JP2018033011A - Voice communication apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a voice communication apparatus capable of reducing echo in a communication partner, by suppressing wraparound of voice from the handset to the transmitter at the time of double talk.SOLUTION: A voice communication apparatus 10 includes an input gain adjuster 120 for adjusting the level of a reception signal according to the input gain, and an output gain adjuster 150 for adjusting the level of a transmission signal according to the output gain, and a control section 160. The control section 160 operates in reception mode for setting the input gain larger than the output gain when the reception signal is detected by reception detection processing, and operates in transmission mode for setting the output gain larger than the input gain when the transmission signal is detected by transmission detection processing. The control section 160 clocks a monitor period, including at least one of a reception monitor period and a transmission monitor period repeatedly. The control section 160 does not perform transmission detection processing but performs reception detection processing during the reception monitor period, and does not perform reception detection processing but performs transmission detection processing during the transmission monitor period.SELECTED DRAWING: Figure 1

Description

  The present invention generally relates to a voice communication device, and more particularly to a full-duplex voice communication device.

  Patent Document 1 discloses a loudspeaker communication device (voice communication device). The loudspeaker device of Patent Document 1 includes a voice switch and an echo canceller that suppresses acoustic echo. Further, the loudspeaker device of Patent Document 1 includes a microphone amplifier that amplifies an output signal (transmission signal) of a microphone (transmitter), a speaker amplifier that amplifies an input signal (received signal) of a speaker (receiver), and An echo suppressor. The voice switch is a receiving side signal path for transmitting a receiving signal sent from the other party's calling terminal to the speaker, and a transmitting side signal for transmitting the transmitting signal collected by the microphone to the other party's calling terminal. By inserting a loss in the route, the call state is switched between receiving and transmitting. The echo suppressor inserts an attenuation amount into the transmitting signal path when the voice switch is in the receiving state, and does not insert an attenuation amount into the transmitting signal path when the voice switch is not in the receiving state. As a result, only an unpleasant echo (residual echo) during a call is attenuated.

Japanese Patent No. 5712350

  However, the echo suppressor of Patent Document 1 does not insert an attenuation amount into the transmitting signal path when double talk is detected. For this reason, at the time of double talk, sound wraps around from the receiver to the transmitter, which may cause echo at the communication partner.

  The subject of this invention is providing the audio | voice communication apparatus which can reduce the echo in a communicating party by suppressing the wraparound of the audio | voice from a receiver at the time of double talk to a transmitter.

  A voice communication apparatus according to an aspect of the present invention includes an input gain adjuster, a receiver, a transmitter, an output gain adjuster, and a control unit. The input gain adjuster is configured to adjust the level of the received signal according to the input gain when receiving the received signal. The receiver is configured to output sound based on the received signal whose level is adjusted by the input gain adjuster. The transmitter is configured to output a transmission signal based on the voice when receiving the voice. The output gain adjuster is configured to adjust a level of the transmission signal output from the transmitter according to an output gain. The control unit is configured to perform reception detection processing for detecting the reception signal and transmission detection processing for detecting the transmission signal. The control unit is configured to operate in a reception mode in which the input gain is set larger than the output gain when the reception signal is detected by the reception detection process. The control unit is configured to operate in a transmission mode in which the output gain is set to be larger than the input gain when the transmission signal is detected by the transmission detection process. The control unit is configured to repeatedly measure a monitoring period including at least one of a reception monitoring period and a transmission monitoring period. The control unit is configured to perform the reception detection process without performing the transmission detection process during the reception monitoring period. The control unit is configured to perform the transmission detection process without performing the reception detection process during the transmission monitoring period.

  The voice communication device according to an aspect of the present invention has an effect of suppressing echo from the receiver to the transmitter and reducing echoes at the communication partner.

FIG. 1 is a block diagram of an audio communication system including an audio communication apparatus according to an embodiment of the present invention. FIG. 2 is a flowchart of the operation of the voice communication apparatus. FIG. 3A is a waveform diagram of input gain and output gain in the intermittent mode of the voice communication device according to the first modification of the embodiment. FIG. 3B is a waveform diagram of input gain and output gain in the intermittent mode of the second modification of the embodiment.

1. Embodiment A voice communication apparatus 10 according to an embodiment of the present invention is used in the voice communication system shown in FIG. The voice communication system includes a voice communication device 10, a signal processing device 20, and a counterpart communication device 30. The voice communication system is suitable, for example, for a call between a caller (for example, a worker) in a place with a loud sound (for example, an airfield or a building site) and a caller (for example, a commander) in an indoor area. Yes. The voice communication device 10 and the signal processing device 20 are portable devices that can be worn by an operator. For example, the counterpart communication device 30 is installed at a place where the commander sends an instruction to the worker. In the voice communication system, the counterpart communication device 30 creates a reception signal Rx based on the voice of the commander input to a microphone or the like and transmits it to the voice communication device 10 via the signal processing device 20. The voice communication device 10 outputs voice based on the received signal Rx. The voice communication device 10 creates a transmission signal Tx based on the worker's voice and transmits it to the counterpart communication device 30 via the signal processing device 20. When the counterpart communication device 30 receives the transmission signal Tx, the counterpart communication device 30 outputs a sound from a speaker or the like based on the transmission signal Tx. In this way, a call between the worker and the commander is performed through the voice communication system. Hereinafter, the voice communication device 10, the signal processing device 20, and the counterpart communication device 30 of the voice communication system will be described in more detail.

  The voice communication device 10 is configured to transmit voice by bone conduction. As shown in FIG. 1, the voice communication device 10 includes a communication unit 110, an input gain adjuster 120, a receiver 130, a transmitter 140, an output gain adjuster 150, and a control unit 160.

  The communication unit 110 is a communication interface for communicating with the signal processing device 20. The communication unit 110 has a function of receiving data of the reception signal Rx indicating the voice input to the counterpart communication device 30 and transmitting data of the transmission signal Tx indicating the voice input to the voice communication device 10. . That is, the communication unit 110 decodes the data of the reception signal Rx received from the signal processing device 20 and outputs the reception signal Rx to the input gain adjuster 120. Further, the communication unit 110 encodes the transmission signal Tx received from the output gain adjuster 150, generates data of the transmission signal Tx, and transmits the data to the signal processing device 20. The received signal Rx is an analog electrical signal, and the volume of the sound output based on the received signal Rx (the sound output from the voice communication device 10) is directly proportional to the level of the received signal Rx. The transmission signal Tx is also an analog electrical signal, and the sound output based on the transmission signal Tx (the sound output from the counterpart communication device 30) is directly proportional to the level of the transmission signal Tx. The communication unit 110 is configured to be able to simultaneously receive data of the reception signal Rx and transmit data of the transmission signal Tx. That is, the communication unit 110 corresponds to the full duplex communication method. In addition, the communication unit 110 has a function of transmitting and receiving control signals to and from external devices (the signal processing device 20 and the counterpart communication device 30). The communication unit 110 is configured to perform communication using a wireless communication method. The wireless communication method may be a well-known method and is not particularly limited.

  When receiving the reception signal Rx, the input gain adjuster 120 is configured to adjust the level of the reception signal Rx according to a gain (hereinafter referred to as “input gain” as necessary). Therefore, the input gain adjuster 120 adjusts the level of the reception signal Rx received from the communication unit 110 according to the input gain and outputs the adjusted signal to the receiver 130. The input gain adjuster 120 is configured so that the input gain can be adjusted within a predetermined range. The input gain adjuster 120 is an amplifier circuit including a fully differential operational amplifier.

