JP2003005800A - Voice signal processing module and voice communication equipment provided with this module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the speaking quality and the transmission efficiency by suppressing echo by a relatively simple processing and reducing the level change of background noise. SOLUTION: A transmission signal processing part 80 and a reception signal processing part 70A are provided with memories 82 and 72 for storage of alternative no-sound compressed data and changeover switches 88, 77a, and 77b for these memories, respectively. When double talk is detected, a signal processing control part 100 discriminates priority of reception or transmission on the basis of the speaking state in the preceding frame. In the case of priority of reception, the changeover switch 88 is switched to transmit no-sound compressed data stored in the memory 82 instead of encoded voice data. In the case of priority of transmission, changeover switches 77a and 77b are switched to generate false background noise on the basis of no-sound compressed data stored in the memory 72, and this false background noise is outputted instead of a received and reproduced voice signal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voice communication device having a hands-free call function such as a digital car telephone device, and a voice signal processing module used in this voice communication device.

[0002]

2. Description of the Related Art In recent years, many digital signal processing techniques have been used in the computer and communication fields. Digital signal processing is a general-purpose technology, especially in the field of voice processing and image processing, because it can easily realize complex processing such as arbitrary change of characteristic constants and adaptive processing that were difficult with analog signal processing. ing.

For example, in a voice communication device having a hands-free call function such as an automobile telephone, during a hands-free call, the received voice output from a speaker wraps around to a microphone and the received voice is sent to the voice communication device of the other party. May cause acoustic echo. Therefore, in order to cancel the wraparound of the received voice and maintain the communication quality, an echo canceller is generally used. The echo canceller removes the echo component by generating a pseudo echo signal by digital signal processing and subtracting the pseudo echo signal from the signal input from the microphone. However, since the echo canceller requires a large amount of signal processing amount and a large memory capacity, it is not suitable for a small voice communication device such as a mobile phone.

On the other hand, a voice switch is known as a technique for simply suppressing acoustic echo. FIG. 5 is a block diagram showing an example of an audio signal processing device employing a voice switch.

In the figure, the received voice data is
First, voice decoding processing is performed by the voice decoder (DEC) 101 to obtain a digital received signal Xs. The digital reception signal Xs is received by the reception signal attenuator (R-LOS).
S) 102 is input to the D / A converter 103, where it is converted into an analog signal and then supplied to the speaker 104 via a receiver amplifier (not shown) to output a loud sound.

On the other hand, the voice of the speaker is converted into a voice signal by the microphone 105 and then input to the A / D converter 106 via a voice amplifier (not shown). It is converted into the signal Ys. The digital transmission signal Ys is transmitted by the transmission signal attenuator (TL).
It is input to a speech coder (ENC) 108 via the OSS 107, where it is subjected to speech coding processing, compressed, and then provided for transmission.

By the way, this audio signal processing apparatus has a double-talk determining section (D-DEC) 109 and an attenuation control section (L).
OSSCONT) 110. In the double talk determination unit 109, the signal power of the digital received signal Xs output from the voice decoder 101 and the A / D converter 1
The signal power of the digital transmission signal Ys output from 06 is monitored, and it is determined whether the transmission and the reception are performed at the same time or the state in which only the transmission or the reception is performed.

[0008] The attenuation control unit 110, based on the determination result of the double talk determination unit 109, each signal attenuator 10 described above.
A predetermined amount of attenuation (loss) is set for 2,107. For example, when the double talk determination unit 109 determines that only the signal power of the digital reception signal Xs exceeds a certain threshold value, it is determined that only the reception voice has a voice and no transmission voice. . Then, in this case, the attenuation control unit 110 sets an attenuation amount in the transmission signal attenuator 107 in order to reduce the signal level of the digital transmission signal Ys. On the contrary, when the double talk determining unit 109 determines that only the transmitting side has voice, the amount of attenuation is set in the reception signal attenuator 102 to reduce the signal power of the digital reception signal Xs. In addition, when it is determined that there is voice in both transmission and reception, that is, when double talk is detected, the attenuation amount that is being set is maintained, or the attenuation amounts in both signal attenuators 102 and 107 are maintained. Is set. Incidentally, the power values of the digital reception signal Xs and the digital transmission signal Ys can be replaced by peak values.

Thus, by setting the attenuation amount in the reception signal path or the transmission signal path in which no voice exists, the speaker 10
It is possible to suppress the acoustic echo component generated by the wraparound from 4 to the microphone 105.

[0010]

However, in the conventional voice signal processing device having such a voice switch, the power value or peak value of the digital reception signal Xs and the digital transmission signal Ys is controlled in order to control the amount of attenuation. Needs to be calculated. For this reason, the number of components increases when it is realized by hardware, and the processing amount of the processor increases when it is realized by software, resulting in an increase in power consumption. Further, since the attenuation amount is set for either transmission or reception, depending on the value, the level of background noise may change between when there is no voice signal and when there is no voice signal, which gives a feeling of strangeness to the call.

Further, if the amount of attenuation is small, the acoustic echo cannot be suppressed sufficiently, which may cause a problem in the presence determination process. For example, in a voice communication device having a function of performing a silent compression by providing a voice detector in the preceding stage of the voice encoder 108 and operating the voice compressor based on the detection result of the voice detector, the voice detector is The residual echo may be detected as voiced, or double-talk voice, which is not so important for a call, may be determined as voiced, resulting in a decrease in silence compression efficiency.

