JP2006054515A - Acoustic system, audio signal processor, and speaker - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an acoustic system, an audio signal processor, and a speaker capable of automatically forming a sound field with much more presence. <P>SOLUTION: The audio signal processor 100 transmits a pulse signal to the speaker 200, a detection section 105 detects a response time until receiving a response pulse signal with respect to the transmitted pulse signal, and a calculation section 107 calculates a distance between a transmission/reception section 102 and the speaker 200 on the basis of the response time. A sound field arithmetic processing section 109 supplies an audio signal to the speaker 200 on the basis of calculated positional information of the speaker 200. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an acoustic system, an audio signal processing device, and a speaker, and more particularly to an audio system that includes a speaker, an audio signal processing device that supplies an audio signal to the speaker, and an audio system.

  In recent years, an audio system that provides a realistic sound field by arranging a plurality of speakers around a listener, and a home theater system that provides a surround effect as if in a theater in combination with a video device have become widespread. . In such an acoustic system, in addition to the two speakers arranged at the front left and right of the listener in order to realize the stereo effect, a plurality of speakers are provided on the front, rear left and right, and back, and a speaker dedicated to low-frequency reproduction is also provided. By trying to get a realistic sound effect.

  Multi-channel audio signals output from a plurality of speakers are generally decoded by an audio signal processing device called an audio amplifier and processed to have an appropriate acoustic effect by digital signal arithmetic processing. Amplified to output. In such an acoustic system using a plurality of speakers, the position of the listener and the arrangement of each speaker are important for the formation of the sound field, but the arrangement of the listener and the speaker varies depending on the size of the installation room. Become. Therefore, in the conventional acoustic system, the user who is a listener listens to the sound and adjusts the volume of the audio signal of each channel, the left and right balance, the delay amount, etc. This adjustment is difficult and cumbersome for general users.

  For such a problem, a method and system for automatically adjusting the sound field by detecting the position of the listener by the acoustic system has been proposed (see Patent Document 1). As shown in FIG. 10, in the conventional acoustic system 10 shown in Patent Document 1, 18 is a remote control device held by a listener, 12 is a subwoofer that outputs low sound, and 13, 15 and 17 are around the listener. The arranged speakers, 11 is a basic device for amplifying a reproduction signal, and 14 and 16 are transmitter / receiver control units (TRCU) provided between the basic device 11 and the speakers 15 and 17, and are close to each speaker. Arranged.

  In the acoustic system 10, the basic device 11 operates as an audio amplifier that amplifies a sound signal to be reproduced to a level that the speaker outputs, and is connected to a plurality of speakers arranged around the listener. It is the same as a general home theater system. This sound system 10 is provided with TRCUs 14 and 16 between a basic device 11 and speakers 15 and 17, and indicates the physical position of all TRCUs by a remote control device 18 through which a listener can transmit and receive radio frequency signals. A feature is that the volume of each speaker is individually controlled.

  Control information such as speaker identification information exchanged between the remote control device 18 and the TRCUs 14 and 16 is transmitted / received by frequency shift modulation of a radio frequency signal of about 900 MHz. The distance between each speaker is calculated.

  Inside the TRCUs 14 and 16, a variable attenuator composed of resistors is provided. By comparing the accumulated propagation times of radio frequency signals repeatedly transmitted and received between the remote control device and each TRCU, By grasping the difference in distance to the speakers and changing the attenuation amount of the variable attenuator based on the distance information, each speaker is adjusted to have an appropriate volume balance.

As described above, in the sound system 10, the sound reproducing device that is trying to obtain the surround effect grasps the separation distance between the remote control device and each speaker by using the radio frequency signal, and adjusts the volume and balance of the speaker. By adjusting, I am trying to reproduce a realistic sound field.
Japanese Patent No. 3396838

  However, in the conventional acoustic system, the remote control device is used as a reference position, and the separation distance between the reference position and each speaker is measured. However, in order to measure the distance from the reference position to each speaker, it is about Since a 900 MHz radio frequency signal is used and a radio frequency signal must be repeatedly transmitted and received in order to grasp the difference in distance from 30 centimeters to several meters, the process of measuring the distance to each speaker is complicated. It takes time and cannot measure accurately. For this reason, it is difficult to say that a realistic sound field is formed even if the volume and balance of the speaker are adjusted based on the measured distance information.

