JP2010103854A - Slidable mobile telephone terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a slidable mobile telephone terminal achieving appropriate space sound and voice volume (transmission sound quality) even in open and closed states (first and second forms, respectively). <P>SOLUTION: A control section inputs user's voice from a microphone via a first amplifier in the first and second forms for converting to sound signals for transmission by radio, converts the sound signals from one's party to the voice of one's party, and executes call processing for outputting to a receiver via a second amplifier (step S1). When the microphone and a receiver are provided each at one end of first and second casings, the one-line distance between the receiver and the microphone in the second shape is shorter than that between the receiver and the microphone in the first form. The control section monitors a connection section (step S2), and the gain of the first amplifier is reduced (step S5) in the case of the second form (step S3-YES) than that in the first form (steps S3-NO, S4). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a slide-type mobile phone terminal capable of making a call both in an open state and in a closed state.

  Sliding mobile phone terminals are widely used. The sliding mobile phone terminal includes a first housing, a second housing, and a connecting portion. A microphone sound hole is provided at one end of the first housing, and a microphone is provided in the microphone sound hole. A receiver sound hole is provided at one end of the second housing, and a receiver is provided in the receiver sound hole. The connecting unit connects the first and second housings, and the first housing and the second housing overlap when the user slides the second housing in a direction parallel to the first housing. A first shape that is not in a state or a second shape in which the first housing and the second housing overlap is formed. Here, depending on the structure of the connecting portion, the first shape represents a state in which the first housing and the second housing partially overlap, and the second shape includes all of the first housing and the second housing. It may represent an overlapping state. In recent years, a slide-type mobile phone terminal capable of making a call with either the first shape or the two shapes has also become widespread (see, for example, Patent Document 1).

  Here, the mobile phone terminal is introduced.

  In the slide-type mobile phone terminal described in Patent Document 1, a first protrusion is provided at the periphery of the microphone of the first casing, and the second casing is opposed to the microphone of the first casing when in the second shape. The second protrusion is provided at the position of the body, and the first and second protrusions are in contact with each other, thereby reducing the occurrence of echo.

  In the foldable mobile phone terminal described in Patent Document 2, the user rotates the second casing 180 degrees with respect to the surface of the first casing by a hinge that connects one end of the first and second casings. Sometimes, the first shape is a state where the first and second housings do not overlap, and the second shape is a state where the first and second housings overlap. In addition, the first microphone is provided at the other end of the first casing, the second microphone is provided at one end of the first casing, the receiver is provided at the other end of the second casing, The microphone and the receiver are used, and in the second shape, the microphone and the second receiver are used. However, this foldable mobile phone terminal requires two microphones. In addition, when the user calls from the first shape to the second shape, it is necessary to change the mobile phone terminal.

  In the foldable mobile phone terminal described in Patent Document 3, the user rotates the second casing 180 degrees with respect to the surface of the first casing by a hinge that connects one end of the first and second casings. In some cases, the first shape is a state where the first and second housings do not overlap, and the second shape is a state where the first and second housings overlap. A microphone is provided at the other end of the first housing, a first receiver is provided at the other end of the second housing, and a second receiver is provided at one end of the second housing (first In the first shape, a microphone and a receiver are used, and in the second shape, a microphone and a second receiver are used. However, in this foldable mobile phone terminal, when the user makes a call from the first shape to the second shape, there is no need to change the mobile phone terminal, but two receivers are required.

JP 2006-135889 A JP 2004-228920 A JP 2005-175747 A

  By the way, in the slide type mobile phone terminal, the linear distance between the receiver sound hole (receiver) and the microphone sound hole (microphone) when the connecting part forms the second shape is that the connecting part forms the first shape. It is shorter than the linear distance between the receiver sound hole (receiver) and the microphone sound hole (microphone).

  For this reason, in the first shape, the distance between the receiver sound hole (receiver) and the microphone sound hole (microphone) is kept far, but in the second shape, the receiver sound hole and the microphone sound hole are close to each other. In the second shape, the received sound (the other party's voice) coming out of the receiver sound hole easily goes around the microphone, and the spatial sound (echo) between the microphone and the receiver is increased. Further, in the second shape, the time for the reception sound from the receiver to wrap around the microphone is shorter than that in the first shape. Therefore, there is a problem that the amount of spatial sound changes between the first shape and the second shape.

  Further, when the user is talking, the distance between the speaker's mouth and the microphone is long in the first shape, whereas the distance between the speaker's mouth and the microphone is short in the second shape. End up. That is, in the second shape, the sound volume representing the amount of sound transmitted from the speaker's mouth to the microphone is larger than that in the first shape. In the second shape, the frequency characteristic of the sound transmitted from the speaker's mouth to the microphone changes with respect to the first shape. Therefore, a difference occurs in the transfer function of the sound field propagation from the speaker's mouth to the microphone between the first shape and the second shape, which causes a problem that the transmitted sound quality changes.

