JPH09298432A - Cw reception sound quality compensation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the articulation of a CW signal tone by correcting a delay characteristic of a low frequency amplifier stage in the reception of an amateur radio communication equipment so as to apply waveform shaping in a time base direction. SOLUTION: A CW signal whose frequency is converted into an intermediate frequency is given to a band signal filter 1, in which an undesired signal component is eliminated and the result is demodulated and the demodulated signal is filtered by a band limit filter 3. Then a low frequency amplifier 6 amplifies the filtered signal based on a control signal from a control signal generator 8 at a prescribed gain to make rising of the signal steep, and the control signal generator 8 generates the control signal in response to the level detected by a level detector 7 so as to control the gain of the amplifier 6. In this case, the operation of the control signal generator 8 is delayed slightly from a rising point of an output signal with a prescribed time constant. Thus, the time till the output signal of the amplifier 6 reaches the maximum amplitude from the leading is reduced depending on the gain and the maximum amplitude is limited to picture value to emphasize the leading of the signal thereby correcting the waveform.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sound quality compensating method for improving the intelligibility of CW reception sound, particularly in an amateur radio communication device.

[0002]

2. Description of the Related Art FIG. 2 shows a configuration of a CW receiving system of a conventional amateur radio communication device for receiving a CW signal having a radio wave format of A1A or the like. In FIG. 2, 1 is a band limiting filter in the intermediate frequency stage, 2 is a demodulator, 3 is a band limiting filter in the low frequency amplifying stage, 4 is a low frequency power amplifier, and 5 is a speaker.

The input of the band limiting filter 1 is a final intermediate frequency amplifying stage, and may have a double super or triple super heterodyne configuration depending on the case. In FIG. 2, the intermediate frequency CW signal is band-pass filtered by the band limiting filter 1 to remove adjacent interference and noise signal components, etc., converted into an audible frequency band by the demodulator 2, and again by the band limiting filter 3. Interference and noise signal components are removed, low-frequency amplifier 4 performs low-frequency amplification,
The loudspeaker 5 converts the CW signal into a sound wave so that the sound can be recognized by the operator. Since the CW signal is intermittent at a single frequency in the audible frequency band, the bandwidth of the band limiting filters 1 and 3 is usually set to several tens Hz to several hundreds Hz.

In recent years, for effective use of radio waves,
2. Description of the Related Art Narrowing of a reception band in a wireless communication device or the like is being attempted. Therefore, as a means for narrowing the reception band, there is a method of narrowing the band by using a plurality of band-limiting filters and the like. In other words, the time constant of the filter
Affects the passing CW signal, and when passing through the filter, the phenomenon that the rising of the CW signal becomes gentle in the time axis direction until the amplitude reaches the maximum in addition to the delay of the CW signal itself. Occur. This state is shown in FIG. This becomes more pronounced as the bandwidth of the filter is reduced.

Therefore, when an operator hears a CW signal in such a wireless communication device, the boundary between a period in which the CW signal does not exist and a period in which the CW signal exists aurally becomes ambiguous, and the intelligibility decreases. Become.

[0006]

In view of the above-mentioned problems of the prior art, therefore, in the present invention, a circuit for correcting the delay characteristic of the CW signal is provided in the demodulated low frequency amplifying stage, and the circuit is arranged in the time axis direction. By performing waveform shaping, the operator hears C
We propose a CW received sound quality compensation method that improves intelligibility of W signal sound.

[0007]

According to the present invention, there is provided a radio communication device for receiving a CW signal, a gain controllable low-frequency amplifier and a level detector, which are provided after a demodulator for converting the CW signal into an audible frequency band. And a low-frequency amplifier stage composed of a control signal generator and a low-frequency amplifier capable of controlling the gain of the CW signal converted to an audible frequency band, and amplifying the signal level with a gain determined by a control signal from the control signal generator. Then, the amplified signal level is detected by a level detector, the detected signal level is compared with a desired signal level by a control signal generator, and the calculated signal level is compared with a desired signal level. A CW reception sound quality compensation method is provided, wherein a control signal for determining a gain is generated, and a gain of the low frequency amplifier capable of controlling the gain is controlled.

[0008]

FIG. 1 shows an embodiment of the present invention. 1 is a band limiting filter of an intermediate frequency stage, 2 is a demodulator, 3 is a band limiting filter in a low frequency amplifying stage, 4 is a low frequency power amplifier, 5 is a speaker, 6 is a low frequency amplifier capable of gain control,
7, a level detector; and 8, a control signal generator.

