JP2003202898A - Speech signal transmitter, speech signal receiver, and speech signal transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a speech signal transmission system and speech signal transmitting method with which the quality of a decoded speech signal right after frame loss can be improved. <P>SOLUTION: A speech signal transmitter 101 encodes a speech signal on the premise that the speech signal has no frame loss in the past to generate 1st speech encoded information, encodes the speech signal on the premise that the speech signal has frame loss in the past to generate 2nd speech encoded information, and multiplexes and transmits the 1st and 2nd pieces of speech encoded information as speech encoded information. A speech signal receiver 102 decodes the 1st speech encoded information when detecting no frame loss of a received speech signal obtained by receiving the speech encoded information and decodes the 2nd speech encoded information in the frame right after a lost frame when detecting the frame loss of the received speech signal. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voice signal transmission system that encodes a voice signal to generate voice coded information, packetizes it, and transmits it.

[0002]

2. Description of the Related Art In packet communication typified by Internet communication, erasure compensation (concealment) processing is performed when encoded information cannot be received at a decoder side due to packet (or frame) loss on a transmission path. Is common. A conventional audio signal transmission system is shown in FIG.

As shown in FIG. 6, a conventional audio signal transmission system comprises an audio signal transmitting device 601 and an audio signal receiving device 602.

The audio signal transmitter 601 is an input device 60.
3, AD converter 604, speech encoder 605, code processor 606, RF modulator 607, transmitter 608
And an antenna 609.

The input device 603 receives the audio signal 610, converts it into an analog audio signal which is an electric signal, and supplies it to the AD conversion device 604. The AD converter 604 converts the analog voice signal from the input device 603 into a digital voice signal and supplies it to the voice encoding device 605. The voice encoding device 605 encodes the digital voice signal from the AD conversion device 604 to generate voice encoded information, and gives it to the code processing device 606. The code processing device 606 performs channel coding processing, multiplexing processing, and packetization processing on the speech coded information from the speech coding apparatus 605, and gives the speech coding information to the RF modulation apparatus 607. The RF modulator 607 modulates the voice coded signal from the code processor 606 and gives it to the transmitter 608. The transmitter 608 is
The speech coded signal from the RF modulator 107 is fed to the antenna 6
A voice coded signal is transmitted via a radio wave (RF signal) 611
To send as.

The audio signal receiving device 602 includes an antenna 61.
2, receiver 613, RF demodulator 614, signal processor 615, speech decoder 616, DA converter 617
And an output device 618.

The receiving device 613 receives a radio wave (RF signal) 611 'which is a voice coded signal via an antenna 612 and generates a reception voice signal which is an analog electric signal to generate R.
It is given to the F demodulator 614. Radio wave (RF signal) 611 '
Is exactly the same as the radio wave (RF signal) 611 if there is no signal attenuation or noise superposition on the transmission path. The RF demodulation device 614 demodulates the reception voice signal from the reception device 613 and gives it to the signal processing device 615. Signal processing device 61
5 performs packet demultiplexing processing, demultiplexing processing, and channel decoding processing of the reception voice signal from the RF demodulation device 614, and gives the reception voice signal to the voice decoding device 616. The audio decoding device 616 decodes the received audio signal from the signal processing device 615 to generate a decoded audio signal and gives it to the DA converter 617. The DA converter 617 converts the digital decoded voice signal from the voice decoding device 616 into an analog decoded voice signal and gives it to the output device 618. The output device 618 converts the analog decoded audio signal from the DA conversion device 617 into air vibration and outputs it as a sound wave 619 so that it can be heard by the human ear.

The voice decoding device 616 includes a voice decoding unit 6
21 and a frame loss monitoring unit 622. The input terminals of the voice decoding unit 621 and the frame loss monitoring unit 622 are connected to the output terminal of the signal processing device. The output terminal of the voice decoding unit 621 is connected to the DA converter 617. The output terminal of the frame loss monitoring unit 622 is connected to another input terminal of the voice decoding unit 621. The frame loss monitoring unit 622 monitors whether or not there is a frame loss in the received voice signal, and when a frame loss is detected, generates a frame loss signal and outputs the voice decoding unit 6
Give to 21. The voice decoding unit 621 generates a decoded voice signal by performing a normal decoding process on the received voice signal from the signal processing device 615 when not receiving the frame loss signal. Further, when receiving a frame loss signal, speech decoding section 621 performs frame loss compensation (concealment) processing on the reception speech signal from signal processing device 615 to generate a decoded speech signal. There are various types of frame loss compensation processing depending on the audio encoding method. For example, ITU-T Recommendation G.264. 729 and the like, it is specified as a part of the decoding algorithm.

[0009]

However, in the conventional voice signal transmission system, when the transmitted frame (or packet) disappears on the transmission path, the voice decoding device 616 restores the previously received coded information. The frame (or packet) loss compensation processing is performed using this. At this time, since the internal states of the speech coding apparatus 605 and the speech decoding apparatus 616 cannot be synchronized, not only the lost portion of the frame but also after the frame loss. There is a problem that the influence of packet loss propagates to the decoding process of the frame and the quality of the decoded voice signal is significantly deteriorated.

