JP2011211330A - Sound collection device, and sound collection/emission device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To generate a sound collection signal in a sound collection mode desired by a user.SOLUTION: A sound collection signal control part 13 generates a plurality of sound collection signals Y1 (t), Y2 (t), Y3 (t) to be processed comprising different directivities for achieving an input directional pattern, from sound collection signals X1 (t), X2 (t), X3 (t) of microphones MC11, MC12, MC13 of a sound collection part 12. An output sound signal generation part 15 generates an output directional signal Z (t) of the input directional pattern, from the plurality of processing sound collection signals Y1 (t), Y2 (t), Y3 (t), and adjusts audio characteristics and frequency characteristics in accordance with additional information related to the input purpose of use, to the output directional signal Z (t) to generate an output sound signal ZZ (t).

Description

  The present invention relates to a sound collection device that includes a microphone and collects sound from the surroundings to generate a sound collection signal, and particularly relates to a small portable sound collection device and a sound emission and collection device including the sound collection device.

  Conventionally, various portable sound pickup devices have been devised. For example, a sound collection device (voice recorder) described in Patent Document 1 includes a plurality of microphones. The sound collection device (voice recorder) described in Patent Document 1 generates and records a stereo audio signal from the sound collection signals of these microphones. Each microphone is rotatably attached to the housing, and the sound collection range is changed by rotating each microphone.

JP 2008-31802 A

  However, in the above-described conventional sound collection device, when there is a direction in which sound collection is mainly desired, the microphone must be mechanically rotated so that the microphone faces the direction. In addition, the sound collection range can be changed only within a rotatable range, so that the sound collection directivity variable horn that can be realized as the sound collection device is limited. In addition, it is impossible to collect sound with a sound quality corresponding to the use environment or use purpose desired by the user.

  Accordingly, an object of the present invention is to realize a sound collection device that can generate a sound collection signal in a sound collection mode desired by a user, and a sound emission and collection device including the sound collection device.

  The present invention relates to a sound collection device. This sound collection device uses a plurality of microphones arranged so as to have different sound collection characteristics, and a processing directivity for generating a plurality of processing directivity signals using sound collection signals of the plurality of microphones. A signal generator, an output directional signal generator that generates an output directional signal using a plurality of processing directional signals based on the operation-specified designation directivity, and an operation-input additional characteristic And an additional characteristic adjusting unit that adjusts at least one of the acoustic characteristic and the frequency characteristic of the output directivity signal.

  In this configuration, a plurality of processing directivity signals are formed from the collected sound signals of a plurality of microphones, and an output directivity signal having the same directivity as the final output signal is formed from the plurality of processing directivity signals. Is done. The final output signal can be obtained by adjusting the acoustic characteristics and frequency characteristics of the output directional signal. Thereby, directivity, acoustic characteristics, and frequency characteristics can be realized in various modes.

  Further, in the sound collecting device of the present invention, the output directivity signal generation unit uses the processing directivity signal other than the main directivity signal which is one of the plurality of processing directivity signals. A coefficient is set, and an output directivity signal is generated using the directivity processing coefficient and the main directivity signal.

  This configuration shows a specific method for generating an output directional signal. With this configuration, an output directivity signal can be generated using only a plurality of processing sound pickup signals.

  In addition, the sound collection device of the present invention includes an operation input unit that inputs designated directivity and additional characteristics, and a display unit that displays the contents of the operation input.

  In this configuration, the contents operated by the user can be easily confirmed visually.

  In the sound collecting device of the present invention, the operation input unit detects an operation input operation and gives it to the display unit when the designated directivity is input. The display unit changes the directional drawing shape based on the operation input operation.

  In this configuration, when the directivity is changed by an operation, the directivity change state can be easily confirmed visually.

  The sound collecting apparatus of the present invention further includes a recording medium for recording the output directivity signal after adjusting the additional characteristics.

  With this configuration, it is possible to record an output sound signal (an output directivity signal after adjustment of additional characteristics) having a desired characteristic based on the collected sound signal.

  The present invention also relates to a sound emission and collection device. The sound emission and collection device includes the sound collection device described above and a sound emission unit that emits the output directivity signal after adjustment of the additional characteristics or the sound signal recorded on the recording medium.

  In this configuration, the user can listen to the output sound signal based on the collected sound signal or the recorded sound signal as necessary.

  According to the present invention, sound collection directivity, acoustic characteristics, and frequency characteristics can be realized in various modes using a microphone sound collection signal. Thereby, the output sound signal based on the sound collection signal having the characteristics desired by the user can be more reliably realized.

