WO2006009004A1 - 音響再生システム - Google Patents
音響再生システム Download PDFInfo
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- WO2006009004A1 WO2006009004A1 PCT/JP2005/012785 JP2005012785W WO2006009004A1 WO 2006009004 A1 WO2006009004 A1 WO 2006009004A1 JP 2005012785 W JP2005012785 W JP 2005012785W WO 2006009004 A1 WO2006009004 A1 WO 2006009004A1
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- sound
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- sound field
- speaker
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04S—STEREOPHONIC SYSTEMS
- H04S7/00—Indicating arrangements; Control arrangements, e.g. balance control
- H04S7/30—Control circuits for electronic adaptation of the sound field
- H04S7/305—Electronic adaptation of stereophonic audio signals to reverberation of the listening space
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04S—STEREOPHONIC SYSTEMS
- H04S7/00—Indicating arrangements; Control arrangements, e.g. balance control
- H04S7/30—Control circuits for electronic adaptation of the sound field
- H04S7/301—Automatic calibration of stereophonic sound system, e.g. with test microphone
Definitions
- the present invention relates to the technical field of sound reproduction systems.
- Patent Document 1 Japanese Patent Laid-Open No. 2001-224100
- the sound reproduction system described in Patent Document 1 includes an equalizer that adjusts the frequency characteristics of an audio signal, an inter-transmission line level adjusting unit that adjusts the level of the audio signal, and an audio signal delay time. And an input audio signal is supplied to the sound emitting means through the equalizer, the transmission line level adjusting means and the delay means.
- noise generating means for individually supplying noise to each signal transmission path during sound field correction, detection means for detecting reproduced sound of noise reproduced by each sound emitting means, and detection Frequency characteristic correction means for correcting the frequency characteristics of each equalizer based on the detection results of the means, and inter-transmission line level correction for correcting the adjustment amounts of the plurality of inter-transmission line level adjustment means based on the detection results of the detection means
- a phase characteristic correcting unit that obtains a phase characteristic of the reproduced sound reproduced by the sound emitting unit based on a detection result of the detecting unit and corrects a delay time of each delay unit based on the obtained phase characteristic. It is characterized by comprising.
- the user can correct the sound field space by inputting a large number of individual reproduction characteristics such as phase characteristics, frequency characteristics, and reverberation characteristics. There is a need to do. Therefore, the sound field space imaged by the user Creating is a very complicated and difficult task.
- an object of the present application to provide an acoustic reproduction system that easily reproduces an arbitrary sound field space such as a sound field space that a user desires to audition.
- the sound reproduction system is installed in the listening room 10, and includes a test signal unit 324 for measuring spatial characteristics such as frequency characteristics and reverberation characteristics of sound amplified in the listening room 10, and DZA modification ⁇ 322 , A power amplifier 323, a speaker system 130, a microphone amplifier 325, an AZD converter 326, a spatial characteristic analysis unit 327, etc., a sound field data measuring means, a liquid crystal display device and a plasma for displaying a sound field space such as various hall images A display control unit 130 for controlling the display unit 333 such as a display, an operation unit 328 such as a mouse for selecting various hole images displayed on the liquid crystal display device or the plasma display display unit 333, and various types By using a storage unit 330 that stores the relationship between the display screen of halls, etc.
- System control unit 329 as a generation means for generating new listening room frequency characteristic correction coefficient LFC, sound pressure level correction coefficient LLC, delay characteristic correction coefficient LDC and reverberation characteristic correction coefficient LZC, and system control unit 329 Based on the frequency characteristics correction coefficient LFC, sound pressure level correction coefficient LLC, delay characteristic correction coefficient LDC, and reverberation characteristic correction coefficient LZC of the new listening room generated in Playback means such as an input processing unit 121 and a signal processing unit 200 for playing back sound, and playback by the playback unit An output means such DZA converter 322 and power amplifier 323 to output the information, and the configuration with.
- the user does not need to perform complicated work when inputting various characteristic data of the sound field data of the music hall as numerical values.
- sound effects similar to those played in a specific music hall or performance hall can be obtained in the sound field space used by the user. That is, in a space such as a room at home, a music hall It is possible to easily set up a space such as a music hall, and to obtain a sense of presence similar to that of a music hall or the like.
- the sound reproduction system of the present invention is a display means such as a liquid crystal display device or a plasma display.
- a diagram of the speaker, a diagram representing the size of the speaker, a diagram representing the positional relationship between the speaker and the user, etc. are displayed. After information related to the target data is displayed on the display device, the target data is selected by the user selecting desired information displayed on the display device. It is also possible to listen to the sound source with headphones in the sound field. As a result, the target sound field can be confirmed by ear.
- the sound reproduction system of the present invention at least a part of the speaker image selected by the mouse is moved along with the movement of the mouse, the speaker image is enlarged, or the positional relationship between the speaker power and the user is increased. Can be changed and edited.
- the speaker image edited in this way can be used as the target data described above, and the frequency characteristics of the listening room that are preliminarily set to determine the sound that is output from the speaker based on the edited spin force.
- the correction coefficient LFC, sound pressure level correction coefficient LLC, delay characteristic correction coefficient LDC or reverberation characteristic correction coefficient LZC is calculated by the calculation unit 331, and the new listening room frequency characteristic correction coefficient LFC sound pressure level correction coefficient LLC, delay characteristic correction Calculated as coefficient LDC or reverberation characteristic correction coefficient LZC.
- the signal processing control unit 260 controls the frequency characteristic adjustment circuit 230 based on the calculated frequency characteristic correction coefficient LFC of the listening room, and changes the frequency characteristic of the sound that is output from the speaker system 130. Also, the signal processing control unit 260 controls the signal level Z delay adjustment unit 240 based on the calculated sound pressure level correction coefficient LLC and delay characteristic correction coefficient LDC, and the signal level or delay of the sound amplified from the speaker system 130 Change the time.
- the signal processing control unit 260 controls the reverberation control circuit 250 and changes the reverberation characteristic of the sound that is amplified from the speaker system 130.
- the sound pressure level between speakers when adjusting the sound pressure level between speakers, a plurality of speakers are displayed on the display screen, and the size of the speakers is changed by an instruction from a mouse or a keyboard.
- the sound pressure level can be changed according to the size of the speaker. For example, when changing the distance from the speaker to the user, a diagram related to the positional relationship between the speaker and the user is displayed on the screen, and the distance between the two is changed by an instruction from the mouse or keyboard. Depending on the distance, the time of sound reaching the user from the speaker can be changed.
- the frequency, the intensity of the frequency, the time of the reverberant sound, the intensity of the reverberant sound, and the output sound from the output means reach the storage unit 330 to the user.
- Information related to at least one of the delay times is recorded.
- the signal processing unit 200 includes at least one of a frequency characteristic adjustment circuit 230, a signal level Z delay adjustment unit 240, and a reverberation control circuit 250 that can adjust the frequency characteristics for each of the frequency bands that are categorized in detail. One is provided.
- the reverberation time for each frequency band can be controlled, the sound generated in the sound field is repeatedly reflected on the surrounding walls and ceiling to form a complex sound field.
- the reverberation characteristic can be controlled. In other words, the reverberation characteristic of one sound field can be easily reproduced in a space such as a home room which is another sound field.
- the sound reproduction system of the present invention is configured such that when information related to a sound field space such as a hall and a speaker is displayed on a liquid crystal display device or a plasma display, the user uses the mouse to select the hall, When information related to the sound field space such as a speaker is selected, the binaural sound source corresponding to each image can be played from the headphone and confirmed by the ear.
- a sound field space such as a hall and a speaker
- the sound reproduction system of the present invention includes sound field data such as reverberation characteristics, frequency characteristics, delay time characteristics, and sound pressure level characteristics associated with image information such as a hall that the user desires to view and tests.
- Sound field data such as reverberation characteristics, frequency characteristics, delay measured by sound field data measurement means equipped with signal section 324, DZA converter 322, power amplifier 323, speaker system 130, microphone amplifier 325, AZD conversion 326, spatial characteristics analysis section 327, etc.
- Comparison operation means such as the operation unit 331 that compares and calculates sound field data such as time characteristics and sound pressure level characteristics, and holes that are stored in the storage means such as the storage unit 330 based on the result of the comparison operation
- an extraction unit such as a system control unit 329 for extracting the image information.
- the sound field space such as the target hall, the positional relationship of the speakers, and the size of the speaker that represents the sound pressure level that is amplified from the speakers are displayed.
- Sound field space corresponding to sound field data in the middle based on the sound field data measured by the sound field data measuring means that just displays the sound field, the positional relationship of the speaker force, and the loudspeaker from the speaker
- An image such as the size of the speaker showing the sound pressure level can be displayed. Therefore, the waiting time during correction to be close to the target data can be enjoyed by visually observing an image representing a halfway time displayed on a display device such as a liquid crystal display device or a plasma display.
