JP3712685B2 - SIGNAL IDENTIFIER, SIGNAL IDENTIFICATION METHOD, AND TRANSMISSION DEVICE - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a signal discriminator, a signal discriminating method, and a transmission apparatus using the signal discriminator for discriminating the type of signal transmitted through a telephone line into a voice signal and a voice band data signal.
[0002]
[Prior art]
As a device that applies a signal discriminator and transmits a signal in a voice frequency band, for example, a digital circuit multiplexing device (Digital Circuit Multiplexing Equipment, hereinafter referred to as DCME) as disclosed in Japanese Patent Laid-Open No. 9-312705 There is.
[0003]
FIG. 22 is a block diagram showing an example of the configuration of this DCME, which is necessary for the description of the embodiment later based on the configuration diagram of the conventional DCME disclosed in Japanese Patent Laid-Open No. 9-312705. The components are shown.
[0004]
In the figure, S20 is an M channel input signal to DCME, and 6 is a sound detection unit that determines whether each of the M channel input signals S20 is in a sound state or a silence state and outputs a determination result. 1 is a signal identification unit, 2 is an audio / data identification unit that determines whether each of the M channel input signals S20 is an audio signal or an audio band data signal, and outputs the determination result; Based on the sound detection result and the signal identification result, an encoding unit 21 and a frame generation unit 22 which will be described later are controlled, and the control information S23 is the same as the device on the opposite side (not shown in FIG. 22). Device).
[0005]
The encoding unit 21 includes m encoders therein, and performs m-efficiency encoding of the m-channel signal among the M-channel input signal S20 in accordance with an instruction from the transmission control unit 23. Also, the frame generation unit 22 assigns the m-channel encoded signal to bits in a predetermined DCME frame according to an instruction from the transmission control unit 23, and outputs the generated DCME frame to the opposite device side. 3 is a 2100 Hz detection unit that determines the presence or absence of a 2100 Hz tone with respect to the input signal S20 and outputs the determination result. 4 is a 2400 Hz detection that determines the presence or absence of a 2400 Hz tone with respect to the input signal S20 and outputs the determination result. Part. The sound detection unit 6, the voice / data identification unit 2, the transmission control unit 23, the encoding unit 21, the frame generation unit 22, the 2100 Hz detection unit 3, and the 2400 Hz detection unit 4 realize the function of the DCME transmission unit 20. The
[0006]
Reference numeral 31 denotes a reception control unit that controls a later-described decoding unit 33 and frame decomposition unit 32 based on the control information S31 received from the opposite device side. The frame decomposition unit 32 decomposes the DCME frame S32 received from the opposite device side into an encoded signal in accordance with an instruction from the reception control unit 31, and outputs this to the decoding unit 33. The decoding unit 33 has m decoders therein, and decodes m-channel encoded signals in accordance with instructions from the reception control unit 31. The reception control unit 31, the frame decomposition unit 32, and the decoding unit 33 realize the function of the DCME reception unit 30.
[0007]
Next, the operation of the DCME transmission unit 20 shown in FIG. 22 will be described.
In conversational voice signals such as telephone calls, it is known that the other party is listening and silent time is about 60 to 70% of the total call time. In particular, transmission of a voice channel signal together with an m-channel line (m is a value smaller than M) enables transmission to be highly efficient. In DCME, the sound detection unit 6 determines whether each input signal S20 of the M channel is sound or silence, and sends the determination result to the transmission control unit 23. The transmission control unit 23 Based on the determination result, among the M channel input signals S20, the channel determined to be sound is preferentially assigned to m encoders (m is a value smaller than M) in the encoding unit 21. As such, the encoder 21 is notified of control information related to the allocation of input channels and encoders.
[0008]
The encoding unit 21 performs high-efficiency encoding on the input signal assigned to the m encoders, and outputs the encoded signal. As an encoding algorithm used in the encoding unit 21, for example, ITU-T Recommendation G. 726, there is an adaptive differential pulse code modulation (hereinafter referred to as ADPCM) system. In this ADPCM system, an input signal with a transmission rate of 64 kbit / s, 40 kbit / s, 32 kbit / s, 24 kbit is used. / S and 16 kbit / s can be compressed and encoded.
[0009]
When the encoder 21 uses this ADPCM method, it is desirable to determine which encoding speed is selected depending on whether the input signal is an audio signal or an audio band data signal. That is, when the input signal is a voice signal, the line can be used more efficiently if the coding speed is kept low as long as the voice quality that does not hinder the call can be maintained. , 32 kbit / s or less. On the other hand, when the input signal is a voice band data signal, it is necessary to set the encoding rate to a higher 40 kbit / s so that no transmission error occurs. Thus, in order to appropriately determine the encoding speed of the encoding unit 21, the audio / data identification unit 2 that determines whether the input signal is an audio signal or an audio band data signal is necessary.
[0010]
In the DCME shown in FIG. 22, the voice / data identifying unit 2 determines whether each of the M channel input signals S20 is a voice signal ("voice") or a voice band data signal ("data"). This determination result is sent to the transmission control unit 23. The transmission control unit 23, based on the determination result, in the encoding unit 21 to which the channel determined to be “data” in the input signal S20 is assigned. Is set to 40 kbit / s, and the encoding rate of the encoder in the encoding unit 21 to which the channel determined to be “speech” in the input signal S20 is assigned is 32 kbit / s, Control information related to the encoding rate of the encoder is notified to the encoding unit 21 so that it is set to either 24 kbit / s or 16 kbit / s.
[0011]
The transmission control unit 23 also notifies the frame generation unit 22 of control information related to the allocation of each encoded channel signal output from the encoding unit 21 and bits in a predetermined DCME frame, thereby generating a frame. Based on this control information, the unit 22 allocates the encoded signal of each channel and the bits in the DCME frame, and transmits the generated data of the DCME frame S22 to the opposite device side.
[0012]
Also, the transmission control unit 23 controls information regarding the allocation between the input signal of the M channel and the encoder, control information regarding the encoding rate in ADPCM encoding, and allocation between the encoded signal and the bits in the DCME frame The control information S23 regarding is transmitted to the opposite device side.
[0013]
The voice / data identification unit 2 inputs the output of the 2100 Hz detection unit 3, the output of the 2400 Hz detection unit 4, and the output of the reception control unit 31. Based on these signals, the determination result is “voice” or “ Reset to “Data”.
[0014]
First, the 2100 Hz detection unit 3 determines whether or not a 2100 Hz tone signal exists in the input signal S <b> 20 by performing processing such as frequency analysis on the input signal S <b> 20, and when the 2100 Hz tone signal exists Outputs “1”, or “0” if it does not exist, as a 2100 Hz detection result. Then, the voice / data identification unit 2 inputs the 2100 Hz detection result, and when the 2100 Hz tone is detected, sets the determination result to “data”.
[0015]
In addition, the 2400 Hz detection unit 4 determines whether or not a 2400 Hz tone signal exists in the input signal S20 by performing processing such as frequency analysis on the input signal S20, and when the 2400 Hz tone signal exists Outputs “1”, or “0” if it does not exist as a 2400 Hz detection result. Then, the voice / data identification unit 2 inputs the 2400 Hz detection result, and when the 2400 Hz tone is detected, resets the determination result to “voice”.
[0016]
Also, the voice / data identification unit 2 inputs the reception side signal identification state from the reception control unit 31 and detects the rising of the reception side signal identification state from “0” (voice) to “1” (data). If so, the determination result is set to “data”.
[0017]
Next, the operation of the DCME receiving unit 30 shown in FIG. 22 will be described.
The reception control unit 31 receives various control information S31 sent by the transmission control unit on the opposite device side, and sends control information to the frame decomposition unit 32 and the decoding unit 33 based on the various control information.
[0018]
Further, the reception control unit 31 determines whether the identification state of the reception side signal is “speech” or “data” based on the received control information S31 related to the encoding rate in ADPCM encoding, and the result is Output to the voice / data identification unit 2. As described above, this output is used by the voice / data identification unit 2 to set the determination result to “data”.
[0019]
The frame decomposing unit 32 receives from the reception control unit 31 control information regarding the allocation of the bits in the DCME frame received from the opposite device side and the encoded data output to the decoding unit 33, and based on this control information The DCME frame S32 received from the opposite device side is decomposed and the encoded signal is output to the decoding unit 33.
[0020]
Next, the decoding unit 33 receives from the reception control unit 31 control information related to the coding rate of each channel and control information related to the allocation of m decoders in the decoding unit 33 and the output of M channels from the DCME. Then, based on this control information, the encoded signal received from the frame decomposing unit 32 is allocated to one of the m decoders in the decoding unit 33, decoded at an appropriate encoding rate, and decoded. The signal of each channel is assigned to one of M channels output from DCME, and output as an output signal S33.
[0021]
[Problems to be solved by the invention]
In recent years, facsimile modems and data modems have been improved in transmission speed. 17, V. 29, V.R. 27ter, V.I. 21. In addition to V.21 having a transmission rate of 28.8 kbit / s. A modem employing the 34 modulation method has been developed. When a data modem terminal equipped with a 34 modulation scheme is connected to a conventional DCME, there is a problem that a transmission error occurs for the reason described below.
[0022]
The reason why such a problem occurs will be described below.
FIG. The start-up sequence in the modem communication procedure by 34 modulation system is shown.
[0023]
In the figure, each signal of phase 1 (indicated by F1 in the figure) is ITU-T recommendation V. 8 is defined as follows. The CI signal is called a call indication signal. 21 channel No. 1 (low-band channel) 300 bit / s signal and ANSam signal are called modified response tone signals. A signal obtained by inverting the phase of a 2100 Hz sine wave at an interval of 450 ms and further modulating the amplitude at 15 Hz, the CM signal is a calling menu signal. V. 21 channel No. 1 (low-band channel) 300 bit / s signal, a signal declaring a modulation method that can be used mainly by a calling terminal, a JM signal is called a common menu signal. 21 channel No. 2 (high band channel) 300 bit / s signal, a signal declaring a modulation scheme that can be commonly used by the calling terminal and the called terminal, and the CJ signal are called CM end terminals. 21 channel No. 1 (low frequency channel) is a 300 bit / s signal, and is a signal indicating the detection confirmation of the JM signal and the end of the CM signal.
[0024]
In each signal of phase 2 (indicated by F2 in the figure), tone A is a 2400 Hz tone transmitted from the answering modem. Tone B is a 1200 Hz tone sent from the calling modem. The INFO sequence is a signal used to exchange modem capabilities, line probing results, and data mode modulation parameters and is sent using binary DPSK modulation at 600 bits / s plus or minus 0.01%. Also, two sets of (INFO0a, INFO0c) and (INFO1a, INFO1c) are used for the INFO sequence. ("A" means the sequence sent by the answering modem and "c" means the INFO sequence sent by the calling modem).
[0025]
V. as described above. When a modem signal in the 34 modulation system is input to the DCME having the configuration shown in FIG. 22, the 2400 Hz detection unit 4 detects the tone A transmitted from the response modem, that is, the 2400 Hz tone. The unit 2 resets the determination result to “voice”. Then, since the encoding speed of the encoder in the encoding unit 21 is set to any one of 32 kbit / s, 24 kbit / s, and 16 kbit / s, there is a possibility that the transmission of the modem signal may be hindered.
[0026]
ITU-T recommendation G.1, which specifies DCME requirements. 763 defines that the signal discriminator determines “speech” when a 2400 Hz tone signal is input. In this way, the 2400 Hz tone signal is No. Used for 5 signaling line signaling tones and channel check test signals. These signals are judged to be “voice” and transmitted at a rate of 32 kbit / s, 24 kbit / s, or 16 kbit / s. It is because it is intended to make it. However, the 2400 Hz tone is V. It is also used in the start-up procedure for 34 modems. When designed according to the provisions of 763, V. There is a problem that a problem arises in the transmission of the modem signal by determining “voice” for the 2400 Hz tone transmitted during the communication of the 34 modem.
[0027]
The present invention has been made to solve the above-described problems. It is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method. It is an object of the present invention to obtain a signal discriminator, a signal discriminating method, and a transmission apparatus capable of normally transmitting 34 modem signals.
