JPH0440041A - Digital communication system - Google Patents

Abstract

PURPOSE:To reproduce an information signal without fail even in a transmission line with a lot of noise by converting a demodulated signal to a digital signal, afterwards, cumulatively adding the digital signals during a period corresponding to a synchronizing signal and reproducing the information signal. CONSTITUTION:This digital communication system is composed of a first equipment with an information signal generating means 13 to output the information signal synchronously with a reference signal from a reference signal generating means 12, modulating means 17 to modulate this information signal and transmitting means 18 to transmit a modulated output, and a second equipment with a receiving means 20 to receive the signal from the transmitting means 18, demodulating means 25 to demodulate the received signal, analog/digital converting means 27 to convert the demodulated output to the digital signal, adding means 29 to cumulatively add the output signals during the period corresponding to the cycle of the reference signal, and means to reproduce the information signal based on the added output. Thus, since the signal received synchronously with the reference signal is demodulated, converted to the digital signal and cumulatively added, the information signal is exactly restored even in the case of including a lot of noise in the transmission line or the like.

Description

[Detailed description of the invention] (b) Industrial application fields The present invention relates to digital communication systems.

(B) Prior Art Conventionally, in digital communication systems, information signals are transmitted by applying digital modulation such as phase shift key ink (PSK) in order to efficiently utilize transmission media.

As a circuit for demodulating such a two-phase phase shift key ink signal and reproducing an information signal, a Costas loop as shown in FIG. 3 is known.

In Figure 3, (1) is an input terminal, (2) is a voltage controlled oscillator (VCO) that oscillates a carrier wave signal, and (3) is a two-phase phase shift keying signal supplied from input terminal (1) and a voltage controlled oscillator (VCO) that oscillates a carrier wave signal. The first multiplier (4) multiplies the oscillation signal supplied from the input terminal (1) with the oscillation signal supplied from the input terminal (1).
A second multiplier that multiplies the oscillation signal from the VCO (2) phase-shifted by 0 degrees, (6) a tenth bus filter connected to the output side of the first multiplier (3), (7) is the second multiplier (
4), the 20th bus filter connected to the output side of (8)
) is a third multiplier that multiplies the output of the 10th bus filter (6) and the output of the 20th bus filter (7), (9)
is a loop filter that is connected to the output side of the third multiplier (8) and supplies the low frequency signal component as a control signal to the VCO (2), and (10) is an output terminal.

Next, the operation will be explained.

Now, the input signal is ±Acos(ωt+φ), [where φ is V
Assuming that the phase difference between the output of CO (2) and the input signal is ko, the output of the first multiplier (3) that multiplies this input signal and the output signal cosωt from VCO (2) is ±A/2 ( co
sφ+cos(2ωt+φ)), and the signal that has passed through the 10th bus filter (6) has the high frequency signal component removed and becomes ±A/2cosφ. Note that when the value of φ is small, the output of the 10th bus filter (6) is ±A
/2, that is, a two-phase phase shift keying signal.

On the other hand, the output of the second multiplier (4) that multiplies the output sinωt of the phase shifter (5) and the input signal is ±A/21sinφ
+5in(2ωi+φ)), and the signal passed through the 20th bus filter (7) becomes ±A/2sinφ.

The output of the third multiplier (8) which multiplies the outputs of the first and 20th bus filters (6) and (7) is A''/4sin
2φ#A! It becomes φ/2, and is proportional to the phase difference φ.

Therefore, by controlling the oscillation output of the VCO (2) so that the phase difference becomes O based on the output of the third multiplier (8), it is possible to demodulate the two-phase phase shift key ink signal. .

(c) Problems to be solved by the invention By the way, in digital communication, in order to reliably reproduce the information signal on the receiving side, a clock signal is regenerated from the received signal, and modulation is performed based on the regenerated clock signal. It is designed to regenerate the information signal that has been received.

However, since the tarokk signal is regenerated based on the signal contained in the information signal, if the transmission path contains a lot of noise, the clock signal may not be regenerated accurately, and as a result, the information signal may not be accurately reproduced. could not be restored.