- FIG. 1 is a block diagram showing a configuration of a surround system according to an embodiment.
- FIG. 2 is an example of an installation diagram of each speaker in the surround system.
- FIG. 3 is a block diagram showing a configuration of a signal processing unit in the embodiment.
- FIG. 4 is a block diagram showing a configuration of a spatial characteristic analysis unit in the embodiment.
- FIG. 5 is a diagram showing a state in which frequency characteristic data, reverberation characteristic data, etc. corresponding to image information such as holes are stored.
- FIG. 6 is a diagram schematically showing image information displayed on display unit 333.
- FIG. 7 is a flowchart showing the operation of the first embodiment.
- FIG. 8 is a flowchart showing the operation of the second embodiment.
- FIG. 9 is a diagram of a speaker displayed on the display unit 333 in the second embodiment.
- FIG. 10 is a diagram showing a positional relationship between a speaker displayed on a display unit 333 and a listening position in the second embodiment.
- FIG. 11 is a flowchart showing the operation of the third embodiment.
- FIG. 12 is a diagram schematically showing part of image information displayed on the display unit 333 in the third embodiment.
- FIG. 13 is a flowchart showing the operation of the second modification.
- FIG. 14 is a diagram showing a positional relationship between a speaker displayed on a display unit 333 and a listening position in Modification 2.
- the following embodiment is an embodiment in which the sound reproduction system of the present application is applied to a 5.
- lch (channel) sound reproduction system hereinafter simply referred to as a surround system.
- FIG. 1 is a block diagram showing a schematic configuration example of the information recording apparatus according to each embodiment.
- FIG. 2 is an example for explaining the installation of each force in the surround system of each embodiment.
- the surround system 100 of each embodiment is installed in a listening room 10, that is, a sound field space for providing a sound to be reproduced to a listener.
- the sound source is reproduced or acquired, and predetermined signal processing is performed on the reproduced sound or the acquired sound.
- the speaker system 130 including a plurality of speakers amplifies the signal-processed sound to each speaker to create a sound field space with a sense of presence (surround feeling) for the listener. It has come to offer.
- the surround system 100 has a certain format having channel components corresponding to each speaker by reproducing a sound source such as a recording medium or by obtaining a sound source from the outside such as a television signal.
- the sound source output device 110 that outputs the bit stream data of the sound source, the bit stream output from the sound source output device 110 to the audio signal for each channel, and the signal processing for each audio signal of each channel, as well as the listening room
- a signal processing device 320 that analyzes 10 reproduction characteristics, a speaker system 130 that also has various speaker powers corresponding to each channel, a microphone 140 that is used to analyze the reproduction characteristics of the listening room 10, and a sound field space
- a display unit 333 for performing various displays for identifying the device.
- a channel is a signal transmission path of an audio signal (DC, DFL, DFR, DSL, DSR, DSW) in which reproduction characteristics such as acoustic characteristics and reverberation characteristics output from the signal processing unit 200 are changed.
- the sound source output device 110 is composed of, for example, a media playback device such as a CD (Compact disc) or a DVD (Digital Versatile Disc) or a receiving device that receives digital television broadcasts, and plays back a sound source such as a CD. Or by obtaining the broadcast sound source, 5. the bit stream data having each channel component corresponding to lch is output to the signal processing device 320.
- a media playback device such as a CD (Compact disc) or a DVD (Digital Versatile Disc) or a receiving device that receives digital television broadcasts, and plays back a sound source such as a CD. Or by obtaining the broadcast sound source, 5.
- the bit stream data having each channel component corresponding to lch is output to the signal processing device 320.
- Bit stream data having each channel component output from the sound source output device 110 is input to the signal processing device 320.
- the signal processing device 320 receives the input bit stream data.
- the signal processing device 320 performs signal processing such as frequency component adjustment, delay time addition, reverberation component addition, and addition to audio signals of other channels on each decoded audio signal. Each audio signal subjected to the signal processing is converted into an analog signal to adjust the signal level. Then, the signal processing device 320 outputs each audio signal whose signal level is adjusted to each speaker of the speaker system 130. [0031]
- the configuration and operation of the signal processing device 320 in each embodiment will be described later in detail. Further, for example, the signal processing device 320 of each embodiment constitutes the sound reproduction system of the present invention.
- the speaker system 130 includes a center speaker 131 installed in front of the listening position (RV) and a front installed in front of the listening position and on the left side or right side of the center speaker 131.
- Left speaker hereinafter referred to as FL speaker
- FR speaker front right speaker
- SL speaker surround left speaker
- 132SL and surround right speaker hereinafter referred to as peak power
- the microphone 140 is connected to the signal processing device 320, and is arranged at a listening position, which is a position where the listener listens.
- the microphone 140 is used when analyzing the spatial characteristics of the listening room 10 described later. It has become.
- the microphone 140 of each embodiment collects a loud sound based on the test signal output from the force system 130, and converts the collected loud sound into an electric signal for collection. It is output to the signal processor 320 as a sound signal.
- the signal processing device 320 of each embodiment is used when bit stream data of a predetermined format having each channel component is input and decoded into an audio signal for each channel.
- An input processing unit 121 that converts the audio data into a signal format
- a signal processing unit 200 that decodes the converted audio data into an audio signal for each channel and performs signal processing for each channel
- an audio signal for each channel DZA converter 322 that performs digital Z-analog (hereinafter referred to as DZA) conversion of the Dio signal
- power amplifier 323 that amplifies the signal level of each channel signal for each channel, and for operating each part Operation unit 328, system control unit 329 that controls each unit based on the operation of operation unit 328, and display control unit that controls the display state of display unit 333 3 32
- a storage unit 330 that stores information such as image information and reproduction characteristics displayed on the display unit 333
- a calculation unit 331 that calculates information such as reproduction characteristics.
- the signal processing device 320 is collected by a microphone 140 and a test signal generator 324 that generates a test signal used when analyzing reproduction characteristics such as frequency characteristics and reverberation characteristics of the listening room 10.
- a microphone amplifier 325 that amplifies the signal to a preset signal level
- an AZD conversion 326 that performs analog Z digital (hereinafter referred to as AZD) conversion that converts the amplified sound collection signal into a digital signal
- AZD analog Z digital
- the input processing unit 121 receives bit stream data in a predetermined format having each channel component, and the input processing unit 121 converts the input bit stream data into a predetermined format.
- the converted audio data is output to the signal processing unit 200.
- the signal processing unit 200 is configured to receive the audio data output from the input processing unit 121 and the test signal generated in the test signal generating unit 324.
- the signal processing unit 200 In addition to decoding the input audio data into audio signals for each channel, it performs predetermined signal processing for each channel and outputs the audio signal to each DZA converter 322 for each channel. Yes.
- the signal processing unit 200 is operated based on the listening room characteristics analyzed by the spatial characteristic analysis unit 327 and the reproduction characteristics based on the image information selected by the display unit 333 under the control of the system control unit 329. A new reproduction characteristic calculated by the unit 331 is set for each channel, and an audio signal is output to each DZA converter 322 for each channel.
- a predetermined process is performed to amplify the input test signal and the sample sound stored in the storage unit 330 for each speaker, and output to each DZA converter 322 for each channel as an audio signal. It is supposed to be.
- Each audio signal that has been subjected to signal processing for each channel is input to the DZ A converter 322.
- the DZA converter 322 receives the input digital signal.
- Each audio signal, which is a digital signal, is converted to an analog signal and output to each power amplifier 323.
- the power amplifier 323 receives an audio signal that has been subjected to signal processing for each channel, amplifies the signal level of the audio signal for each channel, and converts each amplified audio signal. Outputs to each speaker corresponding to each channel.
- the test signal generation unit 324 generates a test signal used when analyzing the reproduction characteristics such as the frequency characteristic and reverberation characteristic of the listening room 10, and outputs the generated test signal to the signal processing unit 200. It has become. Specifically, the test signal generator 324 generates a test signal such as white noise, pink noise, or a sweep signal that sweeps the frequency in a certain frequency range under the system control unit 329, and generates the test signal. The test signal is output to the signal processing unit 200.
- test signal generation unit 324 of each embodiment generates a test signal in conjunction with the signal processing unit 200 and the spatial characteristic analysis unit 327 under the system control unit 329, which will be described later. It is now used when setting sound field data.
- the microphone amplifier 325 receives the sound collection signal output from the microphone 140.
- the microphone amplifier 325 amplifies the input sound collection signal to a preset signal level.
- the amplified sound collection signal is output to the AZD converter 326.
- the sound collection signal output from the microphone amplifier 325 is input to the AZD modification 326.
- the AZD modification 326 converts the input sound collection signal from an analog signal to a digital signal.