  Furthermore, in the conventional acoustic system, consideration is not given to the positional relationship between speakers, which is important for creating a realistic sound field.

  The present invention has been made in view of this point, and an object thereof is to provide an acoustic system, an audio signal processing device, and a speaker that can automatically form a more realistic sound field.

  A first feature according to an embodiment of the present invention is that in an acoustic system, signal generation means for generating a pulse signal, and transmission / reception for wirelessly transmitting the pulse signal as a transmission signal and receiving a response pulse signal for the transmission signal Means, detecting means for detecting a response time until the transmission signal is transmitted and receiving the response pulse signal, and a calculation means for calculating a separation distance between the transmission / reception means and the speaker based on the response time; A speaker position measuring device obtained by the speaker position measuring device, a receiving device for receiving the transmission signal, and a response signal transmitting device for wirelessly transmitting the response pulse signal. And an audio signal supply device for supplying an audio signal to the speaker.

  The second feature of the embodiment of the present invention is that, in the audio signal processing device, an audio signal to be supplied to a speaker is formed, signal generation means for generating a pulse signal, and the pulse signal as a transmission signal is wirelessly transmitted. Transmitting and receiving means for receiving a response pulse signal for the transmission signal; detecting means for detecting a response time from transmission of the transmission signal to reception of the response pulse signal; and the transmission and reception means based on the response time; A speaker position measuring unit that calculates a separation distance from the speaker, and an audio signal supply unit that supplies an audio signal to the speaker based on the speaker position information obtained by the speaker position measuring unit. That is.

  The third feature of the embodiment of the present invention is that, in the loudspeaker, a receiving means for receiving a known pulse signal, and a response for wirelessly transmitting a response pulse signal after a certain time has elapsed after receiving the pulse signal. Signal transmission means.

  According to the present invention, an acoustic system, an audio signal processing device, and an audio system capable of automatically forming a sound field full of presence by measuring the position of a speaker with high accuracy and forming a sound field based on the position information, and A speaker can be provided.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the embodiment, the same components are denoted by the same reference numerals, and the description thereof will be omitted because it is duplicated.

(Embodiment 1)
First, the configuration of the acoustic system according to the present embodiment will be described with reference to FIG.

  As shown in FIG. 1, the acoustic system 20 includes an audio signal processing device 100, speakers 200-1 to 200-4, and a remote control device 300.

  The audio signal processing apparatus 100 decodes a multi-channel audio signal provided by a DVD, digital satellite broadcasting, or the like, and converts it into an audio signal to be output from a plurality of speakers 200 so as to obtain an appropriate acoustic effect for the listener. It has a function to do.

  Examples of sound effects appropriate for the listener include changing to a frequency characteristic that suits the listener's preference, such as high-frequency emphasis, and creating a realistic sound field. In particular, in order to form a realistic sound field, the arrival direction of sound from a plurality of speakers 200 arranged around the listener, the distribution and balance of decoded speech, and the like strongly influence each speaker 200. Accurate location information is important.

  Therefore, in the acoustic system 20, wireless communication using a pulse signal is used in order to automatically and accurately measure the position information of each speaker 200. For the communication using this pulse signal, for example, an ultra wide band (UWB) system or an ultra wide band wireless communication system can be used.

  The audio signal processing device 100 transmits a pulse signal to the speaker 200 and the remote control device 300, respectively. The speaker 200 and the remote control device 300 transmit a response pulse signal in response to the pulse signal from the audio signal processing device 100. The audio signal processing apparatus 100 receives the response pulse signal, and measures (detects) the response time from when the pulse signal is transmitted to when the response pulse signal is received. Then, the audio signal processing device 100 calculates the separation distance between the own device and each of the speaker 200 and the remote control device 300 that transmitted the response pulse signal based on the measured response time. A method for measuring the separation distance will be described later.