  Accordingly, an object of the present invention is to provide a slide type mobile phone terminal that realizes appropriate spatial sound and sound volume (transmission sound quality) both in an open state (first shape) and in a closed state (second shape). It is in.

  The slide-type mobile phone terminal of the present invention includes first and second housings, a connection unit, a microphone, a first amplifier, a control unit, a second amplifier, and a receiver. The connecting portion connects the first and second housings, and when the user slides the second housing in a direction parallel to the first housing, the first housing and the second housing overlap each other. A first shape that is not to be formed or a second shape in which the first housing and the second housing overlap is formed. The microphone collects the user's voice. The first amplifier amplifies the user's voice. In the first and second shapes, the control unit converts the user's voice from the first amplifier into a voice signal and transmits it wirelessly, and executes call processing for converting the voice signal from the other party into the other party's voice. . The second amplifier amplifies the other party's voice from the control unit. The receiver outputs the other party's voice from the second amplifier. The microphone and the receiver are each provided at one end of the first and second housings. In this case, the linear distance between the receiver and the microphone in the second shape is shorter than the linear distance between the receiver and the microphone in the first shape. Therefore, the control unit includes a shape monitoring unit and a gain adjustment unit. The shape monitoring unit monitors the connecting unit and outputs a monitoring result representing the first or second shape. The gain adjustment unit reduces the gain of the first or second amplifier when the monitoring result represents the second shape than when the monitoring result represents the first shape.

  The control unit further includes a gain adjustment table. The gain adjustment table stores information representing the first and second shapes and information representing the first and second gains for controlling the first or second amplifier when the shapes are the first and second shapes. . In this case, the second gain is lower than the first gain. When the monitoring result represents the first shape, the gain adjustment unit refers to the gain adjustment table and controls the first or second amplifier so as to amplify the voice of the user or the other party with the first gain. When the monitoring result indicates the second shape, the gain adjustment unit refers to the gain adjustment table and controls the first or second amplifier so as to amplify the voice of the user or the other party with the second gain.

  As described above, according to the slide type mobile phone terminal of the present invention, the spatial sound between the microphone and the receiver is larger in the second shape than in the first shape. In the second shape, the distance between the mouth and the microphone sound hole is shorter than in the first shape, and the sound volume reaching the microphone sound hole is increased. For this reason, the gain of the first amplifier is lowered when it is in the second shape. Thereby, it is possible to realize appropriate spatial sound and sound volume (transmission sound quality) both in the open state (first shape) and in the closed state (second shape).

  Further, according to the slide type mobile phone terminal of the present invention, when the first and second shapes are used, gains suitable for spatial sound and sound volume are prepared as first and second gains in the gain adjustment table, respectively. The gain of the first amplifier is adjusted according to the first shape or the second shape. Therefore, since the second gain is lower than the first gain, the gain of the first amplifier is lowered when the second shape is obtained. Thereby, it is possible to realize appropriate spatial sound and sound volume (transmission sound quality) both in the open state (first shape) and in the closed state (second shape).

  Further, according to the slide type mobile phone terminal of the present invention, when the user makes a phone call from the first shape to the second shape, it is not necessary to carry the mobile phone terminal. Further, unlike a foldable mobile phone terminal, two microphones and two receivers are not required.

  Hereinafter, a sliding mobile phone terminal according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

[Constitution]
1A and 1B are perspective views showing a configuration of a sliding mobile phone terminal according to an embodiment of the present invention. A sliding mobile phone terminal according to an embodiment of the present invention includes a first casing 1 (hereinafter referred to as casing 1), a second casing 2 (hereinafter referred to as casing 2), and a connecting portion 3. Yes. A microphone sound hole 10 is provided at one end of the housing 1. A receiver sound hole 70 is provided at one end of the housing 2.

  The connecting unit 3 connects the casings 1 and 2 and has a first shape (hereinafter, shape A) in which the sliding mobile phone terminal is opened, or a second shape in which the sliding mobile phone terminal is closed. A shape (hereinafter referred to as shape B) is formed. As shown in FIG. 1A, the shape A represents a state in which the housing 1 and the housing 2 do not overlap when the user slides the housing 2 in a direction parallel to the housing 1. Yes. As illustrated in FIG. 1B, the shape B represents a state in which the housing 1 and the housing 2 overlap when the user slides the housing 2 in a direction parallel to the housing 1. . Here, depending on the structure of the connecting portion 3, the shape A represents a state in which the housing 1 and the housing 2 partially overlap, and the shape B represents a state in which the housing 1 and the housing 2 all overlap. There is also.