[0028]
[Means for Solving the Problems]
The signal discriminator according to the present invention is a signal discriminator for discriminating the type of an input signal into two types, voice and data, and a first detecting means for detecting a tone signal of a specific frequency from the input signal, and the input signal Second detection means for detecting a specific signal used in the startup procedure of the modem signal, and identification means for identifying the type of the input signal based on the outputs of the first and second detection means, The identification means is The specific signal above Undetected When the above tone signal is detected In The signal identification result is voice, but the specific signal is detected In a finished state When the above tone signal is detected In The signal identification result is not voiced.
[0029]
In the signal discriminator according to the present invention, the start-up procedure is V. 34 procedures.
[0030]
In the signal discriminator according to the present invention, the start-up procedure is V. There are 8 procedures.
[0031]
In the signal discriminator according to the present invention, the second detection means is a V.V. ANSam signal detector for detecting ANSam signals in 8 procedures.
[0032]
The signal discriminator according to the present invention uses a third detecting means for detecting a tone signal of a specific frequency from the input signal instead of the ANSam signal detector.
[0033]
The signal discriminator according to the present invention is The second detection means is a 2100 Hz detector that detects a 2100 Hz tone signal. .
[0034]
In the signal discriminator according to the present invention, the second detection means is a V.V. V. 8 in procedure. 21 (channel No. 2) 21 modem signal detector.
[0035]
In the signal discriminator according to the present invention, the second detection means is a V.V. It is a JM signal detector that detects JM signals in 8 procedures.
[0036]
The signal discriminator according to the present invention is an INFO0a signal detector in which the second detection means detects an INFO0a signal during a startup procedure.
[0037]
The signal discriminator according to the present invention includes a sound detector for determining the sound / silence state of the input signal, and after detecting a specific signal used in the startup procedure of the modem signal, the silence state is predetermined. When the time continues, the detection state of the specific signal is initialized.
[0038]
The signal discriminator according to the present invention includes a first sound detector that determines the sound / silence state of the transmission-side signal and a second sound detection that determines the sound / silence state of the reception-side signal. And detecting a specific signal used in a modem signal start-up procedure, and when the state where there is no sound in both the transmission side and the reception side continues for a predetermined period of time. It is to be initialized.
[0039]
The signal discriminator according to the present invention includes a continuity test tone detector for detecting a tone signal of a specific frequency transmitted for the continuity test of the channel from the input signal, and is used in the startup procedure of the modem signal. After detecting a specific signal, the detection state of the specific signal is initialized when a tone signal of a specific frequency transmitted for the continuity test of the channel is detected.
[0040]
In the signal discriminator according to the present invention, the tone signal of the specific frequency detected by the continuity test tone detector is a 2000 Hz tone signal.
[0041]
In the signal discriminator according to the present invention, the tone signal of the specific frequency detected by the first detecting means is a 2400 Hz tone signal.
[0042]
The signal identification method according to the present invention is a signal identification method for identifying a type of an input signal into two types of sound and data, wherein a first step of detecting a tone signal of a specific frequency from the input signal, and the input signal A second step of detecting a specific signal used in a modem signal start-up procedure; and a third step of setting a specific signal detection flag when the specific signal is detected. Not set In state When a tone signal with the specified frequency is detected In The signal identification result is audio, but the specific signal detection flag is set In state When a tone signal with the specified frequency is detected In The signal identification result is not voiced.
[0043]
Further, in the signal identification method according to the present invention, the start-up procedure is as follows. 34 procedures.
[0044]
Further, in the signal identification method according to the present invention, the start-up procedure is as follows. There are 8 procedures.
[0045]
Further, in the signal identification method according to the present invention, the specific signal is V.P. ANSam signal in 8 procedures.
[0046]
The signal identification method according to the present invention uses a tone signal of a specific frequency included in the input signal instead of the ANSam signal.
[0047]
In addition, the signal identification method according to the present invention includes: The specific signal is It is a 2100 Hz tone signal.
[0048]
Further, in the signal identification method according to the present invention, the specific signal is V.P. V. 8 in procedure. 21 (channel No. 2) is a modem signal.
[0049]
Further, in the signal identification method according to the present invention, the specific signal is V.P. It is a JM signal in 8 procedures.
[0050]
In the signal identification method according to the present invention, the specific signal is an INFO0a signal during a startup procedure.
[0051]
In addition, the signal identification method according to the present invention initializes the specific signal detection flag when a silence state continues for a predetermined time after detecting a specific signal used in the startup procedure of the modem signal. .
[0052]
In addition, the signal identification method according to the present invention is the above-mentioned when a state in which both the transmission side and the reception side are silent continues for a predetermined time after detecting a specific signal used in the startup procedure of the modem signal. It initializes the detection state of a specific signal.
[0053]
In addition, the signal identification method according to the present invention includes a fourth step of detecting a tone signal of a specific frequency transmitted for a channel continuity test from the input signal, and is used in the start-up procedure of the modem signal. When a tone signal of a specific frequency transmitted for the continuity test of the channel is detected after detecting this signal, the detection state of the specific signal is initialized.
[0054]
In the signal identification method according to the present invention, the tone signal of the specific frequency detected in the fourth step is a 2000 Hz tone signal.
[0055]
In the signal identification method according to the present invention, the tone signal of the specific frequency detected in the first step is a 2400 Hz tone signal.
[0056]
Moreover, the transmission apparatus according to the present invention is based on the signal discriminator according to any one of claims 1 to 14 that discriminates the type of input signal into two types, voice and data, and the signal discrimination result of the signal discriminator. Encoding means for performing high-efficiency speech encoding at an appropriate encoding speed, transmitting means for transmitting encoded data encoded by the encoding means, and receiving encoded data encoded from the opposite device side The apparatus comprises a receiving means and a decoding means for decoding the encoded data received by the receiving means.
[0057]
The signal discriminator according to the present invention is a guard tone signal detector in which the second detecting means detects a guard tone signal of a modem.
[0058]
In the signal discriminator according to the present invention, the signal detected by the guard tone signal detector is a 1800 Hz tone signal.
[0059]
In the signal discriminator according to the present invention, the signal discrimination result is not voiced for a predetermined time after the first detection means detects the tone signal of the specific frequency.
[0060]
In the signal discriminator according to the present invention, the signal discrimination result is not voiced for a predetermined time after the guard tone signal detector stops detecting the guard tone signal.
[0061]
The signal discriminator according to the present invention comprises a signal level comparator for comparing the level of a tone signal of a specific frequency detected by the first detecting means with the level of a guard tone signal detected by the guard tone signal detector. If the level ratio between the tone signal of the specific frequency and the guard tone signal is within a predetermined range, the signal identification result when the tone signal of the specific frequency is detected is not voice, but the level ratio is predetermined. If it is not within the range, the signal identification result when the tone signal of the specific frequency is detected is the voice.
[0062]
The signal identification method according to the present invention is a signal identification method for identifying a type of an input signal into two types of sound and data, wherein a first step of detecting a tone signal of a specific frequency from the input signal, and the input signal A second step of detecting a specific signal used in a modem signal start-up procedure, wherein the specific signal is not detected In state When a tone signal with the specified frequency is detected In The result of signal identification is voice, but the specific signal is detected In state When a tone signal with the specified frequency is detected In The signal identification result is not voiced.
[0063]
In the signal identification method according to the present invention, the specific signal is a guard tone signal of a modem.
[0064]
In the signal identification method according to the present invention, the guard tone signal of the modem is a 1800 Hz tone signal.
[0065]
The signal identifying method according to the present invention includes a fifth step of setting a first timer when the specific signal is detected, and a predetermined time has not elapsed after the first timer is set. The signal identification result when the tone signal of the specific frequency is detected is not voice.
[0066]
The signal identification method according to the present invention includes a sixth step of setting a second timer when the guard tone signal is no longer detected, and a predetermined time has elapsed after the second timer is set. If not, the signal identification result when the tone signal of the specific frequency is detected is not voice.
[0067]
The signal identification method according to the present invention includes a seventh step of determining whether or not a level ratio of the tone signal of the specific frequency and the level of the guard tone signal is within a predetermined range, and the level ratio When the tone signal of the specific frequency is detected, the signal identification result when the tone signal of the specific frequency is detected is not voice, but when the level ratio is not within the predetermined range, the tone signal of the specific frequency is detected. In this case, the signal identification result is a voice.
[0068]
A transmission apparatus according to the present invention is suitable for a signal discriminator according to any one of claims 30 to 34, wherein the input signal type is classified into two types, voice and data, and based on the signal discrimination result of the signal discriminator. Encoding means for performing high-efficiency speech encoding at an encoding rate, transmitting means for transmitting encoded data encoded by the encoding means, and receiving means for receiving encoded data encoded from the opposite device side And decoding means for decoding the encoded data received by the receiving means.
[0069]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Embodiment 1 FIG.
FIG. 1 is a configuration block diagram showing Embodiment 1 of the present invention.
In the figure, 1A is a signal identification unit, 2A is a voice / data identification unit as identification unit, 3 is a 2100Hz detection unit, 4 is a 2400Hz detection unit as a first detection unit, and 5 is an ANSam as a second detection unit. A signal detection unit (ANSam signal detector), 6 is a sound detection unit (sound detector), and 7 is a hangover addition unit. Here, the components 1A, 6 and 7 substantially constitute a signal discriminator.
[0070]
Next, the operation of FIG. 1 will be described.
An input signal from the terminal side is input to the signal identification unit 1A, and signal detection is performed in each of the voice / data identification unit 2A, 2100Hz detection unit 3, 2400Hz detection unit 4, and ANSam signal detection unit 5 in the signal identification unit 1A.・ Analysis processing is performed. Further, an input signal from the terminal side is input to the sound detection unit 6 and a sound / silence determination process is performed.
[0071]
The 2100 Hz detection unit 3 determines the presence or absence of a 2100 Hz tone signal, for example, by performing frequency analysis on the input signal, and outputs the determination result to the voice / data identification unit 2A.
The 2400 Hz detection unit 4 determines the presence or absence of a 2400 Hz tone signal, for example, by performing frequency analysis on the input signal, and outputs the determination result to the voice / data identification unit 2A.
[0072]
The ANSam signal detection unit 5 determines the presence or absence of an amplitude-modulated 2100 Hz tone signal called an ANSam signal, for example, by performing frequency analysis or signal strength analysis on the input signal, and the determination result is voiced. / Output to the data identification unit 2A.
The sound detection unit 6 determines the sound / no sound by measuring the signal strength of the input signal, for example, and outputs the determination result to the hangover adding unit 7.
[0073]
The hangover adding unit 7 performs a hangover adding process for holding the sound state for a predetermined time after the output of the sound detecting unit 6 changes from the sound state to the soundless state, and the sound / The silence determination result is output to the voice / data identification unit 2A. This hangover time (the predetermined time) is V. 34. Set a value longer than the silent time during transmission / reception of the modem signal. It is necessary to keep the sound state during transmission / reception of 34 modem signals.
[0074]
The voice / data identification unit 2A analyzes, for example, the number of zero crossings and signal strength of the input signal, thereby determining whether the type of the input signal is a voice signal (“voice”) or a voice band data signal (“data”). ) And output the determination result.
Also, the voice / data identification unit 2A inputs the determination results from each of the 2100 Hz detection unit 3, the 2400 Hz detection unit 4, the ANSam signal detection unit 5, and the hangover addition unit 7, and the signal identification state according to the input determination result Reset to “Voice” or “Data”.
[0075]
First, when a 2100 Hz tone is detected, the voice / data identification unit 2A sets the signal identification state to “data”.
When a 2400 Hz tone is detected, if the ANSam signal has already been detected, V. It is determined that the tone is 2400 Hz transmitted during the data call by the 34 modem, and the signal identification state is set to “data”. On the other hand, when the ANSam signal is not detected, V.I. For example, No. 34 is not a tone used in the middle of a data call by a 34 modem. It is determined that this is a 2400 Hz tone signal used for 5 signaling line signaling or channel check test, and the signal identification state is reset to “voice”.
