JP2009171461A - Wireless communication apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless communication apparatus capable of canceling uneasiness by preventing high frequency noise (frequency-inverted sub audio signal), being harsh on the ears, from being heard from a speaker even when simultaneously using frequency inversion scramble and a sub audio signal. <P>SOLUTION: A cutoff frequency switching means is provided for switching a cutoff frequency of a low-pass filter to be used for an inversion descrambler 135 that returns a frequency-inverted audio signal to be original at a receiving side. The cutoff frequency switching means switches the cutoff frequency of the low-pass filter so as to pass all bands of the audio signal returned to be original or so as to cut part of all the bands wherein a frequency-inverted sub audio signal overlaps. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a wireless communication device.

  In general, in wireless communication, the number of recipients cannot be restricted in principle. Therefore, if it is not desired to know the contents of communication other than a specific recipient, a secret communication method using encryption is effective. The secret communication method includes a method of scrambling an audio signal on the frequency axis. As one of the scrambling methods, there is a method of inverting the frequency of an audio signal as disclosed in Patent Document 1. For example, as shown in FIG. 4, when an audio signal of 300 to 3000 Hz is input, the spectrum of the input audio signal is inverted such that 300 Hz is output as 3000 Hz and 3000 Hz is output as 300 Hz.

  This method can be realized by performing amplitude modulation on an input audio signal with respect to a certain carrier frequency. The principle will be described below.

Here, for the sake of explanation, it is assumed that the input audio signal is 300 Hz to 3000 Hz and the carrier frequency is 3500 Hz. In principle, this method is an SSB (Single Sideband) communication method. On the transmission side, the input audio signal (300 Hz to 3000 Hz) is band-limited, and amplitude modulation is performed with a carrier (3500 Hz). This is expressed in the following formula.
2sinω _c t × sinω _s t = −cos (ω _c + ω _s ) t + cos (ω _c −ω _s ) t
Where ω _c = 2πf _c (f _c : carrier frequency)
ω _s = 2πf _s (f _s : input audio signal frequency)

  By this modulation, the spectrum of the modulated wave becomes a DSB (Double Sideband) as shown in FIG. 5, and if only the LSB (Lower Sideband) component is extracted using a low-pass filter, the spectrum as shown in FIG. 6 is inverted. Audio signal is obtained.

  On the other hand, similarly to the transmission side, the reception side performs amplitude modulation again with a carrier (3500 Hz, which is the same as the reception side). Due to this modulation, the spectrum becomes a DSB as shown in FIG. 7, and if only the LSB component is extracted using a low-pass filter, an audio signal whose spectrum is inverted again as shown in FIG. Audio signal equivalent to the input audio signal).

Japanese Utility Model Publication No. 60-127059

  In radio communication equipment, low frequency signals (sub audio signals) that are inaudible or difficult to hear for human ears, such as CTCSS (Continuous Tone Controlled Squelch System), DCS (Digital Code Squelch), LTR (Logic Trunked Radio) Is superimposed on the audio signal and transmitted to realize a squelch or trunking system. There is no problem if the band of the sub audio signal and the band of the audio signal do not overlap in the spectrum, but in general, the audio signal often uses a band of about 300 Hz to 3000 Hz. Since the frequency band extends up to 300 Hz or more, when such a sub audio signal is used, the sub audio signal band and the audio signal band may overlap as shown in FIG. In this case, the low-frequency sound of the sub audio signal is output from the receiving speaker.

  In normal communication (when frequency reversal scramble is not applied), this low frequency sound is of little quality to humans, but when sub-audio signals are superimposed with frequency reversal scramble, the receiving side If the scramble is canceled without removing the audio signal component with the low-pass filter, the frequency-inverted sub audio signal component inevitably overlaps around 3000 Hz of the audio signal band as shown on the right side of FIG. . In this case, this high frequency sound is output from the receiving speaker in addition to the sound. However, compared with the above-described low frequency sound, this high frequency sound is very annoying for humans, so it is desirable to remove it.

  The present invention has been made in view of the above points.Even if a sub-audio signal that uses frequency reversal scrambling and at the same time uses a sub-audio signal that overlaps a part of the band of the audio signal is used, the loudspeaker may be disturbing high frequency noise (frequency reversal An object of the present invention is to provide a wireless communication device that can eliminate the unpleasant feeling because the sub-audio signal is not heard.

