JP3811605B2 - Telephone equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a telephone device, and more particularly to a telephone device that can record an audio data signal and consumes less power.
[0002]
[Prior art]
Recently, mobile phones that perform wireless communication using digital data have become widespread. Digital mobile phones have the advantage that voice data can be encoded with a high compression rate to lower the bit rate, narrow the bandwidth of the call channel, and increase the number of lines. With respect to this encoding process, an encoding parameter is recorded at the time of encoding, and decoding is performed using the encoding parameter at the time of decoding.
[0003]
Some of such mobile phones have a so-called memo function that records their own voice during standby or records the voice of at least one of the other party during a call. When the recorded voice is played back at the time of standby using this memo function, the encoding parameter is supplied to the speech decoder, and the recorded voice can be decoded and listened to. Japanese Laid-Open Patent Publication No. 9-139978 discloses a cellular phone that can decode and listen to recorded voice while listening to received voice sent from the other party during a call.
[0004]
The cellular phone disclosed in this publication includes an encoding circuit that encodes an input audio signal, a transmission circuit that transmits an output signal from the encoding circuit, and a reception circuit that receives a signal received from the other party. A storage circuit for storing at least one of an output signal from the reception circuit and an output signal from the encoding circuit, and a first decoding circuit for decoding the output signal from the reception circuit and outputting a speech signal A second decoding circuit that decodes the output signal from the memory circuit and outputs an audio signal; and an output signal from the receiving circuit and the memory circuit by the first and second decoding circuits during transmission and reception And a control circuit for decoding each of the output signals.
[0005]
According to this cellular phone, two decoding circuits are provided, the first decoding circuit decodes the output signal from the receiving circuit and outputs the received voice, and the second decoding circuit outputs from the recording circuit. By decoding the signal and outputting the recorded voice, it is possible to simultaneously hear the voice of the other party during the call and the voice recorded by the memo function. In addition, this mobile phone can record both the input audio signal and the audio signal received from the other party in a superimposed manner, or can record only one predetermined audio.
[0006]
[Problems to be solved by the invention]
However, in the mobile phone disclosed in the above publication, the circuit scale is increased by having two decoding circuits, and accordingly, the power consumption is also increased. Also, if the input audio signal and the received audio signal are stored in a superimposed manner, it is difficult to hear at the time of reproduction. If only one of them is recorded, it is difficult to grasp the content of the conversation.
[0007]
The present invention has been made to solve the above-described problems, and has a circuit size, a low power consumption, and an audio data signal recorded or recorded so that conversation contents can be easily grasped during reproduction. It is an object of the present invention to provide a telephone device that can reproduce and transmit data signals during a call.
[0008]
[Means for Solving the Problems]
The telephone device according to the first invention has a first conversion means for converting voice into a voice data signal, and an input connected to the first conversion means, and the voice output from the first conversion means. Communication means for performing processing for transmitting a data signal to another station, processing for receiving and outputting a voice data signal transmitted from the other station, and second conversion for converting the voice data signal into voice Means, storage means for storing an audio data signal, connected to receive the output of the first conversion means and the output of the communication means, and is included in the audio data signal output from the first conversion means The audio data signal output from the first conversion means in accordance with a selection method set in advance for each combination of presence and absence of the audio data included in the data and the audio data signal output from the communication means Preliminary communication means includes a first selecting means for storing the selectively storing means either the audio data signals for receiving and output.
[0009]
According to the first invention, the first conversion means converts voice into a voice data signal, and the communication means receives and outputs a voice data signal transmitted from another station. The first selecting means is for each combination of the presence and absence of the audio data included in the audio data signal output from the first conversion means and the audio data included in the audio data signal output from the communication means. According to a preset selection method, either the audio data signal output from the first conversion unit or the audio data signal received and output by the communication unit is selectively stored in the storage unit. Thereby, either one of the audio data signal output from the first conversion unit and the audio data signal output from the communication unit, in which the audio data exists in the audio data signal, is recorded in the storage unit. In the telephone device, since both parties do not speak much, if one of the voices is recorded, the contents of the conversation can be grasped at the time of reproduction. As a result, it is possible to provide a telephone device that can record a voice data signal so that the conversation contents can be easily grasped during reproduction because the circuit size is small, the power consumption is small, and the content of conversation can be easily grasped.
[0010]
In addition to the configuration of the first invention, the telephone device according to the second invention is connected to the selection signal output means for outputting a predetermined selection signal, the output of the communication means and the output of the storage means, and the selection signal In response to the second selection means, a second selection means for selecting one of the voice data signal received and output by the communication means and the voice data signal read from the storage means and providing the second conversion means with the second selection means. In addition.
