JP2006067386A - Portable terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable terminal which can output a plurality of acoustic signals and is excellent in channel separation degree of the plurality of acoustic signals and confidentiality of the acoustic signals. <P>SOLUTION: The portable terminal 1 has a plurality of super-directivity speakers 2a, 2b as sound speakers. The super-directivity speakers 2a, 2b output the acoustic signals generated by a signal processing part 8. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a mobile terminal device.

In recent years, the use opportunity of the portable terminal device which can view an image | video and sound, such as a sound and music simultaneously, has increased. Accordingly, a portable terminal device that outputs sound from a sound speaker to a user in a hands-free form is provided. For example, a portable telephone device that has two or more acoustic speakers and outputs stereo sound has been proposed (see, for example, Patent Documents 1 to 3). In addition, an information device equipped with one super-directional speaker has been proposed (see, for example, Patent Document 4).
JP 2002-57768 A JP 2002-101171 A JP 2002-111817 A JP 2004-112213 A

  However, in a telephone device equipped with a plurality of acoustic speakers, when listening to a plurality of acoustic signals in a hands-free manner, the acoustic signals output from the acoustic speakers are radiated with a wide radiation angle. For this reason, there are problems that the channel separation degree of the acoustic signals of a plurality of channels is lowered and the confidentiality of the acoustic signals is lowered.

  Specifically, in the conventional telephone apparatus, the radiated sound signals of a plurality of channels interfere with each other, and the degree of separation of the plurality of channels decreases. Therefore, the reproduction accuracy of multiple channels was low. Moreover, since the conventional telephone apparatus does not have a function of reducing the radiation angle of the acoustic signal from the acoustic speaker, each acoustic signal radiated from the plurality of acoustic speakers propagates with a wide radiation angle. For this reason, the sound emitted from the telephone device can be heard by anyone other than the user of the telephone device, and the confidentiality cannot be maintained.

  In addition, an information device equipped with only one super-directional speaker cannot reproduce a plurality of channels, and the user cannot hear an acoustic signal of two or more channels.

  Therefore, an object of the present invention is to provide a mobile terminal device that can output a plurality of acoustic signals and that is excellent in channel separation and confidentiality of the plurality of acoustic signals.

  A portable terminal device according to the present invention includes a plurality of superdirective speakers that output an acoustic signal and a signal processing unit that generates an acoustic signal to be input to the superdirective speaker. A “superdirective speaker” is a speaker that exhibits strong directivity in one direction. Such a portable terminal device can output a plurality of acoustic signals, and is excellent in channel separation and confidentiality of the plurality of acoustic signals.

  The portable terminal device preferably includes a control unit that controls the radiation angle of the acoustic signal output from the at least one super-directional speaker. According to this, the portable terminal device can change the directivity direction of the acoustic signal output from the superdirective speaker, and can direct the acoustic signal to the listening point of the user. Therefore, the channel separation degree and the secrecy of the acoustic signal can be further improved.

  Furthermore, the portable terminal device preferably includes a measurement unit that measures the positional relationship between at least one super-directional speaker and the user. And it is preferable that a control part controls a radiation angle based on the measurement result by a measurement part. The positional relationship between the super-directional speaker and the user includes the positional relationship between the super-directional speaker itself and the user, and the positional relationship between the acoustic signal output from the super-directional speaker and the user. For example, the positional relationship between the super-directional speaker and the user includes the distance between the super-directional speaker and the user, the radiation angle of the acoustic signal output from the super-directional speaker to the user, and the like.

  According to this, the mobile terminal device can direct the acoustic signal output from the superdirective speaker to the listening point of the user according to the state of the user of the mobile terminal device. Therefore, the channel separation degree and confidentiality of the acoustic signal can be further improved. In particular, even when the state of the user changes, the mobile terminal device can always appropriately output an acoustic signal following the change.

  The mobile terminal device may also include an omnidirectional speaker, and may include a selection unit that selects a superdirectional speaker or an omnidirectional speaker as an acoustic speaker that outputs an acoustic signal.

