JPH0575574A - Equipment and system for spectrum spread transmission and reception - Google Patents

Abstract

PURPOSE:To give a margin to the power control precision in a mobile station at the upper limit of a communication line capacity. CONSTITUTION:A transmission signal d(t) from a binary modulator 1 is subjected to error correction code encoding by an encoder 3 and is subjected to two-phase PSK modulation by a PSK modulator 4 and is subjected to spread modulation by a spread modulator 5. The spectrum spread signal from the spread modulator 5 is transmitted to a base station through an up converter 6, an output amplifier 7, and a transmission/reception antenna 8. The bit error rate of the signal d(t) from the base station is calculated and discriminated by a detecting part 12. The bit error rate exceeds a prescribed value at the upper limit of the communication line capacity of a system. When the bit error rate exceeds the prescribed value, a transmission clock generator 2 is controlled to reduce the transmission clock speed. At the upper limit of the communication line capacity, the transmission clock speed is reduced, and the processing gain of modulation/demodulation is improved, and a margin is given to the power control precision, and the precision in the mobile station is mitigated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spread spectrum transmitter / receiver and system.

[0002]

2. Description of the Related Art FIG. 6 shows a modulator of a direct spread transmission system. In the figure, the carrier fc from the carrier generator 101 is supplied to the PSK modulator 102, and the carrier fc is two-phase PSK modulated by the transmission signal (binary modulation signal) d (t).

The PSK modulation signal from the PSK modulator 102 is supplied to the spread modulator 103. This spread modulator 10
The spread signal p (t) is supplied to 3 and the PSK modulation signal is spread modulated.

FIG. 7A shows the signal change of the transmission signal d (t), and FIG. 7B shows the PSK output from the PSK modulator 102.
The frequency spectrum of the modulation signal is shown. Td is the period of the transmission signal d (t). Further, FIG. 8A shows the spread signal p
The signal change of (t) is shown, and FIG. 9B shows the frequency spectrum of the spread spectrum signal output from the spread modulator 103. Tp indicates the period of the spread signal p (t). Spread signal p (t) for period Td of transmission signal d (t)
Since the cycle Tp of is short and changes drastically, the spread modulator 103
Then, the frequency spectrum is spread over a wide band (see FIG. 8B).

FIG. 9 shows a demodulation section of a direct spread system reception system. In the figure, the spread spectrum signal is supplied to a bandpass filter 401 having a center frequency fc and a passband of 2 Bp, and components other than the band are excluded.

The spread spectrum signal extracted by the band pass filter 401 is supplied to a spread demodulator 402. The same signal p (t) 'as the above-mentioned spread signal p (t) is supplied to the spread demodulator 402 and spread demodulated. In this case, the signal p (t) 'is controlled so as to be in phase with the spread signal p (t), and p (t) .p (t)' = p (t) ² = 1. ..

The output signal of the spread demodulator 402 is supplied to a bandpass filter 403 having a center frequency of fc and a passband of 2Bd, and a PSK modulated signal is extracted. The PSK modulated signal is supplied to the PSK demodulator 404 and demodulated to obtain the signal d (t).

As described above, the spread spectrum communication is a method of communicating by spreading the frequency spectrum in a wide band, and is characterized by excellent confidentiality and interference.

[0009]

By the way, in order to maintain the communication system of the spread spectrum communication system normally, it is necessary that the received power at the base station side is uniform in the communication channel with each mobile station. Is.

Therefore, the transmission power to the base station must be controlled according to the movement of the mobile station or changes in the external environment, and the control accuracy must be 0.5 dB or less at the upper limit of the communication line capacity of the system. It has been calculated that it must be done. However, it is difficult to realize this accuracy, and it is considered to be a problem of the spread spectrum communication system.

Therefore, an object of the present invention is to give a margin to the power control accuracy of the mobile station at the upper limit of the communication line capacity.

[0012]

A spread spectrum transmitter / receiver according to a first aspect of the present invention transmits a transmission quality based on the transmission quality determination means for determining the transmission quality of a received signal and the transmission quality determined by the transmission quality determination means. Clock control means for controlling the clock speed of the signal.

