JPH06141023A - Privacy communication equipment - Google Patents

Abstract

PURPOSE:To prevent the quality of a restoration voice from being deteriorated and to decrease chip size by using a diffused resistor consisting of a polycrystal Si as the resistance element of an RC active filter through which an original audio signal or restoration audio signal passes. CONSTITUTION:An audio signal S11 inputted to a transmission original voice input terminal 21 is inputted to an RC active filter 32 for folding prevention provided with a diffused resistance element. A signal from which an unrequired high frequency component is eliminated by the filter 32 is spectrum-inverted and made into a privacy telephone by a privacy telephone circuit 34 via a pre-LPF 33. The output signal of the circuit is outputted from the output terminal 37 of a signal system as a transmission output privacy signal S12 via a post-LPF 35 and an RC active filter 36 for smoothing provided with a polycrystal Si element. The signal is inputted to a reception side input terminal 32 as a reception privacy input signal 13. The signal is outputted via the RC active filter 39, a pre-LPF 40, a restoration circuit 41, a post-LPF 42, and the RC active filter 43, and reception restoration output S14 is outputted from an output terminal 39.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a secret communication device for use in cordless phones and the like, which secretly transmits a voice signal and restores the encrypted reception signal to a voice signal, and more particularly to a monolithic IC. The best-known secret communication device.

[0002]

2. Description of the Related Art Conventionally, as a technique in such a field,
For example, there were the following. FIG. 6 is a block diagram showing an example of the configuration of such a conventional confidential communication device. As shown in this figure, the transmission voice signal S ₁ input to the transmission source voice input terminal 1 has unnecessary high-frequency components in the anti-aliasing RC active filter 2 having a diffusion resistance element and the front low-pass filter 3. After being removed, it is made confidential by the confidential circuit 4, the unnecessary high-frequency component in the confidential signal is removed by the post-pass filter 5, and the output waveform is smoothed by the smoothing RC active filter 6 having a diffusion resistance element. The transmitted confidential confidential signal S ₂ is output from the confidential confidential output terminal 7.

On the other hand, on the receiving side, the received confidential talk signal S ₃ input to the received confidential talk input terminal 8 is an unnecessary high frequency component by the anti-aliasing RC active filter 9 having a diffusion resistance element and the front low pass filter 10. Are removed, and are restored by the restoration circuit 11, unnecessary high frequency components in the restored signal are removed by the post-pass filter 12, and the output waveform is smoothed by the smoothing RC active filter 13 having a diffusion resistance element. It is output as a restoration signal S ₄ from the reception restoration output terminal 14.

The above-mentioned RC active filters 2, 6,
9 and 13 are composed of a circuit as shown in FIG. 7. When integrating this secret communication device, the resistance elements 21 and 22 of the RC active filter shown in FIG. 7 are made by using diffused resistors. It was In addition, 23 and 24 are capacitors, 25
Is an operational amplifier.

[0005]

However, in the confidential communication apparatus having the above-mentioned configuration, since diffused resistors are used as the resistance elements 21 and 22 of the RC active filter, there is a problem that high frequency distortion occurs in this RC active filter. there were. Here, for example, assuming that the secret channel system is a spectrum inversion system, the input signal is 2.5 KHz, and the subcarrier frequency supplied to the confidential circuit 4 or the balanced modulator and the restoration circuit 11 or the balanced demodulator is 3.3 KHz. The signal is converted to 0.8 KHz by the confidential circuit 4 and then 1.6 K by the RC active filters 6 and 9.
Generates harmonics such as Hz and 2.4 KHz. After that, the spectrum is inverted by the restoration circuit 11 to obtain 1.7K each.
The frequency components are Hz and 0.9 KHz, and the restored voice includes these frequency components. Therefore, there is a problem that the quality of the restored voice is deteriorated.

Further, when a polycrystalline silicon resistor is used as the resistance element of the RC active filter, harmonic distortion does not occur, but the polycrystalline silicon resistor has a low sheet resistance,
There is a drawback that the chip area of the RC active filter occupying on the semiconductor chip increases, and the chip size becomes large when this secret communication device is integrated.

The present invention solves the above-mentioned drawback of the quality of the restored voice in the prior art being deteriorated, and provides a monolithic IC confidential communication device which does not increase the chip size when integrated on a semiconductor. To aim.

[0008]

In order to achieve the above object, the present invention provides an RC active filter for preventing aliasing as a transmission system, a front low pass filter, a secret circuit, a rear low pass filter and smoothing. In the monolithic IC confidential communication device, which includes an RC active filter for preventing aliasing, a front low pass filter, a restoration circuit, a rear low pass filter and a smoothing RC active filter as a receiving system, the transmission A diffusion resistance is used as each resistance element of the system anti-aliasing RC active filter and the reception system smoothing RC active filter, and the transmission system smoothing RC active filter and the reception system anti-aliasing RC active filter are used. Polycrystalline silicon is used as each resistance element. It is obtained to use a configuration resistance.