For example, as a voice coding system, ITU-
Recommendation G. CELP (Code Excited Linea) shown in FIG.
r Prediction) method, since speech encoding and decoding processing is performed using the past decoded driving excitation signal, different driving excitation signals are combined in the encoder and the decoder by frame erasure processing. If this happens, there is a problem that the internal states of the encoder and the decoder do not match for a while after that, and the quality of the decoded speech signal may deteriorate significantly.

The present invention has been made in view of the above points, and provides a voice signal transmitting device, a voice signal receiving device, and a voice signal transmitting system capable of improving the quality of a decoded voice signal immediately after frame loss. The purpose is to do.

[0012]

The speech signal transmitting apparatus of the present invention performs speech coding processing of a speech signal on the assumption that no frame has been lost in the past to generate first speech coded information. A normal speech encoding means for performing speech encoding processing of the speech signal on the premise that frame loss has occurred in the past to generate second speech encoded information; The first speech coding information and the second speech coding information are multiplexed to generate speech coding information, and the speech coding information per processing unit time is put in a frame to obtain the speech coding information. And means for transmitting via an antenna.

According to this structure, on the side of the voice signal transmitting device, the voice signal is subjected to the voice encoding process on the assumption that the voice signal has lost the frame in the past, and the second voice encoded information is obtained. Since the voice signal receiving apparatus generates and transmits the second voice coded information in the frame immediately after the frame is lost, the voice signal receiving apparatus can decode the second voice coded information. Therefore, the voice signal transmitting apparatus and the voice signal receiving apparatus immediately after the frame is lost. It is possible to improve the quality of the decoded speech signal immediately after the frame is lost because the internal states of the above can be matched.

The audio signal receiving apparatus of the present invention includes the first audio coded information generated by performing the audio coding process of the audio signal on the premise that the frame has not been lost in the past, and the frame in the past. Of the second speech coded information generated by performing the speech coding process of the speech signal on the assumption that the disappearance has occurred, and the speech coded information generated by being multiplexed into the frame and transmitted. A voice signal receiving apparatus for receiving the voice coded information via an antenna to generate a received voice signal; and a first unit when the loss of a frame of the received voice signal is not detected. Means for decoding the speech coded information, and means for decoding the second speech coded information in a frame next to the frame lost when the loss of the frame of the received speech signal is detected, A configuration that includes.

According to this configuration, the voice signal transmitter performs the voice encoding process of the voice signal on the assumption that the frame has been lost in the past, and the second voice encoded information is generated and transmitted. Therefore, since the second voice encoding information can be decoded in the frame immediately after the frame is lost on the side of the voice signal receiving device, the internal states of the voice signal transmitting device and the voice signal receiving device immediately after the frame loss can be confirmed. Since they can be matched, the quality of the decoded speech signal immediately after frame loss can be improved.

The audio signal receiving apparatus of the present invention includes the first audio encoded information generated by performing the audio encoding process of the audio signal on the premise that no frame has been lost in the past, and the frame in the past. Of the second speech coded information generated by performing the speech coding process of the speech signal on the assumption that the disappearance has occurred, and the speech coded information generated by being multiplexed into the frame and transmitted. A voice signal receiving apparatus for receiving the voice coded information via an antenna to generate a received voice signal, frame loss monitoring means for monitoring the loss of a frame of the received voice signal, Multiplexed information separating means for separating the received voice signal, and a changeover switch for selecting and outputting any one of the received voice signals separated by the multiplexed information separation means,
The frame erasure includes: a delay unit connected between the frame erasure monitoring unit and the changeover switch for delaying one frame; and a voice decoding unit for performing a decoding process of a voice signal received from the changeover switch. When the monitoring means detects the loss of a frame of the received voice signal, it gives a frame loss detection signal to the voice decoding means and gives the frame loss detection signal to the changeover switch via the delay means, and the changeover switch. However, when the frame loss detection signal is not received, the first voice coding information of the received voice signal is selected and output, and when the frame loss detection signal is received, the second voice encoded information of the second received voice signal is received. The speech coding information is selected and output, and the speech decoding means selects the frame of the frame lost when it receives the frame loss detection signal. It employs a configuration in which the decoding of the second speech coding information in the next frame of the lost frame after the over beam loss compensation processing.

According to this structure, the voice signal transmitter performs the voice encoding process of the voice signal on the assumption that the frame has been lost in the past, and the second voice encoded information is generated and transmitted. Therefore, since the second voice encoding information can be decoded in the frame immediately after the frame is lost on the side of the voice signal receiving device, the internal states of the voice signal transmitting device and the voice signal receiving device immediately after the frame loss can be confirmed. Since they can be matched, the quality of the decoded speech signal immediately after frame loss can be improved.