  As shown in FIG. 2, the audio signal processing device 100 includes a pulse signal generation unit 101 that generates a pulse signal, a transmission / reception unit 102 that wirelessly transmits the pulse signal as a transmission signal, and receives a response pulse signal corresponding to the transmission signal, A detection means for detecting a response time until a transmission pulse is transmitted and a response pulse signal is received; a position detection processing section 103 as a calculation means for calculating a separation distance between the transmission / reception section 102 and the speaker 200 based on the response time; And a sound field calculation processing unit 109 that supplies an audio signal to the speaker 200 based on position information of the speaker 200. The position detection processing unit 103 includes a detection unit 105 and a calculation unit 107.

  The pulse signal generation unit 101 generates a pulse signal having a short time width (short pulse signal) and sends it to the transmission / reception unit 102.

  The transmission / reception unit 102 transmits the pulse signal output from the pulse signal generation unit 101 to the speaker 200 or the remote control device 300 that is the target of the separation distance calculation, and the response pulse signal corresponding to the pulse signal is transmitted to the speaker 200 or the remote control device. Receive from 300. In addition, the transmission / reception unit 102 sends the pulse signal transmission timing information that transmitted the pulse signal and the response pulse signal timing information that received the response pulse signal corresponding to the pulse signal to the position detection processing unit 103.

  In the position detection processing unit 103, the detection unit 105 detects (measures) the response time from the transmission of the pulse signal to the reception of the response pulse signal from the pulse signal transmission timing information and the response pulse signal timing information. Based on the response time detected by the detection unit 105, the calculation unit 107 calculates a separation distance between the audio signal processing device 100 and the speaker 200 or the remote control device 300 that has transmitted the response pulse signal. The position detection processing unit 103 receives a pulse signal from the pulse signal generation unit 101, transmits the pulse signal to the speaker 200 or the like via the transmission / reception unit 102, and receives a response pulse signal via the transmission / reception unit 102. You may measure response time from the timing which the position detection process part 103 sent the pulse signal to the transmission / reception part 102, and the timing which received the response pulse signal from the transmission / reception part 102. FIG. The calculation of the separation distance is performed for all the speakers 200 and the remote control device 300 that constitute the acoustic system 20.

  The sound field calculation processing unit 109 uses the digital signal calculation processing based on the separation distance between the audio signal processing device 100 calculated by the calculation unit 107 and each of the speaker 200 and the remote control device 300. Adjust the volume balance, distribution, delay, frequency characteristics (spectrum), etc. Specifically, the sound field calculation processing unit 109 determines the volume of each speaker 200 based on the separation distance between the audio signal processing device 100 calculated by the calculation unit 107 and each of the speaker 200 and the remote control device 300. Various information such as balance, distribution, delay, and frequency characteristics (spectrum) are obtained. Then, the sound field calculation processing unit 109 generates a signal in which the obtained various information is added to the audio signal reproduced by the speaker 200, and transmits the signal to the speaker 200 via the transmission / reception unit 102.

  Here, the transmission means in the transmission / reception unit 102 is described as being shared for transmitting the audio signal and the pulse signal, but the present invention is not limited to this, and the audio signal transmission means. And pulse signal transmission means may be prepared separately. Further, by using pulse modulation for changing the position and polarity of the pulse for transmission of the audio signal, the transmission / reception unit 102 can be shared for position detection and audio transmission.

  As shown in FIG. 3, the speaker 200 includes a transmission / reception unit 201 as a reception unit that receives a transmission signal and a response signal transmission unit that wirelessly transmits a response pulse signal, and a reply between reception of the transmission signal and transmission of the response pulse signal. A reply interval adjusting unit 202 and a sound reproducing unit 203 are provided as means for adjusting the interval to a predetermined time.