- the collected sound signal converted into the digital signal is output to the spatial characteristic analysis unit 327.
- the spatial characteristic analysis unit 327 receives a sound collection signal converted into a digital signal.
- the spatial characteristic analysis unit 327 analyzes the frequency characteristic of the input sound collection signal.
- the sound pressure level, the delay time, and the reverberation component are analyzed, and the signal processing unit 200 is controlled via the system control unit 329 based on each analysis result.
- the spatial characteristic analysis unit 327 of each embodiment is a speaker system 130 or Each analysis is performed based on the collected sound signal based on the test signal output from
- the operation unit 328 operates by operating a pointer in the screen in conjunction with a remote control device including various keys such as various confirmation buttons, selection buttons, and numeric keys, various key buttons, or the display unit 333. It consists of a mouse, which is one of the pointing devices for inputting each instruction.
- the operation unit 328 is used when inputting instructions for analyzing the spatial characteristics of the listening room 10 or when selecting or editing image information corresponding to sound field data for processing an audio signal. Used for input
- the system control unit 329 comprehensively controls general functions for performing audio signal amplification from each speaker.
- the system control unit 329 selects a speaker that amplifies the test signal when analyzing the reproduction characteristics such as the frequency characteristic and reverberation characteristic of the listening room 10.
- Let the spatial characteristic analysis unit 327 analyze the sound field data representing the reproduction characteristics (hereinafter referred to as sound field data). Further, processing for setting reproduction characteristics such as a frequency characteristic and a reverberation characteristic is performed based on a user operation of the operation unit 328.
- the storage unit 330 stores image information such as a famous performance hall displayed on the display unit 333, sound field data such as frequency characteristics and reverberation characteristics corresponding to the image information, and doll ears (dummy heads).
- the sound source of the hall which is a so-called binaural sound source that records sound with two attached microphones, the sound field measurement data of the listening room, various correction factors, sample sound data, etc. are stored in advance. And speak.
- the calculation unit 331 is a storage unit that is analyzed by the reproduction characteristic information of the famous performance hall or the like stored in the storage unit 330 and the spatial characteristic analysis unit 327 or after being analyzed by the spatial characteristic analysis unit 327. Based on the listening room playback characteristics information stored in the 330, a new playback is performed to process the audio signal when it is played back. Calculate characteristic information. The new reproduction characteristic information is output to the signal processing unit 200 under the control of the system control unit 329.
- FIG. 3 is a block diagram showing a configuration of the signal processing unit 200 in each embodiment.
- the signal processing unit 200 decodes the audio data input from the input processing unit 121 into an audio signal for each channel, and the decoded audio signal and test signal for each channel.
- the input to the test signal output from the generator 324 is switched.
- the signal processing unit 200 performs predetermined signal processing on the input signal for each channel and, under the control of the system control unit 329, amplifies the input test signal for each speaker. The predetermined processing is performed.
- the signal processing unit 200 receives a decoder 210 that decodes an audio signal for each channel based on the input audio data, and an audio signal of each channel output from the data.
- Input switching section 220 for switching test signals, frequency characteristics adjustment circuit 230 that adjusts the frequency characteristics of audio signals or test signals for each channel, and the signal level between channels with other channels
- a signal level Z delay adjustment unit 240 that delays the input signal for each channel, a reverberation control circuit 250 that generates a reverberation component of the audio signal or test signal for each channel, and adds the reverberation component to the audio signal or test signal;
- Signal processing control that controls each part in the signal processing unit 200 under the control of the system control unit 329 And 260 part.
- the signal processing unit 200 includes a frequency characteristic adjustment circuit 230, a signal level Z delay adjustment unit 240, and a reverberation control circuit 250 for each channel.
- the signal processing control unit 260 and each unit include Connected by bus B.
- Audio data is input to the decoder 210.
- the decoder 210 decodes the input audio data into an audio signal for each channel, and an input switching unit for each channel. Output to 220.
- the audio signal decoded for each channel and the test signal output from the test signal generator 324 are input to the input switching unit 220.
- the input switching unit 220 receives the signal. Under the control of the processing control unit 260, the input of the audio signal output from the decoder 210 and the test signal generated by the test signal generation unit 324 are switched and output to each frequency characteristic adjustment unit. . Further, the input switching unit 220 outputs the test signal to each channel or one channel selected by the signal processing control unit 260 when outputting the test signal.
- Each frequency characteristic adjustment circuit 230 is set with a frequency characteristic correction coefficient LFC for adjusting the gain of the signal component for each frequency band under the control of the signal processing control unit 260. It has become like that.
- Each frequency characteristic adjustment circuit 230 receives an input audio signal or test signal for each channel, and is input based on the set frequency characteristic correction coefficient LFC. The frequency characteristics of the signal are adjusted and output to each signal level Z delay adjustment unit 240.
- Each signal level Z delay adjustment unit 240 is a coefficient for adjusting the signal level between channels (hereinafter referred to as a level correction coefficient LAC) for each channel under the control of the signal processing control unit 260. ) And a coefficient for adjusting the delay amount (delay time) in the audio signal or test signal corresponding to each channel (hereinafter referred to as delay characteristic correction coefficient LDC).
- Each signal level Z delay adjustment unit 240 is input with an audio signal or a test signal whose frequency characteristics are adjusted for each frequency band. The 240 adjusts the signal level and delay amount between channels for the input signal based on the set level correction coefficient LAC and delay characteristic correction coefficient LDC.
- the adjusted audio signal or test signal is output to each reverberation control circuit 250.
- Each reverberation control circuit 250 is set with a reverberation characteristic correction coefficient LZC determined as described later by the signal processing control unit 260, and each reverberation control circuit 250 has a signal level.
- the reverberation control is performed on the adjusted audio signal or test signal and output to each DZA converter 122.
- each reverberation control circuit 250 receives an audio signal or a test signal whose signal level and delay amount are adjusted, and each reverberation control circuit 250 has The audio signal or test signal input for each channel is divided into a plurality of frequency bands.
- Each reverberation control circuit 250 generates a reverberation component for each frequency band in an audio signal or test signal input based on a reverberation characteristic correction coefficient LZC described later, and the generated reverberation component is input.
- the reverberation control is performed by adding to the audio signal or the test signal, and the signal subjected to the reverberation control is output to each DZA conversion 122.
- the signal processing control unit 260 determines and sets each coefficient of each frequency characteristic adjustment circuit 230, each signal level Z delay adjustment unit 240, and each reverberation control circuit 250 under the instruction of the system control unit 329. Come to do! /
- the signal processing control unit 260 includes information indicating gain, which is gain data for each frequency band output from the calculation unit 331, information indicating a signal level, information indicating a delay time, and each reverberation. Based on the information indicating the components, the frequency characteristic correction coefficient LFC, the level correction coefficient LAC, the delay characteristic correction coefficient LDC, and the reverberation characteristic correction coefficient LZC are calculated. The signal level Z delay adjustment unit 240 and the reverberation control circuit 250 are set.
- the signal processing control unit 260 under the instruction of the system control unit 329, performs the frequency characteristic correction coefficient LFC, level correction coefficient LAC, delay characteristic correction coefficient LDC, and reverberation characteristic correction stored in the storage unit 330.
- Coefficient LZC is input, and these correction coefficients also function to be set in each frequency characteristic adjustment circuit 230, each signal level Z delay adjustment unit 240, and each reverberation control circuit 250, respectively.
- FIG. 4 is a block diagram showing the configuration of the spatial characteristic analysis unit 327 in the present embodiment.
- the spatial characteristic analysis unit 327 is input with a sound collection signal generated by collecting a loud sound that has been amplified based on the test signal.
- the spatial characteristic analysis unit 327 As described above, the expansion output for each channel is based on the input sound collection signal. Analysis of voice sound frequency characteristics, analysis of its sound pressure level, analysis of delay time, and analysis of its reverberation components. Based on the results of each analysis, it is sent to the calculation unit 331 via the system control unit 329. Each data is output.
- This spatial characteristic analysis unit 327 includes a frequency characteristic analysis unit 327A that analyzes the frequency characteristic of the listening room 10, and a sound pressure level that analyzes the sound pressure level and the delay time that are amplified from each speaker in the listening room 10.
- the frequency characteristic analysis unit 327A prays for the frequency characteristic at the installation position of the microphone 140 in the listening room 10 based on the collected sound signal in the input test signal, and the system control unit 329 The analysis result is output to the calculation unit 331 as the listening room frequency characteristic data LF. Further, the system control unit 329 stores the analysis result in the storage unit 330 as the frequency characteristic data LF.