[0076]
The sound / silence determination result from the hangover adding unit 7 is obtained from the V.V. 34 used to detect the end of a data call by a modem.
[0077]
FIG. 2 is a flowchart for explaining the operation of the voice / data identification unit 2A.
When the voice / data identification unit 2A starts processing, first, the current signal identification state is checked (step ST1). If it is in the “voice” state, the process proceeds to step ST2, and if it is in the “data” state, the process proceeds to step ST7. move on.
[0078]
First, when the current signal identification state is “voice”, the presence or absence of a voice band data signal (VBD) is determined, for example, by analyzing the number of zero crossings and signal strength of the input signal (step ST2). ) If a voice band data signal is detected, the signal identification state is set to “data” (step ST3), and the process is terminated.
[0079]
If no audio band data signal is detected in step ST2, then the 2100Hz tone presence / absence judgment result input from the 2100Hz detector 3 is checked (step ST4), and a 2100Hz tone is detected. Sets the signal identification state to “data” (step ST3), and ends the process.
[0080]
In step ST4, when 2100 Hz is not detected, the determination result of the presence or absence of the ANSam signal input from the ANSam signal detection unit 5 is checked (step ST5). If the ANSam signal is detected, the specific signal detection is performed. The flag is set to 1 (step ST6), and the process ends.
In step ST5, when the ANSam signal is not detected, the processing is ended as it is.
[0081]
Next, when the current signal identification state is “data”, the presence or absence of an audio signal is determined by analyzing the number of zero crossings and the signal intensity, for example, with respect to the input signal (step ST7). Is detected, the signal identification state is reset to “voice” (step ST8), and the process is terminated.
[0082]
If no audio signal is detected in step ST7, then the determination result of the presence or absence of the ANSam signal input from the ANSam signal detection unit 5 is checked (step ST9). If the ANSam signal is detected, Then, the specific signal detection flag is set (step ST10).
[0083]
Next, the voice / silence determination result after adding the hangover input from the hangover adding unit 7 is checked (step ST11). When the hangover time expires and the silent state is entered, the specific signal detection flag is cleared to zero. (Step ST12).
[0084]
Next, the 2400 Hz tone presence / absence determination result input from the 2400 Hz detection unit 4 is checked (step ST13). If the 2400 Hz tone is detected, the state of the specific signal detection flag is continuously checked (step ST14). If the specific signal detection flag is not set to 1 (specific signal not detected), the signal identification state is reset to “voice” (step ST15), and the process ends.
In step ST13, when the 2400 Hz tone is not detected, the processing is ended as it is.
[0085]
FIG. 34 is a diagram for explaining an operation when a modem signal is input to the signal identification unit 1A. The state of each part when the output signal of 34 response modems is input into this signal identification part 1A is shown.
In the figure, when the answer modem sends an ANSam signal, this ANSam signal is a signal obtained by amplitude-modulating a 2100 Hz tone signal and has a large power component of 2100 Hz, so the 2100 Hz detector 3 detects the 2100 Hz tone, The voice / data identification unit 2A thereby sets the identification result to the “data” state (steps ST3 and ST4).
[0086]
Further, since the ANSam signal detection unit 5 detects the ANSam signal, the specific signal detection flag is set (steps ST5 and ST6 or steps ST9 and ST10).
Thereafter, since the 2400 Hz tone is transmitted from the response modem, the 2400 Hz detector 4 detects the 2400 Hz tone. However, since the specific signal detection flag is already set, the signal identification state is not reset to “voice”. , The “data” state is maintained (steps ST13 and ST14).
[0087]
This V. When the transmission of the 34 modem signal is completed and the silent time of a predetermined time or longer is continued thereafter, the output of the hangover adding unit 7 becomes silent, and thus the specific signal detection flag is cleared to 0 (steps ST11 and ST12).
[0088]
As described above, in this embodiment, V.V. Specific signals used in the 34 modem signal start-up procedure include: Means for detecting the ANSam signal during the 8 steps, and when the ANSam signal is detected, the signal identification state is not reset to “voice” even if the 2400 Hz tone is detected; There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0089]
In this embodiment, the voice / data identification unit 2A Determines whether the type of the input signal is a voice signal (“voice”) or a voice band data signal (“data”) by analyzing the number of zero crossings and signal strength of the input signal. In the above description, the determination result is output. However, the present invention is not limited to this, and the determination may be made by using other analysis means.
[0090]
In addition, the detection algorithm of each part of the 2100 Hz detection unit 3, the 2400 Hz detection unit 4, the ANSam signal detection unit 5, and the sound detection unit 6 is not limited to the method described in the present embodiment.
[0091]
Embodiment 2. FIG.
In the first embodiment, V.I. Specific signals used in the 34 modem signal start-up procedure include: It has a means to detect the ANSam signal in 8 procedures, and when detecting the ANSam signal, the signal identification state is not reset to “speech” even if the 2400 Hz tone is detected, but it is not limited to the ANSam signal. V. Other signals in the eight procedures, e.g. 21 channel No. Two modem signals may be detected.
[0092]
FIG. 4 is a block diagram showing the configuration of the second embodiment of the present invention.
In the figure, 1B is a signal identification unit, 2B is a voice / data identification unit as identification means, 3 is a 2100 Hz detection unit, 4 is a 2400 Hz detection unit, 6 is a sound detection unit, 7 is a hangover addition unit, and 8 is a second As a detection means for V. 21 channel No. 2 is a modem signal detector. Here, the components 1B, 6 and 7 substantially constitute a signal discriminator.
[0093]
Next, the operation of FIG. 4 will be described.
The operations of the 2100 Hz detection unit 3, the 2400 Hz detection unit 4, the sound detection unit 6, and the hangover addition unit 7 are the same as those in the first embodiment.
[0094]
V. 21 channel No. 2 modem signal detector 8 is an ITU recommendation V.3. 21, channel No. The presence / absence of a modem signal modulated by the two methods is determined, and the determination result is output to the voice / data identification unit 2B. V. The JM signal in the 8 procedures is the V. 21 channel No. 2 is a signal modulated by the FSK (frequency shift) method in which 1750 Hz is used as the carrier frequency and the binary code “0/1” corresponds to a frequency of plus or minus 100 Hz. The data rate is 300 bits / s.
[0095]
The voice / data identification unit 2B analyzes the input signal and determines whether the type of the input signal is a voice signal (“voice”) or a voice band data signal (“data”). The voice / data identification unit 2B includes a 2100 Hz detection unit 3, a 2400 Hz detection unit 4, a sound detection unit 6, a hangover addition unit 7, 21 channel No. 2 The determination result from each part of the modem signal detection unit 8 is input, and the signal identification state is reset to “voice” or “data” according to the input determination result.
[0096]
First, when a 2100 Hz tone is detected, the voice / data identification unit 2B sets the signal identification state to “data”.
If a 2400 Hz tone is detected, V. 21 channel No. 2 If the modem signal has already been detected, It is determined that the tone is 2400 Hz transmitted during the data call by the 34 modem, and the signal identification state is set to “data”. V. 21 channel No. 2 If the modem signal is not detected, For example, No. 34 is not a tone used in the middle of a data call by a 34 modem. It is determined that this is a 2400 Hz tone signal used for 5 signaling line signaling or channel check test, and the signal identification state is reset to “voice”.
[0097]
The sound / silence determination result from the hangover adding unit 7 is obtained from the V.V. 34 used to detect the end of a data call by a modem.
[0098]
FIG. 5 is a flowchart for explaining the operation of the voice / data identification unit 2B. Except for step ST9b in the figure, the operation is the same as that of the first embodiment described with reference to FIG.
[0099]
In the first embodiment (FIG. 2), the voice / data identifying unit 2B checks the determination result of the presence / absence of the ANSam signal input from the ANSam signal detection unit 5 in step ST5 and step ST9, and the ANSam signal is detected. However, in the present embodiment (FIG. 5), in step ST9b, the specific signal detection flag is set to 1. 21 channel No. 2 V.2 input from the modem signal detector 8 21 channel No. 2 Check the result of modem signal presence / absence check. 21 channel No. If two modem signals are detected, the specific signal detection flag is set to 1.
[0100]
FIG. 34 is a diagram for explaining the operation when a modem signal is input to the signal identification unit 1B. The state of each part when the output signal of 34 response modems is input into this signal identification part 1B is shown.
In the figure, when the answer modem sends an ANSam signal, the ANSam signal is a signal obtained by amplitude-modulating a 2100 Hz tone signal and has a large power component of 2100 Hz, so the 2100 Hz detector 3 detects the 2100 Hz tone, The voice / data identification unit 2B thereby sets the identification result to the “data” state (steps ST3 and ST4).
[0101]
Thereafter, V. 21 channel No. Since a JM signal modulated by the two methods is transmitted, V. 21 channel No. 2 The modem signal detector 8 21 channel No. Two modem signals are detected, and a specific signal detection flag is set (steps ST9b and ST10).
[0102]
Thereafter, since the 2400 Hz tone is transmitted from the response modem, the 2400 Hz detector 4 detects the 2400 Hz tone. However, since the specific signal detection flag is already set, the signal identification state is not reset to “voice”. , The “data” state is maintained (step 13, ST14).
[0103]
This V. When the transmission of the 34 modem signal is completed and the silent time of a predetermined time or longer is continued thereafter, the output of the hangover adding unit 7 becomes silent, and thus the specific signal detection flag is cleared to 0 (steps ST11 and ST12).
[0104]
As described above, in this embodiment, V.V. Specific signals used in the 34 modem signal start-up procedure include: V. 8 in procedure. 21 channel No. Means for detecting two modem signals; 21 channel No. When a 2 modem signal is detected, the signal identification state is not reset to “voice” even if a 2400 Hz tone is detected. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0105]
Embodiment 3 FIG.
In the second embodiment, V.I. Specific signals used in the 34 modem signal start-up procedure include: V. 8 in procedure. 21 channel No. Means for detecting two modem signals; 21 channel No. When a 2 modem signal is detected, the signal identification state is not reset to “voice” even if a 2400 Hz tone is detected. 21 channel No. 2 Demodulate modem signal, analyze demodulated data, set specific signal detection flag when JM signal sync code is detected, reset signal identification status to “voice” even if 2400Hz tone is detected You may comprise so that it may not.
[0106]
In this way, as in the second embodiment, V.P. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0107]
Embodiment 4 FIG.
In the first and second embodiments, the V.V. Specific signals used in the 34 modem signal start-up procedure include: Means for detecting a signal (ANSam signal or V.21 channel No. 2 modem signal) during 8 procedures; When a signal in 8 steps is detected, the signal identification state is not reset to “voice” even if a 2400 Hz tone is detected. Not only the signals in 8 procedures, but V. Another signal used in the start-up procedure of the 34 modem signal, for example, the INFO0a signal may be detected.
[0108]
FIG. 7 is a block diagram showing the configuration of the fourth embodiment of the present invention.
In the figure, 1C is a signal identification unit, 2C is a voice / data identification unit as identification means, 3 is a 2100Hz detection unit, 4 is a 2400Hz detection unit, 6 is a sound detection unit, 7 is a hangover addition unit, and 9 is a second It is an INFO0a signal detection part as a detection means. Here, the components 1C, 6 and 7 substantially constitute a signal discriminator.
[0109]
Next, the operation of FIG. 7 will be described.
The operations of the 2100 Hz detection unit 3, the 2400 Hz detection unit 4, the sound detection unit 6, and the hangover addition unit 7 are the same as those in the first embodiment.
[0110]
The INFO0a signal detection section 9 The presence / absence of the INFO0a signal in the signal of phase 2 (F2 in FIG. 16) of the startup sequence in the modem communication procedure in the 34 modulation scheme is determined, and the determination result is output to the voice / data identification unit 2C. . This INFO0a signal is a signal transmitted using binary DPSK modulation at 600 bits / s plus or minus 0.01%.
[0111]
The voice / data identification unit 2C analyzes the input signal and determines whether the type of the input signal is a voice signal (“voice”) or a voice band data signal (“data”).