The mobile station apparatus of the present invention has a configuration including the voice signal transmitting apparatus or the voice signal receiving apparatus.

According to this structure, it is possible to obtain a mobile station apparatus having the above effects.

The base station apparatus of the present invention has a configuration including the voice signal transmitting apparatus or the voice signal receiving apparatus.

According to this structure, it is possible to obtain a base station apparatus having the above effects.

The audio signal transmission system of the present invention has a configuration including the audio signal transmitting device and the audio signal receiving device.

According to this structure, it is possible to obtain the audio signal transmission system having the above effects.

In the voice signal transmission method of the present invention, the normal voice encoding step of generating the first voice encoded information by performing the voice encoding process of the voice signal on the assumption that no frame has been lost in the past. A post-frame loss voice encoding step of performing voice encoding processing of the voice signal to generate second voice encoded information on the assumption that frame loss has occurred in the past; and the first voice code. The encoded information and the second speech encoded information are multiplexed to generate speech encoded information, the speech encoded information per processing unit time is put in a frame, and the speech encoded information is transmitted via an antenna. A step of receiving the speech coded information via an antenna to generate a received speech signal;
Decoding the first speech coded information when no loss of frames of the received speech signal is detected,
Decoding the second speech coded information in a frame next to the lost frame when the loss of the frame of the received voice signal is detected.

According to this method, on the side of the audio signal transmitting device, the audio signal is subjected to the audio encoding process on the premise that frame loss has occurred in the audio signal in the past, and the second audio encoded information is obtained. The inside of the voice signal transmitting apparatus and the voice signal receiving apparatus immediately after the frame loss because the second voice coded information is generated and transmitted and the voice signal receiving apparatus side decodes the second voice coded information in the frame immediately after the frame loss. Since the states can be matched, the quality of the decoded speech signal immediately after the frame is lost can be improved.

The audio signal transmission processing program of the present invention is
The normal speech coding step of performing speech coding processing of the speech signal to generate the first speech coded information on the assumption that no frame has been lost in the past, and As a premise, a speech coding step after frame loss for performing speech coding processing of the speech signal to generate second speech coding information, the first speech coding information and the second speech coding information are performed. Generating voice coded information by multiplexing, putting the voice coded information per processing unit time in a frame, and transmitting the voice coded information via an antenna; and the voice coded information via the antenna. To generate a received voice signal, decode the first voice coded information when no loss of frames of the received voice signal is detected, Decoding a second speech coding information in the next frame of the frame lost upon detecting the loss of frames of speech signals, it was to be performed.

According to this program, on the side of the audio signal transmitting device, the audio signal is subjected to the audio encoding process on the assumption that the frame of the audio signal has been lost in the past, and the second audio encoding information is obtained. The inside of the voice signal transmitting apparatus and the voice signal receiving apparatus immediately after the frame loss because the second voice coded information is generated and transmitted and the voice signal receiving apparatus side decodes the second voice coded information in the frame immediately after the frame loss. Since the states can be matched, the quality of the decoded speech signal immediately after the frame is lost can be improved.

[0028]

BEST MODE FOR CARRYING OUT THE INVENTION The essence of the present invention is that a voice signal transmitting apparatus performs a voice encoding process of a voice signal on the assumption that no frame loss has occurred in the voice signal in the past, and a first voice Encoding information is generated, and speech encoding processing of the speech signal is performed on the premise that frame loss has occurred in the speech signal in the past to generate second speech coding information, and the first speech is generated. The coded information and the first voice coded information are multiplexed to generate voice coded information, which is put in a frame and the voice coded information is transmitted via an antenna. A frame of the received voice signal by receiving the voice coded information via the received voice signal to generate a received voice signal, and decoding the first voice coded information when the loss of the frame of the received voice signal is not detected. The disappearance of It is for decoding the second speech coding information in the next frame of the frame lost when.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

(Embodiment 1) FIG. 1 is a block diagram showing a configuration of an audio signal transmission system according to an embodiment of the present invention.

The audio signal transmission system comprises an audio signal transmitting device 101 and an audio signal receiving device 102.

The audio signal transmitting device 101 includes an input device 10
3, AD converter 104, speech encoder 105, code processor 106, RF modulator 107, transmitter 108
And an antenna 109. AD converter 104
Are connected to the input device 103. The input terminal of the audio encoding device 105 is connected to the output terminal of the AD conversion device 104. The input terminal of the code processing device 106 is connected to the output terminal of the speech coding device 105. RF
The input terminal of the modulator 107 is connected to the output terminal of the code processor 106. The input terminal of the transmitter 108 is connected to the output terminal of the RF modulator 107.
The antenna 109 is connected to the output terminal of the transmission device 108.