[0011]
According to the second aspect of the invention, the second selection means is responsive to the selection signal output from the selection signal output means for the voice data signal received and output by the communication means and the voice data signal read from the storage means. Either one is selected and given to the second conversion means. Thereby, based on the selection signal, either the sound based on the sound data signal received by the communication means or the sound based on the sound data signal read from the recording means is converted into sound by the second conversion means. For this reason, for example, when the audio data signal is compressed and encoded, the circuit for decoding the audio data signal may be one channel. As a result, it is possible to provide a telephone device that can reproduce a recorded voice data signal during a call with a small circuit scale and low power consumption.
[0012]
The telephone device according to the third invention is connected to the output of the communication means and the output of the storage means in addition to the configuration of the second invention, and the voice data received and outputted by the communication means in response to the selection signal It further includes third selection means for selecting any one of the signal and the audio data signal read from the storage means and giving the selected signal to the communication means for transmission to another station.
[0013]
According to the third invention, the third selecting means selects one of the audio data signal received and output by the communication means and the audio data signal read from the storage means in response to the selection signal. It is given to the communication means and transmitted to other stations. Thereby, based on the selection signal, either one of the voice based on the voice data signal received by the communication means and the voice based on the voice data signal read from the recording means can be transmitted to the other station by the communication means. As a result, it is possible to provide a telephone device that can transmit a recorded voice data signal to another station during a call.
[0014]
The telephone device according to the fourth invention is connected to the selection signal output means for outputting a predetermined selection signal, the output of the communication means and the output of the storage means, in addition to the configuration of the first invention. A second selection for selecting one of the voice data signal received and output by the communication means and the voice data signal read out from the storage means in response to the signal and sending it to the communication means for transmission to another station Means.
[0015]
According to the fourth aspect of the invention, the second selection means is responsive to the selection signal output from the selection signal output means for the voice data signal received and output by the communication means and the voice data signal read from the storage means. Either one is selected and given to the communication means to be transmitted to another station. Thus, based on the selection signal, either the voice based on the voice data signal received by the communication unit or the voice based on the voice data signal read from the recording unit can be transmitted to the other station by the communication unit. At this time, the audio data signal read from the recording means is one of the audio data signal output from the first conversion means and the audio data signal output from the communication means. As a result, it is possible to provide a telephone device that can transmit a recorded voice data signal to another station during a call.
[0016]
In the telephone device according to the fifth invention, in addition to the configuration of any one of the second to fourth inventions, the selection signal output means is connected to the output of the storage means and is included in the audio data signal read from the storage means. Means for outputting a predetermined selection signal in response to the presence and absence of audio data to be transmitted.
[0017]
According to the fifth invention, the selection signal output means outputs a predetermined selection signal in accordance with the presence and absence of audio data included in the audio data signal read from the storage means. Thus, when the voice data is stored in the storage means, the voice data signal stored in the storage means is output to the second conversion means and the communication means. As a result, it is possible to provide a telephone device that can reproduce or transmit the recorded audio data signal during a call.
[0018]
In the telephone device according to the sixth invention, in addition to the configuration of the first invention, the second conversion means decodes a given voice data signal according to a parameter determined for each channel of the given voice data signal. And a speaker for converting the decoded voice data signal output from the decoding means into voice, and the telephone device switches the voice data signal selected by the first selection means. In response to this, the storage means stores the switching information representing the switching of the audio data signal, and the switching information in the audio data signal read from the storage means is detected and the decoding means And means for providing a signal indicative of parameter switching.
[0019]
According to the sixth aspect, the decoding means decodes the applied audio data signal according to the parameters determined for each channel of the applied audio data signal. In response to the switching of the voice data signal selected by the first selection means, the telephone device stores the switching information indicating the switching of the voice data signal in the storage means, and the voice read from the storage means Switching information in the data signal is detected, and a signal indicating switching of the parameter is given to the decoding means. Thereby, when the audio data signal is compression-encoded, a decoding unit for one channel is prepared, and the parameter of the decoding unit is changed in response to switching of the channel of the audio data signal to be stored. Can be switched. As a result, it is possible to provide a telephone device that can reproduce a recorded voice data signal during a call with a small circuit scale and low power consumption.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.
[0021]
In the following description, a mobile phone will be described as an example, but the present invention is not limited to a mobile phone.
[0022]
<Embodiment 1>
Referring to FIG. 1, mobile phone 100 according to the present embodiment includes transmission voice processing section 110 for converting voice into a voice data signal and reception voice processing section 120 for converting a voice data signal into voice. And an RF (Radio Frequency) transmission processing unit 140 that is connected to the transmission audio processing unit 110 via the transmission switching unit 130, modulates an audio data signal with a baseband signal, and converts it into a radio signal, and the mobile phone 100 An RF reception processing unit 150 that is connected to the reception voice processing unit 120 via a control unit 170 that controls the whole, demodulates the received radio signal and converts it into a voice data signal, an RF transmission processing unit 140, and an RF reception processing unit 150 and an antenna 160 for wireless communication with other stations.