The present invention has been made in view of the above circumstances. An object of the present invention is to suppress echo by a relatively simple process and further reduce the level change of background noise to improve speech quality. Another object of the present invention is to provide an audio signal processing module which shortens the transmission period of unnecessary audio data and improves the transmission efficiency, and an audio communication device equipped with this module.

[0013]

In order to achieve the above object, a voice signal processing module according to the present invention comprises a transmission signal processing unit, a reception signal processing unit, and a signal processing control unit. Then, the transmission signal processing unit identifies the voiced section and the silence section of the input transmission signal, generates encoded voice data in the voiced section, and generates silence compressed data in the silence section. Then, the encoded voice data and the silence compression data are multiplexed together with the type information indicating the type thereof to generate multiplexed transmission data for transmission.
On the other hand, the reception signal processing unit separates the encoded voice data and the silence compression data from the multiplexed reception data based on the type information included in the input multiplexed reception data, and separates the separated encoded data. The voice data and the silence compression data are respectively decoded to reproduce and output the voiced section and the silence section of the received signal.

Further, the signal processing control unit detects a double talk section of the transmission signal and the reception signal, and substitutes silence compression which is prepared in advance in the detected double talk section in place of the encoded voice data. It is configured such that data is transmitted or an alternative silent section prepared in advance is output instead of the sound section of the received signal reproduced by the voice decoding means.

The process of replacing the encoded voice data in the double talk detection section with the alternative silence compression data or the replacement of the voiced section of the received signal with the alternative silence section is performed in the past frame period of the transmission signal and the reception signal. According to the type in, it is determined whether the transmission priority or the reception priority, when the reception priority is determined, the alternative silent compressed data is output in place of the encoded voice data, and when the transmission priority is determined, This can be realized by outputting an alternative silent section instead of the sound section of the reception signal.

Therefore, according to the present invention, the following operational effects are exhibited. That is, in the voice switch, the loss is inserted in the transmission path or the reception path on the silent side, but instead, the silent data is transmitted and received. For this reason, it is possible to eliminate the level change of the background noise between when there is no voice signal and when there is no voice signal during the receiving period, which makes it possible to maintain a natural feeling of the call.

Moreover, when double talk is detected, silent data is transmitted or output in place of the transmitted voice data or the received voice data in that section. Therefore, even if an acoustic echo occurs during the reception period, this acoustic echo is replaced with silent data, and this silent data is transmitted to the call partner device. Further, even if the acoustic echo returns from the other party's device as the received voice during the transmission period, this acoustic echo is replaced with silent data, and this silent data is received and output. For this reason,
The acoustic echo is suppressed and a high quality call can be realized.

Further, since the acoustic echo is replaced with the silent data, the acoustic echo is not detected as voiced and is not transmitted as the encoded voice data, but the silent compressed data is transmitted in this section. Become. Therefore, voice communication with high compression efficiency can be realized.

The present invention also provides a means for updating the alternative silence compression data to the silence compression data generated by the silence encoding means in the silence section of the transmission signal, and an alternative for reproducing the alternative silence section. Silent compressed data,
It is also characterized in that it further comprises means for updating the silence compression data input to the silence decoding means in the silence section of the received signal.

With this configuration, the substitute silence compression data for transmission and the reception are replaced with the silence compression data actually transmitted and received, respectively, regularly or irregularly. It is possible to reduce the difference between the silent section reproduced in the above and the silent section of the actual call, and thereby to keep the natural feeling of the call even higher.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a first embodiment of a voice communication apparatus equipped with a voice signal processing module according to the present invention, and illustrates the configuration of a CDMA mobile communication terminal.

In the figure, a radio signal transmitted from a base station (not shown) is received by an antenna 1 and then input to a receiving circuit (RX) 3 via an antenna duplexer 2 (DUP). In the reception circuit 3, the radio signal is mixed with the reception local oscillation signal output from the frequency synthesizer (SYN) 4 and frequency-converted into a reception intermediate frequency signal. The frequency of the reception local oscillation signal generated from the frequency synthesizer 4 is specified by the oscillation control signal SYC output from the control unit 5.

The received intermediate frequency signal is input to the CDMA signal processing section 6. In the CDMA signal processing unit 6, the reception intermediate frequency signal is first despread by the spreading code assigned to the reception channel, and then, for example, QPSK (Quad
riphase Phase Shift Keying) Demodulated by the demodulation method corresponding to the modulation method. The CDMA signal processing unit 6 reproduces demodulated data in a predetermined format according to the data rate.

The reproduced demodulated data is subjected to received audio signal processing such as audio decoding processing, voice switch processing and PCM decoding processing by an audio signal processing module 7 described later. Then, the analog reception signal obtained by this signal processing is input to the speaker 10 via the reception amplifier 9, and is output from the speaker 10 as a reception voice.

On the other hand, the voice transmitted by the speaker is the microphone 1
After being converted into an analog transmission voice signal by 1, the transmission amplifier 18 amplifies the signal to a predetermined signal level and inputs it to the voice signal processing module 7. Audio signal processing module 7
Then, the analog transmission voice signal is subjected to transmission voice signal processing such as PCM encoding processing, voice switch processing and voice encoding processing, and the transmission voice data obtained by these processings is processed by the CDMA signal processing unit 6 Entered in.