A spread spectrum transmission / reception system according to a second aspect of the present invention controls a transmission quality of a received signal by controlling a transmission quality of the received signal and a transmission quality of the transmitted signal based on the transmission quality of the transmission quality of the received signal. A first spread spectrum transmitter / receiver having control data generating means for generating clock control data and data synthesizing means for synthesizing the clock control data generated by the control data generating means with a transmission signal; The second spread spectrum transmitter / receiver comprises a data extraction means for extracting control data, and a clock control means for controlling the clock speed of the transmission signal based on the clock control data extracted by the data extraction means. ..

[0014]

In the first aspect of the invention, for example, at the upper limit of the communication line capacity, the mobile station determines that the transmission quality has dropped below a predetermined value, and the clock speed of the transmission signal is lowered. Therefore, the cycle of signal change of the transmission signal becomes long, the processing gain of modulation / demodulation is improved, and it becomes possible to have a margin in power control accuracy.

In the second aspect of the invention, for example, at the upper limit of the communication line capacity, it is determined that the transmission quality is lower than a predetermined value at the base station, and clock control data for controlling to lower the clock speed of the transmission signal is created. It is combined with the transmission signal and transmitted. Then, for example, the clock speed of the transmission signal is reduced based on the clock control data extracted from the reception signal in the mobile station. Therefore, the cycle of signal change of the transmission signal becomes long, the processing gain of modulation / demodulation is improved, and it becomes possible to have a margin in power control accuracy.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIG. This example is an example of spread spectrum communication between a base station and a mobile station.

FIG. 1 is a block diagram showing the configuration of a mobile station. In the figure, a transmission signal d (t) (analog signal) such as voice is supplied to the binary modulator 1, and the transmission signal d (t) (binary modulation signal) is output from the modulator 1.
The period Td of the transmission signal d (t) is determined by the speed of the transmission clock from the transmission clock generator 2.

The transmission signal d (t) output from the modulator 1 is error correction coded by the encoder 3 and then supplied to the PSK modulator 4. A carrier fc is supplied to the PSK modulator 4 from a carrier generator (not shown), and the carrier fc is two-phase PSK modulated by the transmission signal d (t).

The PSK modulation signal output from the PSK modulator 4 is supplied to the spread modulator 5. The spread signal p (t) is supplied to the spread modulator 5, whereby the PSK modulation signal is spread modulated.

The center frequency of the spread spectrum signal output from the spread modulator 5 is converted to a high frequency by the up converter 6, and then the spread spectrum signal is supplied to the transmission / reception antenna 8 via the output amplifier (high power amplifier) 7 to be transmitted to the base station. Sent to the station.

Further, the spread spectrum signal from the base station is supplied from the transmitting / receiving antenna 8 to the down converter 9 and frequency-converted so that the center frequency becomes equal to the frequency of the carrier fc. The spread spectrum signal output from the down converter 9 is supplied to the demodulation unit 10,
Spreading demodulation and PSK demodulation are performed.

The error-correction-decoded signal d (t) output from the demodulation unit 10 is subjected to error correction processing in the decoding unit 11 and supplied to the receiving system in the subsequent stage.

The input / output signal of the decoding unit 11 is BER.
(Bit error rate) The bit error rate is supplied to the detection unit 12 and the bit error rate is calculated and determined. Here, at the upper limit of the communication line capacity of the system, the bit error rate of the received signal of the mobile station exceeds a threshold value of about 3.0 × 10 ⁻³ .

When the BER detection unit 12 detects that the bit error rate exceeds a threshold value of about 3.0 × 10 ⁻³ , the BER detection unit 12 controls the transmission clock generator 2 to change the transmission clock speed. Can be lowered.

This example is configured as described above, and since the transmission quality of the received signal deteriorates at the upper limit of the communication line capacity, BE
The speed of the transmission clock from the transmission clock generator 2 is reduced by the control of the R detection unit 12. Therefore, at the upper limit of the communication line capacity, the cycle Td of change of the transmission signal d (t) becomes long, the processing gain of modulation / demodulation is improved, and a margin is generated in the power control circuit.