[0023]
The transmission voice processing unit 110 is connected to the microphone 112 that converts the voice of the user of the mobile phone 100 into voice data, and converts the voice data signal output from the microphone 112 from an analog signal to a digital signal. An A / D (Analog / Digital) converter 114 and a speech encoder 116 connected to the A / D converter 114 and compressing and encoding the digitized audio data signal are included. Speech encoder 116 is connected to transmission switching section 130.
[0024]
The received speech processing unit 120 is connected to the control unit 170 and decodes the speech data signal received via the RF reception processing unit 150. The speech decoder 126 is connected to the speech decoder 126 and decoded. A D / A (Digital / Analog) converter 124 that converts a digital signal into an analog signal, and a speaker 122 that is connected to the D / A converter 124 and converts an analog processed voice data signal into voice and outputs the voice. including.
[0025]
The transmission switching unit 130 selects one of the audio data signal output from the speech encoder 116 and the audio data signal output from the control unit 170 based on the input transmission switching signal, and the RF transmission processing unit 140.
[0026]
The controller 170 will be described in detail with reference to FIGS. 1 and 2.
Based on the input playback switching signal, control unit 170 converts either one of the received audio data signal output from RF reception processing unit 150 and the recorded audio data signal read from memory 200 to transmission switching unit 130 and A playback control unit 180 that outputs to both of the speech decoders 126, and a recording control unit 190 that transmits either the audio data signal output from the speech encoder 116 or the audio data signal output from the playback switching unit 182 to the memory 200. And a memory 200 that is connected to the reproduction control unit 180 and the recording control unit 190 and records one of the transmission audio data signal and the reception audio data signal. Further, the reproduction control unit 180 transmits an initialization signal to the speech decoder 126 based on the content of the recorded audio data signal recorded in the memory 200.
[0027]
The reproduction control unit 180 is connected to the RF reception processing unit 150, and is connected to the reproduction switching unit 182 that outputs an audio data signal input based on the reproduction switching signal to a predetermined circuit, and to the memory 200, and is stored in the memory 200. A memory reading unit 186 that reads the audio data signal, and a label detection unit 184 that is connected to the memory reading unit 186 and detects a label from the audio data signal recorded in the memory 200. When the label detection unit 184 detects a label in the audio data signal read by the memory reading unit 186, the label detection unit 184 transmits an initialization signal to the speech decoder 126. As described above, the playback switching unit 182 receives the received voice data signal output from the RF reception processing unit 150 and the recorded voice read from the memory 200 via the memory reading unit 186 based on the playback switching signal. Either one of the data signals is transmitted to one of the speech decoder 126 and the transmission switching unit 130.
[0028]
The recording control unit 190 is connected to the speech encoder 116, and is connected to the transmission audio detection unit 192 that detects audio in the transmission audio data signal output from the speech encoder 116, and the transmission audio detection unit 192. A recording channel selection unit 194 that selects a channel, and a recording switching unit 196 that is connected to the recording channel selection unit 194, the speech encoder 116, and the playback switching unit 182 and switches an audio data signal based on a recording switching signal. Note that the recording switching unit 196 is connected to the memory 200. The recording switching unit 196 transmits either the transmission audio data signal or the reception audio data signal to the memory 200 based on the recording switching signal output from the recording channel selection unit 194.
[0029]
With reference to FIG. 3, the input signal and output signal in transmission switching section 130 will be described. In the transmission switching unit 130, two states are realized based on the input transmission switching signal.
[0030]
In the state A, the transmission voice data signal input from the speech encoder 116 is output to the RF transmission processing unit 140. In this case, the voice input from the microphone 112 is transmitted to another station via the RF transmission processing unit 140. The operation mode at this time is called a normal call mode (transmission).
[0031]
In state B, either the received audio data signal or the recorded audio data signal input from the reproduction switching unit 182 is transmitted to the RF transmission processing unit 140. In this case, the received voice or the recorded voice is transmitted to another station via the RF transmission processing unit 140. When the received voice data signal is received from the playback switching unit 182, the operation mode at this time is referred to as a mischievous telephone repelling mode, and when the recorded voice data signal is received from the playback switching unit 182, it is referred to as a recording content transmission mode. .
[0032]
Referring to FIG. 4, reproduction switching unit 182 realizes the following four states based on the input reproduction switching signal.
[0033]
In state A, the received audio data signal input from the RF reception processing unit 150 is output to the speech decoder 120. In this case, the received audio data signal received via the RF reception processing unit 150 is decoded by the speech decoder 126, and audio is output from the speaker 122. The operation mode at this time is referred to as a normal call mode (receipt).
[0034]
In the state B, the reception voice data signal input from the RF reception processing unit 150 is output to the transmission switching unit 130. In this case, the received audio data signal received via the RF reception processing unit 150 is transmitted to another station via the RF transmission processing unit 140. The operation mode at this time is called a prank call repelling mode.