(d) Means for Solving the Problems In view of the above points, the present invention provides a reference signal generating means for generating a reference signal, and an information signal generating means for outputting an information signal in synchronization with the reference signal from the reference signal generating means. a first device comprising means, modulating means for modulating the information signal from the information signal generating means, transmitting means for transmitting the output from the modulating means; receiving means for receiving the signal from the transmitting means; demodulating means for demodulating the signal received by the means; analog/digital converting means for converting the demodulated output from the demodulating means into a digital signal; and an output signal from the analog/digital converting means corresponding to the period of the reference signal. It is an object of the present invention to provide a digital communication system comprising: an adding means for cumulatively adding up a period of time; and a second device having means for reproducing an information signal based on an output signal from the adding means.

(e) Function According to the present invention, the transmitting side modulates and transmits the information signal output in synchronization with the reference signal.

The receiving side first demodulates the received signal, then converts it into a digital signal and cumulatively adds it.

Then, an accurate information signal is reproduced from this added value.

(F) Embodiment FIG. 1 is a diagram showing the transmitting side in the system of the present invention. In Fig. 1, (11) is a code generator that generates a spreading code such as a pseudo-noise code, and outputs a ROM (lla) in which one chip of data constituting the code is stored in each storage area and a readout tarlock signal. Clock signal generation circuit (
llb) and an address counter (llc) that specifies the address of the ROM (lla) based on the clock signal from the tarlock signal generating circuit (llb). (12) is a reference signal generation circuit that receives the output of the address counter (llc) and generates an output signal when the count value becomes zero, and the code generator (11)
A reference signal is output for each period of the spreading code output from the .

(13) is an information signal generation section that outputs an information signal that changes according to the output signal from the reference signal generation circuit (12);
A D flip 70 tube (13b) that holds binary data from the information source (13a) in the reference signal, and the Q output of this D flip 70 tube (13b) and the input binary data are supplied. Exclusive OR circuit (EX-OR)
(13c). (14) is a carrier wave signal generation circuit that generates a carrier wave signal, and (15) is an information signal generation section (15) that generates a carrier wave signal from the carrier wave signal generation circuit (14).
a modulation unit that modulates the information signal output from (1);
6) is a spreading section that spreads the spectrum of the signal from the modulation section (15) based on the spreading code from the code generator (11), and together with the modulation section (15), constitutes a modulation circuit (17). . (18) is a transmitting antenna serving as a transmitting circuit that transmits the output signal from the modulation circuit (17).

FIG. 2 is a diagram showing the receiving side of the system of the present invention. In Fig. 2, (2o) is a receiving antenna serving as a receiving means, and (21) is a demodulation circuit that demodulates the received signal from the receiving antenna (2o), which is the same as or correlated with the spreading code from the code generator W (11). a demodulation code generator (22) that generates a demodulation code with a large value; a despreading section (23) that despreads the spectrum of the received signal based on the demodulation code from the demodulation code generator (22) and the received signal; a filter (24) that passes the despread signal;
), and a signal generation circuit (26) that outputs a signal (reference signal) for each period of the demodulation code. In addition, demodulation code is generated!
(22) includes a ROM (22a) in which one chip data is stored in each area similarly to the code generator (11), an address counter (22c) that specifies the address of this ROM (22a), and this address counter. A clock signal generation circuit (22b) that supplies a clock signal to (22c)
), and a clock control circuit (22d) that controls the period or frequency of the clock signal output from the clock signal generation circuit (22b) based on the output of the despreading section (23).
) and more.