  The wireless communication device of the present invention is a wireless communication device capable of simultaneously using frequency reversal scramble and sub-audio signals, and a reversal descrambler for returning the frequency-reversed audio signal at the receiving side, So that the cut-off frequency of the low-pass filter used in is passed through the entire band of the restored audio signal, or the partial band where the frequency-inverted sub audio signal overlaps is cut out of the entire band Cut-off frequency switching means for switching.

  As a more specific form, the cut-off frequency switching means manually switches the cut-off frequency of the low-pass filter. Further, the cut-off frequency switching means switches a plurality of cut-off frequencies when the cut-off frequency of the low-pass filter is cut so as to cut a part of the entire band of the audio signal where the frequency-inverted sub audio signal overlaps. Can be set by switching to Further, the cutoff frequency switching means has detection means for detecting the presence or absence of a sub audio signal, and automatically switches the cutoff frequency of the low-pass filter depending on the presence or absence of the sub audio signal. Furthermore, the cut-off frequency switching means switches the cut-off frequency of the low-pass filter by changing a filter coefficient held in a memory inside the digital signal processor (DSP).

  Furthermore, another wireless communication device of the present invention is a wireless communication device capable of simultaneously using frequency reversal scramble and sub audio signal, and a reversal descrambler for returning the frequency-reversed audio signal at the receiving side, Cut-off frequency for setting the cut-off frequency of the low-pass filter used for this inverting descrambler to cut the partial band where the frequency-inverted sub audio signal overlaps among the entire band of the restored audio signal And setting means.

  According to the wireless communication apparatus of the present invention as described above, frequency-inverted scramble is used, and a frequency-inverted audio signal is received even when a sub-audio signal that overlaps with a part of the band of the audio signal is used By switching the cut-off frequency of the low-pass filter used for the inverting descrambler on the side, or by presetting, the high frequency noise (frequency-inverted sub audio signal) is cut off from the speaker. High frequency noise can be prevented from being heard, and discomfort can be eliminated.

  Embodiments of a wireless communication device according to the present invention will be described below in detail with reference to the drawings. However, the components, combinations, shapes, arrangements, and the like described in the embodiments are merely examples for explanation.

  FIG. 1 is a block diagram showing an analog modulation wireless communication apparatus as an embodiment of the wireless communication apparatus of the present invention. This wireless communication device includes a microphone 11, an AD converter 12, a digital signal processor (hereinafter referred to as DSP) 13, a DA converter 14, a modulation circuit 15, an antenna 16, a demodulation circuit 17, and an AD converter 18. And a DA converter 19 and a speaker 20. The DSP 13 includes an inverting scrambler 131, a sub audio signal generator 132, a switch 133, an adder 134, and an inverting descrambler 135.

  The microphone 11 converts the sender's voice into an analog voice signal. The AD converter 12 converts the analog audio signal output from the microphone 11 into a digital audio signal. An inversion scrambler 131 in the DSP 13 performs frequency inversion on the digital audio signal output from the AD converter 12. The sub audio signal generator 132 in the DSP 13 generates a sub audio signal that overlaps a partial band of the audio signal. The switch 133 in the DSP 13 is turned on when using the sub audio signal, and supplies the sub audio signal generated by the sub audio signal generator 132 to the adder 134. The adder 134 in the DSP 13 is supplied with a frequency-inverted audio signal from the inversion scrambler 131 and a sub-audio signal is supplied from the sub-audio signal generator 132 via the switch 133. Then, the sub audio signal is added to the audio signal (hereinafter, it is assumed that the sub audio signal is added). The DA converter 14 converts the frequency-inverted audio signal and sub audio signal (digital) output from the adder 134 into an analog signal. The modulation circuit 15 converts the frequency-inverted audio signal and sub audio signal converted into analog signals by the DA converter 14 into an RF frequency and transmits the RF signal from the antenna 16 as radio waves.

  The demodulation circuit 17 demodulates the audio signal and the sub audio signal that are frequency-inverted from the RF signal received by the antenna 16. The AD converter 18 converts the frequency-inverted audio signal and sub audio signal output from the demodulation circuit 17 into a digital signal. The inversion descrambler 135 in the DSP 13 inverts the frequency of the frequency-inverted audio signal output from the AD converter 18 again to return the frequency characteristics to the original state. The DA converter 19 converts the audio signal whose frequency characteristics have been restored to the original state by the inversion descrambler 135 into an analog signal and reproduces it by the speaker 20.