In the CDMA signal processing unit 6, the carrier signal is QPSK-modulated based on the transmission data output from the voice signal processing module 7, and the spread carrier allocated to each transmission channel is applied to the modulated carrier signal. Spread spectrum processing is performed by the code. Then, the spread coded transmission carrier signal is input to the transmission circuit (TX) 5.

In the transmission circuit 5, the spread coded transmission carrier signal is first combined with the transmission local oscillation signal generated from the frequency synthesizer 14 and frequency-converted into a radio frequency signal. Then, in this radio frequency signal, only the effective portion of the radio frequency signal is power-amplified based on the transmission data rate notified by the control unit 5, and the amplified transmission radio frequency signal is passed through the antenna duplexer 2. The signal is supplied to the antenna 1 and is transmitted from the antenna 1 to the connected base station.

The input unit 14 is provided with a key group such as a dial key, a call key, a power key, an end key, a volume control key, and a mode designation key. Further, the display unit 15 is provided with an LCD display and an LED lamp. L
The CD display displays the telephone number of the terminal of the communication partner, the operating state of the terminal itself, and a transmission / reception message. The LED lamp is also used to display the discharge state of the battery 71.

Further, the storage unit 13 stores a telephone directory and received messages. In addition, the storage unit 13 also has a function of recording and receiving the transmitted / received voice data when the answering mode is set. Reference numeral 17 denotes a power supply circuit, which generates a predetermined operating power supply voltage Vcc based on the output of the battery 16 and supplies it to each circuit unit.

By the way, the audio signal processing module 7
Is constructed as follows. FIG. 2 is a functional block diagram showing the configuration. The voice signal processing module 7 includes a reception signal processing unit 70A, a transmission signal processing unit 80A, and a signal processing control unit 90.

First, the transmission signal processing section 80A is constructed as follows. That is, the transmission signal output from the transmission amplifier 18 is converted into a digital signal by the A / D converter 81 and then input to the voice detector (VAD) 85. The voice detector 85 detects the voice section of the input digital transmission signal and, based on the detection result, the changeover switch 8
7a is switched and controlled. By this switching control, the signal in the voiced section of the digital transmission signal, that is, the digital voice signal is supplied to the voice encoder (ENC) 83, while the signal in the silent section of the digital transmission signal, that is, the digital background. Silence compressor for noise signals (DTX-ENC)
Supply to 84.

The voice encoder 83 encodes the supplied digital voice signal according to a predetermined voice encoding method to generate encoded voice data. The silence compressor 84 encodes the supplied digital background noise signal by a predetermined encoding compression method and converts it into silence data. A voice encoding method is, for example, AMR (Adaptive MultiRa).
te) The coding scheme is used. Further, as the silence compression method, a method of intermittently transmitting the silence compression data is used. In this method, for example, when there is no sound continuously for a long time, the silent compressed data is not transmitted for each frame, which is the unit time of the audio encoding process, and the data is sent for every several frames.
This is a method of transmitting the silence compressed data only once and not transmitting the data in other periods.

The encoded voice data generated by the voice encoder 83 and the silence compressed data generated by the silence compressor 84 are input to the multiplexing unit (MUX) 86 via the changeover switch 87b. The multiplexing unit 86 generates information indicating the type of transmission data, that is, information indicating sound, silence or no data, based on the detection result of the sound detector 85, and information tx- indicating this transmission data type. Insert type in the header. Then, the encoded voice data input from the voice encoder 83, the silence compressed data input from the silence compressor 84, and the header are multiplexed to generate transmission data TD. CDM
Output to the A signal processing unit 6. The changeover switch 8
7b is switched and controlled by the information tx-type indicating the transmission data type.

Further, the transmission signal processing unit 80A includes a memory (MEM) 82 for storing silent data and a changeover switch 8.
8 and. The memory 82 is composed of, for example, a RAM and stores alternative silent compressed data for reproducing background noise. Then, this alternative silence compression data is read according to the transmission path control signal e-cont generated from the signal processing control unit 100 described later.

The changeover switch 88 replaces the substitute silence compression data read from the memory 82 with the coded voice data generated by the voice encoder 83, and the multiplexer 8 is used.
6, and the switching operation thereof is controlled by the transmission path control signal e-cont generated from the signal processing control unit 100.

The memory 82 is in the write mode during the output period of the silence compression data according to the information tx-type indicating the transmission data type output from the multiplexing unit 86, and is output from the silence compressor 84 during this period. The alternative silent compressed data being stored is updated with the silent compressed data.

Next, the reception signal processing section 70A is constructed as follows. That is, the reception data RD output from the CDMA signal processing unit 6 is input to the separation unit (DEMUX) 71. The separating unit 71 extracts a header from the input received data, and separates the encoded voice data and the silence compression data based on the information rx-type indicating the received data type included in the header. Then, by switching the changeover switch 76a according to the information rx-type indicating the received data type, the coded voice data and the silence compressed data are converted into the voice decoder (DEC) 73 and the pseudo noise generator (DTX-DEC) 74, respectively. Supply to.

The voice decoder 73 encodes the encoded voice data supplied from the separating unit 71 to reproduce a digital voice signal. The pseudo noise generator 74 includes the separating unit 7
A digital pseudo noise signal is reproduced on the basis of the silence compression data supplied from 1. The digital voice signal and the digital pseudo noise signal reproduced by the voice decoder 73 and the pseudo noise generator 74 are D / V-switched via the changeover switch 76b which is controlled to be switched by the information rx-type representing the received data type. It is input to the A converter 75.
The D / A converter 75 reproduces an analog voice signal and a pseudo noise signal from the input digital voice signal and digital pseudo noise signal, and sends the reproduced voice signal and pseudo noise signal to the reception amplifier 9 as a reception signal. Output.