  Here, since the structures of the casings 1 and 2 and the connecting portion 3 and the shapes A and B are known, the details thereof are omitted.

  The sliding mobile phone terminal according to the embodiment of the present invention further includes a memory (not shown) for storing a computer program, a CPU (Central Processing Unit) (not shown) for executing the computer program, and an input device (not shown). And a display device (not shown). The CPU and the memory are provided in the housing 1 or the housing 2. The input device is provided in the housing 2, for example, and the display device is provided in the housing 1, for example.

  FIG. 2 is a block diagram showing a configuration of the sliding mobile phone terminal according to the embodiment of the present invention. The slide cellular phone terminal further includes a microphone 11, a Codec block 20, a DSP (Digital Signal Processor) block 30, a control unit 40, a DSP block 50, a Codec block 60, a power amplifier 71, and a receiver. 72. The control unit 40 and the DSP blocks 30 and 50 can be realized by hardware or software (computer program).

  The microphone 11 is provided in the microphone sound hole 10 at one end of the housing 1 (see FIGS. 1A and 1B).

  The Codec block 20 is provided in, for example, the housing 1 and includes an analog amplifier 21, an A / D converter 22, and a digital amplifier 23. An analog amplifier 21 is connected to the output of the microphone 11. An A / D converter 22 is connected to the output of the analog amplifier 21. A digital amplifier 23 is connected to the output of the A / D converter 22.

  The DSP block 30 is provided in, for example, the housing 1 and includes an equalizer 31, a digital amplifier 32, and a first echo suppression system 33 (hereinafter, echo suppression system 33). An equalizer 31 is connected to the output of the digital amplifier 23. A digital amplifier 32 is connected to the output of the equalizer 31. An echo suppression system 33 is connected to the output of the digital amplifier 32. A controller 40 is connected to the output of the echo suppression system 33.

  The control unit 40 is provided in the housing 1 or the housing 2.

  The DSP block 50 is provided in, for example, the housing 2, and includes a digital amplifier 51, an equalizer 52, and a second echo suppression system 53 (hereinafter, echo suppression system 53). The digital amplifier 51 is connected to the control unit 40. An equalizer 52 is connected to the output of the digital amplifier 51. An echo suppression system 53 is connected to the output of the equalizer 52.

  The Codec block 60 is provided in the housing 2, for example, and includes a digital amplifier 61, a D / A converter 62, and an analog amplifier 63. A digital amplifier 61 is connected to the output of the echo suppression system 53. A D / A converter 62 is connected to the output of the digital amplifier 61. An analog amplifier 63 is connected to the output of the D / A converter 62.

  The power amplifier 71 is provided in the housing 2, for example. The receiver 72 is a speaker and is provided in the receiver sound hole 70 at one end of the housing 2 (see FIGS. 1A and 1B). An analog amplifier 63 is connected to the output of the power amplifier 71. A receiver 72 is connected to the output of the analog amplifier 63.

[Call processing]
In a sliding mobile phone terminal according to an embodiment of the present invention, as with a normal mobile phone terminal, when a user makes a call to the other party or when a call is made from the other party, the user makes a call with the other party. (Hereinafter referred to as call processing). In this case, the control unit 40 controls the microphone 11, the Codec block 20, the DSP block 30, the DSP block 50, the Codec block 60, the power amplifier 71, and the receiver 72.

  Call processing will be described below.

  The microphone 11 collects the user's voice. The analog amplifier 21 amplifies the analog voice that is the user's voice and outputs it to the A / D converter 22. The A / D converter 22 converts the analog sound from the analog amplifier 21 into a sound signal as digital sound and outputs the sound signal to the digital amplifier 23. The digital amplifier 23 amplifies the audio signal from the A / D converter 22 and outputs it to the digital amplifier 32 via the equalizer 31. The digital amplifier 32 amplifies the audio signal from the equalizer 31 and outputs it to the control unit 40 via the echo suppression system 33.

  The control unit 40 converts the audio signal from the echo suppression system 33 into a baseband signal and transmits it to the other party's telephone via a base station by radio. In addition, the control unit 40 receives a baseband signal wirelessly from a destination telephone via a base station, converts it into an audio signal, and outputs it to the digital amplifier 51.