  The receiver 130 is configured to output sound based on the received signal Rx whose level is adjusted by the input gain adjuster 120. The receiver 130 is a bone conduction receiver. The bone conduction receiver has a piezoelectric element that is brought into contact with the human body (particularly the head and neck), and generates sound (bone conduction sound) by generating vibration with the piezoelectric element based on the received signal Rx. .

  The transmitter 140 is configured to output a transmission signal Tx based on the voice when receiving the voice. In particular, the transmitter 140 outputs the transmission signal Tx to the output gain adjuster 150. The transmitter 140 is an electroacoustic transducer that converts sound into an electrical signal, and is, for example, a microphone.

  The output gain adjuster 150 is configured to adjust the level of the transmission signal Tx output from the transmitter 140 according to a gain (hereinafter referred to as “output gain” as necessary). Therefore, the output gain adjuster 150 adjusts the level of the transmission signal Tx received from the transmitter 140 according to the output gain and outputs the adjusted signal to the communication unit 110. The output gain adjuster 150 is an amplifier circuit including a normal operational amplifier.

  The input gain adjuster 120 and the output gain adjuster 150 have a common gain adjustment range. That is, the input gain and the output gain can be adjusted within the same range.

  The control unit 160 is, for example, a microcomputer including a memory and a microprocessor, and executes processes and operations described later when the microprocessor executes a program stored in the memory.

  The control unit 160 is configured to perform a reception detection process for detecting the reception signal Rx and a transmission detection process for detecting the transmission signal Tx. In the reception detection process, the control unit 160 detects the reception signal Rx input from the communication unit 110 to the input gain adjuster 120. For example, if the voltage of the electric circuit between the input gain adjuster 120 and the communication unit 110 is equal to or higher than the threshold, the control unit 160 determines that the received signal Rx has been detected. The controller 160 may detect the received signal Rx by a method different from this. In addition, it is preferable that the threshold value of the reception detection process is set so that erroneous detection due to noise other than the reception signal Rx can be suppressed. In the transmission detection process, the control unit 160 detects the transmission signal Tx input from the transmitter 140 to the output gain adjuster 150. For example, if the voltage on the electric circuit between the transmitter 140 and the output gain adjuster 150 is equal to or higher than the threshold, the control unit 160 determines that the transmission signal Tx has been detected. The controller 160 may detect the transmission signal Tx by another method. Note that it is preferable that the threshold of the transmission detection process is set so as not to detect an unintended transmission signal Tx output from the transmitter 140 due to voice or noise other than the desired voice.

  The control unit 160 has three operation modes: a reception mode, a transmission mode, and a default mode. The control unit 160 is configured to operate in the reception mode when the reception signal Rx is detected by the reception detection process. The control unit 160 is configured to operate in the transmission mode when the transmission signal Tx is detected by the transmission detection process. The control unit 160 is configured to operate in the default mode when the reception signal Rx is not detected by the reception detection process or when the transmission signal Tx is not detected by the transmission detection process.

  The reception mode is a mode in which the input gain is set larger than the output gain. In particular, in the reception mode, the control unit 160 sets the input gain to the first value (reception input setting value). In the reception mode, the control unit 160 sets the output gain to a second value (reception output setting value) smaller than the first value (reception input setting value). The reception input setting value is preferably a value such that the sound volume based on the reception signal Rx becomes an appropriate level. In the present embodiment, the reception input setting value is the maximum value of the gain adjustment range. The reception output setting value is preferably a value such that the sound volume based on the transmission signal Tx is small enough to reduce the echo at the communication partner. In the present embodiment, the reception output setting value is the minimum value of the gain adjustment range.

  The transmission mode is a mode in which the output gain is set larger than the input gain. In particular, in the transmission mode, the control unit 160 sets the output gain to a third value (transmission output setting value) larger than the second value (reception output setting value). In the transmission mode, the control unit 160 sets the input gain to a third value (transmission output setting value) and a fourth value (transmission input setting value) smaller than the first value (reception input setting value). Set to. The transmission output setting value is preferably a value such that the sound volume based on the transmission signal Tx becomes an appropriate level. In the present embodiment, the transmission output setting value is the maximum value of the gain adjustment range. The transmission input setting value is a value such that the sound volume based on the reception signal Rx is sufficiently low. In the present embodiment, the transmission input set value is the minimum value of the gain adjustment range.

  The default mode is a mode for matching the input gain and the output gain. In the present embodiment, the input gain in the default mode is equal to the input gain in the reception mode (reception input setting value). Similarly, the output gain in the default mode is equal to the output gain in the transmission mode (transmission output setting value). In the present embodiment, in the default mode, the input gain and the output gain are the maximum values of the gain adjustment range. Note that the input gain in the default mode does not have to be equal to the input gain in the reception mode in a strict sense, and may be in a range that can be regarded as equal (for example, to the extent that the caller does not notice a change in the input gain). Similarly, the output gain in the default mode may not be equal to the output gain in the transmission mode in a strict sense, and may be in a range that can be regarded as equal.

  When shifting from the default mode to the reception mode, the input gain does not change and the output gain decreases to the minimum value of the gain adjustment range. Similarly, when the mode is changed from the default mode to the transmission mode, the output gain does not change, and the input gain decreases to the minimum value of the gain adjustment range. According to this configuration, since the input gain or the output gain does not change when switching between the default mode and the reception mode or the transmission mode, a sense of incongruity caused by a change in volume can be suppressed. This configuration is not essential.

  Further, the control unit 160 is configured to repeatedly count the monitoring period in the normal state. The control unit 160 counts the monitoring period using a clock built in the microcomputer. The monitoring period is a relatively short time, for example, 1 second. The monitoring period includes at least one of the reception monitoring period and the transmission monitoring period. The control unit 160 is configured to perform reception detection processing without performing transmission detection processing during the reception monitoring period, and to perform transmission detection processing without performing reception detection processing during the transmission monitoring period. Configured. That is, during the reception monitoring period, the control unit 160 does not perform the transmission detection process, and thus operates in the reception mode or the default mode without operating in the transmission mode. On the other hand, during the transmission monitoring period, the control unit 160 does not perform the reception detection process, and thus operates in the transmission mode or the default mode without operating in the reception mode. “Do not perform reception detection processing (transmission detection processing)” not only means that the control unit 160 does not perform reception detection processing (transmission detection processing) itself, but also reception detection processing (transmission detection processing). This includes invalidating (ignoring) the result.

  The control unit 160 is configured to set the lengths of the reception monitor period and the transmission monitor period according to the priority indicating the relationship between the lengths of the reception monitor period and the transmission monitor period. For example, the priority is represented by the ratio (for example, 50%, 100%) of the reception monitoring period to the total of the reception monitoring period and the transmission monitoring period (that is, the monitoring period). Here, when the priority is 100%, the reception monitoring period becomes equal to the monitoring period, and there is no transmission monitoring period. In this case, the control unit 160 operates in the reception mode or the default mode without operating in the transmission mode. On the other hand, when the priority is 0%, the transmission monitoring period becomes equal to the monitoring period, and there is no reception monitoring period. In this case, the control unit 160 operates in the transmission mode or the default mode without operating in the reception mode. As described above, the priority determines which of the reception mode and the transmission mode is prioritized. According to this configuration, it is possible to set which one of receiving and transmitting is prioritized by changing the priority. This configuration is not essential.