Further, the reception signal processing section 70A includes a memory (MEM) 72 for storing silent data and a changeover switch 7.
7a and 77b. The memory 72 is, for example, RA
M, which stores the alternative silence compression data used to create the background noise. Then, this alternative silence compression data is read according to the reception path control signal d-cont generated from the signal processing control unit 100 described later.

The changeover switches 77a and 77b are generated by the pseudo noise generator 74 based on the alternative silence compression data read from the memory 72 instead of the digital voice signal reproduced by the voice decoder 73. The digital pseudo noise signal is supplied to the D / A converter 75, and its switching operation is controlled by a reception path control signal d-cont generated from a signal processing control unit 100 described later.

It should be noted that the memory 72 includes the separating unit 71.
In accordance with the information rx-type indicating the received data type output from the writing mode, the writing mode is set during the reception period of the silent compressed data, and the silent compressed data output from the separating unit 71 during this period causes the alternative silent compressed data being stored to be stored. Update.

The signal processing control section 100 outputs information tx-type indicating the transmission data type output from the multiplexing section 86 of the transmission signal processing section 80A and the separation section 71 of the reception signal processing section 70A. Information indicating the received data type
rx-type and tx-type, respectively
The presence or absence of double talk is determined based on rx-type. Then, based on the determination result, the transmission path control signal e-cont and the reception path control signal d-cont for transmitting or reproducing and outputting the alternative silent compressed data are generated in the double talk section.

Next, the operation of the audio signal processing module configured as described above will be described. It is assumed that a call is made at the terminal, whereby the terminal and the communication partner terminal are connected via a wireless link and a call is started. Then, during the call, the audio signal processing module 7 performs the following processing operation.

That is, first, in the transmission signal processing unit 80A, when the transmission signal is input, the voice detector 85 detects a voice section, and the changeover switch 87 is detected based on the detection result.
a switches. As a result, the digital transmitted voice signal is input to the voice encoder 83 in the voiced section, and the digital background noise signal is input to the silence compressor 84 in the silent section, and is encoded.

The detection result of the sound detector 85 is input to the multiplexing unit 86, and the multiplexing unit 86 generates information tx-type indicating the type of transmission data based on the detection result.
For example, the information is set such that the transmission period of voiced data is “2”, the transmission period of silent compressed data is “1”, and the transmission data does not exist, “0”.

When the information tx-type indicating the transmission data type is output from the multiplexing unit 86, the changeover switch 87b is switched according to this information. As a result, the encoded voice data generated by the voice encoder 83 and the silence compression data generated by the silence compressor 84 are input to the multiplexing unit 86, and in the multiplexing unit 86, the encoded voice data and the silence compression are performed. The data is multiplexed and output to the CDMA signal processing unit 6. At this time, the multiplexing unit 86 creates a header including the information tx-type indicating the transmission data type, and this header is also multiplexed with the encoded voice data and the silence compression data.

On the other hand, when the reception data RD sent from the communication partner device is input to the voice signal processing module 7, in the reception signal processing unit 70A, the separation unit 71 first receives the reception data type included in the header of the reception data RD. Based on the information rx-type that represents, the encoded voice data and the silence compression data are separated.

Information rx-typ representing the received data type
For example, e is the same as the information tx-type indicating the above-mentioned transmission data type, such as “2” during the reception period of voiced data, “1” during the reception period of silence compression data, and “0” during the period when no reception data exists Is set to.

Information rx representing such a received data type
The changeover switches 76a and 76b are switched between the voice decoder 73 and the pseudo noise generator 74, respectively, depending on the -type. Therefore, the coded voice data and the silence compression data are distributed by the changeover switch 76a and are input to the voice decoder 73 and the pseudo noise generator 74, whereby the voice decoder 73 and the pseudo noise generator 74 digitally. The voice signal and the pseudo noise signal are reproduced. Then, the reproduced digital voice signal and pseudo noise signal are converted into an analog voice signal and pseudo noise signal by the D / A converter 75, and output from the speaker 10 via the reception amplifier 9.

Now, during the above transmission / reception signal processing, the signal processing control section 100 carries out the following control. FIG. 3 is a diagram showing the control contents of the signal processing control unit 100.

First, information rx-typ representing the received data type
Information tx-type in which e is "2" and represents the transmission data type
When is “0 or 1,” the signal processing control unit 100 determines that the terminal is in the listening state. Then, the signal processing control unit 100 sets both the reception path control signal d-cont and the transmission path control signal e-cont to "0". At this time, d-co
nt = 0 is a signal for outputting the received encoded voice data as it is. Therefore, at this time, in the reception signal processing unit 70A, the information rx-type indicating the reception data type is received.
= 2, both the changeover switches 76a and 76b are switched to the decoder 73 side, and the reception path control signal d-
When cont = 0, the changeover switch 77b is switched to the voice decoder 73 side. Therefore, the received encoded voice data is decoded by the voice decoder 73, converted into an analog signal by the D / A converter 75, and directly output from the speaker 10 as a received voice.