Further, the voice / data identification unit 2C inputs the determination results from each of the 2100 Hz detection unit 3, the 2400 Hz detection unit 4, the sound detection unit 6, the hangover addition unit 7, and the INFO0a signal detection unit 9, and the input determination result In response to this, the signal identification state is reset to “voice” or “data”.
[0112]
First, when a 2100 Hz tone is detected, the voice / data identification unit 2C sets the signal identification state to “data”.
Further, when the 2400 Hz tone is detected, the V.O. It is determined that the tone is 2400 Hz transmitted during the data call by the 34 modem, and the signal identification state is set to “data”. On the other hand, if the INFO0a signal is not detected, V. For example, No. 34 is not a tone used in the middle of a data call by a 34 modem. It is determined that this is a 2400 Hz tone signal used for 5 signaling line signaling or channel check test, and the signal identification state is reset to “voice”.
[0113]
The sound / silence determination result from the hangover adding unit 7 is obtained from the V.V. 34 used to detect the end of a data call by a modem.
[0114]
FIG. 8 is a flowchart for explaining the operation of the voice / data identifying unit 2C. Except for step ST9c in the figure, the operation is the same as that of the first embodiment described with reference to FIG.
[0115]
In the first embodiment (FIG. 2), the voice / data identification unit 2C checks the determination result of the presence / absence of the ANSam signal input from the ANSam signal detection unit 5 in step ST5 and step ST9, and the ANSam signal is detected. In the present embodiment (FIG. 8), the determination result of the presence or absence of the INFO0a signal input from the INFO0a signal detection unit 9 is set in step ST9c in the present embodiment (FIG. 8). When the INFO0a signal is detected, the specific signal detection flag is set to 1.
[0116]
FIG. 34 is a diagram for explaining the operation when a modem signal is input to the signal identification unit 1C. The state of each part when the output signal of 34 response modems is input into this signal identification part 1C is shown.
In the figure, when the answer modem sends an ANSam signal, the ANSam signal is a signal obtained by amplitude-modulating a 2100 Hz tone signal and has a large power component of 2100 Hz, so the 2100 Hz detector 3 detects the 2100 Hz tone, The voice / data identification unit 2C thereby sets the identification result to the “data” state (steps ST3 and ST4).
[0117]
Thereafter, since the INFO0a signal is transmitted from the response modem, the INFO0a signal detector 9 detects the INFO0a signal, and the specific signal detection flag is set (steps ST9c and ST10).
[0118]
Thereafter, since the 2400 Hz tone is transmitted from the response modem, the 2400 Hz detector 4 detects the 2400 Hz tone. However, since the specific signal detection flag is already set, the signal identification state is not reset to “voice”. , The “data” state is maintained (steps ST13 and ST14).
[0119]
This V. When the transmission of the 34 modem signal is completed and the silent time of a predetermined time or longer is continued thereafter, the output of the hangover adding unit 7 becomes silent, and thus the specific signal detection flag is cleared to 0 (steps ST11 and ST12).
[0120]
As described above, in the second embodiment, V.D. As a specific signal used in the start-up procedure of the 34 modem signal, a means for detecting the INFO0a signal is provided. When the INFO0a signal is detected, the signal identification state is not reset to “voice” even if the 2400 Hz tone is detected. By doing V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0121]
Embodiment 5 FIG.
In the first embodiment, V.I. Specific signals used in the 34 modem signal start-up procedure include: There is a means to detect the ANSam signal in 8 procedures, and when the ANSam signal is detected, the signal identification state is not reset to “speech” even if the 2400 Hz tone is detected, but instead of detecting the ANSam signal Alternatively, detection of a 2100 Hz tone may be substituted.
FIG. 10 is a block diagram showing the configuration of the fifth embodiment of the present invention.
In the figure, 1D is a signal identification unit, 2D is a voice / data identification unit as identification means, 3 is a 2100 Hz detection unit, 4 is a 2400 Hz detection unit, 6 is a sound detection unit, and 7 is a hangover addition unit. Here, the components 1D, 6 and 7 substantially constitute a signal discriminator.
[0122]
Next, the operation of FIG. 10 will be described.
The operations of the 2100 Hz detection unit 3, the 2400 Hz detection unit 4, the sound detection unit 6, and the hangover addition unit 7 are the same as those in the first embodiment.
[0123]
The voice / data identification unit 2D analyzes, for example, the number of zero crossings and signal strength of the input signal, thereby determining whether the type of the input signal is a voice signal (“voice”) or a voice band data signal (“data”). ) And output the determination result.
Further, the voice / data identification unit 2D inputs the determination results from the respective units of the 2100 Hz detection unit 3, the 2400 Hz detection unit 4, and the hangover addition unit 7, and the “voice” or “voice” of the signal identification state according to the input determination results. Reset to “Data”.
[0124]
First, when a 2100 Hz tone is detected, the voice / data identification unit 2D sets the signal identification state to “data”.
When a 2400 Hz tone is detected, when a 2100 Hz tone signal has already been detected, It is determined that the tone is 2400 Hz transmitted during the data call by the 34 modem, and the signal identification state is set to “data”. On the other hand, when the 2100 Hz tone signal is not detected, For example, No. 34 is not a tone used in the middle of a data call by a 34 modem. It is determined that this is a 2400 Hz tone signal used for 5 signaling line signaling or channel check test, and the signal identification state is reset to “voice”.
[0125]
The voice / data discrimination result from the hangover adding unit 7 is V. 34 used to detect the end of a data call by a modem.
[0126]
FIG. 11 is a flowchart for explaining the operation of the voice / data identification unit 2D.
When the voice / data identification unit 2D starts processing, first, the current signal identification state is checked (step ST1). If it is in the “voice” state, the process proceeds to step ST2, and if it is in the “data” state, the process proceeds to step ST7. move on.
[0127]
First, when the current signal identification state is “voice”, the presence or absence of a voice band data signal (VBD) is determined, for example, by analyzing the number of zero crossings and signal strength of the input signal (step ST2). ) If a voice band data signal is detected, the signal identification state is set to “data” (step ST3), and the process is terminated.
[0128]
If no audio band data signal is detected in step ST2, then the 2100Hz tone presence / absence judgment result input from the 2100Hz detector 3 is checked (step ST4), and a 2100Hz tone is detected. Sets the specific signal detection flag to 1 (step ST6), sets the signal identification state to “data” (step ST3b), and ends the process.
In step ST4, when 2100 Hz is not detected, the processing is terminated as it is.
[0129]
Next, when the current signal identification state is “data”, the presence or absence of an audio signal is determined by analyzing the number of zero crossings and the signal intensity, for example, with respect to the input signal (step ST7). Is detected, the signal identification state is reset to “voice” (step ST8), and the process is terminated.
[0130]
If no audio signal is detected in step ST7, the voice / silence determination result after hangover addition input from the hangover addition unit 7 is checked (step ST11), and the hangover time expires. When the silent state is entered, the specific signal detection flag is cleared to 0 (step ST12).
[0131]
Next, the 2400 Hz tone presence / absence determination result input from the 2400 Hz detection unit 4 is checked (step ST13). If the 2400 Hz tone is detected, the state of the specific signal detection flag is continuously checked (step ST14). When the specific signal detection flag is set to 1 (specific signal has been detected), the signal identification state is reset to “voice” (step ST15), and the process ends.
In step ST13, when the 2400 Hz tone is not detected, the processing is ended as it is.
[0132]
FIG. 34 is a diagram for explaining an operation when a modem signal is input to the signal identification unit 1D. The state of each part when the output signal of 34 response modems is inputted into this signal discriminator is shown.
In the figure, when the answer modem sends an ANSam signal, the ANSam signal is a signal obtained by amplitude-modulating a 2100 Hz tone signal and has a large power component of 2100 Hz, so the 2100 Hz detector 3 detects the 2100 Hz tone, The voice / data identification unit 2D thereby sets the specific signal detection flag and sets the identification result to the “data” state (steps ST3b, ST4, ST6).
[0133]
Thereafter, since the 2400 Hz tone is transmitted from the response modem, the 2400 Hz detector 4 detects the 2400 Hz tone. However, since the specific signal detection flag is already set, the signal identification state is not reset to “voice”. , The “data” state is maintained (steps ST13 and ST14).
[0134]
This V. When the transmission of the 34 modem signal is completed and the silent time of a predetermined time or longer is continued thereafter, the output of the hangover adding unit 7 becomes silent, and thus the specific signal detection flag is cleared to 0 (steps ST11 and ST12).
[0135]
As described above, in this embodiment, V.V. Specific signals used in the 34 modem signal start-up procedure include: Instead of providing means for detecting the ANSam signal in the eight procedures, the means for detecting the 2100 Hz tone is used instead, so that the detection process of the ANSam signal is not required, and the V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0136]
Embodiment 6 FIG.
In the first to fifth embodiments, the V.V. In order to detect the end of a data call by a 34 modem, a voice detecting unit 6 and a hangover adding unit 7 are provided, and a voice / silent state of an input signal from the terminal side is judged and specified when the hangover time expires Although the signal detection flag is cleared to 0, the present invention is not limited to this, and for example, a voice / silent state in both transmission and reception may be determined.
[0137]
That is, although not shown, the first sound detector for determining the sound / silence state of the transmission side signal (input signal from the terminal side) and the presence of the reception side signal (input signal from the opposite device side). A second sound detector for determining a sound / silence state, and when the state where there is no sound in both the transmission side and the reception side continues for a predetermined time, It may be determined that the end of the data call by the 34 modem and the specific signal detection flag may be cleared to zero.
[0138]
In this way, V.V. can be shortened in a shorter time than when only the voiced / silent state on the transmitting side is monitored. The effect is that the end of a data call by a 34 modem can be detected.
[0139]
Embodiment 7 FIG.
In addition, V.D. Rather than detecting the end of a data call by a 34 modem, by detecting a specific frequency tone signal for channel continuity test transmitted at the beginning of the call, The end of the data call by the 34 modem may be detected.
[0140]
FIG. 13 is a block diagram showing the configuration of the seventh embodiment of the present invention.
In the figure, 1E is a signal identification unit, 2E is a voice / data identification unit as identification means, 3 is a 2100Hz detection unit, 4 is a 2400Hz detection unit, 5 is an ANSam signal detection unit, and 10 is 2000Hz as a continuity test tone detector. It is a detection unit. Here, the components 1E and 10 substantially constitute a signal discriminator.
[0141]
Next, the operation of FIG. 13 will be described. The operations of the 2100 Hz detector 3, the 2400 Hz detector 4, and the ANSam signal detector 5 are the same as those in the first embodiment.
[0142]
The 2000 Hz detector 10 is No. 6 signaling and no. In 7 signaling, the presence / absence of a 2000 Hz tone signal transmitted for the channel continuity test at the time of call connection is determined, and the determination result is output to the voice / data identification unit 2E.
[0143]
The voice / data identification unit 2E receives the determination result of the 2000 Hz detection unit 10, and when a 2000 Hz tone is detected, It is determined that the data call by the 34 modem has already ended and the next call is started, and the specific signal detection flag is cleared to zero.
Other operations of the voice / data identification unit 2E are the same as those in the first embodiment.
[0144]
As described above, in the seventh embodiment, V.V. is detected by detecting a 2000 Hz tone signal transmitted for the channel continuity test. The effect is that the end of a data call by a 34 modem can be detected.
[0145]
Embodiment 8 FIG.
FIG. 14 is a block diagram showing the configuration of the eighth embodiment of the signal discriminator.
In the figure, 1F is a signal identification unit, 2F is a voice / data identification unit as identification means, 3 is a 2100 Hz detection unit, 4 is a 2400 Hz detection unit, 5 is an ANSam signal detection unit, 6 is a sound detection unit, and 7 is a hangover. Addition unit, 20A is a DCME transmission unit, 21 is an encoding unit as an encoding unit, 22 is a frame generation unit as a transmission unit, 23 is a transmission control unit, 30 is a reception unit of DCME, 31 is a reception control unit, 32 is a frame decomposition unit as a reception unit, 33 is a decoding unit as a decoding unit, S20 is an input signal to DCME, S22 is a transmission DCME frame, S23 is control information, S31 is control information, S32 is a reception DCME frame, S33 Is an output signal from DCME. Here, the components 1F, 6 and 7 substantially constitute a signal discriminator.