  Moreover, the control part 160 is comprised so that a priority may be changed according to the instruction | indication from an external device (the signal processing apparatus 20 or the other party communication apparatus 30). For example, if the control signal received by the communication unit 110 includes a priority change instruction, the control unit 160 changes the priority according to the instruction. According to this configuration, the call quality can be improved by changing the priority by the external device. This configuration is not essential.

  Further, the control unit 160 is configured to operate in the reception mode or the transmission mode in accordance with an instruction from an external device (the signal processing device 20 or the counterpart communication device 30). However, this configuration is not essential. This configuration will be described in more detail. If the control signal received by the communication unit 110 includes an instruction to set the operation mode to the reception mode (hereinafter also referred to as “forced reception instruction”), According to this instruction, it operates in the reception mode for a predetermined period. That is, when receiving the forced reception instruction, the control unit 160 is in a state of operating in the reception mode (forced reception state) for a predetermined period. If the control signal received by the communication unit 110 includes an instruction to set the operation mode to the transmission mode (hereinafter also referred to as “forced transmission instruction”), the control unit 160 follows the instruction. It operates in the transmission mode for a predetermined period. That is, when receiving the forced transmission instruction, the control unit 160 enters a state of operating in the transmission mode (forced transmission state) for a predetermined period. For each of the forced reception instruction and the forced transmission finger instruction, the predetermined period may be a predetermined period or a period in which an instruction from an external device is input. According to this configuration, the operation mode can be temporarily changed easily by the external device. Further, the newer one of the forced reception instruction and the forced transmission instruction may be prioritized, or which one is prioritized may be determined in advance. For example, the forced reception instruction may be prioritized over the forced transmission finger. In this case, the control unit 160 does not enter the forced transmission state from the forced reception state even if it receives the forced transmission instruction in the forced reception state. On the other hand, when the controller 160 is in the forced transmission state and receives a forced reception instruction, the control unit 160 changes from the forced transmission state to the forced reception state.

  Further, the control unit 160 sets the reception input setting value, the transmission input setting value, the reception output setting value, and the transmission output setting value in accordance with an instruction from the external device (the signal processing device 20 or the counterpart communication device 30). Configured to change. For example, if the control signal received by the communication unit 110 includes an instruction to change the reception input setting value, the control unit 160 changes the reception input setting value according to this instruction. According to this configuration, the call quality can be improved by changing any one of the reception input setting value, the transmission input setting value, the reception output setting value, and the transmission output setting value by the external device. This configuration is not essential.

  The voice communication device 10 includes a communication unit 110, an input gain adjuster 120, an output gain adjuster 150, and a power supply that supplies power to the control unit 160. In addition, the voice communication device 10 includes a communication unit 110, an input gain adjuster 120, a receiver 130, a transmitter 140, an output gain adjuster 150, a control unit 160, and a housing that houses a power source. The housing has a portable size and is configured to be attached to a human body. The housing is configured such that the piezoelectric element of the receiver 130 is brought into contact with the human body and the transmitter 140 can receive sound.

  The signal processing device 20 is configured to communicate with the voice communication device 10 and the counterpart communication device 30, respectively. In particular, the signal processing device 20 is configured to transmit the reception signal Rx from the counterpart communication device 30 to the voice communication device 10 and transmit the transmission signal Tx from the voice communication device 10 to the counterpart communication device 30. . As illustrated in FIG. 1, the signal processing device 20 includes a first communication unit 210, a second communication unit 220, a noise canceller 230, an operation unit 240, and a control unit (external control unit) 250.

  The first communication unit 210 is a communication interface for communicating with the voice communication device 10 (communication unit 110). When receiving the reception signal Rx, the first communication unit 210 encodes the reception signal Rx, generates data of the reception signal Rx, and transmits the data to the voice communication device 10 (communication unit 110). The first communication unit 210 decodes the data of the transmission signal Tx received from the voice communication device 10 (communication unit 110), and outputs the transmission signal Tx to the second communication unit 220.

  The second communication unit 220 is a communication interface for communicating with the counterpart communication device 30. Second communication unit 220 decodes data of reception signal Rx received from counterpart communication device 30 and outputs reception signal Rx to first communication unit 210. When receiving the transmission signal Tx, the second communication unit 220 encodes the transmission signal Tx, generates data of the transmission signal Tx, and transmits the data to the counterpart communication device 30.

  The noise canceller 230 is a circuit for removing noise (particularly noise caused by the reception signal Rx) from the transmission signal Tx. The noise canceller 230 includes a monitor unit 231, an adaptive filter 232, and a subtracter 233. The monitor unit 231 is provided on the transmission path of the reception signal Rx between the first communication unit 210 and the second communication unit 220, and monitors the reception signal Rx. The adaptive filter 232 generates and outputs a signal to be removed from the transmission signal Tx based on the reception signal Rx from the monitor unit 231. The characteristic (filter coefficient) of the adaptive filter 232 is set according to the transfer characteristic of the transfer system between the receiver 130 and the transmitter 140. The subtracter 233 is provided in the transmission path of the transmission signal Tx between the first communication unit 210 and the second communication unit 220, and removes the signal output from the adaptive filter 232 from the transmission signal Tx. Since the noise canceller 230 may be a conventionally known circuit, a detailed description thereof is omitted.

  The operation unit 240 is a human machine interface for controlling the voice communication apparatus 10. The operation unit 240 includes, for example, one or a plurality of buttons.

  The external control unit 250 has a function of transmitting control signals including various instructions to the voice communication device 10 in accordance with the operation of the operation unit 240. By using the signal processing device 20, it is possible to change the priority, set the forced reception state, set the forced transmission state, receive input set value, transmit input set value, receive output set value, and transmit output set value. Can be changed. Since the voice communication device 10 can be controlled by the control unit (external control unit) 250 in this way, the configuration of the voice communication device 10 itself can be simplified.

  The signal processing device 20 includes a power source that supplies power to the first communication unit 210, the second communication unit 220, the noise canceller 230, the operation unit 240, and the external control unit 250. In addition, the signal processing device 20 includes a first communication unit 210, a second communication unit 220, a noise canceller 230, an operation unit 240, an external control unit 250, and a housing that stores a power source. The housing is configured to be portable. The signal processing device 20 is attached to clothes, for example.

  The counterpart communication device 30 has a function of converting speech into a reception signal Rx and transmitting it to the signal processing device 20 and a function of converting the transmission signal Tx received from the signal processing device 20 into speech and outputting it. That is, the counterpart communication device 30 converts the input voice into a reception signal Rx, encodes the reception signal Rx, generates data of the reception signal Rx, and transmits the data to the signal processing device 20. Further, the counterpart communication device 30 decodes the data of the transmission signal Tx received from the signal processing device 20, converts the transmission signal Tx into a voice and outputs it. Further, the counterpart communication device 30 has a function of transmitting a control signal including various instructions to the voice communication device 10. By using the other party communication device 30, the priority change, the forced reception state setting, the forced transmission state setting, the reception input setting value, the transmission input setting value, the reception output setting value, and the transmission output setting value are set. Can be changed. Since the voice communication device 10 can be controlled by the counterpart communication device 30 in this way, the configuration of the voice communication device 10 itself can be simplified. Note that the counterpart communication device 30 is realized by a computer having a microphone, a speaker, and a communication interface.

  Next, the operation of the voice communication apparatus 10 will be described with reference to the flowchart of FIG.

  When the voice communication device 10 is activated, the control unit 160 operates in a default mode (S10). Next, the control unit 160 confirms whether or not it is in a forced reception state (S11). When in the forced reception state (S11; YES), the control unit 160 operates in the reception mode (S15). Therefore, the control unit 160 sets the input gain to the reception input setting value (for example, the maximum value of the input gain), and sets the output gain to the reception output setting value (for example, the minimum value of the output gain).