[0035]
In state C, the recorded audio data signal output from the memory reading unit 186 is output to the transmission switching unit 130. In this case, the recorded audio data signal recorded in the memory 200 is transmitted to another station via the RF transmission processing unit 140. The operation mode at this time is called a recording content transmission mode.
[0036]
In state D, the recorded audio data signal output from the memory reading unit 186 is output to the speech decoder 126. In this case, the recorded audio data signal read from the memory 200 is decoded by the speech decoder 126, and audio is output from the speaker 122. The operation mode at this time is called a recording content listening mode.
[0037]
Referring to FIG. 5, in recording switching unit 196, the following two states are realized based on the recording switching signal input from recording channel selecting unit 194.
[0038]
In the state A, the transmission audio data signal output from the speech encoder 116 is output to the memory 200. In this case, the audio data signal input from the microphone 112 is recorded in the memory 200. The operation mode at this time is called a voice recording mode (self).
[0039]
In the state B, the received audio data signal input from the reproduction switching unit 182 is output to the memory 200. In this case, the received audio data signal received via the RF reception processing unit 150 is recorded in the memory 200. The operation mode at this time is called a voice recording mode (partner).
[0040]
The voice recording mode (self) and the voice recording mode (partner) are automatically switched based on a recording switching signal generated by a method described later. Further, in the state B in the recording switching unit 196, when the output from the reproduction switching unit 182 is a recorded audio data signal, processing for ignoring the input signal from the reproduction switching unit 182 is performed. This is to avoid recording the recorded audio data signal read from the memory 200 by the memory reading unit 186 in the memory 200 again.
[0041]
The recording state of the audio data signal in the memory 200 will be described with reference to FIG. FIG. 6 is a diagram schematically showing a recording state of the audio data signal in the memory 200. As shown in FIG. Reception audio signal data is input to the recording switching unit 196 as the X channel and transmission audio data signal as the Y channel. That is, the received audio data signal received via the RF reception processing unit 150 via the reproduction switching unit 182 is input to the X channel, and the transmission audio data signal output from the speech encoder 116 is input to the Y channel. Is done. The X channel and Y channel signals are selectively switched so that one of the channels is recorded in the memory 200 by the recording switching signal output from the recording channel selection unit 194.
[0042]
In this manner, as shown in FIG. 6, in the Y channel to which the transmission audio data signal is input, when audio data is detected, the recording boundary label is recorded in the memory 200, and the audio data is detected. When the detection state is reached, the recording boundary label is recorded in the memory 200. As a result, in the Y channel to which the transmission audio data signal is input, when the audio data is not detected from the state where the audio data is detected and when the audio data is detected from the state where the audio data is not detected, A recording boundary label is recorded in the memory 200. The audio data recorded together with the recording boundary label is encoded data for each frame. The encoded data includes audio power and other parameters. Note that the audio data for one frame differs depending on the type of audio encoding method, but corresponds to approximately 10 to 40 msec of audio when decoded. When receiving the initialization signal, the speech decoder 126 initializes internal variables such as the filter state of the speech decoder 126 and the output buffer.
[0043]
This mobile phone 100 is also provided with number keys 0 to 9 for inputting the destination telephone number, a mode setting key for setting the mode of the mobile phone, a call request key for making a call request, and a call end for making a call end request. Including keys. These key input units are connected to the control unit 170, and the control unit 170 controls the entire mobile phone 100 based on signals from these key input units.
[0044]
Referring to FIG. 7, the program executed on mobile phone 100 has the following control structure with respect to the mode setting process.
[0045]
In step (hereinafter, step is abbreviated as S) 100, control unit 170 determines whether a call request is input from the key input unit. If a call request is input (YES in S100), the process proceeds to S102. On the other hand, if there is no call request from the key input unit (NO in S100), the process returns to S100 and waits until a call request is input.
[0046]
In S102, control unit 170 determines whether there is a recording request from the key input unit. If there is a recording request from the key input unit (YES in S102), the process proceeds to S104, and the operation mode of the mobile phone 100 is set to the voice recording mode. On the other hand, if a recording request is not input from the key input unit (NO in S102), the process proceeds to S106.
[0047]
In S106, control unit 170 determines whether or not a reproduction request has been input from the key input unit. If a reproduction request is input (YES in S106), the process proceeds to S110. On the other hand, if a reproduction request is not input (NO in S106), the process proceeds to S108, and the operation mode of mobile phone 100 is set to the normal call mode.
[0048]
In S110, control unit 170 determines whether the audio requested to be reproduced is recorded audio or received audio. This determination is made based on an input signal from the key input unit. If the playback request from the key input unit is a recorded voice (recorded voice in S110), the process proceeds to S114. On the other hand, if the received voice is requested to be played from the key input unit (received voice in S110), the process proceeds to S112.
[0049]
In S112, control unit 170 sets the operation mode of the mobile phone to a mischievous phone repelling mode.