[0146]
Next, the operation of FIG. 14 will be described.
An input signal S20 to the M-channel DCME from the terminal side is input to the encoding unit 21, the signal identification unit 1F, and the sound detection unit 6 in the DCME transmission unit 20A.
[0147]
The sound detection unit 6 determines whether each of the M-channel input signals S20 is sound or soundless, and outputs the determination result to the hangover addition unit 7. The hangover adding unit 7 performs the hangover adding process as described in the first embodiment, and the voice / data identifying unit 2F and the transmission control unit 23 send the voice / data discrimination result of each channel after the hangover is added. Output.
[0148]
The signal identification unit 1F determines, for each input signal S20 of the M channel, whether the signal type is an audio signal ("audio") or an audio band data signal ("data"), and the determination result Is output to the transmission control unit 23. The details of the operation in the signal identification unit 1F are as described in the first embodiment. However, the voice / data identification unit 2F in the signal identification unit 1F receives the identification state of the reception side signal from the reception control unit 31 and detects the rising of the identification state of the reception side signal from “speech” to “data”. If so, the determination result is set to “data”.
[0149]
The encoding unit 21 has m (m is a value smaller than M) encoder therein, and performs high-efficiency encoding of the input signal in accordance with an instruction from the transmission control unit 23, and converts the encoded signal into an encoded signal. Output. As an encoding algorithm used in the encoding unit 21, for example, ITU-T Recommendation G. 726, there is an adaptive differential pulse code modulation (hereinafter referred to as ADPCM) system. In this ADPCM system, an input signal with a transmission rate of 64 kbit / s, 40 kbit / s, 32 kbit / s, 24 kbit is used. / S and 16 kbit / s can be compressed and encoded.
[0150]
Based on the voice / data determination result and the voice / silence determination result, the transmission control unit 23 gives priority to the channel determined to be voiced in the input signal S20 of the M channel in the encoding unit 21. Further, the coding rate of a channel determined to be “data” is set to 40 kbit / s, and the coding rate of a channel determined to be “voice” is set to 32 kbit / s, 24 kbit / s, and 16 kbit. The encoding unit 21 is instructed to set to either / s.
[0151]
The transmission control unit 23 also notifies the frame generation unit 22 of control information related to the allocation of each encoded channel signal output from the encoding unit 21 and bits in a predetermined DCME frame, thereby generating a frame. Based on this control information, the unit 22 allocates the encoded signal of each channel and the bits in the DCME frame, and transmits the generated data of the DCME frame S22 to the opposite device side.
[0152]
Also, the transmission control unit 23 controls information regarding the allocation between the input signal of the M channel and the encoder, control information regarding the encoding rate in ADPCM encoding, and allocation between the encoded signal and the bits in the DCME frame The control information S23 regarding is transmitted to the opposite device side.
[0153]
On the other hand, the reception control unit 31 in the reception unit 30 of the DCME receives various control information S31 sent by the transmission control unit on the opposite device side, and based on the various control information, the frame control unit 32 and the decoding unit 33 Control information.
[0154]
Further, the reception control unit 31 determines whether the identification state of the reception side signal is “speech” or “data” based on the received control information S31 regarding the encoding rate in ADPCM encoding, and the determination result Is notified to the voice / data identification unit 2F.
[0155]
The frame decomposing unit 32 receives from the reception control unit 31 control information regarding the allocation of the bits in the DCME frame received from the opposite device side and the encoded data output to the decoding unit 33, and based on this control information The DCME frame S32 received from the opposite device side is decomposed and the encoded signal is output to the decoding unit 33.
[0156]
Next, the decoding unit 33 receives control information related to the coding rate of each channel and control information related to the allocation of the m decoders in the decoding unit 33 and the output of the M channel from the DCME from the reception control unit 31. Based on this control information, the encoded signal received from the frame decomposing unit 32 is allocated to any of the m decoders in the decoding unit 33, and is decoded at an appropriate encoding rate. The channel signal is assigned to one of the M channels output from the DCME and output as an output signal S33.
[0157]
As described above, in the present embodiment, V.V. Means for detecting a specific signal used in a 34 modem signal start-up procedure, so that when the specific signal is detected, the signal identification state is not reset to "voice" even if a 2400 Hz tone is detected. V. Since the signal identification result is prevented from becoming “voice” during transmission of the modem signal by the 34 modulation method, There is an effect that a transmission apparatus capable of normally transmitting 34 modem signals can be obtained.
[0158]
Embodiment 9 FIG.
ITU-T Recommendation V. 34, when the response modem transmits tone A (2400 Hz tone) in the phase 2 signal of the start-up sequence in the modem communication procedure shown in FIG. 23, a guard tone of 1800 Hz is transmitted superimposed on this. It is prescribed as follows. Therefore, V.V. As a specific signal used in the start-up procedure of the 34 modem signal, a means for detecting a 1800 Hz guard tone is provided, and when the 1800 Hz guard tone is detected, the signal identification state is changed to “voice” even if the 2400 Hz tone is detected. It may not be reset.
[0159]
FIG. 15 is a block diagram showing the configuration of the ninth embodiment of the present invention.
In the figure, 1G is a signal identification unit, 2G is a voice / data identification unit as an identification unit, 3 is a 2100 Hz detection unit, 4 is a 2400 Hz detection unit as a first detection unit, and 11 is 1800 Hz as a second detection unit. It is a detection unit. Here, the component 1G substantially constitutes a signal discriminator.
[0160]
Next, the operation of FIG. 15 will be described.
An input signal from the terminal side is input to the signal identification unit 1G, and signal detection / detection in each unit of the voice / data identification unit 2G, 2100Hz detection unit 3, 2400Hz detection unit 4, and 1800Hz detection unit 11 in the signal identification unit 1G. Analysis processing is performed.
[0161]
The 2100 Hz detection unit 3 determines the presence or absence of a 2100 Hz tone signal, for example, by performing frequency analysis on the input signal, and outputs the determination result to the voice / data identification unit 2G.
The 2400 Hz detection unit 4 determines the presence or absence of a 2400 Hz tone signal, for example, by performing frequency analysis on the input signal, and outputs the determination result to the voice / data identification unit 2G.
[0162]
The 1800 Hz detection unit 11 determines the presence or absence of a 1800 Hz tone signal, for example, by performing frequency analysis on the input signal, and outputs the determination result to the voice / data identification unit 2G.
[0163]
The voice / data identification unit 2G analyzes the number of zero crossings and signal strength of the input signal, for example, to determine whether the type of the input signal is a voice signal (“voice”) or a voice band data signal (“data”). ) And output the determination result.
Further, the voice / data identification unit 2G inputs the determination results from the respective units of the 2100 Hz detection unit 3, the 2400 Hz detection unit 4, and the 1800 Hz detection unit 11, and “speech” or “ Reset to “Data”.
[0164]
First, when a 2100 Hz tone is detected, the voice / data identification unit 2G sets the signal identification state to “data”.
Further, when a 2400 Hz tone is detected, the output state of the 1800 Hz detection unit 11 is checked. It is determined that the tone is 2400 Hz transmitted during the data call by the 34 modem, and the signal identification state is set to “data”. On the other hand, when the 1800 Hz tone is not being detected, V.D. For example, No. 34 is not a tone used in the middle of a data call by a 34 modem. It is determined that this is a 2400 Hz tone signal used for 5 signaling line signaling or channel check test, and the signal identification state is reset to “voice”.
[0165]
FIG. 16 is a flowchart for explaining the operation of the voice / data identifying unit 2G.
When the voice / data identification unit 2G starts processing, first, the current signal identification state is checked (step ST1). If it is in the “voice” state, the process proceeds to step ST2. If it is in the “data” state, the process proceeds to step ST7. move on.
[0166]
First, when the current signal identification state is “speech”, the presence or absence of a voice band data signal (VBD) is determined, for example, by analyzing the number of zero crossings and signal strength of the input signal (step ST2). If a voice band data signal is detected, the signal identification state is set to “data” (step ST3), and the process is terminated.
[0167]
If no audio band data signal is detected in step ST2, then the 2100Hz tone presence / absence judgment result input from the 2100Hz detector 3 is checked (step ST4), and if a 2100Hz tone is detected. The signal identification state is set to “data” (step ST3), and the process is terminated.
In step ST4, when 2100 Hz is not detected, the processing is terminated as it is.
[0168]
Next, when the current signal identification state is “data”, the presence or absence of an audio signal is determined by analyzing the number of zero crossings and the signal intensity, for example, with respect to the input signal (step ST7). Is detected, the signal identification state is reset to “voice” (step ST8), and the process is terminated.
[0169]
If no audio signal is detected in step ST7, then the 2400Hz tone presence / absence judgment result input from the 2400Hz detection unit 4 is checked (step ST13), and if a 2400Hz tone is detected, it continues. The 1800 Hz tone presence / absence judgment result input from the 1800 Hz detection unit 11 is checked (step ST16). If no 1800Hz tone is detected, the signal identification state is reset to "speech" (step ST17) and the process ends. To do.
In step ST13, when the 2400 Hz tone is not detected, the processing is ended as it is.
[0170]
FIG. 34 is an explanatory diagram for explaining the operation when a 34 modem signal is input to the signal identification unit 1G. The state of each part when the output signal of 34 response modems is input into this signal identification part 1G is shown.
In the figure, when the answer modem sends an ANSam signal, this ANSam signal is a signal obtained by amplitude-modulating a 2100 Hz tone signal and has a large power component of 2100 Hz, so the 2100 Hz detector 3 detects a 2100 Hz tone, The voice / data identification unit 2G thereby sets the identification result to the “data” state (steps ST3 and ST4).
[0171]
Thereafter, since the 2400 Hz tone is transmitted from the response modem, the 2400 Hz detection unit 4 detects the 2400 Hz tone, but since the response modem transmits a 1800 Hz guard tone superimposed on the 2400 Hz tone, the 1800 Hz detection unit 11 simultaneously detects the 1800 Hz tone. Accordingly, the signal identification state is not reset to “speech” and is kept in the “data” state (steps ST13 and ST16).
[0172]
As described above, in this embodiment, V.V. As a specific signal used in the start-up procedure of the 34 modem signal, a means for detecting a guard tone of 1800 Hz is provided, and when the 1800 Hz tone is detected, the signal identification state is not reset to “voice” even if the 2400 Hz tone is detected. By doing so, V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0173]
Embodiment 10 FIG.
In the ninth embodiment, V.I. As a specific signal used in the start-up procedure of the 34 modem signal, a means for detecting a guard tone of 1800 Hz is provided, and when the 1800 Hz tone is detected, the signal identification state is not reset to “voice” even if the 2400 Hz tone is detected. However, when the detection time of the 2400 Hz tone is shorter than the detection time of the 1800 Hz tone, when the 2400 Hz tone is first detected, the state that the 1800 Hz tone is not detected occurs for a short time. V. There is a problem that the signal identification result is reset to “voice” despite the 2400 Hz tone during the start-up procedure of the 34 modem signal.
In this embodiment, in order to solve this problem, the signal identification result is not reset to “voice” for a certain period of time after detecting the 2400 Hz tone.
The configuration block diagram showing the tenth embodiment of the signal discriminator is the same as the configuration block diagram (FIG. 15) showing the ninth embodiment.
[0174]
FIG. 18 is a flowchart for explaining the operation of the voice / data discriminating unit 2G in the tenth embodiment of the signal discriminator.
When the voice / data identifying unit 2G starts processing, first, the determination result of the presence / absence of the 2400 Hz tone input from the 2400 Hz detection unit 4 is checked (step ST18). The first timer is set (step ST19).
[0175]
Next, the current signal identification state is checked (step ST1). If it is in the “voice” state, the process proceeds to step ST2, and if it is in the “data” state, the process proceeds to step ST7.