  If it is not in the forced reception state in step S11 (S11; NO), the control unit 160 checks whether it is in the forced transmission state (S12). When in the forced transmission state (S12; YES), the control unit 160 operates in the transmission mode (S17). Therefore, the control unit 160 sets the output gain to the transmission output setting value (for example, the maximum value of the output gain), and sets the input gain to the transmission input setting value (for example, the minimum value of the input gain).

  When it is not a forced transmission state in step S12 (S12; NO), the control unit 160 is in a normal state and times the monitoring period. That is, the control unit 160 determines whether or not the present is the reception monitor period (S13). If the present is the reception monitoring period (S13; YES), the control unit 160 performs reception detection processing without performing transmission detection processing, and detects the reception signal Rx (S14). If the reception signal Rx is detected (S14; YES), the control unit 160 operates in the reception mode (S15). Thus, in step S14, the control unit 160 does not perform the transmission detection process. Therefore, even if the reception signal Rx and the transmission signal Tx exist at the same time (that is, during double talk), the control unit 160 operates in the reception mode. Thereby, the output gain becomes smaller than the input gain. Therefore, even if the transmitter 140 generates the transmission signal Tx from the sound output from the receiver 130 based on the reception signal Rx, the level of the transmission signal Tx is sufficiently reduced by the output gain adjuster 150. The Therefore, it is possible to suppress the wraparound of the sound from the handset 130 to the handset 140 at the time of double talk and reduce echoes at the communication partner. If the received signal Rx is not detected in step S14 (S14; NO), the control unit 160 returns to step S10 and operates in the default mode. That is, when the reception signal Rx and the transmission signal Tx do not exist at the same time, the input gain and the output gain are matched. In particular, the output gain in the default mode is equal to the output gain in the transmission mode. Therefore, when the transmission signal Tx exists, the transmission signal Tx is transmitted to the signal processing device 20 at the same level as the transmission mode. Thereafter, the output gain does not change even when the mode is switched from the default mode to the transmission mode. That is, since the output gain does not change between the default mode and the transmission mode, a sense of incongruity caused by a change in volume can be suppressed.

  In step S13, if the present is not the reception monitor period (S13; NO), the present is the transmission monitor period. Therefore, the control unit 160 performs the transmission detection process without performing the reception detection process, and detects the transmission signal Tx (S16). If the transmission signal Tx is detected (S16; YES), the control unit 160 operates in the transmission mode (S17). Thus, in step S17, the control unit 160 does not perform the incoming call detection process. Therefore, even if the reception signal Rx and the transmission signal Tx exist simultaneously (that is, even during double talk), the control unit 160 operates in the transmission mode. Thereby, the input gain becomes smaller than the output gain. For this reason, even if the transmitter 140 generates the transmission signal Tx from the voice output from the receiver 130 based on the reception signal Rx, the level of the transmission signal Tx is sufficiently small. Therefore, it is possible to suppress the wraparound of the sound from the handset 130 to the handset 140 at the time of double talk and reduce echoes at the communication partner. If the transmission signal Tx is not detected in step S16 (S16; NO), the control unit 160 returns to step S10 and operates in the default mode. That is, when the reception signal Rx and the transmission signal Tx do not exist at the same time, the input gain and the output gain are matched. In particular, the input gain in the default mode is equal to the input gain in the reception mode. Therefore, when the reception signal Rx exists, the reception signal Rx is output to the receiver 130 at the same level as the reception mode. Thereafter, the input gain does not change even when the mode is switched from the default mode to the reception mode. That is, since the input gain does not change between the default mode and the reception mode, a sense of incongruity caused by a change in volume can be suppressed.

  As described above, in the voice communication device 10 of the present embodiment, the control unit 160 repeatedly counts the monitoring period including at least one of the reception monitoring period and the transmission monitoring period. In the reception mode in which the control unit 160 performs reception detection processing without performing transmission detection processing during the reception monitoring period, and sets the input gain larger than the output gain when the reception signal Rx is detected by the reception detection processing. Operate. The control unit 160 performs the transmission detection process without performing the reception detection process during the transmission monitoring period, and sets the output gain larger than the input gain when the transmission signal Tx is detected by the transmission detection process. Operates in send mode. Therefore, according to the voice communication apparatus 10 of the present embodiment, it is possible to suppress the wraparound of the voice from the receiver 130 to the transmitter 140 at the time of double talk and reduce echoes at the communication partner.

2. The embodiment of the present invention is not limited to the above-described embodiment. The above-described embodiment can be variously changed according to the design or the like as long as the object of the present invention can be achieved.

  The first modification is different from the above embodiment in that the control unit 160 has an intermittent mode instead of the default mode. In addition, since the other structure of a 1st modification is the same as the said Embodiment 1, description is abbreviate | omitted.

  In the first modification, the control unit 160 is configured to operate in the intermittent mode if the reception signal Rx is not detected by the reception detection process or if the transmission signal Tx is not detected by the transmission detection process. The control unit 160 may be configured to be able to select whether to operate in the default mode or the intermittent mode.

  The intermittent mode is a mode in which reception processing and transmission processing are alternately performed. Hereinafter, the intermittent mode will be described in detail with reference to FIG. 3A. In FIG. 3A, the input gain graph and the output gain graph are separated on the vertical axis so that the relationship between the input gain and the output gain can be easily understood.

  In the reception process, the control unit 160 sets the input gain to be equal to or greater than the output gain so that there is an input ON period T1on in which the input gain is greater than the output gain. In the input on period T1on, the control unit 160 sets the input gain to the reception input setting value (for example, the maximum value Gmax of the gain adjustment range), and the reception output setting value (for example, the gain adjustment range, which is smaller than the reception input setting value). To the minimum value Gmin). In addition, the reception process period (reception period) Tr is equal to the input on period T1on. That is, the control unit 160 sets the input gain to the reception input setting value (maximum value Gmax) and the output gain to the reception output setting value (minimum value Gmin) throughout the reception period Tr.

  In the transmission process, the control unit 160 sets the output gain to be greater than or equal to the input gain so that there is an output on period T2on in which the output gain is greater than the input gain. In the output on period T2on, the control unit 160 sets the output gain to a transmission output setting value larger than the reception input setting value, and sets the input gain to a transmission input setting value smaller than the transmission output setting value and the reception input setting value. . For example, the transmission output setting value is the maximum value Gmax of the gain adjustment range, and the transmission input setting value is the minimum value Gmin of the gain adjustment range. The transmission processing period (transmission period) Ts has a dead time Tdt before and after the output on period T2on. That is, the transmission period Ts is a total period of the output on period T2on and the two dead times Tdt. The dead time Tdt is a period in which the input gain is smaller than the reception input setting value and equal to or greater than the transmission input setting value and the output gain is smaller than the transmission output setting value and equal to or greater than the reception output setting value. In the dead time Tdt, the input gain is set to the transmission input setting value (minimum value Gmin), and the output gain is set to the reception output setting value (minimum value Gmin). Due to the dead time Tdt, a period (output off period) T2off in which the output gain is the reception output set value (minimum value Gmin) is a total period of the input on period T1on and the two dead times Tdt. Further, the control unit 160 sets the input gain to the transmission input setting value (minimum value Gmin) throughout the transmission period Ts. That is, the period (input off period) T1off in which the input gain is the transmission input set value (minimum value Gmin) is equal to the transmission period Ts.