[0009]

According to the present invention, as described above, in the monolithic IC confidential communication device, as shown in FIG. 1, the RC active filter 32 for preventing aliasing in the transmission system and the reception system through which the original voice signal or the restored voice signal passes. Since diffused resistors are used as the respective resistance elements of the smoothing RC active filter 43, the chip occupation area of the IC confidential communication device is not so large.

Further, since polycrystalline silicon is used as the resistance element of each of the RC active filter 36 for smoothing of the transmitting system through which the confidential signal passes and the RC active filter 39 for preventing aliasing of the receiving system, for smoothing of the transmitting system. No harmonic distortion occurs in the RC active filter 36 and the RC active filter 39 for preventing aliasing in the receiving system.

Therefore, while suppressing the chip occupying area of the IC-based confidential communication device, generation of harmonics to the confidential signal is prevented, and frequency components other than the frequency series of the input signal are output to the reception restoration output terminal. It is not output, and the voice quality can be improved.

[0012]

Embodiments of the present invention will be described in detail below with reference to the drawings. 1 is a block diagram of a monolithic IC confidential communication device showing an embodiment of the present invention, FIG. 2 is a circuit configuration diagram of an RC active filter in FIG. 1, FIG. 3 is a circuit configuration diagram of a low pass filter in FIG. FIG. 4 shows a balanced modulator and a balanced demodulator which are examples of the confidential circuit and the restoration circuit in FIG.

Referring to FIG. 1, the monolithic IC confidential transmission device includes a transmission source voice input terminal 31, an anti-aliasing RC active filter 32 having a diffusion resistance element, a front low pass filter 33, a secret circuit 34, and a rear low band. R for smoothing having pass filter 35 and polycrystalline silicon element
The C active filter 36 and the confidential transmission output terminal 37 are provided.

The secret-speech receiver includes a reception secret-speech input terminal 38, an anti-aliasing RC active filter 39 having a polycrystalline silicon element, a front low-pass filter 40, a restoration circuit 41, and a rear low-pass filter 42. A smoothing RC active filter 43 having a diffusion resistance element,
It comprises a reception restoration output terminal 44. Next, the operation of this monolithic IC confidential communication device will be described with reference to FIGS. The secret method is the spectrum inversion method,
A case where the subcarrier frequency of spectrum inversion is 3300 Hz will be described.

In FIG. 1, the input signal S ₁₁ input to the transmission source audio input terminal 31 is input to an anti-aliasing RC active filter 32 having a diffusion resistance element. This RC active filter 32, as shown in FIG.
Operational amplifier 55, resistance elements 51 and 5 including diffused resistors
2, composed of capacitors 53 and 54. The anti-aliasing filter is a switched capacitor filter (Sw).
itedCapacitor Filter:
When a signal having a frequency component near the clock frequency of this SCF is input to the input of
To prevent the aliasing phenomenon that is output as a low frequency signal at the output of, and has a characteristic of sufficiently attenuating the frequency component in the vicinity of the clock frequency of the SCF.

A signal from which unnecessary high frequency components have been removed by the anti-aliasing RC active filter 32 having a diffusion resistance element is input to a pre-reduction pass filter (hereinafter referred to as pre-LPF) 33. The front LPF 33 is composed of SCF, and is composed of, for example, a cascade connection of the circuits shown in FIG.

In FIG. 3, 66 and 74 are operational amplifiers,
61, 62, 64, 65, 68, 69, 71, 72, 7
8, 79 are, for example, CMOS configuration switches, 63, 6
Reference numerals 7, 70, 73, 75, 76 and 77 are capacitors. The front LPF 33 allows frequency components of 3000 Hz or less to pass therethrough, and allows the subcarrier frequency 330 of the confidential circuit 34 to pass.
It is for removing frequency components above 0 Hz,
The passband is narrower and steeper than the frequency characteristic of the anti-aliasing RC active filter 32. That is,
When a frequency component of 3300 Hz or higher is input to the confidential circuit 34, it is prevented that the frequency component of the pass band of the post-pass filter 35 appears at the output of the confidential circuit 34. The signal from which unnecessary high frequency components have been removed by the pre-LPF 33 is input to the confidential circuit 34.

In the spectrum inversion method, the secret circuit 34 is realized by the balanced modulator shown in FIG. 4, and is composed of an operational amplifier 85, resistance elements 81 and 84 of polycrystalline silicon structure, and switches 82 and 83 of CMOS structure, for example. Then, the switches 82 and 83 are alternately turned on and off at a cycle of 3300 Hz. This operation causes the spectrum of the input signal to be inverted,
It is made confidential and output.