What is the process when the current signal identification state is “voice” in step ST1? This is the same as in the ninth embodiment.
[0176]
Next, when the current signal identification state is “data”, the presence or absence of an audio signal is determined by analyzing the number of zero crossings and the signal intensity, for example, with respect to the input signal (step ST7). If no 2400 Hz tone is detected, the determination result of the presence or absence of the 2400 Hz tone input from the 2400 Hz detection unit 4 is checked (step ST13).
If a 2400 Hz tone is detected, the value of the first timer is continuously checked (step ST20). If a predetermined time has elapsed after the first timer is set, the value is continuously input from the 1800 Hz detection unit 11. 1800 Hz tone presence / absence determination result is checked (step ST 16), and if the 1800 Hz tone is not detected, the signal identification state is reset to “voice” (step ST 17), and the process ends.
[0177]
If a 1800 Hz tone is detected in step ST16, if the predetermined time has not elapsed after the first timer setting in step ST20, the process is terminated as it is.
The processing in other steps is the same as that in the ninth embodiment.
[0178]
As described above, in the tenth embodiment, the detection time of the 2400 Hz tone is detected for the 1800 Hz tone by not resetting the signal identification result to “speech” for a certain time after the detection of the 2400 Hz tone. V. is shorter than the time. There is an effect that it is possible to prevent the signal identification result from being reset to “voice” despite the 2400 Hz tone during the start-up procedure of the 34 modem signal.
[0179]
Embodiment 11 FIG.
In the tenth embodiment, the detection time of the 2400 Hz tone is shorter than the detection time of the 1800 Hz tone by not resetting the signal identification result to “voice” for a certain period of time after detecting the 2400 Hz tone. If V. Although the signal identification result is prevented from being reset to “voice” despite the 2400 Hz tone in the start-up procedure of the 34 modem signal, it returns to the tone signal non-detection state once the tone signal is detected. When the return time until returning to the non-detection state is longer for the 2400 Hz detector than for the 1800 Hz detector, the 2400 Hz tone is detected, but the 1800 Hz tone non-detection state occurs for a short time, As a result, V.P. There is a problem that the signal identification result is reset to “voice” despite the 2400 Hz tone during the start-up procedure of the 34 modem signal.
In this embodiment, in order to solve this problem, the signal identification result is not reset to “speech” for a certain period of time after the 1800 Hz tone non-detection state.
[0180]
The configuration block diagram showing the eleventh embodiment of the signal discriminator is the same as the configuration block diagram (FIG. 15) showing the ninth embodiment.
[0181]
FIG. 19 is a flowchart for explaining the operation of the voice / data identification unit 2G in the eleventh embodiment of the present invention.
When the voice / data identifying unit 2G starts processing, first, the determination result of the presence / absence of the 2400 Hz tone input from the 2400 Hz detection unit 4 is checked (step ST18). The first timer is set (step ST19).
[0182]
Next, the determination result of the presence or absence of the 1800 Hz tone input from the 1800 Hz detection unit 11 is checked (step ST21). If the detection state of the 1800 Hz tone is changed to the non-detection state, the second timer is set (step ST22). ).
[0183]
Next, the current signal identification state is checked (step ST1). If it is in the “voice” state, the process proceeds to step ST2, and if it is in the “data” state, the process proceeds to step ST7.
In step ST1, the processing when the current signal identification state is “voice” is the same as in the ninth embodiment.
[0184]
Next, when the current signal identification state is “data”, the presence or absence of an audio signal is determined by analyzing the number of zero crossings and the signal intensity, for example, with respect to the input signal (step ST7). If no 2400 Hz tone is detected, the determination result of the presence or absence of the 2400 Hz tone input from the 2400 Hz detection unit 4 is checked (step ST13).
If a 2400 Hz tone is detected, the value of the first timer is continuously checked (step ST20). If a predetermined time has elapsed after the first timer is set, the value is continuously input from the 1800 Hz detection unit 11. 1800 Hz tone presence / absence determination result is checked (step ST16), and if the 1800 Hz tone is not detected, the second timer value is continuously checked (step ST23). If it has elapsed, the signal identification state is reset to “voice” (step ST17), and the process ends.
[0185]
Also, if the predetermined time has not elapsed since the second timer set in step ST23, if the 1800 Hz tone is detected in step ST16, the predetermined time has not elapsed since the first timer set in step ST20. If so, the process ends.
The processing in other steps is the same as that in the ninth embodiment.
[0186]
As described above, in the eleventh embodiment, the signal identification result is not reset to “voice” for a certain period of time after the 1800 Hz tone non-detection state, thereby returning to the tone non-detection state. If the 2400 Hz detector is longer than the 1800 Hz detector, There is an effect that it is possible to prevent the signal identification result from being reset to “voice” despite the 2400 Hz tone during the start-up procedure of the 34 modem signal.
[0187]
Embodiment 12 FIG.
ITU-T Recommendation V. 34, regarding the signal level of the tone A (2400 Hz) and the guard tone of 1800 Hz transmitted in superposition thereto, the transmission level of tone A (2400 Hz) is defined as 1 dB lower than the guard tone (1800 Hz). Therefore, V.V. The signal level ratio between the 2400 Hz tone and the 1800 Hz guard tone transmitted during the 34 modem signal start-up procedure will be a constant value. In the present embodiment, the signal level ratio between the 2400 Hz tone and the 1800 Hz tone is calculated, and it is determined whether the signal level ratio is within a predetermined range. Whether or not the tone is a 2400 Hz tone transmitted during transmission of a modem signal by the 34 modulation method is determined with higher accuracy.
[0188]
FIG. 20 is a block diagram showing the configuration of the twelfth embodiment of the present invention.
In the figure, 1H is a signal identification unit, 2H is a voice / data identification unit as an identification unit, 3 is a 2100Hz detection unit, 4 is a 2400Hz detection unit as a first detection unit, and 11 is 1800Hz as a second detection unit. A detection unit, 12 is a level comparison unit, 3A, 4A, and 11A are band pass filters (BPF), 3B, 4B, and 11B are level calculation units, and 3C, 4C, and 11C are determination units. Here, the component 1H substantially constitutes a signal discriminator.
[0189]
Next, the operation of FIG. 20 will be described.
An input signal from the terminal is input to the signal identification unit 1H, and signal detection / analysis is performed in each part of the voice / data identification unit 2H, 2100Hz detection unit 3, 2400Hz detection unit 4, and 1800Hz detection unit 11 in the signal identification unit 1H. Processing is performed.
[0190]
The 2100 Hz detection unit 3 determines the presence or absence of a 2100 Hz tone signal, for example, by performing frequency analysis on the input signal, and outputs the determination result to the voice / data identification unit 2H.
The input signal to the 2100 Hz detection unit 3 is first processed by the band pass filter 3A that passes a signal in the frequency band near 2100 Hz, and the level calculation unit 3B calculates the level of the output signal of the band pass filter 3A. The determination unit 3C compares the output value of the level calculation unit 3B with a predetermined threshold value. If the output value of the level calculation unit 3B is larger than the threshold value, it is determined that there is a 2100 Hz tone, and the output value of the level calculation unit 3B is If it is smaller than this threshold, it is determined that there is no 2100 Hz tone.
[0191]
The 2400 Hz detection unit 4 determines the presence / absence of a 2400 Hz tone signal by performing frequency analysis on the input signal, for example, and outputs the determination result to the voice / data identification unit 2H.
An input signal to the 2400 Hz detection unit 4 is first processed by a band pass filter 4A that passes a signal in a frequency band near 2400 Hz, and a level calculation unit 4B calculates the level of the output signal of the band pass filter 4A. The determination unit 4C compares the output value of the level calculation unit 4B with a predetermined threshold value. If the output value of the level calculation unit 4B is larger than the threshold value, it is determined that there is a 2400 Hz tone, and the output value of the level calculation unit 4B is If it is smaller than this threshold, it is determined that there is no 2400 Hz tone. The output value of the level calculation unit 4B is also output to the level comparison unit 12.
[0192]
The 1800 Hz detection unit 11 determines the presence or absence of a 1800 Hz tone signal, for example, by performing frequency analysis on the input signal, and outputs the determination result to the voice / data identification unit 2H.
An input signal to the 1800 Hz detection unit 11 is first processed by a band pass filter 11A that passes a signal in a frequency band around 1800 Hz, and a level calculation unit 11B calculates the level of the output signal of the band pass filter 11A. The determination unit 11C compares the output value of the level calculation unit 11B with a predetermined threshold value. If the output value of the level calculation unit 11B is larger than the threshold value, it is determined that there is a 1800 Hz tone, and the output value of the level calculation unit 11B is If it is smaller than this threshold, it is determined that there is no 1800 Hz tone. The output value of the level calculation unit 11B is also output to the level comparison unit 12.
[0193]
The level comparison unit 12 calculates a ratio between the signal level value of the 2400 Hz tone output from the level calculation unit 4B and the signal level value of the 1800 Hz tone output from the level calculation unit 11B, and the signal level ratio is calculated as a voice / data identification unit. Output to 2H.
[0194]
The voice / data identification unit 2H analyzes the number of zero crossings and signal strength of the input signal, for example, to determine whether the type of the input signal is a voice signal (“voice”) or a voice band data signal (“data”). ) And output the determination result.
Further, the voice / data identification unit 2H inputs the determination results from the respective units of the 2100 Hz detection unit 3, the 2400 Hz detection unit 4, and the 1800 Hz detection unit 11, and the signal level ratio from the level comparison unit 12, and the input determination result and The signal identification state is reset to “voice” or “data” according to the signal level ratio.
[0195]
First, when a 2100 Hz tone is detected, the voice / data identification unit 2H sets the signal identification state to “data”.
Further, when a 2400 Hz tone is detected, the output state of the 1800 Hz detection unit 11 is checked. It is determined that there is a high possibility that the tone is 2400 Hz transmitted in the middle of the data call by the 34 modem, and the signal level ratio from the level comparison unit 12 is further checked. When the signal level ratio from the comparison unit 12 is within a predetermined range, V.V. Finally, it is determined that the tone is 2400 Hz transmitted in the middle of the data call by the 34 modem, and the signal identification state is set to “data”.
On the other hand, when the 1800 Hz tone is being detected but the signal level ratio is not within the predetermined range, For example, No. 34 is not a tone used in the middle of a data call by a 34 modem. Finally, it is determined that it is a 2400 Hz tone signal used for 5 signaling line signaling or channel check test, and the signal identification state is reset to “voice”.
If the 1800 Hz tone is not being detected, V.D. For example, No. 34 is not a tone used in the middle of a data call by a 34 modem. It is determined that this is a 2400 Hz tone signal used for 5 signaling line signaling or channel check test, and the signal identification state is reset to “voice”.
[0196]
FIG. 21 is a flowchart for explaining the operation of the voice / data identification unit 2H.
When the voice / data identification unit 2H starts the processing, first, the current signal identification state is checked (step ST1). move on.
[0197]
In step ST1, the processing when the current signal identification state is “voice” is the same as in the ninth embodiment.
[0198]
Next, when the current signal identification state is “data”, the presence or absence of an audio signal is determined by analyzing the number of zero crossings and the signal intensity, for example, with respect to the input signal (step ST7). If no 2400 Hz tone is detected, the determination result of the presence or absence of the 2400 Hz tone input from the 2400 Hz detection unit 4 is checked (step ST13).
When the 2400 Hz tone is detected, the determination result of the presence or absence of the 1800 Hz tone continuously input from the 1800 Hz detection unit 11 is checked (step ST16). When the 1800 Hz tone is not detected, the signal identification state is “voice”. (Step ST17), and the process ends.
If a 1800 Hz tone is detected in step ST16, the signal level ratio input from the level comparison unit 12 is continuously checked (step ST24). If the signal level ratio is not within the predetermined range, The identification state is reset to “voice” (step ST17), and the process ends.
In step ST24, when the signal level ratio is within the predetermined range, the processing is ended as it is.