The input device 103 receives the audio signal 110, converts it into an analog audio signal which is an electric signal, and supplies it to the AD conversion device 104. The AD conversion device 104 converts the analog audio signal from the input device 103 into a digital audio signal and supplies it to the audio encoding device 105. The voice encoding device 105 encodes the digital voice signal from the AD conversion device 104 to generate voice encoded information, and supplies it to the code processing device 106. The code processing device 106 performs channel coding processing, multiplexing processing, and packetization processing on the speech coded information from the speech coding apparatus 105, and gives the speech coding information to the RF modulation apparatus 107. The RF modulator 107 modulates the voice coded signal from the code processor 106 and gives it to the transmitter 108. The transmitter 108 is
The voice coded information per processing unit time from the RF modulator 107 is put in a frame and the voice coded information is transmitted as a radio wave (RF signal) 111 via the antenna 109.

In the voice signal transmitting apparatus 101, the input digital voice signal is processed in units of several tens of ms, and one frame or several frames of encoded data is put in one packet. Is transmitted to the packet network. In this specification, it is assumed that one frame is transmitted in one packet in order to minimize the transmission delay. Therefore, packet loss corresponds to frame loss.

The audio signal receiving apparatus 102 includes an antenna 11
2, reception device 113, RF demodulation device 114, signal processing device 115, speech decoding device 116, DA conversion device 117
And an output device 118. The input terminal of the receiving device 113 is connected to the antenna 112. The input terminal of the RF demodulation device 114 is connected to the output terminal of the reception device 113. The input terminal of the signal processing device 115 is R
It is connected to the output terminal of the F demodulator 114. The input terminal of the voice decoding device 116 is connected to the output terminal of the signal processing device 115. The input terminal of the DA converter 117 is connected to the output terminal of the voice decoding device 116. The input terminal of the output device 118 is the DA converter 117.
Is connected to the output terminal of.

The receiving device 113 receives a radio wave (RF signal) 111 ′ which is voice coded information via the antenna 112, generates a received voice signal which is an analog electric signal, and gives it to the RF demodulation device 114. Radio wave (RF signal) 11
1'is exactly the same as the radio wave (RF signal) 111 if there is no signal attenuation or noise superposition on the transmission path. R
The F demodulation device 114 demodulates the received voice signal from the reception device 113 and gives it to the signal processing device 115. The signal processing device 115 performs packet demultiplexing processing, demultiplexing processing, and channel decoding processing of the reception voice signal from the RF demodulation device 114, and gives the reception voice signal to the voice decoding device 116.
The audio decoding device 116 decodes the received audio signal from the signal processing device 115 to generate a decoded audio signal and gives it to the DA converter 117. The DA converter 117 converts the digital decoded voice signal from the voice decoding device 116 into an analog decoded voice signal and gives it to the output device 118.
The output device 118 converts the analog decoded voice signal from the DA converter 117 into vibration of the air and outputs it as a sound wave 119 so that it can be heard by the human ear.

Next, the speech coding apparatus 105 is shown in FIG.
Also, a detailed description will be given with reference to FIG. FIG. 2 is a block diagram showing the configuration of speech encoding apparatus 105.

As shown in FIG. 1, speech coding apparatus 105
Has a normal frame coding unit 120, a post-frame loss coding unit 121, and a multiplexing unit 122. The input terminal of the normal frame encoding unit 120 is the AD conversion device 104.
Is connected to the output terminal of. The input terminal of the post-frame erasure encoding unit 121 is connected to the output terminals of the AD conversion device 104 and the normal frame encoding unit 120. The multiplexing unit 122 includes the output terminals of the normal frame coding unit 120 and the post-frame loss coding unit 121, and the code processing device 10.
It is connected between 6 input terminals.

The normal frame coding unit 120 receives the voice signal from the AD converter 104 and performs the voice coding process of the voice signal on the assumption that no frame loss has occurred in the voice signal in the past. Speech coded information C is generated and given to the multiplexing unit 122. In addition, the normal frame coding unit 120 provides the post-erasure frame coding unit 121 with the adaptive codebook, the state of the synthesis filter, and other internal state information that should be updated in the coding algorithm.

The post-frame erasure encoding unit 121 receives the voice signal from the AD converter 104, and performs voice encoding processing of the voice signal on the premise that the frame has been lost in the past in the voice signal. The speech coded information C ′ is generated and given to the multiplexing unit 122. In this case, the post-frame erasure encoding unit 121 performs the encoding process of the current frame in the state where the frame erasure compensation process has been performed in the immediately previous frame.

More specifically, the post-frame erasure encoding unit 1
Reference numeral 21 denotes internal state information of two frames before the normal frame encoding unit 120 (adaptive codebook, synthesis filter state, other speech encoding parameters, information on internal states of quantizer and predictor of each parameter, etc.). The frame is received from the normal frame encoding unit 120, the frame erasure compensation process of the immediately preceding frame is performed using the internal state information to update the internal state information, and then the encoding process of the current frame is performed. The multiplexing unit 122 includes the speech coding information C from the normal frame coding unit 120 and the post-frame loss coding unit 121.
The voice coded information C ′ from the above is multiplexed to generate a multiplexed signal, which is output as voice coded information.