- the frequency characteristic analysis unit 327A identifies, for each channel, a plurality of predetermined frequency bands based on the collected sound signal in the input test signal. The sound pressure level for each frequency band is calculated. The frequency characteristic analysis unit 327A outputs the calculated sound pressure level for each frequency band to the calculation unit 331 as the frequency characteristic data LF of the listening room. Further, the system control unit 329 stores the analysis result in the storage unit 330 as the frequency characteristic data LF of the listening room.
- the sound pressure level Z delay time analysis unit 327B based on the sound collection signal in the input test signal, the sound pressure level amplified from the respective sound forces at the installation position of the microphone 140 in the listening room 10 and The delay time is analyzed, and the analysis result is output as predetermined data to the calculation unit 331 via the system control unit 329.
- the system control unit 329 stores the analysis result as data in the storage unit 330 B 0
- the sound pressure level Z delay time analysis unit 327B Based on the collected sound signal, the analysis is performed to equalize the signal level of the audio signal or test signal amplified through each channel and the delay time.
- the loudspeaker level (sound pressure level) and delay time for each channel are calculated based on the collected sound signal obtained when the sound is produced each time.
- the sound pressure level Z delay time analysis unit 327B uses the calculated loud sound level and delay time as sound pressure level data LL and delay time data LD of the listening room via the system control unit 329. Output to 331. Further, the system control unit 329 stores the analysis result in the storage unit 330 as the sound pressure level data LL and the delay time data LD of the listening room.
- the reverberation characteristic analysis unit 327C analyzes the reverberation characteristic in the living room 10 based on the collected sound signal in the input test signal, and the analysis is performed via the system control unit 329. The result is output to the calculation unit 331 as predetermined data.
- the reverberation characteristic is a temporal attenuation characteristic from the time when the reproduction of the loud sound heard at an arbitrary listening position in the listening room 10 is stopped.
- the reverberation characteristic analysis unit 327C calculates a reverberation characteristic for each frequency band based on the collected sound signal in the input test signal, and also calculates the calculated reverberation characteristic in the reverberation of the listening room.
- the characteristic data LZ is output to the calculation unit 331.
- the system control unit 329 stores the analysis result in the storage unit 330 as the reverberation characteristic data LZ of the listening room.
- FIG. 5 is a block diagram showing the internal structure of the storage unit 330.
- the storage unit 330 stores a hall A data area AD in which various data described later regarding the sound field space hall A are stored, and a hole B data area BD in which various data described later regarding the sound field space hall B are stored. , Hall C data area CD where various data to be described later regarding sound field space Hall C is stored, Listening room area LR for storing various data to be described later and various correction factors related to listening room 10, and sample to store sample sound Sound data area There is a data area such as SD.
- Hall A image data that is image information PA
- Hall A frequency characteristic data that represents the frequency characteristic of Hall A AF
- Hall A reverberation characteristic data that represents the reverberation characteristic of Hall A
- Hole A sound source SA which is a so-called binaural sound source, which is a recording method for recording sound with two attached microphones, is recorded!
- the frequency characteristics of the hole B image data PB and the hole B which are image information schematically representing the hole B displayed on the display unit 333, are displayed.
- Hall B frequency characteristics data BF, Hall B reverberation characteristics data BZ representing Hall B reverberation characteristics, and Hall B sound source SB which is a binaurally recorded sound source, are recorded in Hall B.
- Hall C data area CD similar to the Hall A data area AD, the Hall C image data CA, which is the image information schematically representing the Hall C displayed on the display unit 333, and the frequency characteristics of the Hall C.
- Hall C frequency characteristic data CF Hall C reverberation characteristic data CZ, which represents the reverberation characteristics of Hall C
- Hall C sound source SC which is a binaurally recorded sound source
- the frequency characteristic data LF representing the frequency characteristic of the listening room analyzed by the spatial characteristic analyzing unit 327 and the sound representing the sound pressure level are analyzed by the listener 327.
- a frequency characteristic correction coefficient LFC for setting the frequency characteristic of the frequency characteristic adjustment circuit 230, and a sound for setting the signal level of the signal level Z delay adjustment unit 240 are set.
- the pressure level correction coefficient LLC, the delay characteristic correction coefficient LDC for setting the delay time, and the reverberation characteristic correction coefficient LZC for setting the reverberation characteristic of the reverberation control circuit 250 are recorded.
- sample sound data area SD signal processing is performed in the signal processing unit 200 based on the frequency characteristics and reverberation characteristics set by the listener, and the speaker system 130 is connected via the DZA converter 322 and the power amplifier 323. Sound information of sample sound amplified from Sample sound data SS is recorded!
- the hall image data PA in the hall A data area AD is input to the display control unit 332 under the control of the system control unit 329 when the user operates the operation unit 329 to display the hall image.
- the display control unit 332 checks the hall image data PA so that the input hall image data PA is displayed on the display unit 333, and outputs it to the display unit 333.
- the system control unit 329 performs frequency characteristic data AF and reverberation characteristic data AZ in the hall A data area AD. Is read from the storage unit 330 and input to the calculation unit 331.
- the hall image data PB in the hall B data area BD is input to the display control section 332 under the control of the system control section 329 in the same manner as the hall A data area AD.
- the display control unit 332 checks the hall image data PB so that the input hall image data PB is displayed on the display unit 333, and outputs it to the display unit 333.
- the system control unit 329 displays the frequency characteristic data BF and the reverberation characteristic data BZ in the hall B data area BD. Is read from the storage unit 330 and input to the calculation unit 331.
- the hall image data PC in the hall C data area CD is input to the display control section 332 under the control of the system control section 329 in the same manner as the hall A data area AD.
- the display control unit 332 checks the hall image data PC so that the input hall image data PC is displayed on the display unit 333, and outputs it to the display unit 333.
- the system control unit 329 displays the frequency characteristic data CF and the reverberation characteristic data CZ in the hall C data area CD. Is read from the storage unit 330 and input to the calculation unit 331.
- FIG. 7 is a flowchart showing the operation of this embodiment.
- step SI 1 when system control unit 329 detects a user operation of operation unit 328, hole A image data PA, hole B image data PB, and hole C image data stored in storage unit 330 are detected. Based on the PC, the display control unit 332 displays the Hall A image, Hall B image, and Hall C image schematically shown on a display unit 33 3 such as a liquid crystal display or plasma display (Fig. 6). To control.
- step S12 when the system control unit 329 detects that any one of the images displayed in FIG. 6 is selected by the mouse used by the user, the frequency corresponding to the selected hall image is displayed. Characteristic data and reverberation characteristic data are read from the storage unit 330, and these data are input to the calculation unit 331.
- the system control unit 329 selects the frequency characteristic data AF and the reverberation characteristic data AZ in the hall A data area AD in the storage unit 330, and selects them. Data is input to the calculation unit 331. The same processing is performed when Hall image data B or Hall image data C is selected.
- step S 13 system control unit 329 measures sound field data such as frequency characteristics and reverberation characteristics in listening room 10. Specifically, the system control unit 329 causes the test signal generation unit 324 to generate a test signal. The system control unit 329 amplifies the generated test signal into the listening room 10 via the signal processing unit 200, the DZA converter 322, the power amplifier 323, and the force system 130.
- the amplified test signal force is collected by the microphone 140 installed at the listening position.
- the collected sound signal is amplified to a signal level set in advance by the microphone amplifier 325 and output to the AZD converter 326.
- the AZD converter 326 converts the input sound collection signal from an analog signal to a digital signal, and outputs the sound collection signal converted into the digital signal to the spatial characteristic analysis unit 327.
- the spatial characteristic analysis unit 327 analyzes the frequency characteristics which are sound field data of the loud sound output for each channel based on the input sound collection signal in accordance with the instruction of the system control unit 329. And the reverberation component is analyzed. Specifically, the spatial characteristic analysis unit 327 calculates reproduction characteristic data such as frequency characteristic data and reverberation characteristic data in the listening room 10. And the system control unit 329 is the frequency characteristic of the listening room Data LF and listening room reverberation characteristic data LZ are read from the spatial characteristic analysis unit 327 and stored in the listening room area LR in the storage unit 329 via bus B.
- step S 14 system control unit 329 outputs frequency characteristic data LF and listening room reverberation characteristic data LZ of listening room 10 of listening room 10 in listening room region LR of storage unit 330 to operation unit 331.
- the calculation unit 331 calculates gain, which is gain data for each frequency band, using the frequency characteristic data AF of Hall A and the frequency characteristic data LF of the listening room. Then, the system control unit 329 outputs the calculated gain for each frequency from the calculation unit 331 to the signal processing control unit 260. Based on the input gain for each frequency, the signal processing control unit 260 is a frequency characteristic correction coefficient corresponding to the coefficient for setting the frequency characteristic of each frequency characteristic adjustment circuit 230 stored in the prearranged storage unit 330. LFC is calculated and output to the frequency characteristic adjustment circuit 230 provided in each channel, and the frequency characteristic of each frequency characteristic adjustment circuit 230 is set.