  The digital amplifier 51 amplifies the audio signal from the control unit 40 and outputs the amplified signal to the digital amplifier 61 via the equalizer 52 and the echo suppression system 53. The digital amplifier 61 amplifies the audio signal from the digital amplifier 51 and outputs it to the D / A converter 62. The D / A converter 62 converts digital audio, which is an audio signal from the digital amplifier 61, into analog audio and outputs the analog audio to the analog amplifier 63. The analog amplifier 63 outputs the other party's voice that is analog voice from the D / A converter 62 to the power amplifier 71. The power amplifier 71 amplifies the other party's voice and outputs it to the receiver 72. The receiver 72 outputs the other party's voice from the power amplifier 71 to the outside.

  The echo suppression systems 33 and 53 suppress signals representing echoes generated between the receiver 72 and the microphone 11 among the audio signals of the user and the other party, respectively. The echo suppression systems 33 and 53 are also called an echo suppression system and an echo cancellation system. Each of the echo suppression systems 33 and 53 adds a canceling signal representing a parameter for suppressing the echo to a signal representing the echo among the voice signals of the user and the other party.

The equalizers 31 and 52 suppress signals representing the acoustic transfer function F from the audio signals of the user and the other party, respectively. Each of the equalizers 31 and 52 multiplies a signal representing the acoustic transfer function F by a signal representing an inverse function F ⁻¹ for eliminating the signal representing the acoustic transfer function F among the audio signals of the user and the other party. To do.

  A problem with the above-described configuration and call processing will be described.

[Problem 1]
As shown in FIGS. 1A and 1B, the linear distance between the receiver sound hole 70 (receiver 72) and the microphone sound hole 10 (microphone 11) when the connecting portion 3 forms the shape B is determined by the connecting portion 3. It is shorter than the linear distance between the receiver sound hole 70 (receiver 72) and the microphone sound hole 10 (microphone 11) when the shape A is formed. For this reason, in the shape A, the distance between the receiver sound hole 70 (receiver 72) and the microphone sound hole 10 (microphone 11) is kept far, but in the shape B, the receiver sound hole 70 and the microphone sound hole 10 are close to each other. It will be. In the shape B, the received sound (the other party's voice) emitted from the receiver sound hole 70 easily goes around the microphone 11, and the spatial sound (echo) between the microphone 11 and the receiver 72 becomes large. Further, in the shape B, the time for the received sound from the receiver 72 to enter the microphone 11 is shorter than that in the shape A. Therefore, in the shape A and the shape B, it becomes a problem that the spatial sound changes.

[Problem 2]
3A and 3B show call processing when the shapes are A and B, respectively. As shown in FIGS. 3A and 3B, in the call processing, the linear distance between the receiver sound hole 70 (receiver 72) and the microphone sound hole 10 (microphone 11) when the shape is B is the receiver when the shape is A. It is shorter than the linear distance between the sound hole 70 (receiver 72) and the microphone sound hole 10 (microphone 11). For this reason, in the shape A, the distance between the speaker's mouth and the microphone 11 is long, whereas in the shape B, the distance between the speaker's mouth and the microphone 11 is short. That is, in the shape B, the sound volume representing the amount of sound transmitted from the speaker's mouth to the microphone 11 is larger than that in the shape A. In the shape B, the frequency characteristic of the sound transmitted from the speaker's mouth to the microphone 11 changes with respect to the shape A. Therefore, there is a difference between the shape A and the shape B in the transfer function (acoustic transfer function F) of the sound field propagation from the speaker's mouth to the microphone 11 and the transmission sound quality changes.

  A solution to the above problems 1 and 2 will be described.

[Solution 1]
In the shape B, the spatial sound between the microphone 11 and the receiver 72 is larger than that in the shape A. Therefore, in order to alleviate this, the gains of the analog amplifier 21 and the digital amplifiers 23 and 32 (hereinafter referred to as the first amplifiers 21, 23 and 32) are lowered. For this purpose, it is necessary to prepare gains suitable for spatial sound when the shapes are A and B, respectively. Thereby, the problem 1 can be solved.

[Solution 2]
In the shape B, the distance between the mouth and the microphone sound hole 10 is shorter than in the shape A, and the sound volume reaching the microphone sound hole 10 is increased. Therefore, in order to mitigate it, the gains of the first amplifiers 21, 23 and 32 are lowered. For this purpose, it is necessary to prepare gains suitable for the sound volume when the shapes are A and B, respectively. Thereby, the problem 2 can be solved.

[Solution 3]
Each of the echo suppression systems 33 and 53 adds the same canceling signal to the signal representing the echo among the voice signals of the user and the other party, even when the shape A or the shape B. However, as described in the problem 1, in the shape B, the time during which the received sound from the receiver 72 wraps around the microphone 11 is shorter than that in the shape A. Therefore, the spatial sound changes between the shape A and the shape B. Therefore, it is necessary to prepare parameters suitable for suppressing spatial sound (echo) for the shapes A and B as canceling signals. Thereby, the problem 1 can be further solved.