1 is an overall external view of a sound emission and collection device according to an embodiment of the present invention. It is a functional block diagram of the sound emission and collection apparatus which concerns on embodiment of this invention. FIG. 3 is a functional block diagram illustrating a specific configuration example of a first processing directivity signal forming unit 131 illustrated in FIG. 2. FIG. 3 is a functional block diagram illustrating a configuration of an output sound signal generation unit 15 illustrated in FIG. 2. It is a figure which shows the example of a setting screen of a sound collection characteristic. It is a figure which shows the example of a setting screen of a directivity pattern. It is a figure which shows the specific structural example of the directivity signal formation part 151 for output sound processing. It is a figure which shows the example of a setting screen of additional information.

  A sound emitting and collecting apparatus according to an embodiment of the present invention and a sound collecting apparatus included in the sound emitting and collecting apparatus will be described with reference to the drawings. FIG. 1 is an overall external view of a sound emission and collection device according to an embodiment of the present invention.

  The sound emission and collection device includes a portable audio player 900 and a sound collection device 10. The portable audio player 900 includes a flat housing 901, and operators that constitute a display unit 902 and an operation input unit 903 are attached to the surface of the housing 901. An input / output port 904 is formed at one end of the portable audio player 900.

  The sound collection device 10 includes a flat housing 11. The casing 11 may have substantially the same width as the casing 901 of the portable audio player 900. The casing 11 is provided with a plurality of microphones MC11, MC12, MC13. The microphones MC11, MC12, and MC13 are, for example, the same unidirectional microphones, and are fixedly disposed on the housing 11 so that the maximum sound collection sensitivity directions are different.

  The portable audio player 900 and the sound collection device 10 are mechanically fixedly installed by an input / output port 904 and are electrically connected. The output sound signal ZZ (t) from the sound pickup device 10 is transmitted to the portable audio player 900 via the input / output port 904, and various control information from the portable audio player 900 is transmitted to the sound collection device 10. The

  Next, the configuration of the signal processing system of the sound emission and collection device will be described. FIG. 2 is a functional block diagram of the sound emission and collection device according to the embodiment of the present invention.

  First, the configuration of the portable audio player 900 will be briefly described. The portable audio player 900 includes a display unit 902, an operation input unit 903, a control unit 901, a recording unit 911, an application recording unit 912, and a speaker SP900.

  The control unit 901 performs overall control of the portable audio player 900 and communication control with the sound collection device 10. The display unit 902 includes a flat display such as a liquid crystal display. The operation input unit 903 receives an operation input from the user and gives it to the control unit 901.

  The recording unit 911 stores sound data based on the output sound signal ZZ (t) from the sound collecting device 10, music data obtained from an external device or an external network (not shown), and the like. The application storage unit 912 stores an application that controls the sound collection device 10. The control unit 901 controls various sound collection processes by reading and executing the application.

  The speaker SP 900 emits sound based on the above-described sound data and music data, or emits sound based on the output sound signal ZZ (t) from the sound collection device 10.

  In such a configuration, the control unit 901 displays an image based on the sound collection application and the operation information on the display unit 902 when an operation input related to the sound collection process is received when the sound collection application is executed. Along with this processing, the control unit 901 gives operation information to the sound collection device 10.

  Next, the configuration of the sound collection device 10 will be described. The sound collection device 10 includes a sound collection unit 12, a sound collection signal control unit 13, an operation information analysis unit 14, and an output sound signal generation unit 15.

  First, the configuration of the operation information analysis unit 14 that gives various parameters to the collected sound signal control unit 13 and the output sound signal generation unit 15 will be described. The operation information analysis unit 14 includes an operation information acquisition unit 141, a directivity parameter setting unit 142, and an additional characteristic information setting unit 143.

  The operation information acquisition unit 141 extracts directivity information from the acquired operation information and provides it to the directivity parameter setting unit 142. In addition, the operation information acquisition unit 141 extracts acoustic characteristic information and frequency characteristic information other than directivity from the acquired operation information, and provides them to the additional characteristic information setting unit 143.

  The directivity parameter setting unit 142 gives a directivity parameter for generating an output sound signal to the output sound signal generating unit 15 based on the directivity information. In addition, the directivity parameter setting unit 142 gives the sound collection signal control unit 13 directivity parameters for each processing directivity signal necessary for realizing the directivity of the output sound signal.