In the transmission signal processing unit 80A, since the information tx-type indicating the transmission data type is "0 or 1", both the changeover switches 87a and 87b are switched to the silent compressor 84 side. Therefore, the background noise input from the microphone 11 is encoded by the silence compressor 84 to become silence compressed data, and this silence compressed data is transmitted from the multiplexing unit 86 to C.
It is output to the DMA signal processing unit 6.

At this time, the memory 82 is in the write mode while the information tx-type indicating the transmission data type is "1". Therefore, the silence compression data stored in the memory 82 is rewritten with the silence compression data generated by the silence compressor 84. That is, the silence compression data in the memory 82 is constantly updated.

Next, information rx-typ representing the received data type
Information t in which e is "0 or 1" and represents the transmission data type
When the x-type is “2”, the signal processing control unit 100 determines that the terminal is in the transmitting state. Also in this case, the reception path control signal d-cont and the transmission path control signal e-cont
Are both set to "0". At this time, e-cont = 0 is a signal for transmitting the encoded voice data as it is.
Therefore, the transmission signal processing unit 80A changes the switch 87 according to the information tx-type = 2 indicating the transmission data type.
Both a and 87b are switched to the voice encoder 83 side, and the changeover switch 88 is also switched to the voice encoder 83 side. Therefore, the digital audio signal output from the A / D converter 81 is encoded by the audio encoder 83 and becomes encoded audio data. Then, the encoded voice data is directly input to the multiplexing unit 86, where the header is multiplexed and then output to the CDMA signal processing unit 6.

Further, in the reception signal processing unit 70A, since the information rx-type indicating the received data type is "0 or 1", both the changeover switches 76a and 76b are switched to the pseudo noise generator 74 side. Also, the transmission path control signal e-cont
Is “0”, the changeover switches 77a and 77b are switched to the separation unit 71 and the changeover switch 76b side, respectively. Therefore, the received silence compression data is separated by the separation unit 7.
1 is input to the pseudo noise generator 74, where pseudo background noise is generated and the pseudo background noise is converted into D / A converter 75.
Is converted into an analog signal and output from the speaker 10.

At this time, the memory 72 is in the write mode while the information rx-type indicating the received data type is "1". Therefore, the silent compressed data stored in the memory 72 is rewritten with the received silent compressed data. That is, the silence compression data in the memory 72 is constantly updated.

Further, information rx-t indicating the received data type
When both ype and the information tx-type indicating the transmission data type are “0 or 1”, the signal processing control unit 100 determines that both transmission and reception are in a silent state. Then, the reception path control signal d-cont and the transmission path control signal e-cont are both set to "0". Therefore, in the reception signal processing unit 70A, since the information rx-type indicating the reception data type is "0 or 1", both the changeover switches 76a and 76b are switched to the pseudo noise generator 74 side. Further, since the transmission path control signal e-cont is “0”, the changeover switch 77
a and 77b are the separating portion 71 and the changeover switch 7, respectively.
Switch to 6b side. Therefore, the received silence compression data is input from the separation unit 71 to the pseudo noise generator 74,
Here, pseudo background noise is generated, and this pseudo background noise is D
Speaker 1 converted into an analog signal by the A / A converter 75
It is output from 0.

In the transmission signal processing unit 80A, since the information tx-type indicating the transmission data type is "0 or 1", both the changeover switches 87a and 87b are switched to the silent compressor 84 side. Therefore, the background noise input from the microphone 11 is encoded by the silence compressor 84 to become silence compressed data, and this silence compressed data is transmitted from the multiplexing unit 86 to C.
It is output to the DMA signal processing unit 6.

Also at this time, the memories 72 and 82 are in the write mode while the information rx-type indicating the received data type and the information tx-type indicating the transmitted data type are "1". Therefore, the silence compression data stored in the memories 72 and 82 are sequentially updated with new data.

Now, suppose that in the receiving state, the received voice wraps around to the microphone 11 and is detected by the voice detector 85 as the voice section of the transmission signal. Then, the information indicating the transmission data type tx-typ
e becomes "2". Therefore, the changeover switches 87a, 8
Both 7b are switched to the voice encoder 83 side.

However, at this time, the signal processing controller 100
Determines that double talk has occurred because the information tx-type indicating the transmission data type has become “2”. Then, information rx-t indicating the received data type one frame before
Based on ype and the information tx-type indicating the transmission data type, it is determined whether the current call state is the reception priority or the transmission priority.

As a result of this judgment, if it is judged that the reception priority, that is, the change from the reception state to the double talk state, it is determined that the transmission path control signal e-cont in order to suppress the transmission voice of the transmission path.
Is set to "1". Therefore, the changeover switch 87b is switched from the voice encoder 83 side to the memory 82 side, whereby the silence compressed data stored in the memory 82 is replaced with the encoded voice data generated by the voice encoder 83, and the multiplexing unit 86 is used. Entered in. That is, the acoustic echo that wraps around the transmission path is replaced with the silence compression data. Therefore, howling is suppressed from occurring.