  By repeating such reception processing and transmission processing alternately, the input on period T1on and the output on period T2on exist alternately. Therefore, unlike the case where one of the input gain and the output gain is continuously increased from the other, the voice communication apparatus 10 is based on the received signal Rx even if both the transmission signal Tx and the received signal Rx exist. Voice can be output, and the counterpart communication device 30 can output voice based on the transmission signal Tx. Therefore, it is possible to suppress a decrease in call quality. Furthermore, since the period when the input gain is relatively large (input on period T1on) and the period when the output gain is relatively large (output on period T2on) do not overlap, the output gain is small when the input gain is large. Even if the voice circulates from the receiver 130 to the transmitter 140, the level of the transmission signal Tx output from the transmitter 140 is suppressed by the output gain adjuster 150. On the other hand, since the input gain is small when the output gain is large, the level of the transmission signal Tx output from the transmitter 140 is low from the beginning even when the voice circulates from the receiver 130 to the transmitter 140. Therefore, it is possible to suppress the wraparound of the sound from the handset 130 to the handset 140 at the time of double talk and reduce echoes at the communication partner.

  In the intermittent mode, the input gain periodically changes between the reception input setting value (maximum value Gmax) and the transmission input setting value (minimum value Gmin). Therefore, the voice (received voice) output from the receiver 130 is intermittent rather than continuous. Similarly, in the intermittent mode, the output gain periodically changes between the transmission output setting value (maximum value Gmax) and the reception output setting value (minimum value Gmin). Therefore, the voice (sending voice) output from the counterpart communication device 30 is intermittent rather than continuous. The degree to which the received voice and the transmitted voice are intermittent depends on the period of the reception process and the transmission process determined by the total period Tp of the reception period Tr and the transmission period Ts. It is preferable that the period is set to a value that reduces the discomfort of the caller with respect to the received voice and the transmitted voice. For example, the period is set to 0.002 seconds.

  The control unit 160 determines the length of the reception period Tr and the transmission period Ts based on the total period Tp of the reception period Tr and the transmission period Ts and the ratio of the reception period Tr and the transmission period Ts. To do. Moreover, the control part 160 is comprised so that the total period Tp and a ratio may be changed according to the instruction | indication from an external device (the signal processing apparatus 20 and the other party communication apparatus 30). For example, if the control signal received by the communication unit 110 includes an instruction to change the total period Tp, the control unit 160 changes the total period Tp according to the instruction. Similarly, if the control signal received by communication unit 110 includes an instruction to change the ratio, control unit 160 changes the ratio according to this instruction. According to this configuration, the call quality can be improved by changing the total period Tp and the ratio by the external devices (the signal processing device 20 and the counterpart communication device 30).

  Further, the control unit 160 sets the reception input setting value, the transmission input setting value, the reception output setting value, and the transmission output setting value in accordance with an instruction from the external device (the signal processing device 20 or the counterpart communication device 30). Configured to change. For example, if the control signal received by the communication unit 110 includes an instruction to change the reception input setting value, the control unit 160 changes the reception input setting value according to this instruction. According to this configuration, the call quality can be improved by changing any one of the reception input setting value, the transmission input setting value, the reception output setting value, and the transmission output setting value by the external device. This configuration is not essential.

  In addition, the control unit 160 is configured to set the input gain to the reception input setting value in the reception mode, and to set the output gain to the transmission output setting value in the transmission mode. According to this configuration, since the input gain does not change between the reception process in the intermittent mode and the reception mode, it is possible to suppress a sense of discomfort caused by a change in volume. Similarly, since the output gain does not change between the transmission process in the intermittent mode and the transmission mode, a sense of incongruity caused by a change in volume can be suppressed. This configuration is not essential.

  As described above, the control unit 160 has an intermittent mode in which reception processing and transmission processing are alternately performed. In the reception process, the control unit 160 sets the input gain to be equal to or greater than the output gain so that there is an input ON period T1on in which the input gain is greater than the output gain. In the transmission process, the control unit 160 sets the output gain to be greater than or equal to the input gain so that there is an output on period T2on in which the output gain is greater than the input gain. The control unit 160 is configured to operate in the intermittent mode when the reception signal Rx is not detected by the reception detection process or when the transmission signal Tx is not detected by the transmission detection process. In this configuration, the input on period T1on and the output on period T2on exist alternately. Therefore, even when both the transmission signal Tx and the reception signal Rx exist, communication is performed while suppressing the deterioration of the call quality and suppressing the wraparound of the voice from the receiver 130 to the transmitter 140 during double talk. Echo at the other party can be reduced.

  In addition, in the input on period T1on, the control unit 160 is configured to set the input gain to the received input set value and the output gain to the received output set value smaller than the received input set value. In the output on period T2on, the control unit 160 sets the output gain to a transmission output setting value larger than the reception output setting value, and sets the input gain to a transmission input setting value smaller than the transmission output setting value and the reception input setting value. Configured as follows. According to this configuration, it is possible to suppress the wraparound of the sound from the handset 130 to the handset 140 at the time of double talk and reduce echoes at the communication partner. This configuration is not essential.

  In the intermittent mode, the control unit 160 is configured to perform a reception process and a transmission process such that a dead time Tdt exists between the input on period T1on and the output on period T2on. In the dead time Tdt, the input gain is smaller than the reception input setting value and equal to or greater than the transmission input setting value, and the output gain is smaller than the transmission output setting value and equal to or greater than the reception output setting value. According to this configuration, it is possible to reliably prevent the input on period T1on and the output on period T2on from overlapping, and further suppress the wraparound of the voice from the handset 130 to the handset 140 at the time of double talk. Echo can be reduced. In FIG. 3A, the transmission period Ts includes the dead time Tdt, but the reception period Tr may include the dead time Tdt, or the dead time Tdt extends over the reception period Tr and the transmission period Ts. It may be. This configuration is not essential.

  In the first modification, the control unit 160 may be configured to make the reception processing period Tr longer than the transmission processing period Ts if the level of the reception signal Rx is higher than the level of the transmission signal Tx. Good. Further, the control unit 160 may be configured to make the transmission processing period Ts longer than the reception processing period Tr if the level of the transmission signal Tx is higher than the level of the reception signal Rx. More specifically, the control unit 160 determines the level of the received signal Rx input from the communication unit 110 to the input gain adjuster 120 and the level of the transmitted signal Tx input from the transmitter 140 to the output gain adjuster 150. Compare If the level of the received signal Rx is higher than the level of the transmitted signal Tx, the control unit 160 changes the ratio of the received period Tr and the transmitted period Ts so that the received period Tr becomes longer than the transmitted period Ts. . For example, the ratio between the reception period Tr and the transmission period Ts is changed from 1: 1 to 2: 1. Here, as the state where the level of the received signal Rx is higher than the level of the transmitted signal Tx continues, the control unit 160 may make the received period Tr longer than the transmitted period Ts. When the level of the received signal Rx is higher than the level of the transmitted signal Tx, since there is a high possibility that it is during reception, the received period Tr is given priority over the transmitted period Ts. Thereby, the discontinuity of the voice based on the received signal Rx can be reduced and the call quality can be improved. On the other hand, if the level of the transmission signal Tx is higher than the level of the reception signal Rx, the control unit 160 changes the ratio between the reception period Tr and the transmission period Ts so that the transmission period Ts is longer than the reception period Tr. . For example, the ratio between the reception period Tr and the transmission period Ts is changed from 1: 1 to 1: 2. Here, as the state where the level of the transmission signal Tx is higher than the level of the reception signal Rx continues, the control unit 160 may make the transmission period Ts longer than the reception period Tr. When the level of the transmission signal Tx is higher than the level of the reception signal Rx, the transmission period Ts is given priority over the reception period Tr because there is a high possibility that it is during transmission. Thereby, the discontinuity of the voice based on the transmission signal Tx can be reduced and the call quality can be improved. According to this configuration, since the ratio between the reception process period Tr and the transmission process period Ts is adjusted according to the current situation, the call quality can be improved. This configuration is not essential.