  The additional characteristic information setting unit 143 gives additional characteristic information based on the acoustic characteristic information and the frequency characteristic information to the output sound signal generation unit 15.

  The sound collection unit 12 includes the plurality of microphones MC11, MC12, and MC13 described above. The microphone MC11 collects sound and outputs a sound collection signal X1 (t). The microphone MC12 collects sound and outputs a sound collection signal X2 (t). The microphone MC13 picks up sound and outputs a sound pickup signal X3 (t).

  The sound collection control unit 13 includes a first processing directivity signal forming unit 131, a second processing directivity signal forming unit 132, and a third processing directivity signal forming unit 133. The first processing directivity signal forming section 131, the second processing directivity signal forming section 132, and the third processing directivity signal forming section 133 are respectively connected to sound collection signals X1 (t) and X2 (t ), X3 (t). The first processing directivity signal forming unit 131, the second processing directivity signal forming unit 132, and the third processing directivity signal forming unit 133 have the same configuration, and each has a processing directivity signal Y1 ( t), Y2 (t), Y3 (t) are generated and output. Here, a more specific configuration of only the first processing directivity signal forming unit 131 will be described.

  FIG. 3 is a functional block diagram illustrating a specific configuration example of the first processing directivity signal forming unit 131 illustrated in FIG. 2. The first processing directivity signal forming unit 131 includes amplification factor control amplifiers 311, 312, 313, an adder 314, and a control unit 315.

  The control unit 315 receives a processing directivity parameter from a directivity parameter setting unit 142 of the operation information analysis unit 14 described later. For example, if a unidirectional sound signal is generated as the processing directional signal Y1 (t), the unidirectional sound signal is converted into the collected sound signals X1 (t), X2 (t), A parameter realized from X3 (t) is input. The control unit 315 gives each amplification factor based on the processing directivity parameter to each of the amplification factor control amplifiers 311, 312, and 313.

  The amplification factor control amplifier 311 amplifies the collected sound signal X1 (t) with the set amplification factor and outputs it to the adder 314. The amplification factor control amplifier 312 amplifies the collected sound signal X2 (t) with the set amplification factor and outputs the amplified signal to the adder 314. The amplification factor control amplifier 313 amplifies the collected sound signal X3 (t) with the set amplification factor and outputs it to the adder 314.

  The adder 314 adds the amplified sound collection signals X1 (t), X2 (t), and X3 (t) to thereby add a first processing directivity signal Y1 (with a predetermined sound collection directivity). t) is generated and output. The first processing directivity signal Y <b> 1 (t) is input to the output sound signal generation unit 15. The second and third processing directivity signals Y2 (t) and Y3 (t) are similarly generated and input to the output sound signal generator 15.

  The output sound signal generation unit 15 includes an output sound processing directivity signal forming unit 151 and an additional characteristic adjustment unit 152. The output sound processing directivity signal forming unit 151 outputs the output directivity signal from the processing directivity signals Y1 (t), Y2 (t), and Y3 (t) based on the directivity parameter for generating the output sound signal. Z (t) is generated. For example, the output sound processing directivity signal forming unit 151 appropriately adds and subtracts the processing directivity signals Y1 (t), Y2 (t), and Y3 (t) to generate the output directivity signal Z (t). . In addition, for example, the output sound processing directivity signal forming unit 151 sets a coefficient for adjusting the directivity of the main signal from another processing directivity signal using the specific processing directivity signal as the main signal. The output directivity signal Z (t) is generated by multiplying the main signal by the coefficient.

  The additional characteristic adjusting unit 152 generates the output sound signal ZZ (t) by adjusting the characteristic of the output directivity signal Z (t) using the additional characteristic information based on the acoustic characteristic information and the frequency characteristic information. . For example, the additional characteristic adjusting unit 152 generates an output sound signal ZZ (t) by performing an EQ (equalizer) process or a reverberant sound removal process on the output directivity signal Z (t). .

  By performing such processing, it is possible to realize sound collection including desired directivity, acoustic characteristics, and frequency characteristics instructed by the user.

  Next, specific examples will be described with reference to the drawings. When the user operates the operation element to execute the sound collection application, a sound collection characteristic setting screen as shown in FIG. 5 is displayed on the display unit 902. FIG. 5 is a diagram showing an example of a sound collection characteristic setting screen. As shown in the example of FIG. 5, the sound collection characteristic setting screen includes items of “directivity pattern setting”, “sound environment information setting”, and “use application information setting”.