  When the transmission / reception unit 201 receives the pulse signal from the audio signal processing apparatus 100, the transmission / reception unit 201 outputs the pulse signal to the reply interval adjustment unit 202, and the response pulse signal output from the reply interval adjustment unit 202 after a predetermined time is subjected to audio signal processing. It transmits to the apparatus 100. In addition, the transmission / reception unit 201 transmits a signal transmitted from the audio signal processing device 100 (including the audio signal and various information such as volume balance and distribution, delay, frequency characteristics (spectrum), etc. in each speaker 200) to the audio reproduction unit 203. Send it out.

  The reply interval adjustment unit 202 performs adjustment so that the reply interval until the transmission / reception unit 201 receives the pulse signal and transmits the response pulse signal becomes a predetermined time. For this reply interval adjusting unit 202, for example, a circuit such as a rectenna can be used as long as it has a configuration that instantaneously reflects a signal.

  The audio reproduction unit 203 reproduces the audio signal transmitted from the transmission / reception unit 201 based on various types of information such as volume balance, distribution, delay, frequency characteristics (spectrum), etc. in each speaker 200.

  As shown in FIG. 4, the remote control device 300 includes a control instruction unit 301 that remotely controls the audio signal processing device 100, a reception unit that receives a transmission signal, and a transmission / reception unit 302 as a transmission unit that wirelessly transmits a response pulse signal. And a reply interval adjustment unit 303.

  The control instruction unit 301 transmits a control signal for controlling the audio signal processing device 100 to the audio signal device 100 via the transmission / reception unit 302 in accordance with a user instruction. For example, when the control signal for starting the physical position measurement of the speaker 200 and the remote control device 300 is transmitted to the audio signal processing device 100, the physical signal measurement processing is started in the audio signal processing device 100. A pulse signal with a short time width generated by the pulse signal generation unit 101 is transmitted via the transmission / reception unit 102.

  When the transmission / reception unit 302 receives the pulse signal transmitted from the audio signal processing apparatus 100, the transmission / reception unit 302 outputs the pulse signal to the reply interval adjustment unit 303, and the response pulse signal output from the reply interval adjustment unit 303 after a predetermined time is received as the audio signal. Transmit to the signal processing apparatus 100.

  The reply interval adjustment unit 303 performs adjustment so that the reply interval until the transmission / reception unit 302 receives the pulse signal and transmits the response pulse signal becomes a predetermined time.

  Next, a method for measuring the separation distance between the audio signal processing device 100 and the speaker 200 or the remote control device 300 will be described with reference to FIG.

  First, a pulse signal S1 having a short time width of about several nanoseconds is transmitted from the transmission / reception unit 102 of the audio signal processing apparatus 100 to the speaker 200.

  Next, the pulse signal S1 is received by the transmission / reception unit 201 of the speaker 200 after time t1, and the reply pulse signal S2 is returned to the audio signal processing device 100 via the known reply processing time t2 (reply interval).

  Next, the reply pulse signal is received by the transmission / reception unit 102, and the position detection processing unit 103 measures the time t3 (response time) from the transmission of the pulse signal S1 to the reception of the response pulse signal S2.

The position detection processing unit 103 calculates the separation distance d using Equation 1 based on the response time t3, the time t1, and the reply interval t2.

  Here, the parameter c is the phase velocity of the electromagnetic wave, and is a value of about 300,000 kilometers per second. As shown in Equation 1, if the position detection processing unit 103 previously grasps the reply interval t2 in the speaker 200 or the remote control device 300 and measures the response time from transmission to reception of the short pulse signal, the speaker 200 Alternatively, the separation distance d to the remote control device 300 can be calculated.

  For example, if the response time t3 is 16 nanoseconds and the reply interval t2 is 10 nanoseconds, the separation distance d to the speaker 200 or the remote control device 300 is approximately 90 centimeters. When a general home is assumed, the distance from the audio signal processing device 100 to the speaker 200 or the remote control device 300 is about several tens of centimeters to several meters, and the one-way spatial propagation time t1 in pulse transmission is several nanometers. From seconds to tens of nanoseconds.