  In the first modification, the control unit 160 increases the reception input setting value if the level of the received signal Rx is higher than the level of the transmitted signal Tx, and the level of the transmitted signal Tx is higher than the level of the received signal Rx. For example, the transmission output set value may be increased. More specifically, the control unit 160 determines the level of the received signal Rx input from the communication unit 110 to the input gain adjuster 120 and the level of the transmitted signal Tx input from the transmitter 140 to the output gain adjuster 150. Compare Then, if the level of the received signal Rx is higher than the level of the transmitted signal Tx, the control unit 160 increases the received input setting value by a predetermined value. When the level of the received signal Rx is higher than the level of the transmitted signal Tx, there is a high possibility that the received signal is being received. Therefore, the received input setting value is increased and the level of the received signal Rx is increased by the input gain adjuster 120. By doing so, the call quality can be improved. On the other hand, if the level of the transmission signal Tx is higher than the level of the reception signal Rx, the control unit 160 increases the transmission output setting value by a predetermined value. When the level of the transmission signal Tx is higher than the level of the reception signal Rx, there is a high possibility that the transmission is in progress. Therefore, the transmission output setting value is increased and the output gain adjuster 150 increases the level of the transmission signal Tx. The call quality can be improved by raising the value. According to this configuration, since the incoming call input setting value and the outgoing call output setting value are adjusted according to the current situation, call quality can be improved. This configuration is not essential.

  As shown in FIG. 3B, the second modified example is different from the first modified example in the operation of the control unit 160 in the intermittent mode (adjustment of input gain and output gain). In addition, since the other structure of a 2nd modification is the same as a 1st modification, description is abbreviate | omitted. Also in FIG. 3B, the input gain graph and the output gain graph are separated on the vertical axis so that the relationship between the input gain and the output gain can be easily understood.

  In the second modification, the control unit 160 does not increase or decrease the input gain instantaneously in the intermittent mode, but changes the input gain over a certain time. That is, the control unit 160 increases the input gain from the transmission input setting value (minimum value Gmin) to the reception input setting value (maximum value Gmax) over the rise time T1r. In addition, the control unit 160 reduces the input gain from the reception input setting value (maximum value Gmax) to the transmission input setting value (minimum value Gmin) over the fall time T1f. Further, in the intermittent mode, the control unit 160 does not increase or decrease the output gain instantaneously, but changes the output gain over a certain period of time. That is, the control unit 160 increases the output gain from the reception output setting value (minimum value Gmin) to the transmission output setting value (maximum value Gmax) over the rise time T2r. Further, the control unit 160 reduces the output gain from the transmission output setting value (maximum value Gmax) to the reception output setting value (minimum value Gmin) over the fall time T2f. In the second modification, the reception period Tr is a total period of the input gain rise time T1r and the input on period T1on, and is also a total period of the output gain fall time T2f and the output off period T2off. The transmission period Ts is a total period of the input gain fall time T1f and the input off period T1off, and is also a total period of the output gain rise time T2r and the output on period T2on.

  Further, the control unit 160 performs the reception process so that the input gain rise time T1r matches the output gain fall time T2f, and the input gain fall time T1f matches the output gain rise time T2r. And transmission processing are alternately performed. In this case, in the period between the input on period T1on and the output on period T2on, one of the input gain and the output gain decreases and the other increases. For this reason, it is possible to suppress the wraparound of the sound from the handset 130 to the handset 140 at the time of double talk, and to reduce echo at the communication partner. Furthermore, the possibility of a silent period occurring between the input on period T1on and the output on period T2on can be reduced. Therefore, according to this configuration, it is possible to suppress the occurrence of a silent period when switching between the reception process and the transmission process while reducing echoes at the communication partner, thereby improving the call quality. This configuration is not essential.

  In addition, the control unit 160 determines at least one of the rising time T1r, the falling time T1f, the rising time T2r, and the falling time T2f in accordance with an instruction from the external device (the signal processing device 20 or the counterpart communication device 30). It may be configured to change. According to this configuration, the call quality is changed by changing any of the input gain rise time T1r, the input gain fall time T1f, the output gain rise time T2r, and the output gain fall time T2f by an external device. Can be improved.

  In FIG. 3B, the rise time T1r and the fall time T2f coincide with each other, and the fall time T1f and the rise time T2r coincide with each other. That is, the control unit 160 performs the reception process and the transmission process so that the rise time T1r and the fall time T2f overlap at least partially, and the fall time T1f and the rise time T2r overlap at least partially. What is necessary is just to be comprised so that it may carry out alternately.

  The above-described embodiment of the present invention, the first modified example, and the second modified example can further be variously changed according to the design and the like as follows.

  For example, the communication unit 110 and the first communication unit 210 may be configured to communicate using a wired communication method. That is, the voice communication device 10 and the signal processing device 20 may perform wired communication. The wired communication method may be a well-known method and is not particularly limited. Alternatively, the voice communication device 10 and the signal processing device 20 may be connected without using the communication unit 110 and the first communication unit 210. In this case, for example, the input gain adjuster 120 may be connected to the second communication unit 220 via the monitor unit 231 of the noise canceller 230, and the output gain adjuster 150 is connected to the second subtractor 233 of the noise canceller 230. 2 may be connected to the communication unit 220. The control unit 160 may be connected to the external control unit 250 through an external terminal (control terminal) and receive a control signal from the external control unit 250.

  For example, the second communication unit 220 may be configured to communicate using a wired communication method. That is, the signal processing device 20 and the counterparty communication device 30 may perform wired communication. The wired communication method may be a well-known method and is not particularly limited.

  For example, the input gain adjuster 120 is not limited to an amplifier circuit including a fully differential operational amplifier, and may be an amplifier circuit including a normal operational amplifier. The input gain adjuster 120 may be appropriately selected according to the type of the receiver 130. Similarly, the output gain adjuster 150 is not limited to an amplifier circuit including a normal operational amplifier. The output gain adjuster 150 may be appropriately selected according to the type of the transmitter 140. In the above embodiment, the adjustable range of the input gain of the input gain adjuster 120 and the adjustable range of the output gain of the output gain adjuster 150 are not necessarily the same, and may be different.

  For example, the handset 130 may be a handset for air conduction. The air conduction receiver is an electroacoustic transducer that converts an electrical signal into sound, and generates sound waves (air conduction sound) by generating sound waves based on the reception signal Rx. The air-conducting handset is, for example, an earphone or a speaker.

  For example, the priority may be a ratio (for example, 50% or 100%) of the transmission monitor period to the sum of the reception monitor period and the transmission monitor period (that is, the monitor period). Alternatively, the priority may be a ratio between the reception monitoring period and the transmission monitoring period. In short, the priority may be information indicating the relationship between the length of the reception monitor period and the transmission monitor period.

  For example, the control unit 160 may be configured to change the priority for a predetermined period in accordance with an instruction from an external device (the signal processing device 20 or the counterpart communication device 30). For example, when the control unit 160 receives an instruction to set the priority to 100% for a predetermined period, the control unit 160 sets the priority to 100% for the predetermined period and then sets the original value (for example, 50%). Return to. According to this configuration, the priority can be temporarily changed easily by the external device. The predetermined period may be a predetermined period or a period in which an instruction from an external device is input.