[0050]
In S114, control unit 170 determines whether to reproduce or transmit the recorded sound. This determination is made based on an input signal input from the key input unit. If the recorded voice is to be played back (played back in S114), the process proceeds to S118. On the other hand, when recording voice is transmitted (transmitted in S114), the process proceeds to S116.
[0051]
At S116, control unit 170 sets the operation mode of the mobile phone to the recording content transmission mode. At S118, control unit 170 sets the operation mode of mobile phone 100 to the recording content listening mode.
[0052]
In S120, control unit 170 determines whether a call termination request has been received from the key input unit. When the call termination request is received (YES in S120), the process is terminated. On the other hand, if the call end request is not received (NO in S120), the process returns to S102, and the operation mode is set again.
[0053]
Referring to FIG. 8, the program executed on mobile phone 100 has the following control structure regarding the voice recording process. This voice recording process is a process in the voice recording mode in S104 of FIG.
[0054]
In S200, control unit 170 determines whether or not a voice recording mode has been detected. This determination is made by detecting the result of the mode setting process in FIG. When the voice recording mode is detected (YES in S200), the process proceeds to S202. On the other hand, if the voice recording mode is not detected (NO in S200), the process returns to S200 and waits for the detection of the voice recording mode.
[0055]
In S202, control unit 170 initializes frame counter FC (FC = 1), and initializes the recording channel of the 0th frame (CH (0) = received voice).
[0056]
In S204, control unit 170 causes transmission voice detection unit 192 to observe the transmission voice level. At this time, since the voice data encoded as shown in FIG. 6 includes voice power as a parameter, the voice level can be observed without decoding the voice data by monitoring the voice power. .
[0057]
In S206, control unit 170 determines whether transmission voice detection unit 192 has detected transmission voice. When transmission voice detection unit 192 detects a transmission voice (YES in S206), the process proceeds to S208. On the other hand, if transmission voice detection unit 192 does not detect transmission voice (NO in S206), the process proceeds to S210.
[0058]
In S208, control unit 170 sets the recording channel CH (FC) of the FC-th frame as the transmission voice channel. In S210, control unit 170 sets the recording channel CH (FC) of the FC-th frame as the reception voice channel.
[0059]
In S212, control unit 170 determines whether or not CH (FC) = CH (FC-1). That is, it is determined whether or not the channel before one frame counter matches the current channel. If the channel one frame counter before matches the current channel (YES in S212), the process proceeds to S216. On the other hand, if the channel before the one-frame counter does not match the current channel (NO in S212), the process proceeds to S214.
[0060]
In S214, control unit 170 records the recording boundary label in memory 200. In S216, control unit 170 causes memory 200 to store an audio data signal corresponding to recording channel CH (FC).
[0061]
In S220, control unit 170 calculates FC = FC + 1 for frame counter FC. In S222, control unit 170 determines whether or not release of the voice recording mode has been detected. This detection is performed based on an input signal from the key input unit. When release of the voice recording mode is detected (YES in S222), the voice recording process is terminated. On the other hand, if release of the audio recording mode is not detected (NO in S222), the process returns to S204, and either one of the transmission audio data signal and the reception audio data signal is stored in memory 200.
[0062]
Referring to FIG. 9, the program executed by mobile phone 100 has the following control structure regarding the recording content listening process. The recorded content listening process is a process in the recorded content listening mode of S118 shown in FIG.
[0063]
At S300, control unit 170 determines whether or not a recording content listening mode has been detected. This determination is made by detecting the result of the mode setting process in FIG. If the recording content listening mode is detected (YES in S300), the process proceeds to S300. On the other hand, if the recording content listening mode is not detected (NO in S300), the process returns to S300 and waits until the recording content listening mode is detected.
[0064]
In S302, control unit 170 initializes frame counter FC (FC = 1).
[0065]
In S304, control unit 170 instructs memory reading unit 186 to read an audio data signal for one frame from the FC-th frame from memory 200.
[0066]
In S306, control unit 170 determines whether label detection unit 184 has detected a recording boundary label. If label detection unit 184 detects the recording boundary label (YES in S306), the process proceeds to S308. On the other hand, if label detection unit 184 does not detect the recording boundary label (NO in S306), the process proceeds to S310.
[0067]
In S308, control unit 170 transmits an initialization signal to speech decoder 126 to label detection unit 184 to instruct to initialize the filter state, output buffer, and the like.
[0068]
In S310, control unit 170 instructs speech decoder 126 to output audio corresponding to the audio data signal read from memory 200 from the speaker. At this time, the speech decoder 126 decodes the audio data signal, the D / A converter 124 converts the digital signal into an analog signal, the speaker converts the audio signal into audio, and the audio is output from the speaker.
[0069]
In S312, control unit 170 calculates FC = FC + 1 for frame counter FC.