[Solution 4]
The equalizer 31 multiplies a signal representing the acoustic transfer function F in the user's voice signal by a signal representing the same inverse function F ⁻¹ even when the shape A or the shape B is used. However, as described in the problem 2, in the shape B, the frequency characteristic of the sound transmitted from the speaker's mouth to the microphone 11 changes with respect to the shape A. Therefore, in the shape A and the shape B, the speaker's mouth A difference occurs in the transfer function (acoustic transfer function F) of sound field propagation from to the microphone 11. Therefore, it is necessary to prepare an inverse function F ⁻¹ suitable for eliminating signals representing the acoustic transfer function F when the shapes are A and B, respectively. Thereby, the problem 2 can be further solved.

  FIG. 4 is a block diagram illustrating a configuration of the control unit 40 as a configuration for realizing the solutions 1 to 4. The control unit 40 includes a shape monitoring unit 41, a gain adjustment unit 42, an echo suppression unit 43, a function switching unit 44, a gain adjustment table 45, an echo suppression table 46, a function switching table 47, and a call processing unit 48.

  FIG. 5 shows the gain adjustment table 45. The gain adjustment table 45 stores information representing the shapes A and B and information representing the first and second gains. The first gain represents a value for controlling the first amplifiers 21, 23, and 32 when the shape is A (a value suitable for spatial sound and sound volume). The second gain represents a value for controlling the first amplifiers 21, 23, and 32 when the shape B is (a value suitable for spatial sound and sound volume), and is lower than the first gain.

  FIG. 6 shows the echo suppression table 46. The echo suppression table 46 stores information representing the shapes A and B and the first and second canceling signals. The first canceling signal represents a parameter for suppressing echo when the shape is A. The second canceling signal represents a parameter for suppressing echo when the shape is B. The first and second canceling signals are determined in advance.

FIG. 7 shows the function switching table 47. The function switching table 47 stores information representing the shapes A and B and a signal representing the first and second inverse functions F- ¹ . The signal representing the first inverse function F ⁻¹ is an inverse function for eliminating the signal representing the acoustic transfer function F when the shape is A. The signal representing the second inverse function F ⁻¹ is an inverse function for eliminating the signal representing the acoustic transfer function F when the shape is B. A signal representing the first and second inverse functions F ⁻¹ is determined in advance.

[Operation]
FIG. 8 is a flowchart showing the operation of the sliding mobile phone terminal according to the embodiment of the present invention.

  First, the call processing unit 48 executes the above-described call processing (step S1).

  Next, the shape monitoring unit 41 monitors the connecting unit 3 and outputs a monitoring result representing the shape A or the shape B to the gain adjusting unit 42, the echo suppressing unit 43, and the function switching unit 44 (step S2).

  Here, it is assumed that the monitoring result represents the shape A (step S3-NO). In this case, the gain adjusting unit 42, the echo suppressing unit 43, and the function switching unit 44 execute the process for the shape A (step S4).

  In step S4, the gain adjustment unit 42 refers to the gain adjustment table 45 and controls the first amplifiers 21, 23, and 32 to amplify the user's voice with the first gain.

  In step S <b> 4, the echo suppression unit 43 refers to the echo suppression table 46 and outputs the first canceling signal to the echo suppression systems 33 and 53. The echo suppression system 33 adds the first canceling signal to a signal representing an echo in the user's voice signal. The echo suppression system 53 adds the first canceling signal to the signal representing the echo among the audio signals of the other party.

In step S <b> 4, the function switching unit 44 refers to the function switching table 47 and outputs a signal representing the first inverse function F− ¹ to the equalizer 31. The equalizer 31 multiplies a signal representing the acoustic transfer function F in the user's voice signal by a signal representing the first inverse function F- ¹ .

  Here, it is assumed that the monitoring result represents the shape B (step S3-YES). In this case, the gain adjusting unit 42, the echo suppressing unit 43, and the function switching unit 44 execute the process for the shape B (step S5).

  In step S5, the gain adjustment unit 42 refers to the gain adjustment table 45 and controls the first amplifiers 21, 23, and 32 so as to amplify the user's voice with the second gain. As described above, the second gain is lower than the first gain. For this reason, when the monitoring result represents the shape B, the gain adjustment unit 42 reduces the gain of the first amplifiers 21, 23, and 32 than when the monitoring result represents the shape A.