[0199]
As described above, in the twelfth embodiment, the signal level ratio between the 2400 Hz tone and the 1800 Hz tone is calculated, and it is determined whether the signal level ratio is within a predetermined range. There is an effect that it can be determined with higher accuracy whether the tone is a 2400 Hz tone transmitted during transmission of a modem signal by the 34 modulation method.
[0200]
Embodiment 13 FIG.
In the first to twelfth embodiments, V.V. is used as means for detecting a specific signal. Although it has a means for detecting a signal used in the start-up procedure of 34 modem signal and the specific signal is detected, the signal identification state is not reset to “voice” even if a 2400 Hz tone is detected. V. Other than the 34 procedure signal, other modem signal start-up procedures, for example, V. 90 procedures and V.V. A signal of 92 procedures may be detected.
[0201]
【The invention's effect】
As described above, according to the present invention, in the signal discriminator for discriminating the type of the input signal into two types, voice and data, the first detection means for detecting the tone signal of the specific frequency from the input signal, Second detection means for detecting a specific signal used in a modem signal start-up procedure from the input signal; and identification means for identifying the type of the input signal based on the outputs of the first and second detection means. Prepared, The identification means is The specific signal above Undetected When the above tone signal is detected In The signal identification result is voice, but the specific signal is detected In a finished state When the above tone signal is detected In Since the signal identification result is not voice, it is possible to reliably prevent the signal identification result from becoming “voice” during transmission of the modem signal by the modulation method.
[0202]
Further, according to the present invention, the startup procedure includes V. Since there are 34 procedures, V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0203]
Further, according to the present invention, the startup procedure includes V. Since there are 8 procedures, V. There is an effect that a signal discriminator useful for preventing the signal discrimination result from becoming “voice” during transmission of the modem signal by the 34 modulation method can be obtained.
[0204]
According to the present invention, the second detection means is a V.P. Since it is an ANSam signal detector that detects an ANSam signal in 8 procedures, by detecting the ANSam signal, even if a tone of a specific frequency is detected, the signal identification state is not reset to “voice”. For example V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0205]
Further, according to the present invention, since the third detecting means for detecting the tone signal of the specific frequency from the input signal is used instead of the ANSam signal detector, the ANSam signal detection process becomes unnecessary. With a simple configuration, e.g. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0206]
Moreover, according to this invention, Since the second detection means is a 2100 Hz detector that detects a 2100 Hz tone signal. Detects 2100 Hz tone The tone of the specific frequency is detected. Even if the signal identification state is not reset to “voice” even if the There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0207]
According to the present invention, the second detection means is a V.P. V. 8 in procedure. 21 (channel No. 2) 21 modem signal detector. 21 channel No. 2 When a modem signal is detected, the signal identification state is not reset to “voice” even if a tone of a specific frequency is detected. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0208]
According to the present invention, the second detection means is a V.P. Since it is a JM signal detector that detects a JM signal in 8 procedures, by detecting a tone of a specific frequency when detecting a JM signal, the signal identification state is not reset to “voice”. For example V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0209]
According to the present invention, the second detection means is an INFO0a signal detector that detects the INFO0a signal during the startup procedure. Therefore, when the INFO0a signal is detected, even if a tone having a specific frequency is detected. By not resetting the signal identification state to “voice”, for example, V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0210]
Further, according to the present invention, the sound detector for determining the sound / silence state of the input signal is provided, and the silence state continues for a predetermined time after detecting the specific signal used in the startup procedure of the modem signal. In this case, the detection state of the specific signal is initialized. 34 Can detect end of data call by modem There is an effect.
[0211]
Moreover, according to this invention, the 1st sound detector which determines the sound / silence state of a transmission side signal, and the 2nd sound detector which determines the sound / silence state of a reception side signal are included. After detecting a specific signal used in the modem signal start-up procedure, the detection state of the specific signal is initialized when a state where there is no sound in both the transmission side and the reception side continues for a predetermined time. Therefore, compared to the case where only the voiced / silent state on the transmission side is monitored, for example, V.I. The effect is that the end of a data call by a 34 modem can be detected.
[0212]
According to the present invention, the continuity test tone detector for detecting a tone signal of a specific frequency transmitted from the input signal for channel continuity test is provided, and the specific signal used in the startup procedure of the modem signal After detecting a tone signal of a specific frequency transmitted for the continuity test of the channel, the detection state of the specific signal is initialized. The effect is that the end of a data call by a 34 modem can be detected.
[0213]
According to the present invention, the tone signal of the specific frequency detected by the continuity test tone detector is a 2000 Hz tone signal. so For example, V. The effect is that the end of the data call by the 34 modem can be detected efficiently.
[0214]
Further, according to the present invention, since the tone signal of the specific frequency detected by the first detection means is a 2400 Hz tone signal, the signal identification state is not reset to “voice” even if the 2400 Hz tone is detected. By doing so, V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0215]
According to the invention, in the signal identification method for identifying the type of the input signal into two types, voice and data, a first step of detecting a tone signal of a specific frequency from the input signal, and a modem from the input signal A second step of detecting a specific signal used in a signal start-up procedure; and a third step of setting a specific signal detection flag when the specific signal is detected, wherein the specific signal detection flag is set Been Without When a tone signal with the specified frequency is detected In The signal identification result is voice, but the specific signal detection flag is set. In the state When a tone signal with the specified frequency is detected In Since the signal identification result is not voice, for example, V. There is an effect that it is possible to reliably prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0216]
Further, according to the present invention, the specific signal is V.P. Since it is an ANSam signal in 8 procedures, when the ANSam signal is detected, the specific frequency is, for example, 2400H. _Z Even if the tone of the signal is detected, the signal identification state is not reset to “voice”. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0217]
In addition, according to the present invention, since a tone signal of a specific frequency included in the input signal is used instead of the ANSam signal, the ANSam signal detection process is not required, and a simpler configuration, for example, V . There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0218]
Moreover, according to this invention, The specific signal is Since it is a 2100 Hz tone signal, a 2100 Hz tone is detected. The tone of the specific frequency is detected. Even if the signal identification state is not reset to “voice” even if the There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0219]
Further, according to the present invention, the specific signal is V.P. V. 8 in procedure. 21 (channel No. 2) is a modem signal. 21 channel No. In the case where two modem signals are detected, the signal identification state is not reset to “voice” even if a tone having a specific frequency of, for example, 2400 Hz is detected. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0220]
Further, according to the present invention, the specific signal is V.P. Since this is a JM signal in 8 procedures, when a JM signal is detected, the signal identification state is not reset to “voice” even if a tone having a specific frequency of 2400 Hz, for example, is detected. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0221]
Further, according to the present invention, the specific signal is V.P. Since the signal is an INFO0a signal in 8 procedures, when the INFO0a signal is detected, the signal identification state is not reset to “voice” even if a tone having a specific frequency of, for example, 2400 Hz is detected. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0222]
Further, according to the present invention, the specific signal detection flag is initialized when the silent state continues for a predetermined time after the specific signal used in the modem signal startup procedure is detected. 34 Can detect end of data call by modem There is an effect.
[0223]
Further, according to the present invention, after detecting a specific signal used in the startup procedure of the modem signal, the specific signal is detected when a state where there is no sound in both the transmission side and the reception side continues for a predetermined time. Is detected in a shorter time than in the case of monitoring only the voice / silence state on the transmission side. The effect is that the end of a data call by a 34 modem can be detected.
[0224]
According to the present invention, the method further includes a fourth step of detecting a tone signal having a specific frequency transmitted from the input signal for a channel continuity test. After detecting a specific signal used in the 34 modem signal start-up procedure, the detection state of the specific signal is initialized when a tone signal of a specific frequency transmitted for the continuity test of the channel is detected. E.g. The effect is that the end of a data call by a 34 modem can be detected.
[0225]
According to the present invention, the tone signal of the specific frequency detected in the fourth step is a 2000 Hz tone signal. The effect is that the end of the data call by the 34 modem can be detected efficiently.
[0226]
In addition, according to the present invention, since the tone signal of the specific frequency detected in the first step is a 2400 Hz tone signal, the signal identification state is not reset to “voice” even if the 2400 Hz tone is detected. For example, V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0227]
Furthermore, according to the present invention, the type of the input signal is classified into two types of voice and data, and the signal discriminator according to any one of claims 1 to 14 and an appropriate signal based on the signal discrimination result of the signal discriminator. Encoding means for performing high-efficiency speech encoding at an encoding rate, transmitting means for transmitting encoded data encoded by the encoding means, and receiving means for receiving encoded data encoded from the opposite device side And decoding means for decoding the encoded data received by the receiving means. It is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method. The 34 modem signal can be transmitted normally.
[0228]
According to the present invention, since the second detection means is a guard tone signal detector for detecting a guard tone signal of a modem, for example, V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0229]
Further, according to the present invention, since the signal detected by the guard tone signal detector is a tone signal of 1800 Hz, for example, V. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0230]
Further, according to the present invention, since the signal identification result is not voice during a predetermined time after the first detection means detects the tone signal of the specific frequency, the detection time of 2400 Hz tone is the detection time of 1800 Hz tone. For example, V. There is an effect that it is possible to prevent the signal identification result from being reset to “voice” despite the 2400 Hz tone during the start-up procedure of the 34 modem signal.
[0231]
Further, according to the present invention, since the signal identification result is not voiced for a predetermined time after the guard tone signal detector stops detecting the guard tone signal, the return time to the tone non-detection state is detected at 2400 Hz. If the detector is longer than the 1800 Hz detector, e.g. There is an effect that it is possible to prevent the signal identification result from being reset to “voice” despite the 2400 Hz tone during the start-up procedure of the 34 modem signal.
[0232]
According to the present invention, there is further provided a signal level comparator for comparing the level of the tone signal of the specific frequency detected by the first detection means with the level of the guard tone signal detected by the guard tone signal detector, When the level ratio between the tone signal of the specific frequency and the guard tone signal is within a predetermined range, the signal identification result when the tone signal of the specific frequency is detected is not voice, but the level ratio is within the predetermined range. If the tone signal of the specific frequency is detected, the signal identification result is voice. There is an effect that it can be determined with higher accuracy whether the tone is a 2400 Hz tone transmitted during transmission of a modem signal by the 34 modulation method.
[0233]
According to the present invention, in the signal identification method for identifying the type of the input signal into two types, voice and data, a first step of detecting a tone signal of a specific frequency from the input signal, and a modem signal from the input signal A second step of detecting a specific signal used in a start-up procedure, wherein the specific signal is not detected In state When a tone signal with the specified frequency is detected In The result of signal identification is voice, but the specific signal is detected In state When a tone signal with the specified frequency is detected In Since the signal identification result is not voice, for example, V. There is an effect that it is possible to reliably prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0234]
According to the present invention, the specific signal is a modem guard tone signal. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0235]
According to the present invention, the guard tone signal of the modem is a 1800 Hz tone signal. There is an effect that it is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method.
[0236]
Further, according to the present invention, the method includes a fifth step of setting a first timer when the specific signal is detected, and when the predetermined time has not elapsed after the first timer is set, Since the signal identification result when the tone signal of the frequency is detected is not voice, when the detection time of the 2400 Hz tone is earlier than the detection time of the 1800 Hz tone, for example, V. There is an effect that it is possible to prevent the signal identification result from being reset to “voice” despite the 2400 Hz tone during the start-up procedure of the 34 modem signal.
[0237]
Further, according to the present invention, the method includes a sixth step of setting a second timer when the guard tone signal is not detected, and when a predetermined time has not elapsed after setting the second timer, Since the signal identification result when the tone signal of the specific frequency is detected is not voice, when the return time to the tone non-detection state is longer for the 2400 Hz detector than for the 1800 Hz detector, for example There is an effect that it is possible to prevent the signal identification result from being reset to “voice” despite the 2400 Hz tone during the start-up procedure of the 34 modem signal.
[0238]
Further, according to the present invention, it includes a seventh step of determining whether the level ratio of the tone signal of the specific frequency and the level of the guard tone signal is within a predetermined range, wherein the level ratio is a predetermined level. If it is within the range, the signal identification result when the tone signal of the specific frequency is detected is not voice, but if the level ratio is not within the predetermined range, the signal when the tone signal of the specific frequency is detected Since the identification result is voice, for example, V.I. There is an effect that it can be determined with higher accuracy whether the tone is a 2400 Hz tone transmitted during transmission of a modem signal by the 34 modulation method.