Next, the normal frame coding section 120 and the post-frame loss coding section 121 of the speech coding apparatus 105 will be described in detail with reference to FIGS. 1 and 2.

As shown in FIG. 2, the normal frame coding section 120 has a coding section 201 and a delay section 202. The post-frame erasure encoding unit 121 includes the encoding unit 20.
3, a delay unit 204 and a frame loss compensation processing unit 205.

The input terminal of the encoding unit 201 is connected between the output terminal of the AD converter 104 and the input terminal of the multiplexing unit 122. The delay unit 202 is connected to the output terminal of the encoding unit 201. The input terminal of the encoding unit 203 is connected between the output terminal of the AD conversion device 104 and the input terminal of the multiplexing unit 122. The input terminal of the delay unit 204 is connected to the output terminal of the delay unit 202. The input terminal of the frame loss compensation processing unit 205 is the delay unit 20.
4 is connected to the output terminal. The output terminal of the frame loss compensation processing unit 205 is connected to the other input terminal of the encoding unit 203.

The encoding unit 201 receives the audio signal from the AD converter 104, and supposes that no frame loss has occurred in the audio signal in the past, and the audio signal of the audio signal is generated based on the predetermined internal state information. Encoding processing is performed to generate speech encoded information C, which is given to the multiplexing unit 122. The delay unit 202 is for updating the internal state information of the encoding unit 201. The delay unit 202 updates the internal state information (adaptive codebook or synthesis filter state information or the like) of the encoding unit 201 to be used for encoding the next frame after the encoding of the current frame is completed.

The encoder 203 receives the voice signal from the AD converter 104, and on the basis of predetermined internal state information, the voice code of the voice signal on the assumption that a frame has been lost in the voice signal in the past. Processing is performed to generate speech coded information C ′, which is given to the multiplexing unit 122. Delay part 2
04 is for receiving the internal state information from the delay unit 202 and extracting the internal state updated in the encoding two frames before from the current frame. The delay unit 204 is
The internal state information (information about the adaptive code length and the synthesis filter state, the information about the encoding parameter two frames before, etc.) used at the time of encoding one frame before is given to the frame loss compensation processing unit 205.

The frame erasure compensation processing section 205 uses the coding parameters two frames before and the coding internal state information used in the coding process one frame before obtained by the coding process two frames before. Encoding internal state information when the frame erasure compensation process is performed one frame before is generated.

As a result, the speech coded information C ′ when the frame loss compensation processing is performed on the frame one frame before can be generated by the post-frame loss coding section 121, and thus the speech decoding apparatus 116 can. It is possible to perform the decoding process corresponding to the case where the frame one frame before is lost. The frame loss compensation processing unit 205 is set to 1
The internal state information when the frame loss compensation processing is performed before the frame is given to the encoding unit 203. Encoding unit 203
Uses the internal state information received from frame erasure compensation processing section 205 to perform coding processing of the current frame to generate speech coded information C ′, which is given to multiplexing section 122.

Next, the speech decoding apparatus 116 is shown in FIG.
And FIG. 3 will be described in detail. FIG. 3 is a block diagram showing the configuration of speech decoding apparatus 116.

As shown in FIG. 1, the speech decoding device 116.
Is the multiplexed information demultiplexing unit 123 and the frame loss monitoring unit 12
4, a delay unit 125, a changeover switch 126, and a voice decoding unit 127.

The input terminal of the multiplexed information separation unit 123 is connected to the output terminal of the signal processing device 115. Also,
The input terminal of the frame loss monitoring unit 124 is also connected to the output terminal of the signal processing device 115. The input terminal of the delay unit 125 is connected to the output terminal of the frame loss monitoring unit 124. The input terminal of the changeover switch 126 is connected to the two output terminals of the multiplexed information separation unit 123.
The other input terminal of the changeover switch 126 is the delay unit 1.
25 output terminals. Speech decoding unit 127
The input terminal of is connected to the output terminals of the frame loss monitoring unit 124 and the changeover switch 126. The output terminal of the voice decoding unit 127 is connected to the input terminal of the DA converter 117.

The multiplexed information demultiplexing unit 123 and the frame loss monitoring unit 124 receive the received voice signal from the signal processing device 115. The multiplexed information separation unit 123 separates the received voice signal to generate two pieces of voice coded information C and C ′, which are given to the changeover switch 126. Frame loss monitoring unit 124
Checks whether or not the frame (packet) in the received voice signal transmitted is normally received. The frame loss monitoring unit 124 generates a frame loss detection signal indicating that the frame is lost when the frame has not arrived, gives the frame loss detection signal to the changeover switch 126 via the delay unit 125, and the speech decoding unit 127. Give to. The delay unit 125 receives the frame loss detection signal from the frame loss monitoring unit 124, delays it by one frame, and gives the frame loss detection signal to the changeover switch 126. The frame loss detection signal that is input to the changeover switch 126 is information that indicates that one frame before was a frame loss because it passes through the delay unit 125. Changeover switch 126
When not receiving the frame loss detection signal from frame loss monitoring section 124, selects speech coded information C from multiplexed information demultiplexing section 123 and gives it to speech decoding section 127. Further, the change-over switch 126 selects the audio coded information C ′ from the multiplexed information demultiplexing unit 123 and gives it to the audio decoding unit 127 when receiving the frame loss detection signal from the frame loss monitoring unit 124. Therefore, the voice decoding unit 127 decodes the voice coded information C when the frame loss detection signal is not received, and when the frame loss detection signal is received, performs the frame loss compensation processing of the lost frame to generate a decoded voice signal. Then, the speech coded information C ′ is decoded in the frame next to the frame that has disappeared thereafter.