[0070]
In S314, control unit 170 determines whether or not release of the recording content listening mode has been detected. This determination is made based on an input signal from the key input unit. When the release of the recording content listening mode is detected (YES in S314), the recording content listening process is terminated. On the other hand, if the release of the recording content listening mode is not detected (NO in S314), the process returns to S304, the audio data signal is read from the memory for the next frame, and the audio corresponding to the audio data signal read from memory 200 is read. Is output from the speaker 122.
[0071]
Operation modes other than the voice recording mode and the recording content listening mode described above will be described.
[0072]
For the recorded content transmission process in the recorded content transmission mode of S116 shown in FIG. 7, the transmission switching unit 130 is set to state B and the reproduction switching unit 182 is set to state C. By transmitting the recorded audio data signal recorded in the memory 200 to the RF transmission processing unit 140 via the reproduction switching unit 182 and the transmission switching unit 130, the recorded content can be transmitted to the other party.
[0073]
The mischievous telephone repelling process in the mischievous telephone repelling mode of S112 shown in FIG. 7 sets the transmission switching unit 130 to the state B and the reproduction switching unit 182 to the state B. By transmitting the received voice data signal received via the RF reception processing unit 150 to the RF transmission processing unit 140 via the reproduction switching unit 182 and the transmission switching unit 130, the received voice data signal is transmitted to another station. Can do.
[0074]
Since the normal call process in the normal call mode of S108 shown in FIG. 7 is the same process as that of a general digital mobile phone, detailed description thereof will not be repeated here.
[0075]
An operation of mobile phone 100 based on the structure and flowchart as described above will be described.
[0076]
[Audio recording operation]
When the user of mobile phone 100 makes a call request (YES in S100) and enters a recording request from the key input unit during a call with a call partner of another station (YES in S200), frame counter FC and 0 The recording channel CH (0) of the second frame is initialized (S202). When the transmission voice level is observed by the transmission voice detector 192 (S204) and the transmission voice is detected (YES in S206), the recording channel CH (FC) of the FC-th frame is set as the transmission voice channel.
[0077]
That is, when the user of the mobile phone 100 generates sound, the initialized recording channel (initialized to received sound) is changed to the transmission channel, and the previous frame counter CH (0) and the current frame counter are changed. Channel CH (1) is not the same (NO in S212), the recording boundary label is recorded in the memory 200 (S214). An audio data signal corresponding to the recording channel CH (FC) is stored in the memory 200. For frame counter FC, calculation of FC = FC + 1 is performed (S220), and if release of the voice recording mode is not detected (NO in S222), the transmission voice level is observed by transmission voice detector 192, and the transmission voice is detected. The recording channel is switched depending on whether or not it is detected.
[0078]
In this way, when the user of the mobile phone 100 generates sound, an audio data signal corresponding to the sound generated by the user is recorded in the memory 200, and the user does not generate sound. The received audio data signal is recorded in the memory 200. At this time, the recording channel of the previous frame counter is compared with the recording channel of the current frame counter, and if they are different, the recording boundary label is recorded in the memory 200.
[0079]
[Recording operation listening]
When a playback request for recorded audio is made (recorded audio in S110, playback in S114), the operation mode is set to a recording content listening mode (S118). The recorded content listening mode may be during a call as shown in FIG. 7 or after the call is over. The operation for listening to the recorded content during a call will be described below.
[0080]
When the user of mobile phone 100 inputs switching to the recording content listening mode from the key input unit (YES in S300), frame counter FC is initialized (S302). An audio data signal for one frame from the FC-th frame is read through the memory reading unit 186 (S304), and when the label detection unit 184 detects a recording boundary label (YES in S306), the label detection unit 184 performs speech. An initialization signal is transmitted to the decoder 126. With this initialization signal, the filter state and output buffer stored in the speech decoder 126 are initialized. The recorded audio data signal read from the memory 200 is decoded by the speech decoder 126, converted to analog by the D / A converter 124, converted into audio by the speaker 122, and output (S310).
[0081]
For frame counter FC, calculation of FC = FC + 1 is performed (S312), and when the recording content is to be heard (NO in S314), one frame of audio from a predetermined frame is based on the next frame counter. A data signal is read from the memory 200.
[0082]
In this manner, transmission of the initialization signal to the speech decoder 126 is controlled based on the presence or absence of the recording boundary label in the audio data signal read from the memory 200. By repeating this, the recording content is heard.
[0083]
As described above, the mobile phone according to the present embodiment detects a transmission voice data signal input from the microphone during a call with the other party, and transmits either the transmission voice data signal or the reception voice data signal. To the memory. As a result, only one of the transmission voice data and the reception voice data during the call is recorded in the memory, and the conversation can be recorded in the memory for one channel. As a result, since only one recording channel is required, it is possible to provide a telephone device that can record a voice data signal with a small circuit scale, low power consumption, and capable of grasping conversation contents during reproduction.
[0084]
<Embodiment 2>
The second embodiment of the present invention will be described below. Note that the cellular phone according to the present embodiment is different only in the control unit in the first embodiment described above, and the other hardware structure and flowchart are the same, and therefore detailed description thereof will not be repeated here. .