The demodulator (25) also includes a delay circuit (ZS) that delays the signal that has passed through the filter (24) by a time corresponding to one data.
a) and a multiplier (25b) to which the delayed signal and the signal passed through the filter (24) are input. (27) converts the demodulated output from the demodulator (25) into a clock source (28) having a frequency higher than the code frequency.
), the AD converter (29) is an adder circuit that cumulatively adds the output signals from the AD converter (27);
an adder (29a) that is connected to the output terminal of the adder (29a) and adds the output of a first holding circuit (to be described later); and a signal generating circuit that holds the output of the adder (29a) based on a clock signal from the tarok source (28). Signal from (26) (reference signal)
a first holding circuit (29b) that is reset based on , and a second holding circuit (29b) that holds the output of the first holding circuit (29b) based on the signal (reference signal) from the signal generation circuit (26).
29c). (30) is a reproducing circuit that reproduces an information signal based on the value held in the second holding circuit (29c), and a comparator (31) that compares the held output of the second holding circuit (29c) with a reference value. , this comparator (31
) based on the signal (reference signal) from the signal generating circuit (26).

Next, the operation will be explained.

On the transmitting side, an information signal generator (13) generates an information signal from an information source (13a) according to a reference signal from a reference signal generator (12).
Outputs the information signal from the EX-OR circuit (13c),
This output information signal and the D flip-flop (13b
) with the information signal from one timing before.

The information signal digitally processed in this way is sent to the modulation section (15).
For example, the carrier wave signal from the carrier wave signal generation circuit (14) is subjected to two-phase phase shift keying. The spectrum of this two-phase phase shift key ink signal is spread by a spreading code from a code generator (11) in a spreading section (16), and then transmitted via a transmitting antenna (18).

Such a transmission signal is received by a receiving antenna (20) and then supplied to a demodulation circuit (21). Demodulation circuit (21)
Then, the spectrum of the received signal is despread by multiplying the received signal (spread spectrum signal) by the demodulation code from the demodulation code generator (22). It is assumed that the demodulation code output from the demodulation code generator (22) has been synchronized with the spread code by synchronization detection control with the spread code on the transmitting side prior to the demodulation operation of the received signal. .

The output signal from the despreading section (23) is then supplied to the filter (24) to extract only the carrier signal component.
This carrier signal component is supplied to a demodulator (25). The demodulator (25) demodulates the two-phase phase shift keying signal by multiplying the carrier signal passed through the filter (24) by the carrier signal supplied via the delay circuit (25a).

This demodulated two-phase phase shift key ink signal is converted into a digital signal by an AD conversion circuit (27) in response to a clock signal from a clock source (28).

This digital signal is supplied to an adder (29a) and added to the output signal from the first holding circuit (29b).

Further, the output signal of this adder (29a) is transmitted to the first holding circuit (29a) according to the clock signal from the tarok source (28).
9b). Note that the content of the first holding circuit (29b) is the signal (reference signal) from the signal generation circuit (26).
It is reset according to the falling edge of .

Therefore, the output signals from the AD conversion circuit (27) are cumulatively added every generation period of the reference signal. This cumulatively added value (integral value) is held in the second holding circuit (29C) in response to the rise of the signal (reference signal).

Here, the digital value corresponding to the H level output of the demodulator (25) is 10 in decimal notation, the digital value corresponding to the L level output is 0 in decimal notation, and the number of cumulative additions within the reference signal period is 10. times, the second holding circuit (29c
) corresponds to the H level and is 100, and the value corresponding to the L level is 0.

Thus, the output signal of the second holding circuit (29c) is set to the reference value (
For example, by comparing with 50), it becomes possible to reproduce the information signal, which is held in the third holding circuit (32) and supplied to the subsequent stage circuit.

Furthermore, even if a noise component is superimposed on the output signal from the demodulator (25), by performing cumulative addition as described above, the noise component can be averaged and made smaller than the signal component. .

In this way, the operation of the present invention is achieved; however, the present invention is not limited to the above-described embodiments; for example, a predetermined broadcast frequency or its local oscillation frequency, or a commercial power supply frequency may be used as the synchronization signal. Furthermore, as a modulation method, not only the method described above but also other modulation methods can be used.

Furthermore, although the spectrum of the modulated signal is spread, it goes without saying that this spreading operation is not necessarily required.

(G) Effects of the Invention According to the present invention, when an information signal that changes in synchronization with a synchronization signal is modulated and transmitted, and when this transmitted signal is received,
- After first converting the demodulated signal into a digital signal, the digital signal is cumulatively added for a period corresponding to the synchronization signal, and the information signal is reproduced based on the addition result, so it can be used even on a noisy transmission line. Information signals can be reliably reproduced.