  In the wireless communication apparatus configured as described above, when transmission is performed, an analog audio signal from the microphone 11 is converted into a digital audio signal by the AD converter 12, and frequency inversion is performed by the inversion scrambler 131 inside the DSP 13. When the sub audio signal is used at the same time, the sub audio signal generated by the sub audio signal generator 132 is added to the audio signal whose frequency is inverted by the adder 134 and then converted to an analog signal by the DA converter 14. Then, the signal is converted into an RF frequency by the modulation circuit 15 and transmitted from the antenna 16 as a radio wave.

  On the other hand, when reception is performed, the RF signal received by the antenna 16 is demodulated by the demodulation circuit 17, the audio signal and the sub audio signal whose frequency is inverted are taken out, and converted into a digital signal by the AD converter 18. The sub audio signal is used in the DSP 13 to realize a squelch or trunking system. On the other hand, the frequency-inverted audio signal is frequency-inverted again by the inversion descrambler 135 inside the DSP 13 to restore the frequency characteristics to the original state, converted to an analog signal by the DA converter 19 and reproduced as audio from the speaker 20. Let

  Although not described, the exchange of signals between the DSP 13 and the AD converters 12 and 18 and between the DSP 13 and the DA converters 14 and 19 is performed in a format that can be processed by the DSP 13. The inversion scrambler 131, the inversion descrambler 135, and the sub audio signal generator 132 are realized by software inside the DSP 13. Furthermore, since both the inverting scrambler 131 and the inverting descrambler 135 have the same structure, they are described separately for the sake of explanation here, but if either one is used, it can be used for both transmission and reception. There is no problem.

  FIG. 2 is a diagram showing a specific configuration of the inversion descrambler 135 of the wireless communication device. The inversion descrambler 135 includes a carrier generator 31, a modulator 32, and a low pass filter 33. As described above, the inversion descrambler 135 is a frequency inverter for restoring the frequency characteristics of the audio signal on the receiving side, and the carrier generated by the carrier generator 31 is inverted in frequency. The DSB shown in FIG. 7 is generated by amplitude modulation by the modulator 32 using the obtained audio signal, and the LSB component of the DSB is extracted by the low-pass filter 33, so that the audio signal whose frequency characteristics are restored is output. Can get to. At this time, if the sub audio signal is added to the input frequency-inverted audio signal, the frequency is inverted by the inversion descrambler 135 to the high frequency side of the output audio signal after restoring the frequency characteristics. As described in the prior art, the sub audio signals overlap and can be heard as annoying high frequency noise from the speaker 20 of FIG.

  Therefore, in the present invention, the cutoff frequency of the low-pass filter 33 of the inverting descrambler 135 is changed according to the presence or absence of the sub audio signal. That is, when the sub audio signal is not used, the speaker 20 is allowed to pass through the entire band (300 Hz to 3000 Hz) of the audio signal by setting the cutoff frequency of the low pass filter 33 of the inverting descrambler 135 to around 3000 Hz. So that you can listen to sound with good sound quality. On the other hand, when the sub audio signal is used, the high frequency side of the audio signal is slightly cut by setting the cutoff frequency of the low pass filter 33 of the inverting descrambler 135 to, for example, around 2800 Hz as shown in FIG. However, the frequency-inverted sub audio signal present in this portion is cut to suppress annoying high frequency noise. At this time, the more the high frequency side of the audio signal is cut, the smaller the high frequency noise can be reduced. However, in exchange for this, the sound quality deteriorates greatly. Can not expect much. Therefore, when the sub audio signal is used, the cut-off frequency of the low-pass filter 33 of the inverting descrambler 135 can be set by switching to a plurality of frequencies. Judgment is based on the degree of deterioration and the amount of noise suppression.

  The cutoff frequency of the low-pass filter 33 can be changed by changing a filter coefficient held in a memory (not shown) inside the DSP 13. Therefore, by switching the filter coefficient manually or automatically, the cut-off frequency of the low-pass filter 33 is switched as described above to realize the above operation.

  As a method for manually switching the filter coefficient (that is, the cut-off frequency of the low-pass filter 33) (cut-off frequency switching means), a switch is provided on the panel surface of the wireless communication device, and the user operates this switch. When the user operates the switch, the switch signal is supplied to the DSP 13, and the filter coefficient held in the memory changes.