- arithmetic unit 331 calculates reverberation characteristics for each frequency band using Hall A reverberation characteristic data AZ and listening room reverberation characteristic data LZ. Then, the system control unit 329 outputs the calculated reverberation characteristic for each frequency from the calculation unit 331 to the signal processing control unit 260. Based on the input reverberation characteristic data for each frequency, the signal processing control unit 260 is a reverberation characteristic corresponding to a coefficient for setting the reverberation characteristic of each reverberation control circuit 250 stored in the pre-arranged storage unit 330. The correction coefficient LFC is calculated and output to the frequency characteristic adjustment circuit 230 provided for each channel, and the frequency characteristic of each frequency characteristic adjustment circuit 230 is set.
- step S15 when the system control unit 329 detects that the user has selected “end” using the operation unit 328 (step S15; YES), the system control unit 329 performs this process. End.
- the system control unit 329 detects that the user has selected “continue” using the operation unit 328 (step S 15; NO)
- the system control unit 329 performs image information such as a hall image. To display, go to step S11.
- the sound field data measurement of the listening room corresponding to step S 13 is performed.
- it is not limited to this before the sound field correction corresponding to step S14.
- it can be performed before displaying the hole image corresponding to step S11.
- it is not necessary to measure the sound field data of the listening room every time. If it is in one listening room, it is sufficient to perform it only once if the installation equipment such as audio equipment in the listening room is not changed. is there.
- the listening room frequency characteristic data and reverberation characteristic data stored in the listening room area of the storage unit 330 are used for the calculation of the listening room sound field correction coefficient in step S14. .
- the microphone 140 position must be changed to the position where the user listens, and the sound field data measurement of the listening room corresponding to step S13 must be performed again. It is.
- each hall sound source data stored in each hall data area is stored in the user's headphones (not shown) under the control of the system control unit 329 after the hall image displayed on the display unit 333 is selected. ) Can be made louder.
- the force described for the processing of the frequency characteristic data and the reverberation characteristic data in each hall is the same for the sound pressure level data and the delay time data in each hall. To be processed.
- FIG. 8 is a flowchart showing the operation of this embodiment.
- step S21 when the system control unit 329 detects a user operation of the operation unit 328, the system control unit 329 is selected by the operation of the operation unit 328 from the storage unit 330 in which image information schematically representing each speaker is recorded. The image information of the selected speaker is output to the display control unit 332. After that, the system control unit 329 controls the display control unit 332 so that the selected speaker image is displayed on the display unit 333 such as a liquid crystal display device or a plasma display device. As a result, for example, as shown in FIG. Pee force 132FR is displayed on the display unit 130.
- the display unit 333 such as a liquid crystal display device or a plasma display device.
- step S22 when the system control unit 329 detects that the FL speaker 132FL image displayed on the display unit 130 is enlarged by the user operating the mouse, the display control unit 332 is displayed on the display unit 130.
- FL speaker displayed on 130 Controls to enlarge the 132FL image (Fig. 9 (b)).
- the system control unit 329 displays the display control unit 332 on the FL displayed on the display unit 130. Speaker Controls to reduce the 132FL image (not shown.) O
- the system control unit 329 can generate an audio signal level corresponding to the size of the speaker image. Increase or decrease the target sound pressure level AL of the FL speaker according to the size of the displayed FL speaker 132FL.
- step S23 the system control unit 329 measures the sound pressure level, which is sound field data in the listening room 10. Specifically, the system control unit 329 causes the test signal generation unit 324 to generate a test signal. Thereafter, the system control unit 329 amplifies the generated test signal into the listening room 10 via the signal processing unit 200, the DZA converter 322, the power amplifier 323, and the speaker system 130.
- the spatial characteristic analysis unit 327 receives the sound pressure level that is the sound field data of the loud sound output for each channel based on the input sound collection signal in accordance with an instruction from the system control unit 329. Perform analysis. Specifically, the playback data in the sound pressure level Z delay time analysis unit 327B force listening room 10 is calculated. Then, the system control unit 329 outputs the listening room sound pressure level data LL from the spatial characteristic analysis unit 327, and stores the listening room sound level data LL in the storage unit 330. Groom area Record in LR.
- step S24 system control unit 329 reads sound pressure level LL in listening room area LR in storage unit 330 shown in FIG.
- the system control unit 329 inputs the read sound pressure level LL to the calculation unit 331. Further, the system control unit inputs the sound pressure level AL obtained in step 22 to the calculation unit 331.
- the calculation unit 331 calculates a new sound pressure level correction coefficient LLC from the input sound pressure level LL and sound pressure level AL.
- the system control unit 329 outputs the changed listening room sound pressure level correction coefficient LLC from the calculation unit 331, and the sound pressure level correction coefficient LLC in the listening room region LR in the storage unit 330 is output. Re-record as. Further, the system control unit 329 inputs the changed sound pressure level correction coefficient LLC of the listening room to the signal processing control unit 260.
- the signal processing control unit 260 sets the input sound pressure level correction coefficient LLC to the signal level Z delay adjustment unit 240, the audio signal level transmitted to each channel is changed by the signal level Z delay adjustment unit 240. Is done.
- step S25 when the system control unit 329 detects that the user has selected “end” using the operation unit 328 (step S25; YES), the system control unit 329 performs this process. End.
- the system control unit 329 detects that the user has selected “continue” using the operation unit 328 (step S25; NO)
- the system control unit 329 causes each speaker (131, 132FL, 132FR, In order to display a typical speaker on the display device 333 in order to change the sound pressure of 132SL, 132SR, 134), the process proceeds to step S21.
- the present embodiment is not limited to the process of displaying the speaker and changing the volume in step S21.
- the system control unit 329 displays an image (FIG. 10 (a)) showing the positional relationship between the speaker and the user for changing the time until the loud sound output from each speaker reaches the user. It is also possible to control the display control unit 332 so that it is displayed on the unit 333.
- Fig. 10 (a) is a diagram schematically showing the listening position (RV), FL speaker 132 FL, and FR ⁇ Pe force 132FR, and their positional relationship.
- C1 represents a circle centered at the listening position (RV).
- Fig. 10 (a) shows that FL speaker 132FL and FR ⁇ Pe force 132FR are at the listening position (RV), etc. Represents being at a distance.
- the system control unit 329 monitors the input from the operation unit 328, and the position of the speaker image selected on the display screen of the display unit 333 is set in the horizontal direction and the vertical direction based on the input instruction.
- the calculation unit 331 calculates the force whose coordinate has changed. Then, the system control unit 329 calculates the vertical movement distance and the horizontal movement distance of the speaker image in the listening room 10 from the coordinate change in the horizontal direction and vertical direction of the speaker image to the calculation unit 331.
- the system control unit 329 From the coordinates corresponding to the FR speaker 132FR image of Fig. 10 (a) displayed on the screen of the display unit 333, the FR ⁇ Pe force 132 of Fig. 10 (b) on the screen of the display unit 333 that is the movement destination.
- the calculation unit 331 is controlled to calculate the distance to the coordinates corresponding to the FR image.
- the distance calculation method is arbitrary.
- the following method can be used. That is, the coordinates corresponding to the movement destination of the FR ⁇ Pe force 132FR image (Fig. 10 (b)) are (X2, Y2), and the coordinates before the movement of the FR speaker 132FR image (Fig. 10 (a)) are ( XI, Y1)
- R1 ((X2-X1) 2 + ( ⁇ 2- ⁇ 1) 2 ) 1 2 (1)
- R1 is the FR speaker on the screen displayed on the display unit 333.
- the distance R1 on the display screen of the display unit 333 from the movement destination of the FR ⁇ Pe force 132FR image and before the movement is calculated.
- the system control unit 329 causes the calculation unit 331 to calculate the distance R2 between the position before movement of the FR speaker 132FR image displayed on the display unit 333 and the listening position (RV).
- the FR ⁇ Pe force 132FR in the listening room 10 and the distance R 4 to the listening position (RV) are stored in the storage unit 330 in advance.
- the system control unit 329 inputs the stored FR ⁇ Pe force 132FR in the listening room 10 and the distance R4 to the listening position (RV) from the storage unit 330 to the calculation unit 330.
- the calculation unit 330 is connected to the FR unit on the display screen of the display unit 333.
- Pee force 132FR image's destination force is also the distance Rl before the movement, FR speaker on the display screen of the display unit 333
- the distance R2 between the position before the 132FR image is moved and the listening position (RV), and in the listening room 10
- RV listening position
- the system control unit 329 controls the display control unit 332 so that the distance R3 that is the calculation result is displayed in FIG. Figure 10 (b) shows the FR ⁇ Pe force 132FR approaching the original position force listening position by 50cm.