  According to this, the portable terminal device can output the acoustic signal in a state desired by the user of the portable terminal device or the acoustic data provider who provides the portable terminal device with acoustic data. For example, by selecting a super-directional speaker, the mobile terminal device can provide acoustic information in a highly confidential state and can provide a sound field with high channel separation. On the other hand, the mobile terminal device can provide a highly diffusive sound field by selecting an omnidirectional speaker.

  As described above, according to the present invention, it is possible to provide a mobile terminal device that can output a plurality of acoustic signals and is excellent in channel separation and confidentiality of the plurality of acoustic signals.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view of the mobile terminal device 1. The mobile terminal device 1 includes a plurality of casings 1 a and 1 b, a display 4, operation keys 5, a transmitter 6, and a hinge mechanism 7. The mobile terminal device 1 includes a plurality of superdirectional speakers 2a and 2b and an omnidirectional speaker 3 as acoustic speakers. Thus, the portable terminal device 1 uses a plurality of sound speakers as sound output means.

  The housing 1 a and the housing 1 b are connected by a hinge mechanism 7. The hinge mechanism 7 is a connecting member that rotatably connects the plurality of housings 1a and 1b. Note that the connecting member is not limited to the hinge mechanism 7 as long as the connecting member can be rotatably connected. The casings 1a and 1b of the mobile terminal device 1 can be folded with the display 4 facing inward by rotation. Therefore, the portable terminal device 1 can be easily accommodated even if the volume is increased by providing a plurality of acoustic speakers.

  Superdirective speakers 2a and 2b output acoustic signals having superdirectivity. The plurality of superdirective speakers 2a and 2b are driven simultaneously. As superdirective speakers 2a and 2b, for example, parametric speakers can be used. The parametric speaker is an acoustic speaker that forms an audible sound field in the air by a parametric array effect due to the non-linear characteristics of air. Parametric loudspeakers use the property of sound waves that the higher the frequency, the smaller the directivity angle and the higher directivity can be obtained, and the directivity is obtained by outputting an acoustic signal using high-frequency sound waves as a carrier wave. A parametric speaker radiates an acoustic signal, which is amplitude-modulated by a high-frequency carrier wave, into the air. The user can demodulate and listen to an acoustic signal desired to be received from a sound wave radiated into the air due to the nonlinear phenomenon of air.

  The plurality of superdirective speakers 2 a and 2 b are provided at both ends of the mobile terminal device 1. That is, the plurality of super-directional speakers 2a and 2b are provided at both ends of the casing when the connected casings 1a and 1b are viewed as one casing. Specifically, superdirective speakers 2a and 2b are respectively provided at the ends of the casings 1a and 1b opposite to the hinge mechanism 7 respectively. Thus, it is preferable that the plurality of superdirective speakers 2a and 2b are provided apart from each other in the housings 1a and 1b. As a result, the distance between the superdirective speakers 2a and 2b increases, and the channel separation of the acoustic signals output from the plurality of superdirective speakers 2a and 2b can be improved.

  As described above, the mobile terminal device 1 has the casings 1a and 1b that can be rotated and the super-directional speakers 2a and 2b are provided in the respective casings 1a and 1b. By adjusting (the angle at which the mobile terminal device 1 is folded), the orientation of the superdirective speakers 2a and 2b can be adjusted, and the radiation angle of the acoustic signal output from the superdirective speakers 2a and 2b can be adjusted. For example, by directing the radiation angle of the acoustic signal to the listening point of the user, the mobile terminal device 1 can improve the listening accuracy and secrecy of the acoustic signal.

  The omnidirectional speaker 3 diffuses and outputs an acoustic signal. The omnidirectional speaker 3 can be used when the sound signal does not require directivity or when the sound signal is output at the user's ear. According to the omnidirectional speaker 3, since the radiation surface is wide and diffusibility is high, the position of the omnidirectional speaker 3 is slightly located from the ear when outputting an acoustic signal to the user's ear of the mobile terminal device 1. Even in the case of deviation, an acoustic signal can be output with a large volume to the user. The omnidirectional speaker 3 is provided in the housing 1a apart from the superdirectional speaker 2a.