[0085]
Referring to FIG. 10, the mobile phone according to the present embodiment includes a control unit 270 that is separate from the mobile phone according to the first embodiment. The control unit 270 is connected to the RF reception processing unit 150 and the memory reading unit 286, and based on the reproduction switching signal from the recording audio detection unit 288, either the received audio data signal or the recorded audio data signal is a speech decoder. 126 includes a reproduction switching unit 282 that transmits to 126, a memory 300 that stores an audio data signal, and a recorded audio detection unit 288 that is connected to the memory reading unit 286 and detects audio recorded in the memory 300.
[0086]
When the recording sound detection unit 288 detects the recording sound in the sound data signal read from the memory 300 via the memory reading unit 286, the recording sound detection unit 288 transmits a reproduction switching signal to the reproduction switching unit 282 and sends an initialization signal to the speech decoder 126. Send.
[0087]
When the playback switching unit 282 receives the playback switching signal from the recorded audio detection unit 288, the playback switching unit 282 gives priority to the recorded audio data signal over the received audio data signal and transmits the audio data signal to the speech decoder 126.
[0088]
Referring to FIG. 11, the program executed by mobile phone 100 according to the present embodiment has the following control structure regarding the recording content listening process. In the following description, it is assumed that the audio data signal recorded in the memory 300 is only the Y channel audio data signal shown in FIG.
[0089]
In S400, control unit 270 determines whether or not the recording content listening mode is detected during a call. This determination is made based on whether or not a change to the recording content listening mode has been input from the input key button.
[0090]
In S402, control unit 270 initializes frame counter FC (FC = 1). At S404, control unit 270 instructs memory reading unit 286 to read the audio data signal for one frame from the FC-th frame from memory 300. In S406, control unit 270 causes recorded audio detection unit 288 to observe the recorded audio level in the audio data signal read in S404. As in the first embodiment, the recorded sound detection unit 288 observes the recorded sound level without decoding by observing the sound power included in the parameters of the Y channel sound data signal recorded in the memory 300. be able to.
[0091]
In S408, when control unit 270 detects the recording sound recorded in memory 300 by recording sound detection unit 288 (YES in S408), the process proceeds to S410. On the other hand, if recording voice detection unit 288 does not detect the recording voice (NO in S408), the process proceeds to S412.
[0092]
In S410, control unit 270 sets the reproduction channel CH (FC) of the FC-th frame for the frame counter as the recording audio channel. In S412, control unit 270 sets the reproduction channel CH (FC) of the FC-th frame for the frame counter as the reception voice channel.
[0093]
In S414, control unit 270 determines whether or not CH (FC) = CH (FC-1). If the playback channel of the current frame counter is the same as the previous playback channel of the frame counter (YES in S414), the process proceeds to S418. On the other hand, if the playback channel of the current frame counter is not the same as the playback channel of the previous frame counter (NO in S414), the process proceeds to S416.
[0094]
In S416, control unit 270 instructs recording sound detection unit 288 to transmit an initialization signal to speech decoder 126. The filter state and output buffer stored in the speech decoder 120 are initialized by the initialization signal transmitted to the speech decoder 126.
[0095]
In S418, control unit 270 causes speaker 122 to output a recording audio data signal read from memory 300 by speech decoder 126 or a received audio data signal received. In S422, control unit 270 performs an operation of FC = FC + 1 for frame counter FC. In S424, control unit 270 determines whether or not release of the recording content listening mode has been detected. This determination is made based on whether or not a request key for canceling the recording content listening mode is input from the input key button. When the release of the recorded content listening mode is detected (YES in S424), the recorded content listening process is terminated. On the other hand, if the release of the recording content listening mode is not detected (NO in S424), the process returns to S404, and the audio data signal for one frame is read from memory 300 for the next frame counter, and the recorded audio data signal is recorded. Is detected, the playback channel of the frame is set as a recording audio channel. If no recording audio is detected, the playback channel of the frame is set as a reception audio channel.
[0096]
In this way, either the recorded audio data signal recorded in the memory 300 or the received received audio data signal is output from the speaker.
[0097]
The operation of the mobile phone based on the above structure and flowchart will be described.
[0098]
If the user of this mobile phone requests a change to the recording content listening mode during a call (YES in S400), frame counter FC is initialized (S402). An audio data signal for one frame from the FC-th frame is read from the memory 300 via the memory reading unit 286. When recording audio detection unit 288 detects recording audio in the audio data signal read from memory 300 (YES in S408), the playback channel is set to the recording audio channel (S410). If the playback channel in the current frame counter and the playback channel in the previous frame counter are the same (YES in S414), the initialization signal from recording audio detector 288 to speech decoder 126 is not transmitted. The audio corresponding to the recorded audio data signal read from the memory by the speech decoder 126 is output from the speaker 122 (S418). On the other hand, when recording voice is not detected in the recording voice data signal read from memory 300 via memory reading unit 286 (NO in S408), the reproduction channel is set as the reception voice channel (S412). If the playback channel of the current frame counter is different from the playback channel of the previous frame counter (YES in S414), an initialization signal is transmitted to speech decoder 126, and the filter state and output buffer are initialized. (S416).