  Therefore, in order to accurately measure the response time t3 that is the timing difference between the transmission signal and the reception signal, it is desirable to shorten the reply interval t2 and use a short pulse signal having a time width of about several nanoseconds.

  In addition, the short pulse signal is single (the transmission cycle is infinite), or a signal having a cycle of several tens of nanoseconds or more is prevented from transmitting / receiving a plurality of pulses during the time t3, so that the timing is correct. It becomes easy to detect the difference. It is also effective to detect a timing difference by transmitting a plurality of short pulse signals having a known pattern and calculating a correlation with the received signal.

  In addition, since a plurality of speakers 200 and a remote control device 300 are normally present in the acoustic system 20, the distance between which speaker 200 or the remote control device 300 is measured prior to the above-described procedure for measuring the distance. It is necessary to specify what to do. Therefore, it is necessary to attach identification information unique to each speaker 200 and remote control device 300 first.

  Then, the identification information of the speaker 200 or the remote control device 300 to be measured is broadcast from the audio signal processing device 100 to each speaker 200 and the remote control device 300. Each speaker 200 and remote control device 300 receives the identification information and, if it matches the identification information of itself, determines that it is the measurement object and returns a response pulse signal to the received pulse signal. Is set. On the other hand, when the received identification information is not its own, a setting is made so as not to return the received pulse signal. By the above procedure, a response pulse signal is returned only from the speaker 200 or the remote control device 300 to be measured, and the distance from the speaker 200 or the remote control device 300 can be measured.

  As described above, in the sound system 20 of the present embodiment, the audio signal processing apparatus 100 detects a response time until a pulse signal is transmitted to the speaker 200 and a response pulse signal to the pulse signal is received, Based on this response time, the separation distance between the transmitting / receiving unit 102 and the speaker 200 is calculated.

  Therefore, since the pulse signal is transmitted and received in order to detect the response time used for calculating the separation distance, the separation distance is calculated with a certain degree of accuracy by exchanging the radio frequency signal multiple times. As compared with the above, the distance can be calculated accurately and easily in a short time, and the position of the speaker 200 can be grasped with high accuracy.

  Furthermore, since the audio signal processing apparatus 100 supplies an audio signal to the speaker 200 based on the obtained positional information of the speaker 200, it is possible to form a sound field full of presence.

  Furthermore, in the audio signal processing device 100, since the audio signal transmission unit and the pulse signal transmission unit are shared, the audio signal processing device 100 can be downsized. Further, when an audio signal is generated based on a pulse signal in the sound field calculation processing unit 109 of the audio signal processing device 100, the pulse signal generation unit used for generating the audio signal is used as a pulse for measuring a separation distance. The signal generator 101 can be shared, and the configuration of the audio signal processing apparatus 100 can be simplified.

  Further, in the acoustic system 20 of the present embodiment, the speaker 200 adjusts the reply interval from when the pulse signal is received to when the response pulse signal is transmitted to a sufficiently short time with respect to the response time. .

  Therefore, by setting the reply interval to a fixed time, the one-way time required for the pulse signal transmitted from the audio signal processing device 100 to reach the speaker 200 can be easily obtained, so that the separation distance can be easily calculated. can do. Furthermore, by making the reply interval sufficiently shorter than the response time and the one-way time, an error in the separation distance due to the reply interval error can be suppressed, so that the separation distance can be calculated with high accuracy.

  In addition, by using a short pulse signal with a time width of several nanoseconds for the pulse signal and response pulse signal, the transmission timing and reception timing of the pulse signal and response pulse signal can be accurately captured, so the separation distance is accurate. It can be calculated well.

(Embodiment 2)
The acoustic system 20A of the second embodiment has the same overall configuration as the acoustic system according to the first embodiment. However, the audio signal processing apparatus 100 in the acoustic system 20A includes a plurality of transmission / reception units such as a transmission / reception unit 102A and a transmission / reception unit 102B.