[0239]
In addition, according to the present invention, the type of the input signal is classified into two types, that is, voice and data. Encoding means for performing high-efficiency speech encoding at an encoding rate, transmitting means for transmitting encoded data encoded by the encoding means, and receiving means for receiving encoded data encoded from the opposite device side And decoding means for decoding the encoded data received by the receiving means. It is possible to prevent the signal identification result from becoming “voice” during transmission of the modem signal by the 34 modulation method. The 34 modem signal can be transmitted normally.
[Brief description of the drawings]
FIG. 1 is a configuration block diagram showing a first embodiment of the present invention.
FIG. 2 is a flowchart for explaining the operation of a voice / data identifying unit 2A in FIG.
FIG. It is a figure for demonstrating operation | movement when 34 modem signals are input into the signal identification part 1A in FIG.
FIG. 4 is a configuration block diagram showing a second embodiment of the present invention.
FIG. 5 is a flowchart for explaining the operation of the voice / data identifying unit 2A in FIG. 4;
FIG. It is a figure for demonstrating operation | movement when 34 modem signals are input into the signal identification part 1B in FIG.
FIG. 7 is a configuration block diagram showing a fourth embodiment of the present invention.
8 is a flowchart for explaining the operation of a voice / data identification unit 2C in FIG.
FIG. It is a figure for demonstrating operation | movement when 34 modem signals are input into the signal identification part 1C in FIG.
FIG. 10 is a configuration block diagram showing Embodiment 5 of the present invention.
11 is a flowchart for explaining the operation of the voice / data identifying unit 2C in FIG.
FIG. It is a figure for demonstrating operation | movement when 34 modem signals are input into the signal identification part 1C in FIG.
FIG. 13 is a configuration block diagram showing Embodiment 7 of the present invention.
FIG. 14 is a configuration block diagram showing an eighth embodiment of the invention.
FIG. 15 is a configuration block diagram showing Embodiment 9 of the present invention.
FIG. 16 is a flowchart for explaining the operation of voice / data identifying unit 2G in FIG. 15 according to the ninth embodiment of the present invention;
FIG. It is a figure for demonstrating operation | movement when 34 modem signals are input into the signal identification part 1G in FIG.
FIG. 18 is a flowchart for explaining the operation of voice / data identification unit 2G in FIG. 15 according to the tenth embodiment of the present invention;
FIG. 19 is a flowchart for explaining the operation of voice / data identification unit 2G in FIG. 15 according to the eleventh embodiment of the present invention;
FIG. 20 is a configuration block diagram showing Embodiment 12 of the present invention.
FIG. 21 is a flowchart for explaining the operation of the voice / data identifying unit 2H in FIG.
FIG. 22 is a configuration diagram illustrating an example of a configuration of a conventional DCME.
FIG. It is a figure which shows the startup sequence in the modem communication procedure by 34 modulation system.
[Explanation of symbols]
1A-1H signal identification unit, 2A-2H voice / data identification unit, 3 2100 Hz detection unit, 3A, 4A, 11A BPF, 3B, 4B, 11B level calculation unit, 3C, 4C, 11C determination unit, 4 2400 Hz detection unit, 5 ANSam signal detection unit, 6 voice detection unit, 7 hangover addition unit, 8V. 21 channel No. 2 modem signal detection unit, 9 INFO0a signal detection unit, 10 2000 Hz detection unit, 20A DCME transmission unit, 21 encoding unit, 22 frame generation unit, 23 transmission control unit, 30 DCME reception unit, 31 reception control unit, 32 Frame decomposition unit, 33 decoding unit.

Claims (41)

In a signal discriminator that identifies the type of input signal into two types, voice and data,
First detecting means for detecting a tone signal of a specific frequency from the input signal;
Second detection means for detecting a specific signal used in the startup procedure of the modem signal from the input signal;
A identification means for identifying a type of the input signal based on an output of said first and second detection means, said identification means, if it detects the tone signal in the form of undetected the specific signal The signal discriminator is characterized in that the signal identification result is voice, but when the tone signal is detected in a state where the specific signal has been detected , the signal identification result is not voice. The above startup procedure is described in V. The signal discriminator according to claim 1, wherein the number of steps is 34. The above startup procedure is described in V. 2. The signal discriminator according to claim 1, wherein there are 8 procedures. The second detection means includes V.I. The signal discriminator according to claim 1, wherein the signal discriminator is an ANSam signal detector that detects an ANSam signal in eight procedures. 5. The signal discriminator according to claim 4, wherein, instead of the ANSam signal detector, third detecting means for detecting a tone signal having a specific frequency from the input signal is used. 2. The signal discriminator according to claim 1, wherein the second detection means is a 2100 Hz detector that detects a 2100 Hz tone signal . The second detection means includes V.I. V. 8 in procedure. 21 (channel No. 2) 2. A signal identifier according to claim 1, which is a 21 modem signal detector. The second detection means includes V.I. The signal discriminator according to claim 1, wherein the signal discriminator is a JM signal detector for detecting a JM signal in 8 procedures. 2. The signal discriminator according to claim 1, wherein the second detection means is an INFO0a signal detector for detecting an INFO0a signal during a startup procedure. A sound detector for determining the sound / silence state of the input signal is provided, and the specific signal is detected when the silence state continues for a predetermined time after detecting the specific signal used in the startup procedure of the modem signal. 2. The signal discriminator according to claim 1, wherein the state is initialized. A first sound detector for determining the sound / silence state of the transmitter signal and a second sound detector for determining the sound / silent state of the receiver signal; 2. The detection state of the specific signal is initialized when a state in which both the transmission side and the reception side are silent is continued for a predetermined time after the specific signal to be used is detected. A signal discriminator as described in 1. A continuity test tone detector for detecting a tone signal of a specific frequency transmitted from the input signal for channel continuity test; after detecting the specific signal used in the start-up procedure of the modem signal; 2. The signal discriminator according to claim 1, wherein when a tone signal having a specific frequency transmitted for a continuity test is detected, a detection state of the specific signal is initialized. Tone signal of a specific frequency which the continuity test tone detector detects the signal discriminator according to claim 12 which is a tone signal of 2000 Hz. 14. The signal discriminator according to claim 1, wherein the tone signal having a specific frequency detected by the first detection means is a 2400 Hz tone signal. In the signal identification method for identifying the type of input signal into two types, voice and data,
A first step of detecting a tone signal of a specific frequency from the input signal;
A second step of detecting a specific signal used in a modem signal startup procedure from the input signal;
A third step of setting a specific signal detection flag when the specific signal is detected, and when a tone signal of the specific frequency is detected in a state where the specific signal detection flag is not set , A signal identification method, wherein the identification result is voice , but the signal identification result is not voice when the tone signal of the specific frequency is detected in a state where the specific signal detection flag is set. The above startup procedure is described in V. The signal identification method according to claim 15, wherein there are 34 procedures. The above startup procedure is described in V. The signal identification method according to claim 15, wherein there are 8 procedures. The specific signal is V.V. The signal identification method according to claim 15, wherein the signal is an ANSam signal in eight procedures. 19. The signal identification method according to claim 18, wherein a tone signal having a specific frequency included in the input signal is used instead of the ANSam signal. The signal identification method according to claim 15 , wherein the specific signal is a tone signal of 2100 Hz. The specific signal is V.V. V. 8 in procedure. The signal identification method according to claim 15, wherein the signal is a 21 (channel No. 2) modem signal. The specific signal is V.V. The signal identification method according to claim 15, wherein the signal is a JM signal in eight procedures. 16. The signal identification method according to claim 15, wherein the specific signal is an INFO0a signal during a startup procedure. 16. The signal identification method according to claim 15, wherein the specific signal detection flag is initialized when a silence state continues for a predetermined time after detecting a specific signal used in the startup procedure of the modem signal. . After detecting a specific signal used in the start-up procedure of the modem signal, the detection state of the specific signal is initialized when a state where there is no sound in both the transmission side and the reception side continues for a predetermined time. The signal identification method according to claim 15. Including a fourth step of detecting a tone signal of a specific frequency transmitted from the input signal for a channel continuity test, and detecting the specific signal used in the modem signal start-up procedure; 16. The signal identification method according to claim 15, wherein when a tone signal having a specific frequency transmitted for a test is detected, a detection state of the specific signal is initialized. 27. The signal identification method according to claim 26, wherein the tone signal of the specific frequency detected in the fourth step is a 2000 Hz tone signal. 28. The signal identification method according to claim 15, wherein the tone signal having a specific frequency detected in the first step is a 2400 Hz tone signal. The signal discriminator according to any one of claims 1 to 14, wherein the type of an input signal is classified into two types: voice and data.
Encoding means for performing high-efficiency speech encoding at an appropriate encoding rate based on the signal identification result of the signal identifier;
Transmitting means for transmitting the encoded data encoded by the encoding means;
Receiving means for receiving encoded data encoded from the opposite device side;
A transmission apparatus comprising: decoding means for decoding encoded data received by the receiving means. 2. The signal discriminator according to claim 1, wherein the second detecting means is a guard tone signal detector for detecting a guard tone signal of a modem. The signal discriminator according to claim 30, wherein the signal detected by the guard tone signal detector is a tone signal of 1800 Hz. 31. The signal discriminator according to claim 30, wherein the signal discriminating result is not a voice during a predetermined time after the first detecting means detects a tone signal of a specific frequency. 31. The signal discriminator according to claim 30, wherein the signal discriminating result is not voiced for a predetermined time after the guard tone signal detector no longer detects the guard tone signal. A signal level comparator for comparing a level of a tone signal of a specific frequency detected by the first detection means and a level of a guard tone signal detected by the guard tone signal detector; and the tone signal of the specific frequency and the guard When the level ratio of the tone signal is within a predetermined range, the signal identification result when the tone signal of the specific frequency is detected is not voice, but when the level ratio is not within the predetermined range, 31. The signal discriminator according to claim 30, wherein a signal discrimination result when a tone signal is detected is voice. In the signal identification method for identifying the type of input signal into two types, voice and data,
A first step of detecting a tone signal of a specific frequency from the input signal;
A second step of detecting a specific signal used in the startup procedure of the modem signal from the input signal, and when the tone signal of the specific frequency is detected in a state where the specific signal is not detected , A signal identification method characterized in that the signal identification result is voice , but when the tone signal of the specific frequency is detected in a state where the specific signal is detected , the signal identification result is not voice. 36. The signal identification method according to claim 35, wherein the specific signal is a guard tone signal of a modem. The signal identification method according to claim 36, wherein the guard tone signal of the modem is a 1800 Hz tone signal. A fifth step of setting a first timer when the specific signal is detected, a case where a predetermined time has not elapsed after the first timer is set, and a tone signal of the specific frequency is detected 36. The signal identification method according to claim 35, wherein the signal identification result is not a voice. Including a sixth step of setting a second timer when the guard tone signal is no longer detected, and detecting a tone signal of the specific frequency when a predetermined time has not elapsed since the second timer was set 36. The signal identification method according to claim 35, wherein a signal identification result in the case of the determination is not voice. A seventh step of determining whether a level ratio of the tone signal at the specific frequency and the level of the guard tone signal is within a predetermined range, and if the level ratio is within the predetermined range, The signal identification result when the frequency tone signal is detected is not voice, but if the level ratio is not within the predetermined range, the signal identification result when the tone signal of the specific frequency is detected is voice. 36. A signal identification method according to claim 35, wherein: 35. The signal discriminator according to any one of claims 30 to 34, wherein the input signal type is classified into two types: voice and data.
Encoding means for performing high-efficiency speech encoding at an appropriate encoding rate based on the signal identification result of the signal identifier;
Transmitting means for transmitting the encoded data encoded by the encoding means;
Receiving means for receiving encoded data encoded from the opposite device side;
A transmission apparatus comprising: decoding means for decoding encoded data received by the receiving means.

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