  For example, in response to an instruction from an external device (the signal processing device 20 or the counterpart communication device 30), the control unit 160 sets the reception input setting value, the transmission input setting value, the reception output setting value, and the transmission output setting value. What is necessary is just to be comprised so that at least one may be changed.

  For example, in the default mode, the control unit 160 may have an input gain that is different from the input gain (received input setting value) in the reception mode, and the output gain is the output gain (transmitted output setting value) in the transmission mode. May be different. For example, in the default mode, the input gain and the output gain may be the minimum value of the gain adjustment range. The control unit 160 may not have the default mode. For example, in step S10 of FIG. 2, the control unit 160 may operate in the reception mode or transmission mode instead of the default mode.

  For example, the signal processing device 20 may be provided integrally with the counterpart communication device 30. That is, the signal processing device 20 does not necessarily need to be worn by a person wearing the voice communication device 10. The signal processing device 20 may be provided integrally with the voice communication device 10. Further, instead of the signal processing device 20, the voice communication device 10 may include a noise canceller 230.

  For example, the counterpart communication device 30 may be a set of the voice communication device 10 and the signal processing device 20. That is, the voice communication system may be configured such that persons wearing the voice communication device 10 and the signal processing device 20 can make a call. In the voice communication system, the counterpart communication device 30 may function as a master unit or a base station, and each of the plurality of voice communication devices 10 may function as a slave unit or a mobile station. The signal processing device 20 is provided in either the voice communication device 10 or the counterpart communication device 30 as necessary. In particular, the signal processing device 20 is desirably provided integrally with the counterpart communication device 30. In this way, it can be expected that the voice communication device 10 is reduced in size and weight, reduced in power consumption, and reduced in equipment cost.

3. Aspect The voice communication device (10) according to the first aspect of the present invention includes an input gain adjuster (120), a receiver (130), a transmitter (140), an output gain adjuster (150), A control unit (160). The input gain adjuster (120) is configured to adjust the level of the received signal according to the input gain when receiving the received signal. The handset (130) is configured to output sound based on the received signal whose level is adjusted by the input gain adjuster (120). The transmitter (140) is configured to output a transmission signal based on the voice when receiving the voice. The output gain adjuster (150) is configured to adjust the level of the transmission signal output from the transmitter (140) according to the output gain. The control unit (160) is configured to perform a reception detection process for detecting the reception signal and a transmission detection process for detecting the transmission signal. The control unit (160) is configured to operate in a reception mode in which the input gain is set larger than the output gain when the reception signal is detected by the reception detection process. The control unit (160) is configured to operate in a transmission mode in which the output gain is set larger than the input gain when the transmission signal is detected by the transmission detection process. The control unit (160) is configured to repeatedly count a monitoring period including at least one of a reception monitoring period and a transmission monitoring period. The control unit (160) is configured to perform the reception detection process without performing the transmission detection process during the reception monitoring period. The control unit (160) is configured to perform the transmission detection process without performing the reception detection process during the transmission monitoring period. According to the 1st aspect, there exists an effect that the echo in a communicating party can be reduced by suppressing the wraparound of the audio | voice from a receiver at the time of double talk to a transmitter.

  The voice communication device (10) according to the second aspect of the present invention can be realized by a combination with the first aspect. In the second aspect, the control unit (160) determines the length of the reception monitor period and the transmission monitor period according to a priority indicating the relationship between the length of the reception monitor period and the transmission monitor period. Configured to set. According to the second aspect, it is possible to set which one of receiving and transmitting is prioritized by changing the priority.

  The voice communication device (10) of the third aspect according to the present invention can be realized by a combination with the second aspect. In the third aspect, the control unit (160) is configured to change the priority in accordance with an instruction from the external device (20, 30). According to the third aspect, the call quality can be improved by changing the priority by the external device (20, 30).

  The voice communication device (10) of the fourth aspect according to the present invention can be realized by a combination with the second or third aspect. In the fourth aspect, the control unit (160) is configured to change the priority for a predetermined period in response to an instruction from the external device (20, 30). According to the fourth aspect, the priority can be temporarily changed by the external device (20, 30) as necessary.

  The voice communication device (10) according to the fifth aspect of the present invention can be realized by a combination with any one of the first to fourth aspects. In the fifth aspect, the control unit (160) is configured to operate in the reception mode or the transmission mode for a predetermined period in response to an instruction from the external device (20, 30). . According to the fifth aspect, the reception mode or the transmission mode can be forcibly set by the external device (20, 30).

  The voice communication device (10) of the sixth aspect according to the present invention can be realized by a combination with any one of the first to fifth aspects. In a sixth aspect, the control unit (160) has a default mode for matching the input gain and the output gain. The controller (160) is configured to operate in the default mode when the received signal is not detected by the received call detection process or when the transmitted signal is not detected by the transmitted call detection process. According to the sixth aspect, since the input gain and the output gain are matched when the received signal and the transmitted signal do not exist at the same time, the call quality can be improved, and the receiver from the receiver at the time of double talk can be improved. It is possible to reduce the echo at the communication partner by suppressing the wraparound of the voice.

  The voice communication device (10) according to the seventh aspect of the present invention can be realized by a combination with the sixth aspect. In the seventh aspect, the input gain in the reception mode is equal to the input gain in the default mode, and the output gain in the transmission mode is equal to the output gain in the default mode. According to the seventh aspect, since the input gain does not change at the time of switching between the default mode and the reception mode, a sense of incongruity caused by a change in volume can be suppressed. Similarly, since the output gain does not change at the time of switching between the default mode and the transmission mode, a sense of incongruity caused by a change in volume can be suppressed.

  The voice communication device (10) of the eighth aspect according to the present invention can be realized by a combination with any one of the first to sixth aspects. In the eighth aspect, the control unit (160) has an intermittent mode in which reception processing and transmission processing are alternately performed. In the reception process, the control unit (160) is configured to set the input gain to be equal to or greater than the output gain so that there is an input on period (T1on) in which the input gain is greater than the output gain. The control unit (160) is configured to set the output gain to be equal to or greater than the input gain so that there is an output on period (T2on) in which the output gain is greater than the input gain in the transmission process. . The control unit (160) is configured to operate in the intermittent mode when the received signal is not detected by the received call detection process or when the transmitted signal is not detected by the transmitted call detection process. According to the 8th aspect, there exists an effect that the echo in a communicating party can be reduced by suppressing the wraparound of the sound from the handset (130) to the handset (140) at the time of double talk.

  The voice communication device (10) according to the ninth aspect of the present invention can be realized by a combination with the eighth aspect. In a ninth aspect, the control unit (160) sets the input gain to a received input set value and the output gain to a received output set value smaller than the received input set value during the input on period (T1on). Configured to do. In the output on period (T2on), the control unit (160) sets the output gain to a transmission output setting value larger than the reception output setting value, and sets the input gain to the transmission output setting value and the reception input setting. The transmission input setting value is set to be smaller than the value. According to the 9th aspect, there exists an effect that the echo in a communicating party can be reduced by suppressing the wraparound of the sound from the handset (130) to the handset (140) at the time of double talk.