FIG. 2 shows the relationship between clock speed and processing gain. If the processing gain is Gp, then Gp
= B / B1, and in the case of Gp = B / B2. By lowering the clock speed from T1 to T2, the frequency spectrum is sharpened and the processing gain is improved by B1 / B2.

FIG. 3 shows the relationship between the rate of decrease in the transmission signal speed and the increase in the margin accuracy of the power control circuit that occurs at this time. Therefore, by controlling so that the clock speed of the transmission signal is lowered at the upper limit of the communication line capacity as described above, it is possible to allow the control accuracy of the output amplifier 7 to have a margin as shown in FIG.

As described above, when the spread spectrum communication system requires the highest accuracy, it is calculated that the accuracy is 0.5 dB or less. For example, by reducing the clock speed by 10%, 0.5 dB can be obtained. Therefore, the power control accuracy of 1.0 dB is satisfied, and the accuracy of the mobile station can be moderated.

It should be noted that, although not described above, the energy of the transmission signal is increased by lowering the clock speed of the transmission signal. Therefore, under the control of the BER detection unit 12, the output amplifier 7 is controlled to such an extent that the bit error rate does not deteriorate. The gain may be reduced. Thereby, power consumption can be saved.

Next, another embodiment of the present invention will be described with reference to FIGS.

FIG. 4 is a block diagram showing the structure of the base station. In the figure, the spread spectrum signal from the mobile station is supplied from the transmitting / receiving antenna 21 to the down converter 22 and frequency-converted so that the center frequency becomes equal to the frequency of the carrier fc. The spread spectrum signal output from the down converter 22 is supplied to the demodulation unit 23, and is subjected to spread demodulation and PSK demodulation.

The error-correction-decoded signal d (t) output from the demodulation unit 23 is subjected to error correction processing in the decoding unit 24 and supplied to the receiving system in the subsequent stage.

The input / output signal of the decoding section 24 is BER.
The bit error rate is supplied to the detection unit 25, and the bit error rate is calculated and determined. Here, at the upper limit of the communication line capacity of the system, the bit error rate of the received signal of the mobile station exceeds a threshold value of about 3.0 × 10 ⁻³ .

The clock control information creating section 26 creates and outputs clock control information for controlling the speed of the transmission clock of the mobile station. When the BER detection unit 25 detects that the bit error rate exceeds a threshold value of about 3.0 × 10 ⁻³ , the BER detection unit 25 controls the creation unit 26 to reduce the speed of the transmission clock as clock control information. Information is created.

The transmission signal d (t) (analog signal) such as voice is supplied to the binary modulator 27, and this modulator 2
A transmission signal d (t) (binary modulation signal) is output from 7. The period Td of the transmission signal d (t) is determined by the speed of the transmission clock from the transmission clock generator 28.

Transmit signal d (t) output from modulator 27
Is supplied to the clock control information synthesizer 29. The clock control information created by the creating unit 26 is supplied to the combining unit 29 and combined with the transmission signal d (t).

The transmission signal d (t) output from the combiner 29, which is combined with the clock control information, is error correction coded by the encoder 30 and then supplied to the PSK modulator 31. A carrier fc is supplied to the PSK modulator 31 from a carrier generator (not shown), and the carrier fc is two-phase PSK modulated by the transmission signal d (t).

The PSK modulation signal output from the PSK modulator 31 is supplied to the spread modulator 32. The spread signal p (t) is supplied to the spread modulator 32, whereby the PSK
The modulation signal is spread-modulated.

The center frequency of the spread spectrum signal output from the spread modulator 32 is converted into a high frequency by the up converter 33, and then the spread spectrum signal is supplied to the transmitting / receiving antenna 21 via the output amplifier (high power amplifier) 34 and moved. Sent to the station.

FIG. 5 is a block diagram showing the structure of the mobile station. 5, parts corresponding to those in FIG. 1 are designated by the same reference numerals, and detailed description thereof will be omitted.