  In step S <b> 5, the echo suppression unit 43 refers to the echo suppression table 46 and outputs the second canceling signal to the echo suppression systems 33 and 53. The echo suppression system 33 adds the second canceling signal to a signal representing an echo in the user's voice signal. The echo suppression system 53 adds the second canceling signal to the signal representing the echo among the audio signals of the other party.

Further, in step S5, the function switching section 44 refers to the function switching table 47, and outputs a signal representative of a second inverse function ^{F -1} to the equalizer 31. The equalizer 31 multiplies a signal representing the acoustic transfer function F in the user's voice signal by a signal representing the second inverse function F- ¹ .

  When the user changes the shape of the sliding mobile phone terminal while making a call (step S6-YES), the above-described step S2 is executed. Further, even if the user does not change the shape of the sliding mobile phone terminal (step S6-NO), but the call process is continued (step S7-YES), the above-described step S2 is executed. When the user ends the call, the call processing unit 48 ends the call process (step S7-NO).

[effect]
As described above, according to the slide type mobile phone terminal according to the embodiment of the present invention, the spatial sound between the microphone 11 and the receiver 72 is larger in the shape B than in the shape A. Further, in the shape B, compared to the shape A, the distance between the mouth and the microphone sound hole 10 is shortened, and the sound volume reaching the microphone sound hole 10 is increased. For this reason, gains suitable for the spatial sound and the sound volume for the shapes A and B are prepared as first and second gains in the gain adjustment table 45, respectively, and the first amplifier 21 according to the shape A or the shape B. , 23 and 32 are adjusted. Therefore, since the second gain is lower than the first gain, when the shape is B, the gains of the first amplifiers 21, 23, and 32 are reduced. Thereby, it is possible to realize appropriate spatial sound and sound volume (transmission sound quality) both in the open state (shape A) and in the closed state (shape B).

  Further, according to the slide type mobile phone terminal according to the embodiment of the present invention, in the shape B, the time for the received sound from the receiver 72 to wrap around the microphone 11 is shorter than that in the shape A. Sound changes. Therefore, parameters suitable for suppressing the spatial sound (echo) for the shapes A and B are prepared in the echo suppression table 46 as the first and second canceling signals, respectively. Thus, the spatial sound with respect to the voice signal of the user or the other party is suppressed. Thereby, a more appropriate spatial sound can be realized in an open state (shape A) or a closed state (shape B).

Further, according to the slide type mobile phone terminal according to the embodiment of the present invention, in the shape B, the frequency characteristics of the sound transmitted from the speaker's mouth to the microphone 11 change with respect to the shape A. Therefore, a difference occurs in the transfer function (acoustic transfer function F) of sound field propagation from the speaker's mouth to the microphone 11. Therefore, an inverse function F ⁻¹ suitable for eliminating a signal representing the acoustic transfer function F when the shape is A or B is prepared in the function switching table 47, and depending on the shape A or the shape B, A signal representing the acoustic transfer function F is excluded from the user's voice signal. As a result, a more appropriate sound volume (transmission sound quality) can be realized both in the open state (shape A) and in the closed state (shape B).

  Further, according to the slide type mobile phone terminal according to the embodiment of the present invention, when the user makes a phone call from the shape A to the shape B, it is not necessary to change the mobile phone terminal. Further, unlike a foldable mobile phone terminal, two microphones and two receivers are not required.

  Note that the sliding mobile phone terminal according to the embodiment of the present invention is not limited to the above-described configuration and operation.

  In the present invention, when the monitoring result represents the shape B, the gain adjustment unit 42 replaces the first amplifiers 21, 23, and 32 with the digital amplifiers 51 and 61, the analog amplifier 63 (hereinafter, the second amplifiers 51, 61, 63) may be reduced. In this case, the gain adjustment table 45 includes information indicating the shapes A and B, information indicating the first and second gains for controlling the second amplifiers 51, 61, and 63 when the shapes are A and B, Is stored. When the monitoring result represents the shape A, the gain adjustment unit 42 refers to the gain adjustment table 45 and controls the second amplifiers 51, 61, and 63 so as to amplify the partner's voice with the first gain. When the monitoring result indicates the shape B, the gain adjustment unit 42 refers to the gain adjustment table 45 and controls the second amplifiers 51, 61, and 63 so as to amplify the other party's voice with the second gain.

  In the present invention, as shown in FIG. 9, the order in which the equalizer 31 and the digital amplifier 32 are connected may be switched with the order in which the digital amplifier 51 and the equalizer 52 are connected.