  Superdirective speakers 2a and 2b and omnidirectional speaker 3 can output an acoustic signal as a stereo sound source or a binaural sound source. Superdirective speakers 2a and 2b and omnidirectional speaker 3 can select a sound source obtained by reproducing an acoustic signal. According to this, it is possible to provide the user with a reproduction sound having a high channel separation degree and high secrecy not only with a monaural sound source but also with a stereo sound source or a binaural sound source with higher stereogenicity.

  The transmitter 6 receives user's voice input. The operation key 5 receives an instruction input by the user. For example, the operation key 5 acquires an instruction from a user regarding a method of reproducing an acoustic signal and control of a radiation angle. Further, by connecting the language recognition means to the transmitter 6, the portable terminal device 1 can acquire the user's instruction by voice. The display 4 displays image data, character data, and the like.

  As shown in FIG. 2, the portable terminal device 1 includes a signal processing unit 8, a control unit 9a, a measurement unit 9b, and a selection unit 9c. The signal processing unit 8 generates acoustic signals to be input to the superdirective speakers 2 a and 2 b and the omnidirectional speaker 3. The signal processing unit 8 includes an acoustic signal generator 8a, an amplitude modulator 8b, a high frequency generator 8c, and an amplifier 8d.

  The acoustic signal generator 8 a generates an acoustic signal (hereinafter referred to as “pre-processing acoustic signal”) that is the basis of the acoustic signal input to the superdirective speakers 2 a and 2 b and the omnidirectional speaker 3. The acoustic signal generator 8a generates an acoustic signal including acoustic data. The acoustic signal generator 8a inputs the unprocessed acoustic signal for the superdirective speakers 2a and 2b to the amplitude modulator 8b and the unprocessed acoustic signal for the omnidirectional speaker 3 to the amplifier 8d.

  The high frequency generator 8c generates a high frequency signal having a frequency in the ultrasonic band. For example, the high frequency generator 8c sets the frequency of the ultrasonic band to 40 kHz and generates a high frequency signal. The high frequency generator 8c inputs the generated high frequency signal to the amplitude modulator 8b. The amplitude modulator 8b amplitude-modulates the unprocessed acoustic signal input from the acoustic signal generator 8a with the high-frequency signal input from the high-frequency generator 8c. The amplitude modulator 8b inputs the modulated acoustic signal (hereinafter referred to as “modulated acoustic signal”) to the amplifier 8d.

  The amplifier 8 d amplifies the input pre-processing acoustic signal and uses it as an acoustic signal input to the omnidirectional speaker 3. The amplifier 8d inputs an acoustic signal obtained by amplifying the unprocessed acoustic signal input from the acoustic signal generator 8a to the omnidirectional speaker 3. The amplifier 8d amplifies the inputted modulated acoustic signal to be an acoustic signal to be input to the superdirective speakers 2a and 2b. The amplifier 8d inputs the acoustic signal obtained by amplifying the modulated acoustic signal input from the amplitude modulator 8b to the superdirective speakers 2a and 2b. Superdirective speakers 2a and 2b and omnidirectional speaker 3 perform electroacoustic conversion on the input acoustic signal and output it.

  The controller 9a controls the radiation angle of the acoustic signal output from the superdirective speakers 2a and 2b. The controller 9a can control the radiation angle of the acoustic signal by changing the angle of the superdirective speakers 2a and 2b itself or by changing the directivity angle of the acoustic signal output by the superdirective speakers 2a and 2b. . The controller 9a directs an acoustic signal to the user's listening point. The radiation angle at which the acoustic signal should be directed varies depending on the user of the mobile terminal device 1 and the method of use. The controller 9a may control the radiation angle based on an instruction from the user input from the operation key 5.

  When changing the angles of superdirective speakers 2a and 2b themselves, control unit 9a controls superdirective speakers 2a and 2b. Superdirective speakers 2a and 2b are provided in casings 1a and 1b so that the angle can be changed. FIG. 3 shows how superdirective speakers 2a and 2b are attached to housings 1a and 1b so that the angles can be changed. FIG. 3 shows the mobile terminal device 1 as viewed from above. In FIG. 3, superdirective speakers 2a and 2b are provided such that the angles of the casings 1a and 1b with respect to the casing walls can be changed. When changing the directivity angle of the acoustic signal output from the superdirective speakers 2a and 2b, the control unit 9a controls the acoustic signal input from the signal processing unit 8 to the superdirective speakers 2a and 2b.