In FIG. 1, a CW signal converted to a desired intermediate frequency is first input to a band limiting filter 1,
After filtering unnecessary signal components and the like, the signal is converted by the demodulator 2 into a single frequency in an audible frequency band. Unnecessary signal components and the like generated by the demodulator 2 are filtered again by the band limiting filter 3.
The CW signal obtained by filtering a desired unnecessary signal component is input to a low-frequency amplifier 6 whose gain can be controlled, and is amplified at a gain determined by a control signal from a control signal generator 8.

In the output signal of the low-frequency amplifier 6, the slope of the amplitude increase at the rising point of this signal is
Therefore, the time from when the signal rises to when the signal reaches the amplitude corresponding to the maximum value of the amplitude when the low-frequency amplifier 6 does not exist is shortened. The output level detector 7 of the output signal whose rising time is shortened
, A control signal corresponding to the detected level is calculated, a control signal is output from the control signal generator 8, and the gain of the low frequency amplifier 6 is controlled. By making the operation of the control signal generator 8 have a constant time constant, the generation of the control signal can be slightly delayed from the rising point of the output signal.

As a result, the time from when the output signal of the low frequency amplifier 6 rises to when it reaches the maximum amplitude value is shortened according to the gain of the low frequency amplifier 6, and the maximum amplitude value is controlled by the control signal generator. The waveform can be corrected to an output signal which is limited by the operation value determined by 8 and in which the rising of the signal is emphasized.

FIG. 3 shows the waveform of the CW signal observed at points A, B and C in FIG. FIG. 3A is a waveform diagram before the received pulse-like CW signal is converted into an intermediate frequency and input to the band limiting filter 1, and FIG. FIG. 2 is a diagram showing a waveform diagram of a CW signal converted into an audible frequency band at 2 and passed through the band limiting filter 3 again. FIG. 3C is a waveform diagram showing a CW signal whose waveform has been corrected according to the present invention. In FIG. 3A, “a” indicates a portion where the rise time of the CW signal is reduced by the low-frequency amplifier 6. b indicates an operation value determined by the control signal generator 8.

According to the present invention, distortion is generated at the portion a in FIG. 3C. When this is heard through the speaker 5, it is heard with an appropriate click sound, and is recognized as a starting point of the Morse code in terms of audibility. It will be easier. Further, since the gain itself of the low-frequency amplifier 6 is limited in the portion b, for example, the peak value of the amplitude is less likely to be distorted and the tone is dirty.

In addition to the method of incorporating the present invention in a receiving circuit of a wireless communication device, the present invention can be used by adding it to an audio output (external speaker terminal or the like) of a conventional wireless communication device.

FIG. 4 is a block diagram when the present invention is used as an additional device. Basically, the low-frequency amplifier 6 of FIG.
It is possible to provide the level detector 7, the control signal generator 8, the low-frequency power amplifier 4, and the speaker 5, but the output of the conventional wireless communication device is not constant. A level variable circuit 9 for adjusting the value to an appropriate value is required.

[0016]

The present invention acts particularly on the rising portion of the output signal of the low frequency amplifier 6, and makes the boundary between the period in which the signal does not exist and the period in which the signal exists exist clearer. For this reason, by providing the present invention, it is possible to improve the decrease in auditory intelligibility,
The code recognition rate when a human hears the CW signal with his ear is improved.

Also, there is an effect that a feeling of fatigue is small even when listening for a long time.

[Brief description of drawings]

FIG. 1 is a block diagram showing one embodiment of the present invention.

FIG. 2 is a block diagram showing a conventional technique.

FIG. 3 is a waveform chart according to the present invention.

FIG. 4 is a block diagram showing one embodiment of the present invention.

[Explanation of symbols]

 6 Low frequency amplifier 7 Level detector 8 Control signal generator

Claims (1)

[Claims] A wireless communication device for receiving a CW signal, comprising:
After the demodulator that converts the signal to the audio frequency band,
In a low frequency amplification stage composed of a gain controllable low frequency amplifier, a level detector and a control signal generator, a CW signal converted into an audible frequency band is controlled by the gain controllable low frequency amplifier from a control signal generator. The signal level is amplified with a gain determined by the control signal of, the amplified signal level is detected by a level detector, the control signal generator compares the detected signal level with a desired signal level, and the calculated result is obtained. A CW reception sound quality compensation system, wherein a control signal for determining the gain of the low frequency amplifier capable of controlling the gain is generated to control the gain of the low frequency amplifier capable of controlling the gain.