  When the user selects the “directivity pattern setting” item, various basic directivity patterns as shown in FIG. 6 are displayed on the display unit 902. FIG. 6 is a diagram showing an example of a directivity pattern setting screen. 6A shows a unidirectional pattern, FIG. 6B shows a bidirectional pattern, FIG. 6C shows an omnidirectional pattern, and FIG. 6D shows a unidirectional narrow pattern. Shows the case. FIG. 6E shows an example in which the directivity pattern display screen changes in accordance with the operation of the operator.

  First, the directivity patterns shown in FIGS. 6A to 6D are displayed so as to be selectable. Directivity patterns may be collectively displayed on these, or may be sequentially displayed one by one by operating the operation element of the operation input unit 903. When a directivity pattern is selected in this state, the selected directivity pattern continues to be displayed as it is. Here, as shown in FIG. 6E, when the user performs a rotation operation using the operation element, the directivity pattern is also rotated and displayed in accordance with the rotation operation. As a result, the user can not only select the desired directivity from the basic directivity pattern but also set the details by rotating the directivity pattern. Note that the directivity pattern can be set to a wider directivity or a narrow directivity. In this case, for example, if the display unit of the touch panel is used, directivity patterns can be directly operated on the display screen, and the user can set various directivity patterns more intuitively.

  When the directivity pattern is set in this way, the set directivity information is given to the operation information analysis unit 14 of the sound collection device 10 as described above as part of the operation information. This directivity information is given to the sound collection control unit 13 and the output sound processing directivity signal forming unit 151 of the output sound signal generating unit 15.

  For example, when the directivity pattern of the post-rotation directivity shown in FIG. 6E, that is, the sound collection directivity pattern having a narrow directivity of + 45 ° with respect to the reference orientation is selected, the processing directivity signal Y1 ( t), Y2 (t) are converted to hypercardioid signals and cardioid signals whose maximum sound pickup sensitivity direction is set to + 45 °, and a directivity parameter for converting the processing directivity signal Y3 (t) to an omnidirectional signal is This is given to the sound control unit 13. Further, the processing directivity signal Y1 (t) composed of a hyper cardioid signal is used as a main signal, the processing directivity signal Y2 (t) composed of a cardioid signal and the processing directivity signal Y3 (t) composed of an omnidirectional signal. Is provided to the output sound processing directivity signal forming unit 151.

  The output sound processing directivity signal forming unit 151 has a configuration shown in FIG. 7, for example. FIG. 7 is a diagram illustrating a specific configuration example of the output sound processing directivity signal forming unit 151. The output sound processing directivity signal forming unit 151 includes an amplification unit 512 and an amplification factor determination unit 511. The amplification factor determination unit 511 calculates the amplitudes of the processing directivity signal Y2 (t) composed of cardioid signals and the processing directivity signal Y3 (t) composed of omnidirectional signals. The amplification factor determination unit 511 calculates a basic coefficient by dividing the amplitude of the processing directional signal Y2 (t) made of a cardioid signal by the amplitude of the processing directional signal Y3 (t) made of a non-directional signal. The amplification factor coefficient G (t) is set by calculating the power of the basic coefficient. The amplifying unit 510 multiplies the amplification factor G (t) by the processing directivity signal Y1 (t) of the main signal composed of the hyper cardioid signal, so that the output directivity signal narrower than the hyper cardioid is output. Z (t) can be generated.

  Next, when the user selects an item “sound environment information setting” or “use application information setting”, various more detailed setting items as shown in FIG. 8 are displayed on the display unit 902. It is a figure which shows the example of a setting screen of additional information, FIG. 8 (A) is an example of a screen for setting the detailed item of “sound environment information setting”, and FIG. 8 (B) is “use application information setting”. It is an example of a screen for setting a detailed item.

  In the detailed setting screen of the “sound environment information setting” item, as shown in the example of FIG. 8A, items of “background noise removal”, “acquired sound reverberation component addition”, and “reproduction reverberation component addition” is there. When items related to these acoustic characteristics are selected, the selection information is provided to the operation information analysis unit 14 of the sound collection device 10 as described above as part of the operation information. The selection information is provided as additional characteristic information to the additional characteristic adjusting unit 152 of the output sound signal generating unit 15.

  If the “background noise removal” is set based on the additional characteristic information, the additional characteristic adjustment unit 152 executes the background noise removal process on the output directivity signal Z (t) by a known method. If “added sound collection reverberation component” is set based on the additional characteristic information, the additional characteristic adjusting unit 152 performs the process of adding the reverberant sound collected by the microphone to the output directivity signal Z (t). And execute. If “reproduction reverberation component addition” is set based on the additional characteristic information, the additional characteristic adjusting unit 152 performs the reverberant addition process according to the environment selected by the user in advance, and outputs the directivity signal Z (t ).