  By such a control unit 9a, the direction of the acoustic signal output from the superdirective speakers 2a and 2b can be directed to a desired direction. Therefore, the mobile terminal device 1 can direct the acoustic signal to an angle at which the user can easily listen, that is, the listening point of the user. Therefore, the mobile terminal device 1 can improve the listening accuracy of the acoustic signal and improve the secrecy.

  In particular, as shown in FIG. 3, the control unit 9a is configured to radiate the acoustic signals so that the acoustic signals output from the two superdirective speakers 2a and 2b are directed to the left and right ears of the user, respectively. Is preferably controlled. According to this, the sound pressure of the acoustic signal from the superdirective speaker 2a toward the right ear to which the acoustic signal from the superdirective speaker 2a is not directed can be reduced. Similarly, the sound pressure of the acoustic signal from the superdirective speaker 2b to the left ear to which the acoustic signal from the superdirective speaker 2b is not directed can be reduced.

  According to this, regardless of the position and orientation of the mobile terminal device 1 with respect to the user, an acoustic signal with high directivity can reach each of the user's left ear and right ear with high channel separation. Specifically, sound signals of a plurality of channels output from the plurality of superdirective speakers 2 a and 2 b are received by each ear of the user of the mobile terminal device 1. Therefore, the channel separation degree of the sound pressure in each of the user's left ear and right ear can be increased. Therefore, for example, when a two-channel acoustic signal is reproduced, such as a stereo sound source, the mobile terminal device 1 can avoid crosstalk between superdirective speakers, and can provide a high-quality stereo sound source. Become.

  The measuring unit 9b measures the positional relationship between the superdirective speakers 2a and 2b and the user. The measuring unit 9b measures, for example, the distance between the superdirective speakers 2a and 2b and the user, the radiation angle of the acoustic signal output from the directional speakers 2a and 2b to the user, and the like. That is, the measurement unit 9b measures the relative distance and angle of the user with respect to the superdirective speakers 2a and 2b. The measurement unit 9b inputs the measurement result to the control unit 9a. The measurement unit 9b may input all the measurement results to the control unit 9a, and controls the measurement results when the positional relationship between the user of the mobile terminal device 1 and the superdirective speakers 2a and 2b is changed. You may input into the part 9a.

  In this case, the control unit 9a can control the radiation angle based on the measurement result by the measurement unit 9b. For example, the control unit 9a directs the acoustic signal to the position of the user's ear based on the distance and the radiation angle. Specifically, the control unit 9a calculates the radiation angle of the acoustic signal based on the measurement result. The control unit 9a changes the radiation angle based on the calculated radiation angle.

  The selection unit 9c selects the superdirective speakers 2a and 2b or the omnidirectional speaker 3 as an acoustic speaker that outputs an acoustic signal. The selection unit 9c may select one acoustic speaker to be used for outputting the acoustic signal or a plurality of acoustic speakers. The selection unit 9c can select an acoustic speaker based on an instruction regarding a user's reproduction method input from the operation key 5 or an instruction regarding a reproduction method from an acoustic data provider given to the acoustic data.

  The selection unit 9c inputs the selection result to the acoustic signal generator 8a. The acoustic signal generator 8a inputs the pre-processing acoustic signal to the amplitude modulator 8b when one of the superdirective speakers 2a and 2b is selected, and performs processing when the omnidirectional speaker 3 is selected. The front acoustic signal is input to the amplifier 8d.

  According to this, the mobile terminal device 1 can output an acoustic signal in a state desired by the user of the mobile terminal device 1 or the acoustic data provider that provides the mobile terminal device 1 with acoustic data. For example, the mobile terminal device 1 can provide acoustic information in a highly confidential state by selecting the superdirective speakers 2a and 2b, and can provide a sound field with high channel separation. On the other hand, the mobile terminal device 1 can provide a highly diffusive sound field by selecting the omnidirectional speaker 3.