When the input frequency of the balanced modulator is fi and the subcarrier frequency is fs, fs ± fi, 3fs ± f
It is converted into an output signal having frequency components of i, 5fs ± fi, .... For example, fs = 3300 Hz, fi = 250
0Hz, 800Hz, 5800Hz, 7400
A signal having frequency components of Hz, 12400 Hz ... Is output.

The output of the confidential circuit 34 is input to a post-reduction pass filter 35 (hereinafter referred to as a post-LPF), and 3
Passes frequency components below 000 Hz, 3300 Hz
The above frequency components are removed. Rear LPF35 is front LP
Like F33, it is composed of SCF, and is composed of, for example, cascade connection of the circuits shown in FIG. The output of the post-LPF 35 is connected to a smoothing RC active filter 36 having a polycrystalline silicon element to smooth the output waveform of the post-LPF 35 having a staircase waveform. As shown in FIG. 5, the smoothing RC active filter 36 having a polycrystalline silicon element is composed of an operational amplifier 95, resistance elements 91 and 92, and capacitors 93 and 94. Polycrystalline silicon resistors are used for the resistance elements 91 and 92. The output of the smoothing RC active filter 36 having this polycrystalline silicon element is output from the transmission system as the transmission confidential output signal S ₁₂ from the transmission confidential output terminal 37. The transmitted confidential confidential signal is input to the receiving confidential confidential input terminal 38 on the receiving side as a received confidential confidential input signal S ₁₃ via a wireless system.

On the receiving side, the receiving confidential talk input terminal 38
The received confidential input signal S ₁₃ input to is the anti-aliasing RC active filter 39 having a polycrystalline silicon element.
Is input to and unnecessary harmonic components are removed. The anti-aliasing RC active filter 39 having the polycrystalline silicon element has the same role as the anti-aliasing RC active filter 32 having the transmission side diffusion resistance element, and is similarly configured by the circuit shown in FIG. That is, the resistance element 9
Polycrystalline silicon resistors 1 and 92 are used.

The output of the anti-aliasing RC active filter 39 having a diffusion resistance element is connected to a front LPF 40, and like the front LPF 33 on the transmission side, a frequency component having a subcarrier frequency of 3300 Hz or higher is removed. The output of the pre-LPF 40 is input to the restoration circuit 41, that is, the balanced demodulator, and spectrum-inverted again to restore the confidential signal. That is, the input signal of the balanced demodulator is fs
-Fi and the subcarrier frequency is fs, fi, 2
It is converted into an output signal having frequency components of fs ± fi, 4fs ± fi ....

For example, fs = 3300 Hz, fi = 25
00Hz, 2500Hz, 4100Hz, 91
A signal having frequency components of 00 Hz, 10700 Hz ... Is output. This restoration circuit 41, that is, the balanced demodulator, is the same as the confidential circuit 34 on the transmission side, that is, the balanced modulator.
It is composed of the circuit shown in FIG. The output of the restoration circuit 41 is connected to the rear LPF 42, and like the rear LPF 35 on the transmission side, frequency components of 3300 Hz or higher are removed. The output of the post-LPF 42 is connected to a smoothing RC active filter 43 having a diffusion resistance element,
If the output waveform of F42 is a staircase waveform, it is smoothed.

The smoothing RC active filter 43 having this diffusion resistance element is constructed by the circuit shown in FIG. That is, diffused resistors are used for the resistance elements 51 and 52. The output of the smoothing RC active filter 43 having this diffusion resistance element is connected to the reception restoration output terminal 44, and the restoration signal is output from the reception system.

The basic operation of the present invention has been described above. Next, the harmonic distortion output from the system will be compared with the conventional circuit. It is generally known that when a diffused resistor is used as the resistance element of the RC active filter, a large amount of harmonic distortion appears. For simplicity of explanation, only the second and third harmonic distortions are considered. In the conventional confidential communication device shown in FIG. 6, RC active filters 2, 6, 9,
Since a diffusion resistance element is used as the resistance element of 13, harmonic distortion occurs in these four RC active filters. If the transmission source voice input is 2500 Hz, the RC active filter 2 for preventing aliasing will generate 5000 Hz, 7
A harmonic distortion of 500 Hz occurs, but is removed by the front LPF3. The fundamental wave 2500Hz is 800H in the confidential circuit 4.
z is converted into z, and harmonics of 1600 Hz and 2400 Hz are generated in the smoothing RC active filter 6 of the transmission system and the RC active filter 9 of the transmission system for preventing aliasing, and these harmonics are respectively 170
It is converted into 0 Hz and 900 Hz and output to the reception restoration output.

Further, in the RC active filter 13 for smoothing the receiving system, 5000 Hz, 7500
Harmonic distortion of Hz occurs. That is, the input fundamental wave 2
In addition to the harmonics of 500 Hz, 5000 Hz and 7500 Hz, frequency components of 1700 Hz and 900 Hz, which are different in series from the fundamental wave, appear at the reception / reconstruction output terminal 14, resulting in a harsh sound.