Next, the speech decoding unit 127 of the speech decoding device 116 will be described in detail with reference to FIGS. 1 and 3.

As shown in FIG. 3, the speech decoding unit 127
Is a decoding unit 301, a frame erasure compensation processing unit 302,
Delay unit 303, changeover switch 304 and changeover switch 3
Have 05. The input terminal of the decoding unit 301 is connected to the output terminal of the changeover switch 126. One input terminal of the changeover switch 304 and the changeover switch 305 is connected to the output terminal of the decoding unit 301. The other input terminals of the changeover switch 304 and the changeover switch 305 are connected to the output terminal of the frame loss compensation processing unit 302. Also, the changeover switch 304 and the changeover switch 3
The other input terminal of 05 is the frame loss monitoring unit 124.
Is connected to the output terminal of. The output terminal of the changeover switch 304 is connected to the input terminal of the DA converter 117. The output terminal of the changeover switch 305 is the delay unit 303.
Is connected to the input terminal of. The output terminal of the delay unit 303 has a decoding unit 301 and a frame erasure compensation processing unit 302.
Is connected to the input terminal of.

The decoding unit 301 receives the voice coded information C or the voice coded information C ′ from the changeover switch 126 and performs the decoding process of the voice coded information C or the voice coded information C ′ to obtain the decoded voice signal. Is generated and given to the DA converter 117 via the changeover switch 304. Also, the decoding unit 301
Gives internal state information (adaptive codebook, synthesis filter state, coding parameter information, etc.) to the delay unit 303 via the changeover switch 305.

The delay unit 303 is for updating the internal state information of the decoding unit 301. The delay unit 303
The decoding information of the previous frame and the input information are given to the decoding unit 301 and the frame erasure compensation processing unit 302 as internal state information of the decoding process of the current frame or the frame erasure compensation process. Decoding section 301 or frame erasure compensation processing section 302
Is a switch 3 for changing parameters related to internal state information.
It is given to the delay unit 303 via 05.

The changeover switch 304 is a switch for changing over the decoded audio signal. Switch 305
Is a decoding unit 301 and a frame erasure compensation processing unit 302
This is a switch for updating the internal state of the. These two changeover switches 304 and 305 are interlocked and switched by a frame loss detection signal from the frame loss monitoring unit 124. Specifically, the two changeover switches 30
4, 305 are connected to the output terminal of the decoding unit 301 when not receiving the frame loss detection signal, and connected to the output terminals of the frame loss compensation processing unit 302 when receiving the frame loss detection signal.

Next, the operation of speech coding apparatus 105 will be explained in detail with reference to FIG. 4 together with FIG. 1 and FIG.
FIG. 4 is a flowchart for explaining the operation of speech encoding apparatus 105.

As shown in FIG. 4, first, in step ST4
In 01, the normal frame encoding unit 120 performs normal encoding processing. Next, the normal frame encoding unit 1
20 internal state information (information such as adaptive codebook, synthesis filter state variables, coding parameters and other parameters quantizer and predictor state variables) is reflected in the result of the coding process of the current frame. The process of updating is performed.

Next, in step ST402, the post-frame erasure encoding process is performed when the frame erasure compensation unit 121 has performed the frame erasure compensation process on the immediately preceding frame. In this case, first, the process of generating the internal state information of the post-frame loss coding unit 121 obtained when the frame loss compensation process is performed on the immediately preceding frame is performed, and after the frame loss is performed using the internal state information. Encoding processing is performed. Step ST402
The coding process after frame loss in step ST4
The encoding process may be exactly the same as the encoding process performed in 01, but the amount of information to be transmitted and the amount of calculation required for encoding can be suppressed by limiting the encoding to only the excitation parameter that is greatly affected by frame loss. . More specifically, spectrum parameters such as LSP parameters are not coded (assuming that spectrum parameter coding information coded in ST401 is used), and adaptive codebooks, fixed codebooks, and both codes that are excitation parameters. Encode the gain quantization information for the book. The excitation parameter encoding method may be the same as the conventional method, but all excitation parameters may be encoded, and only some excitation parameters susceptible to frame loss are limited. Encoding may be performed. For example, if the fixed codebook is not coded (assuming that the fixed codebook coding information coded in ST401 is used), and the coding process of only the adaptive codebook and the gain information is performed, the information to be transmitted is transmitted. It is possible to minimize the increase in the amount of calculation and the amount of calculation. Furthermore, if a configuration is provided in which the search range of the adaptive codebook (pitch) is limited to the vicinity of the adaptive codebook (pitch) encoded in ST401, the increase in the amount of information to be transmitted and the amount of encoding calculation can be further reduced. It is also possible to do.