FIG. 1A is a perspective view illustrating a configuration of a sliding mobile phone terminal according to an embodiment of the present invention. FIG. 1B is a perspective view showing a configuration of a sliding mobile phone terminal according to an embodiment of the present invention. FIG. 2 is a block diagram showing a configuration of the sliding mobile phone terminal according to the embodiment of the present invention. FIG. 3A shows a call process when the sliding mobile phone terminal according to the embodiment of the present invention has the shape A. FIG. 3B shows call processing when the sliding mobile phone terminal according to the embodiment of the present invention is in the shape B. FIG. 4 is a block diagram illustrating a configuration of the control unit 40 in FIG. 2 as a configuration for realizing the solutions 1 to 4. FIG. 5 shows the gain adjustment table 45. FIG. 6 shows the echo suppression table 46. FIG. 7 shows the function switching table 47. FIG. 8 is a flowchart showing the operation of the sliding mobile phone terminal according to the embodiment of the present invention. FIG. 9 is a block diagram showing another configuration of the sliding mobile phone terminal according to the embodiment of the present invention.

Explanation of symbols

1 housing,
2 housing,
3 connecting part,
10 Microphone sound hole,
11 Microphone,
20 Codec blocks,
21 Analog amplifier,
22 A / D converter,
23 Digital amplifier,
30 DSP (Digital Signal Processor) block,
31 equalizer,
32 Digital amplifier,
33 Echo suppression system (Echo suppression system, Echo cancellation system),
40 control unit,
41 shape monitoring unit,
42 Gain adjuster,
43 Echo suppression part,
44 function switching part,
45 Gain adjustment table,
46 Echo suppression table,
47 Function switching table,
48 Call processing unit,
50 DSP blocks,
51 Digital amplifier,
52 equalizer,
53 Echo suppression system,
60 Codec blocks,
61 Digital amplifier,
62 D / A converter,
63 Analog amplifier,
70 Receiver sound hole,
71 power amplifier,
72 receivers,

Claims (11)