On the other hand, it is assumed that a received voice is sneak into the transmission path in the communication partner device, and the terminal device of its own enters the double talk state due to the influence. Then, in this case, since the transmission state has changed to the double-talk state, the signal processing control unit 100 determines that transmission is prioritized. Then, the reception path control signal d-cont is set to "1" in order to suppress the audio output of the reception path. Therefore, the changeover switch 7
7a and 77b are switched to the side of the memory 72 and the pseudo noise generator 74, respectively. As a result, the silence compression data stored in the memory 72 is input to the pseudo noise generator 74, which generates pseudo background noise. The pseudo background noise is input to the D / A converter 75 instead of the digital audio signal reproduced by the audio encoder 73 and output from the speaker 10. That is, the acoustic echo sent from the call partner device is replaced with the pseudo background noise in the reception signal processing section 70A. Therefore, howling is suppressed from occurring.

As described above, in the first embodiment,
Memories 82 and 72 for storing alternative silent compressed data in the transmission signal processing unit 80A and the reception signal processing unit 70A, respectively.
And switching switches 88, 77a, 77b for transmitting or reproducing and outputting the alternative silent compressed data stored in these memories 82, 72. Then, when double talk is detected, the signal processing control unit 100 determines whether the reception priority or the transmission priority is based on the call state in the previous frame. The silence compression data stored in the memory 82 is transmitted instead of the encoded voice data. On the other hand, when the transmission priority is given, the changeover switch 77a,
By switching 77b, pseudo background noise is generated based on the silence compression data stored in the memory 72, and the pseudo background noise is output from the speaker 10 instead of the received and reproduced digital audio signal. There is.

Therefore, according to this embodiment, in the transmitting state and the receiving state, the silence compression data is transmitted / received instead of inserting the loss in the silence section. For this reason, it is possible to eliminate the level change of the background noise between when there is no voice signal and when there is no voice signal during reception, which makes it possible to keep the natural feeling of the call high.

Even if an acoustic echo occurs during the receiving period or the transmitting period, instead of this acoustic echo,
The silence compression data stored in the memories 82 and 72 is transmitted or output from the speaker 10 as pseudo background noise. For this reason, the acoustic echo that has sneak into the microphone 11 from the speaker 10 in the terminal itself is suppressed, and the acoustic echo sent from the communication partner device is also suppressed. Therefore, howling is prevented from occurring. Moreover, by replacing the acoustic echo with the silence compression data and transmitting the data, the information amount of the transmission data can be reduced and the transmission efficiency can be further improved.

Further, the silence compression data stored in the memories 82 and 72 is updated to the silence compression data generated or received in the silence section during the transmission / reception period. Therefore, the silence compression data used as the substitute data is always kept up to date. Therefore, even if the alternative silence compression data is used to suppress the acoustic echo, the terminal always outputs background noise corresponding to the call environment at that time, and the natural feeling of the call is kept higher. be able to.

Furthermore, in the signal processing control unit 100, the information tx-type and the reception data type indicating the transmission data type output from the multiplexing unit 86 of the transmission signal processing unit 80A and the separation unit 71 of the reception signal processing unit 70A, respectively. Double talk is determined based on the information rx-type that represents. Therefore, it is not necessary to detect the signal power value or the peak value of the transmission voice signal and the reception voice signal, and thus double talk can be determined without increasing the circuit configuration or increasing the software processing amount. It will be possible.

(Second Embodiment) The second embodiment of the present invention is provided with a noise data bank in which several types of alternative silence compression data are stored in advance, and a noise level estimation unit. Then, the background noise level immediately before the occurrence of double talk is estimated, and based on this estimation result, the corresponding alternative silent compression data is selected from the noise data bank, and this alternative silent compression data is converted into encoded voice data. The substitute background sound is transmitted or the pseudo background noise generated on the basis of the alternative silent compressed data is replaced with the received and reproduced voice and is output.

FIG. 4 is a circuit block diagram showing a second embodiment of the audio signal processing module according to the present invention. In the figure, the same parts as those in FIG. 2 are designated by the same reference numerals and detailed description thereof is omitted.

The reception signal processing unit 70B has a noise data bank (N-BANK) 79 and a noise estimation unit (NE) 78.
And a noise data bank 90 and a noise estimation unit 89 are provided in the transmission signal processing unit 80B.

Noise data banks 79 and 90 are both RO
It is composed of M, and several kinds of alternative silent compression data are stored in advance. These alternative silence compression data are created in advance in association with each of a plurality of standard background noise levels.

The noise estimation units 78 and 89 hold, for each encoded frame, at least the silence-compressed data received one frame before and the silence-compressed data to be transmitted. Then, when double talk occurs, the alternative silence compression data having the level closest to the silence compression data held one frame before is selectively output from the noise data banks 79, 90.

With such a configuration, when the state of receiving priority is changed to the state of double talk, the signal processing control unit 100 sets the transmission path control signal e-cont to "1" in order to suppress the transmission voice of the transmission path. Set to ". Therefore, the changeover switch 87b is switched from the voice encoder 83 side to the memory 82 side. At this time, the noise estimation unit 89 provides the noise data bank 90 with the number of the alternative silence compression data having the level closest to the silence compression data one frame before, and the noise data bank 90 substitutes the number corresponding to the above number. The silent compressed data is read. Therefore, the alternative silence compression data read from the noise data bank 90 is input to the multiplexing unit 86 instead of the encoded voice data generated by the voice encoder 83. That is, the acoustic echo that wraps around the transmission path is replaced with the alternative silence compression data. Therefore, howling is suppressed from occurring.