- the system control unit 329 sends the delay coefficient data to the calculation unit 331 so that the delay time of the Z delay adjustment unit 240FL is proportional to the distance difference R1.
- the system control unit 329 inputs the delay coefficient data calculated by the calculation unit 331 to the signal processing control unit 260.
- the signal processing control unit sets the input delay coefficient data in the delay circuit FL.
- the user at the listening position (RV) can listen to the sound that is also amplified by the FR speaker 132 FR faster than the sound that is also amplified by the FL speaker 132 FL force.
- the user can select the FR speaker 132FR image with the mouse and move it away from the listening position (RV). In this case, the user at the listening position (RV) can listen to the sound that is amplified from the FR peak 132FR later than the sound that is also amplified by the FL speaker 132FL.
- step 21 is not limited to the diagram described above, a diagram representing frequency characteristics of sound field data, a diagram representing phase characteristics, a diagram representing reverberation characteristics, and various types. It is also possible to represent a diagram of the speakers.
- step S24 the user can edit these charts using the mouse.
- step S26 or step S28 based on the result edited in step S24, the system control unit 329 causes the calculation unit 331 to calculate the frequency characteristics and reverberation characteristics.
- the microphone When the user changes the listening position, the microphone is placed at the position where the user listens. By changing the position of 0, it is possible to newly perform the listening room sound field data measurement corresponding to step S11 and the calculation of the listening room sound field coefficient data corresponding to step S12.
- FIG. 11 is a flowchart showing the operation of this embodiment.
- step S31 when the system control unit 329 detects the user operation of the operation unit 328, the movie theater image data PM, the large hall image data PB, and the small hall image shown in FIG. Based on the image such as the data PS and the living image data PL, the display control unit 332 is controlled so as to display any one of the display units 333 such as a liquid crystal display device and a plasma display.
- the display control unit 332 is controlled so as to display any one of the display units 333 such as a liquid crystal display device and a plasma display.
- step S32 when the system control unit 329 detects that any one of the images displayed in FIG. 12 is selected by the mouse used by the user, the reverberation characteristic data corresponding to the selected image is displayed. Are read from the storage unit 330 and these data are input to the calculation unit 331.
- the system control unit 329 selects the movie theater reverberation characteristic data PZ corresponding to the movie theater image data PM in the storage unit 330, and selects them. Data is input to the calculation unit 331. The same processing is performed when large hall image data PB, small hall image data PS, or living image data PL is selected.
- step S 33 system control unit 329 measures sound field data such as reverberation characteristics in listening room 10. Specifically, the system control unit 329 causes the test signal generation unit 324 to generate a test signal. The system control unit 329 generates the generated test signal. Is amplified in the listening room 10 via the signal processing unit 200, the DZ A converter 322, the power amplifier 323, and the speaker system 130.
- the sound is picked up by the microphone 140 installed at the listening position where the test signal power is expanded.
- the collected sound signal is amplified to a signal level set in advance by the microphone amplifier 325 and output to the AZD converter 326.
- the AZD converter 326 converts the input sound collection signal from an analog signal to a digital signal, and outputs the sound collection signal converted into the digital signal to the spatial characteristic analysis unit 327.
- the spatial characteristic analysis unit 327 analyzes the reverberation characteristic that is the sound field data of the loud sound output for each channel based on the input sound collection signal in accordance with an instruction from the system control unit 329. I do. Specifically, the spatial characteristic analysis unit 327 calculates reverberation characteristic data that is reproduction characteristic data in the listening room 10. Then, the system control unit 329 reads the reverberation characteristic data LZ of the listening room 10 from the spatial characteristic analysis unit 327 and stores it in the listening room region LR in the storage unit 329 via the nose B.
- system control unit 329 outputs reverberation characteristic data LZ of the listening room of listening room 10 in listening room region LR of storage unit 330 to calculation unit 331.
- the calculation unit 331 calculates the reverberation characteristics for each frequency band using the movie theater reverberation characteristic data PZ and the listening room reverberation characteristic data PZ. Then, the system control unit 329 outputs the calculated reverberation characteristic for each frequency from the calculation unit 331 to the signal processing control unit 260. Based on the input reverberation characteristic data for each frequency, the signal processing control unit 260 is a reverberation characteristic corresponding to a coefficient for setting the reverberation characteristic of each reverberation control circuit 250 stored in the pre-arranged storage unit 330. The correction coefficient LZC is calculated and output to the reverberation control circuit 250 provided for each channel, and the reverberation characteristics of each reverberation control circuit 250 are set.
- step S 35 system control unit 329 inputs listening room reverberation characteristic data LZ and reverberation characteristic data corresponding to each image stored in storage unit 330 to calculation unit 331.
- the calculation unit 331 compares and calculates the input listening room reverberation characteristic data LZ and the reverberation characteristic data input from the storage unit 330.
- the calculation unit 331 performs this comparison operation on reverberation characteristic data corresponding to all image data stored in the storage unit 330. And compared with listening room reverberation characteristics data LZ Of the reverberation characteristic data, the reverberation characteristic data that most closely approximates the listening room reverberation characteristic data LZ is selected.
- the computation unit 331 compares the listening room reverberation characteristic data LZ with any one of the reverberation characteristic data stored in the storage unit 330 for the reverberation time for each frequency band, and reverberation for each frequency band. Calculate the integral of the time difference. Then, among the reverberation characteristic data stored in the storage unit 330, the reverberation characteristic data having the smallest integrated value can be selected as the reverberation characteristic data most similar to the listening room reverberation characteristic data LZ.
- step S36 the system control unit 329 performs display control so that the display unit 333 displays image data corresponding to the reverberation characteristic data that is closest to the resung room reverberation characteristic data LZ selected in step 35.
- the unit 332 is controlled.
- step 37 if the image displayed on display unit 333 in step S36 is the same as the image displayed on display unit 333 in step 31 (step S37: YES), system control unit 329 The control unit 329 ends this process.
- the system control unit 329 returns to step S33.
- the reverberation characteristic correction coefficient LZC calculated in 34 is set in the reverberation control circuit 250, and the sound field data of the reverberation characteristic in the listening room 10 is measured again.
- step S31 Normally, the power to repeat this measurement and comparison calculation process several times The image displayed on the display unit 333 in step S31 even if this measurement and comparison calculation process is repeated a predetermined number of times, for example, five times. If the reverberation characteristic data measured in 10 rooms in the living room is not the closest to the reverberation characteristic data corresponding to, this process can be forcibly terminated.
- step S37 the display unit 333 may display how many times the processing from step S33 to step S36 needs to be repeated. In addition, by displaying the time required for the remaining processing on the display unit 333 in numerical values in units of minutes or seconds, it is possible to allow the user to share the progress of the calculation.
- the system control unit 329 can repeat step S33 to step S36 for each speaker arranged in the listening room 10.
- the system control unit 329 By displaying a schematic diagram of the speaker arranged in the listening room 10 in advance on the display unit 333 and coloring the schematic diagram of the speaker for which the calculation has been completed, it is possible to allow the user to share the progress of the calculation. Oh ,.
- the image displayed on the display unit 333 is not limited to an image prepared in advance, and graphics data drawn with 3D CAD (Computer Aided Design) or the like may be displayed.
- 3D CAD Computer Aided Design
- the value obtained by the simulation is used as the reverberation characteristic data.
- the system control unit 329 may display on the display unit 333 messages corresponding to the arrangement of furniture, the presence / absence of curtains, the presence / absence of obstacles, noise, and the like.
- the sound field data of the first listening room corresponding to step S33 is measured before the sound field correction corresponding to step S34! /, but this is not a limitation. . For example, this is performed before the hall image corresponding to step S31 is displayed.
- each hall sound source data stored in each hall data area is stored in the user's headphones (not shown) under the control of the system control unit 329 after the hall image displayed on the display unit 333 is selected. ) Can be made louder.
- the main purpose is to correct the image of the space.
- a signal processing circuit such as a so-called equalizer, which is known as an audio device.
- the main purpose is to arrange a plurality of timbres with the same power. Therefore, a schematic diagram of a speaker photograph is used as an image such as an icon displayed on the display unit 333. [0142]
- the speaker image and the frequency characteristic data are preliminarily associated with each other and stored in the storage unit 330.
- a so-called inexpensive speaker image is displayed on the display unit 333.
- the speaker image displayed on the display unit 333 is changed to a so-called expensive speaker.
- the frequency characteristics of the listening room is corrected many times, and when the correction is completed, a photograph or schematic diagram of a famous speaker is displayed on the display unit 333.
- the system control unit 329 causes the test signal generation unit 324 to generate a test signal, and enters the listening room 10 via the signal processing unit 200, the DZ A converter 322, the power amplifier 323, and the speaker system 130. Make a loud voice.