The clock control information extraction unit 1 outputs the signal d (t), which is the synthesized clock control information output from the decoding unit 11.
3 is supplied. The signal d (t) from which the clock control information has been removed, which is output from the extraction unit 13, is supplied to the receiving system in the subsequent stage.

The clock control information extracted by the extraction unit 13 is supplied to the transmission clock generator 2 to control the speed of the transmission clock.

Other configurations of the mobile station shown in FIG. 5 are similar to those of the example shown in FIG.

The present embodiment is configured as described above, and since the transmission quality of the received signal of the base station deteriorates at the upper limit of the communication line capacity, the base station creating unit 26 has clock control information for lowering the clock speed of the transmitted signal. Created, this is the transmitted signal d
It is combined with (t) and transmitted to the mobile station. Therefore, the speed of the transmission clock from the transmission clock generator 2 is reduced by the clock control information extracted by the extraction unit 13 of the mobile station. Therefore, at the upper limit of the communication line capacity, the transmission signal d
The period Td of change of (t) becomes long, the processing gain of modulation / demodulation is improved, a margin is generated in the power control circuit, and the accuracy of the mobile station can be made gentle as in the example of FIG.

Incidentally, even if not mentioned above, the energy of the transmission signal increases by decreasing the clock speed of the transmission signal, so that the bit error rate does not deteriorate based on the clock control information detected by the extraction unit 13. Alternatively, the gain of the output amplifier 7 may be reduced. Thereby, power consumption can be saved.

In the above embodiment, the transmission quality is determined by detecting the bit error rate.
The transmission quality may be determined using the / N ratio detection circuit.

[0047]

According to the first aspect of the invention, for example, at the upper limit of the communication line capacity, the mobile station determines that the transmission quality is lower than a predetermined value, and the clock speed of the transmission signal is reduced. Therefore, it is possible to allow a margin for accuracy and to loosen the accuracy of the mobile station.

According to the second aspect of the present invention, for example, at the upper limit of the communication line capacity, it is judged that the transmission quality is lower than a predetermined value at the base station, and clock control data for controlling to lower the clock speed of the transmission signal is created. Then, the mobile station lowers the clock speed of the transmission signal based on the clock control data extracted from the reception signal by the mobile station. Therefore, the cycle of signal change of the transmission signal becomes long, the processing gain of modulation / demodulation is improved, the power control accuracy can be given a margin, and the accuracy of the mobile station can be made gentle.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a mobile station.

FIG. 2 is a diagram for explaining a processing gain of spread spectrum communication.

FIG. 3 is a diagram showing a relationship between a decrease in transmission signal speed and an increase in margin accuracy.

FIG. 4 is a block diagram showing a configuration of a base station.

FIG. 5 is a block diagram showing a configuration of a mobile station.

FIG. 6 is a diagram showing a configuration of a direct diffusion modulation unit.

FIG. 7 is a diagram showing a signal change and a frequency spectrum in the PSK modulator.

FIG. 8 is a diagram showing a signal change and a frequency spectrum in a spread modulator.

FIG. 9 is a diagram illustrating a direct spread demodulation unit.

[Explanation of symbols]

 1 Binary modulator 2,28 Transmit clock generator 3,30 Encoder 4,31 PSK modulator 5,32 Spread modulator 7,34 Output amplifier 10,23 Demodulator 11,24 Decoder 12,25 Bit error rate detection Part 13 Clock control information extraction part 26 Clock control information creation part

Claims (2)

[Claims] 1. A transmission quality determination means for determining the transmission quality of a received signal, and a clock control means for controlling a clock speed of a transmission signal based on the transmission quality determined by the transmission quality determination means. Spread spectrum transmitter and receiver. 2. Transmission quality judging means for judging the transmission quality of a received signal, and control data creation for creating clock control data for controlling the clock speed of a transmission signal based on the transmission quality judged by this transmission quality judging means. Means and a data synthesizing means for synthesizing the clock control data created by the control data creating means into a transmission signal, and a data extracting means for extracting the clock control data from the received signal. A spread spectrum transmission / reception system comprising a second spread spectrum transmission / reception device, comprising: clock control means for controlling the clock speed of a transmission signal based on the clock control data extracted by the data extraction means.