On the other hand, when the transmission priority state changes to the double talk state, the signal processing control unit 100 sets the reception path control signal d-cont to "1" in order to suppress the voice output of the reception path. Therefore, the changeover switches 77a, 7a
7b is switched to the noise data bank 79 and the pseudo noise generator 74 side, respectively. At this time, the noise estimation unit 7
In No. 8, the number of the substitute silence compression data having the level closest to the silence compression data of the preceding frame is given to the noise data bank 79, whereby the substitute silence compression data corresponding to the above number is read from the noise data bank 79. Therefore, the alternative silence compression data read from the noise data bank 79 is input to the pseudo noise generator 74, which generates pseudo background noise. The pseudo background noise is input to the D / A converter 75 instead of the digital audio signal reproduced by the audio encoder 73 and output from the speaker 10. That is, the acoustic echo sent from the call partner device is replaced with the pseudo background noise in the reception signal processing unit 70B. Therefore, howling is suppressed from occurring.

Therefore, also in the second embodiment, as in the first embodiment described above, since the silent compressed data is transmitted instead of the loss, the natural feeling of the call can be kept high. Moreover, instead of the acoustic echo, the alternative silence compression data stored in the noise data banks 79 and 90 is transmitted or output as pseudo background noise, so that the acoustic echo is suppressed to prevent howling. Is possible. Moreover, by replacing the acoustic echo with the silence compression data and transmitting the data, the information amount of the transmission data can be reduced and the transmission efficiency can be further improved.

Further, in this embodiment, noise data banks 79 and 9 in which several types of alternative silence compression data are stored in advance.
By using 0, it is possible to reduce the memory capacity for storing the alternative silent compressed data as compared with the first embodiment, and thus it is possible to reduce the size and cost of the module. Become. Moreover, since the process of updating the alternative silent compressed data stored in the memory as in the first embodiment is not required at all, the power consumption of the module can be reduced accordingly.

(Other Embodiments) The present invention is not limited to the above first and second embodiments. For example, in the second embodiment, a plurality of silence compression data corresponding to a plurality of levels of background noise are stored in the noise bank 7.
The case of storing in 9, 90 was described. However, the present invention is not limited to this, and a plurality of silence compression data corresponding to a plurality of different types of background noise may be stored. It is also possible to prepare a plurality of silence compression data having different levels corresponding to each of the plurality of types of background noises and store this in a noise bank. By doing so, even if the type of background noise in the call environment changes, it is possible to output the optimum background noise each time, and thus the naturalness of the call can be kept higher.

In each of the above embodiments, the case where the audio signal processing module is configured by a hardware circuit has been described as an example, but a microprocessor or a DSP is used.
The (Digital Signal Processor) may be implemented by a configuration that operates by software, or may be implemented by a configuration in which a hardware circuit and a circuit that operates by software are mixed.

Further, in each of the above-mentioned embodiments, the CDMA mobile communication terminal has been described as an example, but other digital mobile communication terminals such as TDMA mobile phones and wired voice communication terminals such as digital button phones and digital fixed-line phones are also available. This invention can be applied.

In addition, types of voice communication terminals and their configurations,
The configuration of the audio signal processing module and its processing contents can be modified in various ways without departing from the scope of the present invention.

[0082]

As described above in detail, according to the present invention, the transmission signal is divided into the voiced section and the silent section based on the voiced detection result, each of which is encoded and transmitted. In the audio signal processing module having the function of decoding the coded data that has arrived and reproducing the voiced section and the silent section of the received signal, a signal processing control unit is newly provided. Then, the signal processing control unit detects the double talk section of the transmission signal and the reception signal, and in the detected double talk section, substitute silence compression data prepared in advance in place of the encoded voice data is prepared. Instead of the voiced section of the received signal reproduced by the voice decoding means, the alternative silent section prepared in advance is output.

Therefore, according to the present invention, the echo can be suppressed by a relatively simple process, the background noise level change can be reduced to improve the call quality, and the unnecessary voice data transmission period can be shortened. It is possible to provide a voice signal processing module that improves the transmission efficiency and a voice communication device including the module.

[Brief description of drawings]

FIG. 1 is a functional block diagram showing a configuration of a CDMA mobile communication terminal which is a first embodiment of a voice communication device including a voice signal processing module according to the present invention.

2 is a circuit block diagram showing a configuration of an audio signal processing module of the terminal shown in FIG.

FIG. 3 is a diagram showing the operation content of the audio signal processing module shown in FIG.

FIG. 4 is a circuit block diagram showing a second embodiment of an audio signal processing module according to the present invention.

FIG. 5 is a functional block diagram showing an example of the configuration of a conventional audio signal processing device having a voice switch function.

[Explanation of symbols]

1 ... antenna 2 ... Antenna duplexer (DUP) 3 ... Receiving circuit (RX) 4 ... Frequency synthesizer (SYN) 5 ... Transmission circuit (TX) 6 ... CDMA signal processing unit 7 ... Voice signal processing module 9 ... Receiver amplifier 10 ... speaker 11 ... Microphone 12 ... Control unit 13 ... storage unit 14 ... Input section 15 ... Display 16 ... Battery 17 ... Power supply circuit 18 ... Transmitter amplifier 70A, 70B ... Received voice signal processing unit 71 ... Separation unit (DEMUX) 72, 82 ... memory 73 ... Speech decoder (DEC) 74 ... Pseudo noise generator (DTX-DEC) 75 ... D / A converter 76a, 76b, 77a, 77b ... Changeover switch 78, 89 ... Noise estimation unit (NE) 79, 90 ... Noise data bank (N-BANK) 80A, 80B ... Transmitted voice signal processing unit 81 ... A / D converter 83 ... Voice encoder (ENC) 84 ... Silent compressor (DTX-ENC) 85 ... Voice detector (VAD) 86 ... Multiplexing part (MUX) 87a, 87b, 88 ... Changeover switch 100 ... Signal processing control unit