- the amplified test signal force is collected by the microphone 140 installed at the listening position, amplified to a preset signal level by the microphone amplifier 325, and then output to the A ZD converter 326.
- the AZD converter 326 converts the input sound collection signal from an analog signal to a digital signal, and outputs the sound collection signal converted into the digital signal to the spatial characteristic analysis unit 327.
- the spatial characteristic analysis unit 327 analyzes the frequency characteristics, which are sound field data of the loud sound output for each channel, based on the input sound collection signal according to the instruction of the system control unit 329. Do. Specifically, the spatial characteristic analysis unit 327 calculates frequency characteristic data that is reproduction characteristic data in the listening room 10. Then, the system control unit 329 reads the listening room frequency characteristic data LF from the spatial characteristic analysis unit 327 and stores it in the listening room region LR in the storage unit 329 via the bus B.
- system control unit 329 outputs the frequency characteristic data LF of the listening room of the listening room 10 in the listening room area LR of the storage unit 330 to the computing unit 331.
- the calculation unit 331 calculates the frequency characteristic for each frequency band using the frequency characteristic data corresponding to the expensive speaker and the listening room frequency characteristic data LF. Then, the system control unit 329 outputs the calculated frequency characteristic for each frequency from the calculation unit 331 to the signal processing control unit 260.
- the signal processing control unit 260 Based on the frequency characteristic data, the frequency characteristic correction coefficient LFC corresponding to the coefficient for setting the frequency characteristic of each frequency characteristic adjustment circuit 230 stored in the force storage unit 330 is calculated and assigned to each channel. Output to the provided frequency characteristic adjustment circuit 230 and set the frequency characteristic of each frequency characteristic adjustment circuit 230.
- the system control unit 329 reads out an image of a speaker having a frequency characteristic approximate to the frequency characteristic analyzed by the spatial characteristic analysis unit 327 from the storage unit 330, and displays the speaker image on the display unit 332. To do. If necessary, repeat the frequency characteristic correction.
- the listening room 10 is corrected, the user visually recognizes that the speaker image displayed on the display unit 333 changes from a small inexpensive speaker to a large expensive spin force.
- the image of the speaker, etc. displayed on the display unit 333 changes even during the correction waiting time, so you can enjoy the situation visually. No longer care.
- time delay correction is performed in order to align the time until a speaker sound that is also amplified by a plurality of speaker speakers provided in the listening room 10 reaches the user.
- the user power as a listener also displays how far each speaker is on the display unit 333, so that the user can easily understand the progress of time delay correction.
- the system control unit 329 delays the sound that is loudened from the speaker based on the amount of movement. .
- FIG. 14 shows the distance relationship between the four speakers displayed on display unit 333 and the user who is the listener.
- RV represents the listening position
- C3 represents a concentric circle located lm from the listening position
- C4 represents a concentric circle located 2 m from the listening position.
- Figure 14 shows the RR ⁇ Pe force 132RR moved from the listening position onto a 2m concentric circle C4.
- FR ⁇ Pe force 132FR is the force that was initially displayed between the concentric circle C3 and the concentric circle C4.
- the user can operate the operation unit 328 to move it to the concentric circle C4, which is 2 m away from the listening position. This is shown in Figure 4.
- the system control unit 329 controls the generation timing of the speaker sound that is loudened from each speaker so that each speaker is loudened at a distance of 2 m from the listening position.
- step S41 the system control unit 329 displays an image representing the positional relationship between the speaker and the user for changing the time until the loud sound output from each speaker reaches the user (Fig. 14).
- the display control unit 332 is controlled so as to be displayed on the display unit 333.
- FIG. 14 is a diagram schematically showing the listening position (RV), the FL speaker 132FL, the FR speaker 132FR, the RL speaker 132RL, and the RR ⁇ Pee force, and their positional relationship. This indicates that the listening position (RV) force of each speaker is equidistant.
- step 42 the system control unit 329 monitors the input from the operation unit 328, and the position of the selected speaker image on the display screen of the display unit 333 is set in the horizontal direction and the vertical direction based on the input instruction.
- the calculation unit 331 calculates the force whose coordinate has changed in the direction.
- the system control unit 329 sends the vertical movement distance and horizontal movement distance of the speaker image in the listening room 10 to the calculation unit 331 based on the coordinate change in the horizontal direction and vertical direction of the speaker image. Calculate.
- the system control unit 329 From the coordinates corresponding to the FR ⁇ Pe force 132FR image of Fig. 14 displayed on the screen of the display unit 333 to the coordinates corresponding to the FR speaker 132FR image of Fig. 14 on the screen of the display unit 333 as the movement destination.
- the calculation unit 331 is controlled so as to calculate the distance.
- the distance displayed on display unit 333 is the speed of sound in the air previously input to storage unit 330. Based on the above, it is possible to express the time it takes for the sound amplified from each speaker to reach the user at the listening position (RV).
- step 43 the system control unit 329 causes the test signal generation unit 324 to generate a test signal, and the signal processing unit 200, the DZA converter 322, the power amplifier 323, or the speaker system 130 is selected.
- the listening room 10 the system control unit 329 causes the test signal generation unit 324 to generate a test signal, and the signal processing unit 200, the DZA converter 322, the power amplifier 323, or the speaker system 130 is selected.
- the amplified test signal power is collected by the microphone 140 installed at the listening position, amplified to a preset signal level by the microphone amplifier 325, and then output to the A ZD converter 326.
- the AZD converter 326 converts the input sound collection signal from an analog signal to a digital signal, and outputs the sound collection signal converted into the digital signal to the spatial characteristic analysis unit 327.
- step 44 the spatial characteristic analysis unit 327 receives the sound generation timing of the loud sound output for each channel and the microphone 14 in accordance with the instruction of the system control unit 329. The time difference from the selected timing is calculated. Then, system control unit 329 reads listening room delay time data LD from spatial characteristic analysis unit 327 and stores it in listening room region LR in storage unit 329 via nose B.
- system control unit 329 outputs the calculated delay time data for each speaker from calculation unit 331 to signal processing control unit 260.
- the signal processing control unit 260 calculates a delay characteristic correction coefficient LFC for each speaker based on the input delay time data, and outputs it to the signal level Z delay adjustment unit 240 provided for each channel.
- Z delay adjustment section Sets the delay time of 240.
- the arrival time is the longest, that is, the time delay set for each speaker with reference to the speaker farthest from the listening position RV You can set the amount.
- step 45 the system control unit 329 uses the delay time data for each speaker calculated by the spatial characteristic analysis unit 327 and the sound speed in the air previously input to the storage unit 330 to Each time, the distance of the listener (RV) is calculated by the calculation unit 331. Then, the calculated result is moved as the distance between each speaker and the listener (RV) on the display unit 333. Also displayed on the display 333 corresponding to the speaker for which correction has been completed. The speaker is colored so that the user can easily understand the progress of the correction visually.
- Step 46 When the delay time of each speaker corresponding to the positional relationship between the listener (RV) and each speaker set in Step 46! /, And Step 42! /, Is obtained (Step 46: YES), the series of processing ends. If the delay time of each speaker corresponding to the positional relationship between the listener (RV) set in step 42 and each force is not obtained (step 46: NO), return to step 43 to return to the delay time. Repeat the correction process.
- the speaker when the volume level of a speaker that is also amplified by a plurality of speaker speakers provided in the listening room 10 is adjusted, the speaker schematically represented as the volume that is amplified from the speaker on the display unit 333.
- a modification will be described in which the user can visually grasp the volume of sound that is loudened from the speaker in correspondence with the size of the speaker.
- the system control unit 329 causes the test signal generation unit 324 to generate a test signal, and the signal processing unit 200, D / A conversion ⁇ 322, power amplifier 323, speaker system 130! Loudspeak in the listening room 10 through the speaker.
- the amplified test signal force is collected by the microphone 140 installed at the listening position, amplified to a preset signal level by the microphone amplifier 325, and then output to the A ZD converter 326.
- the AZD converter 326 converts the input sound collection signal from an analog signal to a digital signal, and outputs the sound collection signal converted into the digital signal to the spatial characteristic analysis unit 327.
- the spatial characteristic analysis unit 327 analyzes the sound pressure level of the loud sound output for each channel based on the input sound collection signal according to the instruction of the system control unit 329. Specifically, the playback data in the sound pressure level Z delay time analysis unit 327B force listening room 10 is calculated. The system control unit 329 then listens to the listening room sound for each channel. The pressure level data LL is output from the spatial characteristic analysis unit 327 and recorded in the listening room area LR in the storage unit 330.
- the system control unit 329 reads the sound pressure level LL in the listening room area LR in the storage unit 330 shown in FIG.
- the system control unit 329 inputs the read sound pressure level LL to the calculation unit 331.