On the other hand, in the monolithic IC confidential communication apparatus of the present invention, the RC active filter 32 for preventing aliasing in the transmission system having the diffusion resistance element and the RC active filter 4 for smoothing having the diffusion resistance element in the reception system.
3, harmonics are generated similarly to the conventional example, but since the smoothing RC active filter 36 of the transmission system and the anti-aliasing RC active filter 39 of the reception system use a polycrystalline silicon resistor as a resistance element, No waves are generated.

Therefore, the transmission source voice input is 2500H.
In the case of z, 5000 Hz and 7500 Hz are generated in the RC active filter 32 for preventing aliasing in the transmission system, but they are removed by the pre-LPF 33 and RC for smoothing in the reception system.
5000Hz and 7 generated by the active filter 43
A harmonic distortion of 500 Hz appears in the reception restoration output. Since this is a series of input fundamental waves of 2500 Hz (integral multiple), it does not sound so harsh.

Even when the input frequency is 2500 Hz or more, in the monolithic IC confidential communication device of the present invention, the RC active filter 3 for preventing aliasing in the transmission system is used.
2, RC active filter for smoothing of receiving system 4
3, the harmonic distortion occurs, and the RC active filter 36 for smoothing in the transmission system through which the spectrum-inverted signal passes and the RC active filter 3 for preventing aliasing in the reception system
Since harmonic distortion does not occur in 9, frequency components other than the frequency series of the input signal are not output to the reception restoration output terminal,
The voice quality does not deteriorate.

In the above description, the case of the spectrum inversion method is explained as a secret method, but the present invention is not limited to the spectrum inversion method, and can be applied to, for example, a band division permutation method. It should be noted that the present invention is not limited to the above-described embodiments, and various modifications can be made based on the spirit of the present invention, and they are not excluded from the scope of the present invention.

[0031]

As described above in detail, according to the present invention, in the monolithic IC confidential communication device, the diffused resistor is used as the resistance element of the RC active filter through which the original voice signal or the restored voice signal passes. So
The chip occupying area of the confidential communication device formed into a monolithic IC can be reduced.

Furthermore, since the polycrystalline silicon resistor is used as the resistance element of the RC active filter through which the confidential signal passes, harmonic distortion does not occur in the RC active filter. Therefore, no harmonic is generated for the encrypted signal, and frequency components other than the frequency series of the input signal are not output to the reception restoration output, so that the voice quality can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram of a monolithic IC confidential communication device showing an embodiment of the present invention.

FIG. 2 is a circuit configuration diagram of an RC active filter (using diffused resistors) in FIG.

FIG. 3 is a circuit configuration diagram of a low pass filter in FIG.

FIG. 4 is a balanced modulator and a balanced demodulator that are examples of the confidential circuit and the restoration circuit in FIG.

5 is a circuit configuration diagram of an RC active filter (using a polycrystalline silicon element) in FIG.

FIG. 6 is a block diagram showing a configuration example of a conventional confidential communication device.

7 is a circuit configuration diagram of an RC active filter in FIG.

[Explanation of symbols]

31 source audio input terminal 32 anti-aliasing RC active filter with diffused resistance element 33, 40 pre-passage low pass filter 34 confidential circuit 35, 42 post-passage low pass filter 36 smoothing RC with polycrystalline silicon resistance element Active filter 37 Transmission confidential output terminal 38 Reception confidential input terminal 39 RC active filter for prevention of aliasing having polycrystalline silicon resistance element 41 Restoring circuit 43 Smoothing RC active filter having diffusion resistance element 44 Reception restoration output terminal 51, 52 Diffusion resistance Resistance elements 53, 54, 63, 67, 70, 73, 75, 76, 7
7, 93, 94 capacitors 55, 66, 74, 85, 95 operational amplifiers 61, 62, 64, 65, 68, 69, 71, 72, 7
8, 79, 82, 83 CMOS switch 81, 84, 91, 92 Resistance element composed of polycrystalline silicon resistor

Claims (1)

[Claims] 1. An RC active filter for preventing aliasing, a pre-passive low-pass filter, a secret circuit, a post-passive low-pass filter and an RC active filter for smoothing as a transmission system, and an anti-aliasing RC active filter as a receiving system, In a monolithic confidential communication device including a front low pass filter, a restoration circuit, a rear low pass filter, and a smoothing RC active filter, (a) an RC active filter for preventing aliasing of the transmission system and a smoothing of the reception system. A diffused resistor is used as each resistance element of the RC active filter for use in the transmission, and (b) Polycrystalline silicon resistance is used as each resistance element of the RC active filter for smoothing of the transmission system and the RC active filter for preventing aliasing of the reception system. Confidential communication characterized by Location.