  The mobile terminal device 1 as described above can output a plurality of acoustic signals, and is excellent in channel separation and confidentiality of the plurality of acoustic signals. Since the mobile terminal device 1 includes a plurality of superdirective speakers 2a and 2b, the multichannel audio signals can be output from the superdirective speakers 2a and 2b as highly directivity acoustic signals. That is, the mobile terminal device 1 can output an acoustic signal having a small radiation angle and high directivity.

  For example, by directing the acoustic signals output from the superdirective speakers 2a and 2b to the listening point of the user, it is possible to propagate the highly directional acoustic signal toward the listening point while maintaining a large listening sound pressure. . Therefore, the portable terminal device 1 can reduce the listening sound pressure in the direction away from the direction of the listening point, and can reduce the listening space. Therefore, the mobile terminal device 1 can ensure high confidentiality.

  In particular, the mobile terminal device 1 includes a measurement unit 9b and a control unit 9a. Therefore, the mobile terminal device 1 can direct the acoustic signals output from the superdirective speakers 2a and 2b to the listening point of the user according to the state of the user. Therefore, the channel separation degree and confidentiality of the acoustic signal can be further improved.

  In particular, even when the user's state changes and the positional relationship between the superdirective speakers 2a and 2b and the user changes, the mobile terminal device 1 always follows the change and appropriately generates an acoustic signal. Can be output. Therefore, it is possible to always improve the reproduction accuracy of the acoustic signal that the user listens to.

(Example of change)
The present invention is not limited to the above embodiment, and various modifications can be made. For example, as illustrated in FIG. 4, the mobile terminal device 201 may be configured from one housing 1 a. In this case, an operation key 5, a mouthpiece 6, a plurality of super-directional speakers 2a and 2b, and an omnidirectional speaker 3 are provided in one housing 1a. Superdirective speakers 2a and 2b are provided at a distance on both sides of housing 1a with display 4 interposed therebetween. According to such a portable terminal device 201, by using only one housing 1a, an operation for folding the housing becomes unnecessary, and the simplicity of the usage method can be improved.

  Moreover, you may provide the some super-directional speaker 2a, 2b in the housing | casing 1a like the portable terminal device 301 shown in FIG. Also in this case, the superdirective speakers 2a and 2b are provided at a distance on both sides of the casing 1a with the display 4 interposed therebetween. The housing 1 a and the housing 1 b are connected by a hinge mechanism 7. The casings 1a and 1b of the portable terminal device 301 can be folded with the display 4 and superdirective speakers 2a and 2b outside by rotation.

  According to this, when the user holds the plurality of super-directional speakers 2a, 2b facing the user with the display 4 folded outward, the user holds the portable terminal device 301. It is possible to listen to acoustic signals using the plurality of superdirective speakers 2a and 2b in a folded state. At this time, the controller 9a adjusts the angle between the superdirective speakers 2a and 2b and the housing 1a, thereby improving the channel separation of the acoustic signals output from the superdirective speakers 2a and 2b. .

  Furthermore, like the portable terminal device 401 illustrated in FIG. 6, the casing 1 a and the casing 1 b may be coupled so as to be overlapped by rotation. In the portable terminal device 401, the housing 1a and the housing 1b are rotatably connected by a hinge mechanism 407. The hinge mechanism 407 is a connecting member that rotatably connects the housing 1a and the housing 1b. The connecting member is not limited to the hinge mechanism 407 as long as it can be connected rotatably.

  In the mobile terminal device 401, superdirective speakers 2a and 2b are provided in the casings 1a and 1b, respectively. Accordingly, in the mobile terminal device 401, the rotation angle between the housing 1a and the housing 1b (the angle at which the housing 1a and the housing 1b are deployed) is adjusted, so that the super terminals provided in the housings 1a and 1b are adjusted. The interval between the directional speakers 2a and 2b can be adjusted. Therefore, the mobile terminal device 401 can adjust the interval of the acoustic signals from the plurality of superdirective speakers at the listening point. For example, it is preferable to adjust the interval so that the acoustic signal is directed in accordance with the width of the right ear and the left ear, which are the two listening points of the user. Thereby, the listening accuracy and confidentiality of the acoustic signal are improved. The user can adjust the radiation angle of the acoustic signal output from the superdirective speakers 2a and 2b according to the user only by adjusting the rotation angle between the housing 1a and the housing 1b.