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Claims (6)

[Claims] 1. A transmission signal processing unit, a reception signal processing unit,
A signal processing control unit, wherein the transmission signal processing unit is based on a determination result of the voice determination unit for identifying a voice section and a silence section of the input transmission signal, A voice coding unit that encodes a voiced section of the input transmission signal to generate encoded voice data; and a silent section of the input transmission signal based on a determination result of the voice determination unit. Silence encoding means for encoding to generate silence compression data, encoded voice data generated by the voice encoding means, silence compression data generated by the silence encoding means, and types of these data And multiplex means for generating multiplexed transmission data by multiplexing with the type information indicating the, and the reception signal processing unit is based on the type information included in the input multiplexed reception data. , The multiplexed reception Separating means for separating encoded voice data and silent compressed data from the data; voice decoding means for decoding the encoded voice data separated by the separating means to reproduce and output the voiced section of the reception signal; And a silence decoding unit that reproduces and outputs the silence section of the reception signal by decoding the silence compression data separated by the separation unit, wherein the signal processing control unit is the transmission signal input to the transmission signal processing unit. And double-talk detecting means for detecting a double-talk section of the receiving signal output from the receiving-signal processing section; A process of supplying the substitute silenced compressed data to the multiplexing means, and a preliminarily prepared instead of the voiced section of the reception signal reproduced by the voice decoding means. The audio signal processing module, characterized in that a replacement means for selectively performing a process for outputting an alternate silent interval that. 2. The replacement means determines a transmission priority or a reception priority according to the types of the transmission signal and the reception signal in the past frame period, and the determination means determines the reception priority. In this case, means for supplying to the multiplexing means alternative compressed silence data prepared in advance in place of the encoded voice data, and the voice decoding means when the determination means determines that the transmission priority is given. 2. The audio signal processing module according to claim 1, further comprising means for outputting a previously prepared alternative silent section in place of the sound section of the received voice signal reproduced by. 3. The replacement means updates the alternative silence compression data with silence compression data generated by the silence encoding means in a silence interval of a transmission signal, and reproduces the alternative silence interval. 3. The audio signal processing module according to claim 1, further comprising: means for updating the alternative silent compression data of 1. to the silence compression data input to the silence decoding means in a silence section of a received signal. . 4. An input means for inputting a transmission signal, an output means for outputting a reception signal, and encoding the transmission signal input by the input means to generate multiplexed transmission data. A voice signal processing module for decoding the input multiplexed reception data to reproduce a reception signal and outputting it from the output means, and a communication line for directing the multiplexed transmission data generated by the voice signal processing module to a communication partner device And a transmission / reception unit that receives the multiplexed reception data that has arrived from the communication partner device via a communication line and inputs the reception data to the audio signal processing module, wherein the audio signal processing module includes the input unit. Based on the judgment result of the voiced sound judging means, the sounded sound judging means for distinguishing between the sound sound section and the silent section of the transmission signal inputted by A voice coding means for coding the voiced section of the transmitted voice signal to generate coded voice data; and encoding a silent section of the input voiced signal based on the determination result of the voiced determination means. Silence encoding means for generating silence compression data, encoded voice data generated by the voice encoding means and silence compression data generated by the silence encoding means, together with type information indicating the type of these data. Based on the multiplexing means for generating multiplexed transmission data by multiplexing and outputting the multiplexed transmission data to the transmission / reception unit, and the type information included in the multiplexed reception data input from the transmission / reception unit, Separation means for separating encoded voice data and silence compression data from the multiplexed reception data, and decoding the encoded voice data separated by the separation means to determine the voiced section of the reception signal. A voice decoding means for reproducing and outputting from the output means; a silence decoding means for decoding the silence compressed data separated by the separating means to reproduce a silence section of the reception signal and outputting from the output means; Double talk detecting means for detecting a double talk section of the transmitted signal input to the talk signal processing section and the received signal output from the received signal processing section, and a double talk section detected by the double talk detecting section, A process of supplying alternative silence compression data prepared in advance in place of the encoded voice data to the multiplexing means and a voice section of the reception signal reproduced by the voice decoding means are prepared in advance. A voice communication device comprising: a replacement unit that selectively executes a process of outputting an alternative silent section to the output unit. 5. The replacing means includes a judging means for judging whether transmission priority or reception priority is given according to types of a transmission signal and a reception signal in a past frame period, and when the reception priority is determined, A means for supplying, to the multiplexing means, alternative silence compression data prepared in advance in place of the encoded voice data, and the presence of the received signal reproduced by the voice decoding means when it is determined that the transmission priority is given. 5. The voice communication device according to claim 4, further comprising: a means for outputting, from the output means, an alternative silent section prepared in advance in place of the sound section. 6. The replacement means updates the alternative silence compression data with silence compression data generated by the silence encoding means in a silence interval of a transmission signal, and reproduces the alternative silence interval. 6. The voice communication device according to claim 4, further comprising means for updating the alternative silent compressed data of 1. to the silent compressed data input to the silent decoding means in a silent section of a received signal.