  A feature of the acoustic system 20A according to the second embodiment is that the two-dimensional positions of the speaker 200 and the remote control device 300 are accurately measured using a plurality of transmission / reception units included in the audio signal processing device 100.

  As shown in FIG. 6A, the audio signal processing apparatus 100 includes a transmission / reception unit 102A and a transmission / reception unit 102B, which are arranged apart from each other by a known interval d1.

  Then, the distance to the speaker 200 that is the position measurement target is measured for each of the transmission / reception unit 102A and the transmission / reception unit 102B using the method using the short pulse signal described in the first embodiment, and the separation distance d2 and the separation distance are measured. d3 is obtained.

Since the positions of the transmission / reception unit 102A and the transmission / reception unit 102B are known, the coordinate position of the speaker 200 can be specified from the separation distance obtained by measurement. For example, assuming the coordinate system shown in FIG. 6B where the center position of the audio signal processing apparatus 100 is the origin and the positions of the transmission / reception unit 102A and the transmission / reception unit 102B are arranged symmetrically with respect to the origin on the X axis, The coordinate x of the speaker 200 is calculated using Equation 2 from d1, d2, and d3.

In addition, the coordinate y of the speaker 200 is calculated using Equation 3 using the coordinate x calculated from Equation 2.

  In FIG. 6B, the coordinate y of the speaker 200 is a positive value, and the coordinate x is positive when d3 is larger than d2, and is negative when d3 is smaller. By such a simple calculation, the two-dimensional position of the speaker 200 can be specified from the separation distance measured by the short pulse signal. By obtaining two-dimensional position information for all the speakers 200 using the method as described above, the positional relationship between the speakers 200 can be grasped.

  Note that, here, an example in which the two transmission / reception units 102A and the transmission / reception unit 102B are built in the audio signal processing apparatus 100 is shown, but the present invention is not limited to this, and the transmission / reception unit 102A and the transmission / reception unit 102B As long as the coordinates are known at two points from the audio signal processing apparatus 100, the apparatus may be independent of the audio signal processing apparatus 100.

  In this way, the two-dimensional positions of the audio signal processing apparatus 100 and the speaker 200 are measured, but in order to form a sound field full of realism in the vicinity of the listener, the two-dimensional position of the listener is also grasped. There is a need to. Since the listener is assumed to be carrying or beside the remote control device 300, the two-dimensional position of the listener can be determined by measuring the position of the remote control device 300. . Note that the two-dimensional position of the remote control device 300 can also be measured in the same manner as the position measurement method of the speaker 200 described above.

  Based on the two-dimensional position information of the speaker 200 and the remote control device 300 (listener) obtained as described above, the sound field calculation processing unit 109 uses the digital signal calculation processing to output sound output from each speaker 200. Adjust the volume balance, distribution, delay, frequency characteristics (spectrum), etc. That is, various types of volume balance, distribution, delay, frequency characteristics (spectrum), and the like in each speaker 200 so that the sound field with the most realistic feeling can be formed at the position of the remote control device 300 where it is assumed that there is a listener. Ask for information. Then, the sound field calculation processing unit 109 generates a signal in which the obtained various information is added to the audio signal reproduced by the speaker 200, and transmits the signal to the speaker 200 via the transmission / reception unit 102.

  The speaker 200 that has received the audio signal amplifies and outputs the signal to a level at which the audio reproduction unit 203 can output the audio. The power source necessary for this is an AC outlet installed on the wall near the speaker 200. Or a battery such as a storage battery built in the speaker 200.

  As described above, in the acoustic system 20A of the second embodiment, the audio signal processing apparatus 100 includes the transmission / reception unit 102A and the transmission / reception unit 102B arranged at a known interval, and the transmission / reception unit 102A and the transmission / reception unit. The two-dimensional position of the speaker 200 is calculated based on the response time from when the pulse signal in each of 102B is transmitted to the speaker 200 until the response pulse signal is received. Specifically, the first separation distance between the transmission / reception unit 102A and the speaker 200 is calculated from the response time in the transmission / reception unit 102A, and the second separation distance between the transmission / reception unit 102B and the speaker 200 is calculated from the response time in the transmission / reception unit 102B. Based on the known interval between the transmission / reception unit 102A and the transmission / reception unit 102B, the first separation distance, and the second separation distance, the two-dimensional positional relationship between the transmission / reception unit 102A, the transmission / reception unit 102B, and the speaker 200 is calculated. Then, the audio signal processing apparatus 100 supplies an audio signal to each speaker 200 based on the two-dimensional position information obtained for each speaker 200.