  The voice communication device (10) according to the tenth aspect of the present invention can be realized by a combination with the ninth aspect. In a tenth aspect, the control unit (160) is configured so that, in the intermittent mode, the dead time (Tdt) exists between the input on period (T1on) and the output on period (T2on). It is configured to perform a reception process and the transmission process. The dead time (Tdt) is a period in which the input gain is smaller than the reception input setting value and greater than or equal to the transmission input setting value and the output gain is smaller than the transmission output setting value and greater than or equal to the reception output setting value. is there. According to the 10th aspect, it can prevent reliably that the said input on period (T1on) and the said output on period (T2on) overlap. Therefore, there is an effect that it is possible to further suppress the wraparound of the sound from the handset (130) to the handset (140) at the time of double talk and to reduce echo at the communication partner.

  The voice communication device (10) according to the eleventh aspect of the present invention can be realized by a combination with the ninth or tenth aspect. In the eleventh aspect, the control unit (160), in response to an instruction from the external device (20, 30), adds up the period of the reception process (Tr) and the period of the transmission process (Ts). It is configured to change (Tp). According to the eleventh aspect, the external device (20, 30) changes the call quality by changing the total period (Tp) of the reception process period (Tr) and the transmission process period (Ts). Improvements can be made.

  The voice communication device (10) according to the twelfth aspect of the present invention can be realized by a combination with any one of the ninth to eleventh aspects. In the twelfth aspect, the control unit (160) sets the ratio between the reception process period (Tr) and the transmission process period (Ts) in response to an instruction from the external device (20, 30). Configured to change. According to the twelfth aspect, the external device (20, 30) can improve the call quality by changing the ratio of the reception processing period (Tr) and the transmission processing period (Ts).

  The voice communication device (10) according to the thirteenth aspect of the present invention can be realized by a combination with any one of the ninth to twelfth aspects. In a thirteenth aspect, if the level of the received signal is higher than the level of the transmitted signal, the control unit (160) makes the reception process period (Tr) longer than the transmitted process period (Ts). Configured to do. The controller (160) is configured to make the transmission processing period (Ts) longer than the reception processing period (Tr) if the level of the transmission signal is higher than the level of the reception signal. . According to the thirteenth aspect, since the ratio between the reception process period (Tr) and the transmission process period (Ts) is adjusted according to the current situation, the call quality can be improved.

  The voice communication device (10) of the fourteenth aspect according to the present invention can be realized by a combination with any one of the ninth to thirteenth aspects. In the fourteenth aspect, the control unit (160), in response to an instruction from the external device (20, 30), the reception input setting value, the transmission input setting value, the reception output setting value, and the transmission output. It is configured to change at least one of the speech output setting values. According to the fourteenth aspect, by changing any one of the reception input setting value, the transmission input setting value, the reception output setting value, and the transmission output setting value by the external device (20, 30), Improvements can be made.

  The voice communication device (10) according to the fifteenth aspect of the present invention can be realized by a combination with any one of the ninth to fourteenth aspects. In the fifteenth aspect, the control unit (160) increases the reception input setting value if the level of the received signal is higher than the level of the transmitted signal, and the level of the transmitted signal is set to the level of the received signal. If it is higher than the level, the transmission output set value is increased. According to the fifteenth aspect, since the incoming call input setting value and the outgoing call output setting value are adjusted according to the current situation, the call quality can be improved.

  The voice communication device (10) according to the sixteenth aspect of the present invention can be realized by a combination with any one of the ninth to fifteenth aspects. In the sixteenth aspect, in the intermittent mode, the control unit (160) causes the input gain rising time (T1r) and the output gain falling time (T2f) to overlap at least partially. The process and the transmission process are alternately performed. Further, in the intermittent mode, the control unit (160) causes the input processing and the transmission processing so that the input gain fall time (T1f) and the output gain rise time (T2r) overlap at least partially. It is comprised so that a speech process may be performed alternately. In the sixteenth aspect, it is possible to suppress the occurrence of a silent period when switching between the reception process and the transmission process while reducing echoes at the communication partner, thereby improving the call quality.

  The voice communication device (10) according to the seventeenth aspect of the present invention can be realized by a combination with the sixteenth aspect. In the seventeenth aspect, the control unit (160), in response to an instruction from the external device (20, 30), the input gain rise time (T1r), the input gain fall time (T1f), At least one of the output gain rise time (T2r) and the output gain fall time (T2f) is changed. According to the seventeenth aspect, the input device rise time (T1r), input gain fall time (T1f), output gain rise time (T2r), and output gain rise time are external devices (20, 30). The call quality can be improved by changing any of the falling times (T2f).

  The voice communication device (10) according to the eighteenth aspect of the present invention can be realized by a combination with any one of the ninth to seventeenth aspects. In the eighteenth aspect, the control unit (160) sets the input gain to the reception input setting value in the reception mode, and sets the output gain to the transmission output setting value in the transmission mode. Configured to be. According to the eighteenth aspect, since the input gain does not change between the reception process in the intermittent mode and the reception mode, it is possible to suppress a sense of incongruity caused by a change in volume. Similarly, since the output gain does not change between the transmission process in the intermittent mode and the transmission mode, a sense of incongruity caused by a change in volume can be suppressed.

DESCRIPTION OF SYMBOLS 10 Voice communication apparatus 120 Input gain adjuster 130 Handset 140 Transmitter 150 Output gain adjuster 160 Control part 20 Signal processing apparatus (external apparatus)
30 Counterpart communication device (external device)
T1on input on period T2on output on period

Claims (8)

An input gain adjuster that adjusts the level of the received signal according to the input gain when receiving the received signal;
A receiver that outputs sound based on the received signal whose level is adjusted by the input gain adjuster;
A transmitter that receives a voice and outputs a transmission signal based on the voice;
An output gain adjuster for adjusting the level of the transmission signal output from the transmitter according to an output gain;
An incoming call detection process for detecting the received signal and a transmission detection process for detecting the transmitted signal, and when the received signal is detected by the received call detection process, the input gain is set larger than the output gain. A control unit that operates in a transmission mode in which the output gain is set to be greater than the input gain when the transmission signal is detected by the transmission detection process;
With
The controller is
The monitoring period including at least one of the reception monitoring period and the transmission monitoring period is repeatedly counted,
During the reception monitoring period, perform the reception detection processing without performing the transmission detection processing,
During the transmission monitor period, the transmission detection process is performed without performing the reception detection process.
Configured as
Voice communication device. The control unit is configured to set a length of the reception monitor period and the transmission monitor period according to a priority indicating a relationship between a length of the reception monitor period and the transmission monitor period.
The voice communication apparatus according to claim 1. The control unit is configured to change the priority in response to an instruction from an external device.
The voice communication apparatus according to claim 2. The control unit is configured to change the priority for a predetermined period in response to an instruction from an external device.
The voice communication apparatus according to claim 2 or 3. The control unit is configured to operate in the reception mode or the transmission mode for a predetermined period in response to an instruction from an external device.
The voice communication device according to claim 1. The controller is
A default mode for matching the input gain and the output gain;
If the reception signal is not detected by the reception detection process or if the transmission signal is not detected by the transmission detection process, the reception mode is configured to operate in the default mode.
The voice communication device according to claim 1. The input gain of the reception mode is equal to the input gain of the default mode,
The output gain of the transmission mode is equal to the output gain of the default mode;
The voice communication apparatus according to claim 6. The controller is
The reception process for setting the input gain to be equal to or higher than the output gain so that the input on-period is larger than the output gain, and the output so that the output gain is larger than the input gain. Having an intermittent mode for alternately performing a transmission process for setting a gain to be equal to or greater than the input gain;
If the reception signal is not detected by the reception detection process or if the transmission signal is not detected by the transmission detection process, it is configured to operate in the intermittent mode.
The voice communication apparatus according to claim 1.

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