First and second housings;
When the first housing and the second housing are connected, and the user slides the second housing in a direction parallel to the first housing, the first housing and the second housing are A connecting portion for forming a first shape that does not overlap, or a second shape in which the first housing and the second housing overlap;
A microphone to collect the user's voice;
A first amplifier for amplifying the user's voice;
In the first and second shapes, the user's voice from the first amplifier is converted into a voice signal and transmitted wirelessly, and a call process is performed to convert the voice signal from the other party into the other party's voice. A control unit,
A second amplifier for amplifying the voice of the other party from the control unit;
A receiver that outputs the voice of the other party from the second amplifier;
Comprising
The microphone and the receiver are each provided at one end of the first and second casings, and a linear distance between the receiver and the microphone when the second shape is the first shape is the receiver when the first shape is the first shape. Shorter than the linear distance between the microphone and the microphone,
The controller is
A shape monitoring unit that monitors the connecting unit and outputs a monitoring result representing the first or second shape;
When the monitoring result represents the second shape, a gain adjustment unit that reduces the gain of the first or second amplifier than when the monitoring result represents the first shape;
A sliding mobile phone terminal comprising: The controller is
A gain adjustment table storing information representing the first and second shapes, and information representing first and second gains for controlling the first or second amplifier when the first and second shapes are present;
Further comprising
The second gain is lower than the first gain,
The gain adjusting unit is
When the monitoring result represents the first shape, referring to the gain adjustment table, the first or second amplifier is controlled to amplify the voice of the user or the other party with the first gain,
When the monitoring result represents the second shape, the first or second amplifier is controlled so as to amplify the voice of the user or the other party with the second gain with reference to the gain adjustment table.
The sliding mobile phone terminal according to claim 1. Further comprising an echo suppression system for suppressing a signal representing an echo generated between the receiver and the microphone in the user's voice signal;
The controller is
An echo suppression table storing information representing the first and second shapes, and first and second canceling signals representing parameters for suppressing the echoes when the first and second shapes are respectively;
An echo suppressor;
Further comprising
When the monitoring result represents the first shape,
The echo suppression unit refers to the echo suppression table and outputs the first canceling signal to the echo suppression system;
The echo suppression system adds the first canceling signal to a signal representing the echo among the voice signals of the user,
When the monitoring result represents the second shape,
The echo suppression unit refers to the echo suppression table and outputs the second canceling signal to the echo suppression system;
The echo suppression system adds the second canceling signal to a signal representing the echo in the user's voice signal.
The sliding mobile phone terminal according to claim 2. A receiving-side echo suppression system that suppresses a signal representing the echo among the voice signals of the other party;
Further comprising
When the echo suppression system and the receiver echo suppression system are the first and second echo suppression systems,
When the monitoring result represents the first shape,
The echo suppression unit refers to the echo suppression table and outputs the first canceling signal to the first and second echo suppression systems;
The first and second echo suppression systems respectively add the first canceling signal to a signal representing the echo among the voice signal of the user and the voice signal of the counterpart.
When the monitoring result represents the second shape,
The echo suppression unit refers to the echo suppression table and outputs the second canceling signal to the first and second echo suppression systems;
The first and second echo suppression systems respectively add the second canceling signal to a signal representing the echo among the voice signal of the user and the voice signal of the counterpart.
The slide type mobile phone terminal according to claim 3. An equalizer for suppressing a signal representing an acoustic transfer function of the user's voice signal;
Further comprising
The controller is
A function switching table storing information representing the first and second shapes, and signals representing first and second inverse functions for eliminating the acoustic transfer function when the shapes are the first and second shapes, respectively. ,
A function switching unit;
Further comprising
When the monitoring result represents the first shape,
The function switching unit refers to the function switching table and outputs a signal representing the first inverse function to the equalizer,
The equalizer multiplies a signal representing the acoustic transfer function in the voice signal of the user by a signal representing the first inverse function,
When the monitoring result represents the second shape,
The function switching unit refers to the function switching table and outputs a signal representing the second inverse function to the equalizer;
The equalizer multiplies a signal representing the acoustic transfer function in the voice signal of the user by a signal representing the second inverse function.
The slide-type mobile phone terminal according to any one of claims 2 to 4. A connecting portion connects the first and second housings, and when the user slides the second housing in a direction parallel to the first housing, the first housing and the second housing. Forming a first shape that does not overlap with the body, or a second shape in which the first housing and the second housing overlap;
A microphone collects the user's voice;
A first amplifier amplifying the user's voice;
In the first and second shapes, the apparatus converts the user's voice from the first amplifier into a voice signal and transmits it wirelessly, and converts the voice signal from the other party into the other party's voice. Executing the process;
A second amplifier amplifying the voice of the other party from the device;
The receiver outputs the voice of the other party from the second amplifier, wherein the microphone and the receiver are provided at one end of the first and second casings, respectively, and have the second shape. When the linear distance between the receiver and the microphone is shorter than the linear distance between the receiver and the microphone when the first shape,
Monitoring the connecting portion and outputting a monitoring result representing the first or second shape;
The apparatus, when the monitoring result represents the second shape, reducing the gain of the first or second amplifier than when the monitoring result represents the first shape;
A communication method for a sliding mobile phone terminal comprising: When the monitoring result represents the first shape, the device includes information representing the first and second shapes, and a first for controlling the first or second amplifier when the first and second shapes are present. Controlling the first or second amplifier so as to amplify the voice of the user or the other party with the first gain with reference to a gain adjustment table in which information representing two gains is stored; Here, the second gain is lower than the first gain,
When the monitoring result represents the second shape, the device refers to the gain adjustment table, and causes the first or second amplifier to amplify the voice of the user or the other party with the second gain. A controlling step;
The communication method of the sliding mobile phone terminal according to claim 6, further comprising: When the monitoring result represents the first shape,
The apparatus stores an echo storing information representing the first and second shapes and first and second canceling signals representing parameters for suppressing the echo when the shapes are the first and second shapes, respectively. Referring to a suppression table, adding the first canceling signal to a signal representing an echo generated between the receiver and the microphone of the user's voice signal;
When the monitoring result represents the second shape,
The apparatus refers to the echo suppression table, and adds the second canceling signal to a signal representing the echo among the voice signals of the user;
The communication method of the sliding mobile phone terminal according to claim 7, further comprising: When the monitoring result represents the first shape,
The apparatus refers to the echo suppression table, and adds the first canceling signal to a signal representing the echo among the voice signal of the user and the voice signal of the counterpart,
When the monitoring result represents the second shape,
The apparatus refers to the echo suppression table, and adds the second canceling signal to a signal representing the echo among the voice signal of the user and the voice signal of the counterpart,
The communication method of the sliding mobile phone terminal according to claim 8, further comprising: When the monitoring result represents the first shape,
The apparatus stores information representing the first and second shapes and a signal representing first and second inverse functions for eliminating the acoustic transfer function when the shapes are the first and second shapes, respectively. Referring to a function switching table, multiplying a signal representing an acoustic transfer function among signals of the user by a signal representing the first inverse function;
When the monitoring result represents the second shape,
The apparatus refers to the function switching table, and multiplies a signal representing the acoustic transfer function by a signal representing the second inverse function among the voice signals of the user;
The communication method of the sliding mobile phone terminal according to any one of claims 7 to 9, further comprising:   The computer program which makes a computer perform each step which the said apparatus of the communication method of the sliding mobile telephone terminal in any one of Claims 6-10 performs.

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