  As a method for automatically switching the filter coefficient (that is, the cut-off frequency of the low-pass filter 33) (detection frequency switching means), a detection means for detecting whether or not a sub audio signal is present in the received signal is provided in the DSP 13. The filter coefficient is switched depending on whether or not the sub audio signal is detected by the detecting means. As the detection means, a sub audio signal detection means for realizing a squelch or trunking system can be used.

  If the cut-off frequency of the low-pass filter 33 is switched in this way, the sound can be heard with the original good sound quality when the sub audio signal is not used, and it is annoying when the sub audio signal is used. High frequency noise can be suppressed, and discomfort can be eliminated. Further, since the cut-off frequency of the low-pass filter 33 can be switched by changing the filter coefficient held in the memory inside the DSP 13, it is not necessary to add a new part to mount this function.

  The above is a case where the cut-off frequency of the low pass filter 33 of the inverting descrambler 135 is switched according to the presence or absence of the sub audio signal, but when the sub audio signal is determined to be used in the system, By changing the filter coefficient in advance, the cut-off frequency of the low-pass filter 33 can be set as the cut-off frequency for cutting the sub audio signal. In this case, the means provided in the present invention is not a cut-off frequency switching means but a cut-off frequency setting means.

1 is a block diagram showing an analog modulation wireless communication apparatus as an embodiment of a wireless communication apparatus of the present invention. The specific block diagram of the inversion descrambler used for the radio | wireless communication apparatus of FIG. The wave form diagram which shows the switching state of the cut-off frequency of the low-pass filter used for the inversion descrambler of FIG. The wave form diagram which shows the outline of the frequency inversion scramble which is a secret communication method. FIG. 6 is a waveform diagram for explaining the principle of frequency reversal scrambling, and shows a result of amplitude modulation performed on the transmission side. The wave form diagram which extracted the LSB component from DSB of FIG. The wave form diagram which shows the result of having performed amplitude modulation again on the receiving side. FIG. 8 is a waveform diagram obtained by extracting an LSB component from the DSB of FIG. 7. The wave form diagram which shows the case where the zone | band of a sub audio signal has overlapped with the zone | band of the audio | voice signal. FIG. 6 is a waveform diagram showing a case where the frequency-inverted sub audio signal component overlaps around 3000 Hz of the audio signal band when the frequency characteristic of the audio signal is restored.

Explanation of symbols

13 Digital signal processor (DSP)
131 Inversion Scrambler 132 Sub Audio Signal Generator 134 Adder 135 Inversion Descrambler 31 Carrier Generator 32 Modulator 33 Low Pass Filter

Claims (6)

In a wireless communication device that can use frequency reversal scrambling and a sub audio signal simultaneously,
An inversion descrambler for returning the frequency-inverted audio signal on the receiving side,
The cut-off frequency of the low-pass filter used in this inverting descrambler is set so that the entire frequency band of the audio signal that has been restored is allowed to pass, or the sub-audio signal that is frequency-inverted of all the bands overlaps. Cut-off frequency switching means for switching to cut,
A wireless communication device comprising:   The wireless communication device according to claim 1, wherein the cutoff frequency switching means manually switches a cutoff frequency of the low-pass filter.   The cut-off frequency switching means switches the cut-off frequency of the low-pass filter to a plurality of cut-off frequencies so as to cut a part of the entire band of the audio signal where the frequency-inverted sub audio signal overlaps. The wireless communication device according to claim 2, wherein the wireless communication device can be set.   The cut-off frequency switching means includes detection means for detecting the presence or absence of a sub audio signal, and automatically switches the cut-off frequency of the low-pass filter depending on the presence or absence of the sub audio signal. Wireless communication equipment.   5. The cutoff frequency of the low-pass filter according to claim 1, wherein the cutoff frequency switching means switches a cutoff frequency of the low-pass filter by changing a filter coefficient held in a memory inside a digital signal processor (DSP). The wireless communication device described in 1. In a wireless communication device that can use frequency reversal scrambling and a sub audio signal simultaneously,
An inversion descrambler for returning the frequency-inverted audio signal on the receiving side,
Cut-off frequency for setting the cut-off frequency of the low-pass filter used for this inverting descrambler to cut the partial band where the frequency-inverted sub audio signal overlaps among the entire band of the restored audio signal Setting means;
A wireless communication device comprising:

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