Further, when transmitting an information signal, if the spectrum of the transmitted signal is spread using a spreading code, the noise resistance characteristics will be improved.

Further, by detecting one period of the code from the code generator and outputting the synchronization signal, it is possible to easily synchronize the synchronization signals on the transmitting and receiving sides.

[Brief explanation of drawings]

FIG. 1 is a diagram showing the transmitting side of the system of the present invention, FIG. 2 is a diagram showing the receiving side of the present invention, and FIG. 3 is a diagram showing the Costas loop in the conventional system. (11)...Code generator, (12)...Reference signal generation circuit, (13)...Information signal generation section, (14)...
・Carrier signal generation circuit, (15)...Modulation section, (16
)...Diffusion section, (17)...Modulation circuit, (18)...
...Transmission antenna, (20) ...Reception antenna, (2
1)... Demodulation circuit, (22)... Demodulation code generator,
(23)...Despreader, (24)...Filter, (
25)...Demodulator, (26)...Signal generation circuit, (
27)...AD converter, (28)...Tarlock source,
(29)...addition circuit, (29a)...adder, (
29b)...First holding circuit, (29c)...Second holding circuit, (30)...Reproducing circuit, (31)...Comparator, (32)...Third holding circuit.

Claims (9)

[Claims] (1) Reference signal generation means for generating a reference signal, information signal generation means for outputting an information signal in synchronization with the reference signal from this reference signal generation means, and modulation means for modulating the information signal from this information signal generation means. , a first device having a transmitting means for transmitting an output from the modulating means; a receiving means for receiving a signal from the transmitting means; a demodulating means for demodulating the signal received by the receiving means; analog/digital conversion means for converting the demodulated output from the analog/digital conversion means into a digital signal; an output signal from the analog/digital conversion means for a period corresponding to the period of the reference signal;
A digital communication system comprising: an adding means for cumulatively adding; and a second device having means for reproducing an information signal based on an output signal from the adding means. (2) The modulation means includes code generation means for generating a spreading code such as a pseudo-noise code, and is configured to spread the spectrum of the information signal using the spreading code from the code generation means. The digital communication system according to claim 1. (3) The reference signal generating means is a means for detecting one period of the spreading code outputted from the code generating means, and is configured to output a reference signal every one period of the spreading code. The digital communication system according to claim 2, characterized in that: (4) The demodulation means includes demodulation code generation means for generating a demodulation code that is the same as or highly correlated with the spreading code output from the code generation means, and the demodulation code from the demodulation code generation means and the reception means. 3. The digital communication system according to claim 2, further comprising despreading means for despreading the spectrum of the received signal based on the received signal. (5) The digital communication system according to claim 4, wherein the demodulation means includes a demodulator that demodulates the information signal from the output signal from the despreading means. (6) The demodulation means includes a detection means for detecting one period of the demodulation code output from the demodulation code, and supplies the output of the detection means to the addition means as a control signal for controlling the addition period. The digital communication system according to claim 4 or 5, characterized in that the digital communication system is configured as follows. (7) The reproduction means includes comparison means for comparing the added output from the addition means with a reference value, and the output signal of the comparison means is used as the reproduced information signal. digital communication system. (8) Reference signal generation means for generating a reference signal, information signal generation means for outputting an information signal in synchronization with the reference signal from this reference signal generation means, and modulation means for modulating the information signal from this information signal generation means. , a first device having a transmitting means for transmitting an output from the modulating means; a receiving means for receiving a signal from the transmitting means; a demodulating means for demodulating the signal received by the receiving means; A digital communication system comprising: an integrating means for digitally integrating the demodulated output from the integrating means for every predetermined period; and a second device having means for reproducing an information signal based on the output signal from the integrating means. (9) The integrating means includes an analog/digital converting means for converting the demodulated output from the demodulating means into a digital signal, and integrates the output signal from the analog/digital converting means for a period corresponding to the period of the reference signal. 9. The digital communication system according to claim 8, further comprising an adding means for adding.