In addition to the case where the encoding process is performed on the premise that only the immediately preceding frame is the lost frame, a plurality of types of frame loss patterns in the case where several frames are lost continuously or in the past several frames are used. However, if the encoded information for each of them is transmitted, various cases can be dealt with, and robustness against frame loss is enhanced.

Next, in step ST403, the multiplexing and packetization processing of the voice coding information C obtained in the coding process of step ST401 and the voice coding information C ′ obtained in the coding process of step ST402. Is done. In the multiplexing and packetizing process, an error protection process using CRC or the like and a channel coding process to which an error correction code is added are performed.

Next, the operation of speech decoding apparatus 116 will be described in detail with reference to FIG. 5 together with FIGS.
FIG. 5 is a flowchart for explaining the operation of speech decoding apparatus 116.

As shown in FIG. 5, first, in step ST5
At 01, the frame erasure monitoring unit 124 determines whether the frame to be decoded is an erasure frame. The frame loss monitoring unit 124 determines that the packet is a normal frame if the packet storing the encoded information of the next frame has arrived in the buffer that is buffering the received packet, and the packet has not arrived. For example, it is determined as a lost frame. If it is a lost frame in step ST501, the process proceeds to step ST502, and if it is a normal frame, the process proceeds to step ST503.

When the frame is an erasure frame in step ST501, speech decoding section 127 performs frame erasure compensation processing in step ST502. The speech decoding unit 127 generally performs a process of repeatedly using the coding parameter received in the immediately preceding frame or repeatedly using the immediately preceding decoding parameter. For specific frame loss compensation processing, for example, ITU
-T Recommendation G. 729 and the like. The voice decoding unit 127 generates the decoded voice signal of the current frame by the frame loss compensation process, updates the internal state information for the next frame, and ends the decoding process.

When it is determined in step ST501 that the frame is a normal frame, the multiplexed information (packet information) received by the multiplexed information separation section 123 is separated in step ST503. By this processing, the audio coded information C, C'is extracted. Next, step ST
At 504, the speech decoding unit 127 determines whether or not the frame has just disappeared. If the frame has just disappeared in step ST504, the operation proceeds to step ST505, and if the frame has not just disappeared, the operation proceeds to step ST506.

In the speech decoding apparatus 116, the robustness is further enhanced by determining the frame erasure status of the past several frames so as to correspond to a plurality of types of frame erasure patterns.

When it is immediately after frame loss in step ST504, speech decoding section 127 performs post-loss frame decoding processing in step ST505. The post-erasure frame decoding process is a decoding process using the audio coded information C ′. The voice decoding unit 127 updates the internal state information required for the decoding process of the next frame after the decoding process and ends the decoding process.

When it is not immediately after frame loss in step ST504, speech decoding section 127 performs normal frame decoding processing in step ST506. The normal frame decoding process is a decoding process using the audio coded information C. The voice decoding unit 127 updates the internal state information necessary for the decoding process of the next frame after the normal frame decoding process, and ends the decoding process.

The present invention can provide a base station apparatus and a mobile station apparatus in a mobile communication system including at least one of the voice signal transmitting apparatus and the voice signal receiving apparatus. The present invention also includes an audio signal transmission program that executes the operations of the audio signal transmitting device and the audio signal receiving device.

[0071]

As described above, according to the present invention,
On the side of the voice signal transmitter, the voice signal is subjected to voice encoding processing on the premise that frame loss has occurred in the voice signal in the past, second voice encoded information is generated and transmitted, and Since the second voice coding information is decoded in the frame immediately after the frame is lost on the side of the signal receiving device, the internal states of the voice signal transmitting device and the voice signal receiving device immediately after the frame loss can be matched. It is possible to improve the quality of the decoded speech signal immediately after the frame is lost.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an audio signal transmission system according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a voice encoding device of a voice transmission system according to an embodiment of the present invention.

FIG. 3 is a block diagram showing a voice decoding device of a voice transmission system according to an embodiment of the present invention.

FIG. 4 is a flowchart for explaining the operation of the speech coder in the speech transmission system according to the embodiment of the present invention.

FIG. 5 is a flowchart for explaining the operation of the voice decoding device of the voice signal transmission system according to the embodiment of the present invention.

FIG. 6 is a block diagram showing a configuration of a conventional audio signal transmission system.