[0099]
That is, when the audio data is not detected from the state in which the audio data is detected in the recorded audio data signal read from the memory 300 (when the Y channel in FIG. 6 falls), the reproduction channel of the corresponding channel becomes the received audio. The channel is changed and an initialization signal is transmitted to the speech decoder 126. As a result, the speaker 122 is changed from a state in which sound based on the recorded sound data signal is output to a state in which sound based on the received sound data signal received is output.
[0100]
As described above, the cellular phone according to the present embodiment can select one of the voice data signal received from the other party and the voice data signal stored in the memory and output the voice from the speaker. For this reason, a speech decoder for decoding a compression-coded audio data signal may be provided for one channel, a telephone device that can reproduce a recorded audio data signal during a call with a small circuit scale and low power consumption. Can provide.
[0101]
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.
[Brief description of the drawings]
FIG. 1 is a control block diagram of a telephone device according to Embodiment 1 of the present invention.
FIG. 2 is a control block diagram of a recording control unit and a reproduction control unit shown in FIG.
FIG. 3 is a diagram illustrating an operation mode of a transmission switching unit according to Embodiment 1 of the present invention.
FIG. 4 is a diagram showing an operation mode of a reproduction switching unit according to Embodiment 1 of the present invention.
FIG. 5 is a diagram showing an operation mode of a recording switching unit according to the first embodiment of the present invention.
FIG. 6 is a diagram schematically showing a recording state of an audio data signal.
FIG. 7 is a flowchart showing a control procedure of mode setting processing according to the first embodiment of the present invention.
FIG. 8 is a flowchart showing a control procedure of audio recording processing according to Embodiment 1 of the present invention.
FIG. 9 is a flowchart showing a control procedure of a recording content listening process according to Embodiment 1 of the present invention;
FIG. 10 is a control block diagram of a reproduction control unit according to Embodiment 2 of the present invention.
FIG. 11 is a flowchart showing a control procedure of a recorded content listening process according to Embodiment 2 of the present invention;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 100 Mobile phone, 110 Transmission voice processing part, 120 Reception voice processing part, 130 Transmission switching part, 140 RF transmission processing part, 150 RF reception processing part, 160 Antenna, 170 Control part, 180, 280 Playback control part, 190 Recording control Part, 200, 300 memory.

Claims (6)

First conversion means for converting sound into an audio data signal;
A process having an input connected to the first conversion means, and transmitting a voice data signal output from the first conversion means to another station; and receiving a voice data signal transmitted from the other station. Communication means for performing output processing;
A second conversion means for converting the audio data signal to audio;
Storage means for storing an audio data signal;
The audio data included in the audio data signal output from the first conversion means and the audio data signal output from the communication means are connected to receive the output of the first conversion means and the output of the communication means. The voice data signal output from the first conversion means and the voice data signal received and output by the communication means in accordance with a selection method preset for each combination of presence and absence of the voice data included A first selection means for selectively storing any one of the above in the storage means. Selection signal output means for outputting a predetermined selection signal;
Connected to the output of the communication means and the output of the storage means, and in response to the selection signal, either one of the audio data signal received and output by the communication means and the audio data signal read from the storage means The telephone apparatus according to claim 1, further comprising: second selection means for selecting and providing the second conversion means to the second conversion means. One of an audio data signal connected to the output of the communication means and the output of the storage means and received and output by the communication means in response to the selection signal and an audio data signal read from the storage means The telephone apparatus according to claim 2, further comprising third selection means for selecting and giving to the communication means for transmission to another station. Selection signal output means for outputting a predetermined selection signal;
Connected to the output of the communication means and the output of the storage means, and in response to the selection signal, either one of the audio data signal received and output by the communication means and the audio data signal read from the storage means The telephone apparatus according to claim 1, further comprising: second selection means for selecting and giving to the communication means to transmit to another station. The selection signal output means is connected to the output of the storage means, and means for outputting the predetermined selection signal according to the presence and absence of audio data included in the audio data signal read from the storage means The telephone device according to claim 2, comprising: The second conversion means includes a decoding means for decoding a given audio data signal according to a parameter determined for each channel of the given audio data signal;
A speaker that converts the decoded audio data signal output from the decoding means into audio;
The telephone device has means for storing switching information representing switching of the voice data signal in the storage means in response to switching of the voice data signal selected by the first selection means;
2. The apparatus according to claim 1, further comprising: means for detecting the switching information in the audio data signal read from the storage means and providing a signal indicating switching of the parameter to the decoding means. Telephone device.

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