FIG. 2, 3... Audio output terminal, 4... Control data output terminal, 5 ... Syndrome series "High" probability measurement value output terminal, 6 ... Predetermined syndrome series "High" probability data input terminal, 7
... Comparator, 8 ... Judgment data output terminal, 9 ...
Received wave level output terminal, 10...median value detector,
11... Median value output terminal, 12... Voltage input terminal corresponding to a predetermined received wave level, 13... Analog comparator, 14... Analog comparator output terminal, 1
5...And gate, 16...Output terminal, Sref...
...predetermined "High" probability data, Vref...predetermined received wave level equivalent voltage.

Claims (1)

[Claims] 1. A mobile radio communication system for transmitting voice signals, in which a transmitting side frequency-multiplexes a control digital signal outside the voice band, and a receiving side frequency-multiplexes this digital signal. In the wireless line monitoring and control method, which separates the control signal and transmits the control signal simultaneously with the voice signal to control the wireless line, an error correction code is used as the code format of the digital signal, and the syndrome sequence generated from it is used. A wireless line monitoring and control method characterized by estimating the transmission quality of a voice signal by monitoring and controlling the wireless line based on the estimation result. 2 A mobile radio communication system that transmits voice signals, in which the transmitting side frequency-multiplexes a control digital signal outside the voice band and transmits it, and the receiving side separates this digital signal frequency-wise and transmits the control signal. In a wireless line monitoring and control system that performs wireless line control by extracting and transmitting a control signal at the same time as a voice signal, an error correction code is used as the code format of the digital signal, and the syndrome sequence generated from the error correction code is monitored and the reception input is performed. It simultaneously monitors electric fields, detects conditions where the received input electric field is high and the audio signal transmission quality is degraded, detects the occurrence of same-channel interference, and performs wireless line control based on the results. A wireless line monitoring and control method.