[Explanation of symbols]

101 audio signal transmitter 102 audio signal receiver 103 input device 104 AD converter 105 speech coding apparatus 106 code processing device 107 RF modulator 108 transmitter 109 antenna 110 audio signals 111,111 'radio waves 112 antenna 113 Receiver 114 RF demodulator 115 Signal processing device 116 speech decoding device 117 DA converter 118 Output device 119 sound waves 120 Normal frame coding unit 121 Frame Loss Encoding Unit 122 Multiplexer 123 multiplexed information demultiplexing unit 124 Frame loss monitoring unit 125 delay section 126 changeover switch 127 voice decoding unit 201 encoder 202 Delay unit 203 encoder 204 Delay unit 205 frame loss compensation processing unit 301 Decoding unit 302 frame loss compensation processing unit 303 Delay unit 304, 305 selector switch

Claims (8)

[Claims] 1. A normal speech coding means for performing speech coding processing of a speech signal to generate first speech coded information on the premise that no frame has been lost in the past, and frame loss in the past. On the premise that the voice signal is subjected to the voice encoding process to generate the second voice encoded information, the post-frame loss voice encoding means, the first voice encoded information and the second voice encoded information. Means for multiplexing the audio coded information to generate the audio coded information, inserting the audio coded information per processing unit time into a frame, and transmitting the audio coded information through an antenna. An audio signal transmitting device characterized by: 2. The first speech coded information generated by performing speech coding processing of a speech signal on the premise that no frame has been lost in the past, and frame loss in the past have been generated. As a premise, a voice signal receiving device for receiving the voice coded information generated by multiplexing the voice coded information of the voice signal and generated by multiplexing the second voice coded information generated in the frame. And means for receiving the voice coded information via an antenna to generate a received voice signal, and decoding the first voice coded information when the loss of a frame of the received voice signal is not detected. And a unit for decoding the second speech coded information in the frame next to the frame lost when the loss of the frame of the received voice signal is detected. Voice signal receiving apparatus. 3. The first speech coded information generated by performing speech coding processing of a speech signal on the premise that no frame has been lost in the past, and frame loss in the past have been generated. As a premise, a voice signal receiving device for receiving the voice coded information generated by multiplexing the voice coded information of the voice signal and generated by multiplexing the second voice coded information generated in the frame. A means for receiving the voice coded information via an antenna to generate a received voice signal, a frame loss monitoring means for monitoring the loss of a frame of the received voice signal, and the received voice signal are separated. Multiplexed information demultiplexing means, a changeover switch for selecting and outputting any one of the received voice signals separated by the multiplexed information demultiplexing means, the frame loss monitoring means and the changeover switch And a voice decoding means for decoding the received voice signal from the changeover switch, wherein the frame loss monitoring means is a frame of the received voice signal. When the erasure is detected, the frame erasure detection signal is given to the voice decoding means and the frame erasure detection signal is given to the changeover switch through the delay means, and the changeover switch receives the frame erasure detection signal. When not present, the first speech coding information of the received speech signal is selected and output, and when the frame loss detection signal is received, the second speech coding information of the reception speech signal is selected and output. The speech decoding means performs frame erasure compensation processing for a frame lost when the frame erasure detection signal is received, and then performs the lost erasure flag. Audio signal receiving apparatus, characterized by a decoding process of the second speech coding information in the next frame over arm. 4. A mobile station apparatus comprising the voice signal transmitting apparatus according to claim 1 or the voice signal receiving apparatus according to claim 2 or 3. 5. A base station apparatus comprising the voice signal transmitting apparatus according to claim 1 or the voice signal receiving apparatus according to claim 2 or 3. 6. A voice signal transmission system comprising the voice signal transmitting device according to claim 1 and the voice signal receiving device according to claim 2 or 3. 7. A normal speech coding step of performing speech coding processing of a speech signal to generate first speech coded information on the assumption that no frame has been lost in the past.
A post-frame loss voice encoding step of performing voice encoding processing of the voice signal to generate second voice encoded information on the premise that frame loss has occurred in the past; and the first voice encoded information. And a step of multiplexing the second speech coded information to generate speech coded information, putting the speech coded information per processing unit time in a frame, and transmitting the speech coded information via an antenna. Receiving the voice coded information via an antenna to generate a received voice signal, and decoding the first voice coded information when no frame loss of the received voice signal is detected. And decoding the second speech coded information in a frame next to the lost frame when the loss of the frame of the received voice signal is detected. Audio signal transmission method comprising and. 8. A normal speech coding step of performing speech coding processing of a speech signal to generate first speech coded information on the assumption that no frame has been lost in the past.
A post-frame loss voice encoding step of performing voice encoding processing of the voice signal to generate second voice encoded information on the premise that frame loss has occurred in the past; and the first voice encoded information. And a step of multiplexing the second speech coded information to generate speech coded information, putting the speech coded information per processing unit time in a frame, and transmitting the speech coded information via an antenna. Receiving the voice coded information via an antenna to generate a received voice signal, and decoding the first voice coded information when no frame loss of the received voice signal is detected. And decoding the second speech coded information in a frame next to the lost frame when the loss of the frame of the received voice signal is detected. Audio signal transmission processing program characterized and.