  As shown in the example of FIG. 8B, the detailed setting screen of the “use usage information setting” item includes “conference recording”, “recording for performance playback”, and “recording for performance playback (for practice)”. There are items. When items related to these frequency characteristics are selected, these pieces of selection information are provided as part of the operation information to the operation information analysis unit 14 of the sound collection device 10 as described above. The selection information is provided as additional characteristic information to the additional characteristic adjusting unit 152 of the output sound signal generating unit 15.

  If the “conference recording” is set based on the additional characteristic information, the additional characteristic adjusting unit 152 adjusts the frequency characteristic of the output directivity signal Z (t) so as to emphasize the voice band of the person. Execute. The additional characteristic adjusting unit 152 adjusts the frequency characteristic of the output directivity signal Z (t) so as to leave, for example, a high frequency component when “recording for performance reproduction” is set based on the additional characteristic information. Execute the process. If the “recording for performance playback (for practice)” is set based on the additional characteristic information, the additional characteristic adjusting unit 152 outputs the directivity signal Z (for output) so that only the sound of a specific instrument is emphasized. The process of adjusting the frequency characteristic of t) is executed.

  As described above, by using the configuration of this embodiment, it is possible to more reliably generate a sound signal collected with characteristics desired by the user. At this time, the user can generate a sound signal having a desired characteristic simply by operating the operator.

  Note that the adjustment of the above-described acoustic characteristics and frequency characteristics is an example, and other characteristic adjustments may be performed.

  In the above description, an example in which three microphones are used has been described. However, it is sufficient that at least two microphones are provided.

  In addition, an example is shown in which three processing sound pickup signals are formed, and an output directivity signal having an operation input is formed from the three processing sound pickup signals. However, the processed sound collection signal for generating the output directivity signal is not limited to this, and may be any number that can realize the directivity input by the operation. For example, if the output directional signal is to be omnidirectional, only the omnidirectional processing sound collection signal need be generated.

10-sound collecting device, 11-housing, 12-sound collecting unit, 13-sound collecting signal control unit, 131-first processing directivity signal forming unit, 132-second processing directivity signal forming unit, 133 -Third processing directivity signal forming unit, 311, 312, 313-gain control amplifier, 314-adder, 315-control unit, 14-operation information analysis unit, 141-operation information acquisition unit, 142-directivity Parameter setting unit, 143-additional characteristic information setting unit, 15-output sound signal generation unit, 151-directivity signal forming unit for output sound processing, 152-additional characteristic adjustment unit,
900-portable audio player, 901-housing, 902-display unit, 903-operation input unit, 904-input / output port, 910-control unit, 911-recording unit, 912-application storage unit,
MC11, MC12, MC13-Microphone, SP900-Speaker

Claims (6)

A plurality of microphones arranged so as to have different sound collection characteristics,
A processing directional signal generation unit that generates a plurality of processing directional signals using sound pickup signals of a plurality of microphones;
An output directivity signal generating unit that generates an output directivity signal using a plurality of processing directivity signals based on the operation input designated directivity;
An additional characteristic adjusting unit that adjusts at least one of the acoustic characteristic and the frequency characteristic of the output directivity signal based on the input additional characteristic;
A sound collecting device. The sound collection device according to claim 1,
The output directivity signal generation unit sets a directivity processing coefficient using a processing directivity signal other than the main directivity signal which is one of the plurality of processing directivity signals, and the directivity A sound collecting device that generates the output directivity signal using a processing coefficient and the main directivity signal. The sound collecting device according to claim 1 or 2,
An operation input unit for inputting the designated directivity and the additional characteristic;
A sound collection device comprising: a display unit that displays contents of operation inputs. The sound collection device according to claim 3,
The operation input unit detects an operation input operation when the designated directivity is operated and input to the display unit,
The sound collection device, wherein the display unit changes a directional drawing shape based on the operation input operation. A sound collecting device according to any one of claims 1 to 4,
A sound collection device comprising a recording medium for recording the output directivity signal after adjusting the additional characteristic. A sound collecting device according to claim 5 is provided.
A sound emission and collection device comprising a sound emission unit that emits the output directivity signal after adjustment of the additional characteristic or a sound signal recorded on a recording medium.