  Moreover, you may connect so that the housing | casing 1a and the housing | casing 1b can be piled up by a slide like the portable terminal device 501 shown in FIG. For example, the portable terminal device 501 can slidably connect the housing 1a and the housing 1b by providing the housing 1a with a groove for sliding the housing 1b. In the portable terminal device 501, the casings 1a and 1b only have to be slidably connected, and the mechanism for this is not limited.

  In the mobile terminal device 501, the casings 1a and 1b are also provided with super-directional speakers 2a and 2b, respectively. Thereby, in the portable terminal device 501, the space | interval of super-directional speaker 2a, 2b provided in each housing | casing 1a, 1b can be adjusted by adjusting the width | variety which slides the housing | casing 1a and the housing | casing 1b. Therefore, the mobile terminal device 501 can adjust the intervals of the acoustic signals from the plurality of superdirective speakers at the listening point. For example, it is preferable to adjust the interval in accordance with the width of the right ear and the left ear, which are two listening points of the user. Thereby, the listening accuracy and confidentiality of the acoustic signal are improved. The user can adjust the interval between the acoustic signals output from the superdirective speakers 2a and 2b only by adjusting the width of sliding the housing 1a and the housing 1b according to the user.

  Furthermore, like the portable terminal devices 401 and 501 shown in FIGS. 6 and 7, it is configured by a plurality of casings 1 a and 1 b, and the casings 1 a and 1 b are connected so as to be rotatable or slidable. Thus, the casings 1a and 1b can be overlapped by rotating or sliding. Therefore, it is possible to easily store the mobile terminal devices 401 and 501 that are mounted with a plurality of acoustic speakers and easily increase in volume.

  Further, the omnidirectional speaker 3 may be integrated with the display 4. By integrating with the display 4, the omnidirectional speaker 3 can output an acoustic signal from a wide radiation surface, and can output an acoustic signal having high diffusibility.

It is a perspective view which shows the portable terminal device which concerns on embodiment of this invention. It is a block diagram which shows the structure of the portable terminal device which concerns on embodiment of this invention. It is a figure which shows a mode that the super-directional speaker which concerns on embodiment of this invention can change an angle. It is a perspective view which shows the portable terminal device with which the housing | casing which concerns on the example of a change of this invention is one. It is a perspective view which shows the rotation type portable terminal device which concerns on the example of a change of this invention. It is a perspective view which shows the rotary portable terminal device which concerns on the example of a change of this invention. It is a perspective view which shows the slide-type portable terminal device which concerns on the example of a change of this invention.

Explanation of symbols

1, 201, 301, 401, 501 Portable terminal device 1a, 1b Case 2a, 2b Super-directional speaker 3 Non-directional speaker 4 Display 5 Operation key 6 Transmitter 7, 407 Hinge mechanism 8 Signal processing unit 8a Acoustic signal Generator 8b Amplitude modulator 8c High frequency generator 8d Amplifier 9a Control unit 9b Measurement unit 9c Selection unit

Claims (4)

A plurality of super-directional speakers that output acoustic signals;
A portable terminal device comprising: a signal processing unit that generates the acoustic signal to be input to the superdirective speaker.   The portable terminal device according to claim 1, further comprising a control unit that controls a radiation angle of the acoustic signal output from at least one superdirective speaker. A measurement unit for measuring a positional relationship between at least one superdirective speaker and a user;
The mobile terminal device according to claim 2, wherein the control unit controls the radiation angle based on a measurement result by the measurement unit. With omnidirectional speakers,
The mobile terminal device according to claim 1, further comprising: a selection unit that selects the superdirective speaker or the omnidirectional speaker as the acoustic speaker that outputs the acoustic signal.

Images