- the system control unit inputs the sound pressure level UL set by the user to the calculation unit 331.
- the calculation unit 331 calculates a new sound pressure level correction coefficient LLC from the input sound pressure level LL and sound pressure level UL.
- the system control unit 329 outputs the changed listening room sound pressure level correction coefficient LLC from the calculation unit 331, and the sound pressure level correction coefficient LLC in the listening room area LR in the storage unit 330 is output. Re-record as. Further, the system control unit 329 inputs the changed sound pressure level correction coefficient LLC of the listening room to the signal processing control unit 260.
- the signal processing control unit 260 sets the input sound pressure level correction coefficient LLC to the signal level Z delay adjustment unit 240, the audio signal level transmitted to each channel is changed by the signal level Z delay adjustment unit 240. Is done.
- the system control unit 332 changes the size of the speaker displayed on the display unit 333 according to the sound pressure level of each speaker.
- the above sound pressure adjustment processing is executed until the sound pressure of each speaker becomes equal.
- the target may be set according to the user's preference at the start of correction, such as raising the front speaker by 3 dB compared to the rear by simply equalizing the sound pressure of all speakers.
- the surround system 100 of the present embodiment is installed in the listening room 10 and the test signal unit 324, DZA that measures the spatial characteristics such as the frequency characteristics and reverberation characteristics of the sound that is amplified in the listening room 10.
- Data display means a display control unit 130 for controlling a display unit 333 such as a liquid crystal display device or a plasma display for displaying a sound field space such as various hall images, and a liquid crystal display device or a plasma display display unit 333.
- the operation section 328 such as a mouse for selecting various hall images to be selected, and the relationship between the display screen for various halls and the frequency characteristic data and reverberation characteristic data which are target data for various halls are stored.
- Frequency characteristics data, sound pressure level Z delay time characteristics data and reverberation characteristics data which are target data of the memory 330 and various halls selected by a mouse, etc., and listening measured by the sound field data measuring means
- reproduction means such as the input processing unit 121 and the signal processing unit 200 that reproduce the sound input from the sample sound data SS and the sound source output device 110, and the reproduction unit
- the DZA converter 322 for outputting the reproduced information and the output means such as the power amplifier 323 are provided.
- the surround system 100 has a chart representing the frequency characteristics of the sound field data, a chart representing the phase characteristics, a chart representing the reverberation characteristics, various displays on the display means such as a liquid crystal display device and a plasma display.
- a diagram of various types of speakers, a diagram representing the size of the speaker, or a diagram representing the positional relationship between the speaker and the user is displayed.
- the target data is selected by the user selecting desired information displayed on the display device. Sound for selection It is also possible to listen to the sound source with headphones in the field. As a result, the target sound field can be confirmed by ear.
- the surround system 100 of the present embodiment moves at least a part of the speaker image selected by the mouse with the movement of the mouse to enlarge the speaker image, or the positional relationship between the speaker and the user. Can be changed and edited.
- the speaker image edited in this way can be used as the target data described above, and based on the edited speaker, the frequency characteristics of the listening room that have been preliminarily set to determine the sound that is output from the speaker are corrected.
- the coefficient LFC, sound pressure level correction coefficient LLC, delay characteristic correction coefficient LDC or reverberation characteristic correction coefficient LZC are calculated by the calculation unit 331, and the new listening room frequency characteristic correction coefficient LFC sound pressure level correction coefficient LLC, delay characteristic Calculate as correction coefficient L DC or reverberation characteristic correction coefficient LZC.
- the signal processing control unit 260 controls the frequency characteristic adjustment circuit 230 to change the frequency characteristic of the sound that is output from the speaker system 130.
- the signal processing control unit 260 controls the signal level Z delay adjustment unit 240 based on the calculated sound pressure level correction coefficient LLC and delay characteristic correction coefficient LDC, and the signal level or delay time of the loudspeaker system 130 is increased. To change.
- the signal processing control unit 260 controls the reverberation control circuit 250 and changes the reverberation characteristic of the sound amplified from the speaker system 130.
- the sound pressure level between speakers when adjusting the sound pressure level between speakers, a plurality of speakers are displayed on the display screen, and the size of the speakers is changed by an instruction from a mouse or a keyboard.
- the sound pressure level can be changed according to the size of the speaker. For example, when changing the distance from the speaker to the user, a diagram related to the positional relationship between the speaker and the user is displayed on the screen, and the distance between the two is changed by an instruction from the mouse or keyboard. Depending on the distance, the sound that reaches the user from the speaker It becomes possible to change the time.
- the surround system 100 of the present embodiment has the frequency, the intensity of the frequency, the time of the reverberant sound, the intensity of the reverberant sound, and the output sound from the output means reach the user in the storage unit 330. Information related to at least one of the delay times is recorded.
- the signal processing unit 200 includes at least one of a frequency characteristic adjusting circuit 230, a signal level Z delay adjusting unit 240, and a reverberation control circuit 250 that can adjust the frequency characteristic for each finely divided frequency band. It has been.
- the reverberation time for each frequency band since it is possible to control the reverberation time for each frequency band, the sound generated in the sound field is repeatedly reflected on the surrounding walls and ceiling to form a complex sound field. It is possible to control the reverberation characteristics. In other words, the reverberation characteristic of one sound field can be easily reproduced in a space such as a home room which is another sound field.
- the surround system 100 is configured such that when information related to a sound field space such as a hole and a speaker is displayed on a liquid crystal display device or a plasma display, the user uses the mouse to select the hole, When information related to sound field space such as speakers is selected, the binaurally recorded sound source corresponding to each image is also played back with headphones and can be confirmed with the ear.
- a sound field space such as a hole and a speaker
- the user uses the mouse to select the hole
- the binaurally recorded sound source corresponding to each image is also played back with headphones and can be confirmed with the ear.
- the surround system 100 includes sound field data such as reverberation characteristics, frequency characteristics, delay time characteristics, and sound pressure level characteristics associated with image information such as halls that the user desires to view and tests.
- Reverberation characteristics measured by sound field data measurement means including signal section 324, DZA converter 322, power amplifier 323, speaker system 130, microphone amplifier 325, A / D conversion 326, spatial characteristic analysis section 3 27, etc.
- the comparison calculation means such as the calculation unit 331 that compares and calculates the sound field data such as frequency characteristics, delay time characteristics, and sound pressure level characteristics, and the storage means such as the storage unit 330 based on the comparison calculation result.
- the system further includes extraction means such as a system control unit 329 that extracts image information such as a stored hall.
- the sound field space such as the target hall, the positional relationship of the speakers, and the size of the speaker that represents the sound pressure level that is output from the speakers are displayed.
- Sound field space corresponding to sound field data in the middle based on the sound field data measured by the sound field data measuring means that just displays the sound field, the positional relationship of the speaker force, and the loudspeaker from the speaker
- An image such as the size of the speaker showing the sound pressure level can be displayed. Therefore, the waiting time during correction to be close to the target data can be enjoyed by visually observing an image representing a halfway time displayed on a display device such as a liquid crystal display device or a plasma display.
- the information displayed on the liquid crystal display device or the plasma display has been described mainly with reference to charts.
- the present application is not limited to these, and the frequency (Hz ) And signal level (dB) can be entered numerically.
- the frequency (Hz) and delay time (ms) representing the reverberation characteristics can be entered numerically.
- the chart representing the sound field data of the hall and the like indicating the sound field space and the speaker has been described separately, but the present application is not limited to these, but one liquid crystal display device Or you may be able to edit the sound field data and check the playback sound by displaying the sound field data such as the hall showing the sound field space and the speaker on the plasma display together. In addition, if the sound field data of the speaker, etc. is corrected, and the sound field data in the hall indicating the sound field space that has been set in advance is the same or close to the value, those holes are displayed on the screen. You may make it display.
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Abstract
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JP2006529043A JPWO2006009004A1 (ja) | 2004-07-15 | 2005-07-11 | 音響再生システム |
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EP1850638A3 (en) * | 2006-04-28 | 2013-09-25 | Yamaha Corporation | Sound field controlling device |
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US11895482B2 (en) | 2012-03-06 | 2024-02-06 | Dolby Laboratories Licensing Corporation | Method and apparatus for screen related adaptation of a Higher-Order Ambisonics audio signal |
US10771912B2 (en) | 2012-03-06 | 2020-09-08 | Dolby Laboratories Licensing Corporation | Method and apparatus for screen related adaptation of a higher-order ambisonics audio signal |
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WO2015029205A1 (ja) | 2013-08-30 | 2015-03-05 | 共栄エンジニアリング株式会社 | 音響処理装置、音響処理方法、及び音響処理プログラム |
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CN113519171A (zh) * | 2019-03-19 | 2021-10-19 | 索尼集团公司 | 声音处理装置、声音处理方法和声音处理程序 |
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