  Therefore, since the pulse signal is transmitted and received in order to detect the response time used for calculating the separation distance, the separation distance is calculated with a certain degree of accuracy by exchanging the radio frequency signal multiple times. Compared to, it is possible to calculate the separation distance in a short time and accurately and easily. Furthermore, since a plurality of transmission / reception units are provided, and an accurate separation distance between each of the transmission / reception units and the speaker 200 can be obtained, the two-dimensional position of the speaker 200 can be accurately calculated. Furthermore, since the audio signal processing apparatus 100 supplies an audio signal to each speaker 200 based on the two-dimensional position information obtained for each speaker 200, it is possible to form a sound field full of presence.

  Further, with respect to the remote control device 300 assumed to be possessed by the listener or beside it, the two-dimensional position can be calculated with high accuracy in the same manner as the speaker 200, so that a plurality of speakers 200 can be obtained. Since the two-dimensional positional relationship between the listener and the listener can be obtained, a sound field full of realism can be formed in the vicinity of the listener.

(Embodiment 3)
The acoustic system 20B of the third embodiment shown in FIG. 7 has the same overall configuration as the acoustic system according to the first and second embodiments. However, the acoustic system 20B according to the third embodiment is characterized in that the speaker 200 and the remote control device 300 return a pulse signal having a pattern different from the pulse signal transmitted from the audio signal processing device 100 as a response pulse signal. Then, the new speech processing device 100 is to accurately distinguish between the reflected pulse signal reflected from the reflector such as the wall and the response pulse signal.

  In the present embodiment, there is a reflector 400 such as an object or a wall that reflects a pulse signal. In this case, the audio signal processing device 100 receives not only the response pulse signal returned from the speaker 200 or the remote control device 300 but also the reflected pulse signal that the pulse signal transmitted by the device itself is reflected by the reflector 400 and returns. There is a possibility that accurate separation distance measurement cannot be performed. In this embodiment, as a countermeasure against this, the speaker 200 or the remote control device 300 to be measured returns a response pulse signal by changing the pulse signal pattern based on the identification information of the own device.

  Here, for example, 4-bit identification information is added to the speaker 200 and the remote control device 300 so that they can be identified.

  In FIG. 7, identification information “1001” is added to the speaker 200. The single short pulse signal S <b> 1 transmitted by the audio signal processing apparatus 100 is received by the transmission / reception unit 201 of the speaker 200. The transmission / reception unit 201 inverts the polarity of the pulse according to the bit value of the identification information, generates a pulse train corresponding to the bit value of the identification information, and returns it as the response pulse signal S3.

  In addition, the single short pulse signal S1 transmitted by the audio signal processing apparatus 100 is reflected by the reflector 400 as a reflected pulse signal RS1.

  The transmission / reception unit 102 of the audio signal processing apparatus 100 receives the response pulse signal S3 and the reflected pulse signal RS1, and the response pulse signal S3 is separated from the pulse signal S1 so that it can be distinguished from the reflected pulse signal RS1. The pulse signals have different patterns. Specifically, the single short pulse signal S1 transmitted from the audio signal processing apparatus 100 is also reflected by the reflector 400 and mixed into the reception signal of the transmission / reception unit 102 as a single reflected pulse signal RS1, for example, By making the response pulse signal a pulse train, even if the reflected pulse signal RS1, which is a single pulse signal, is mixed, the response pulse signal portion can be determined.

  Further, in a normal case, the audio signal processing device 100 and the speaker 200 or the remote control device 300 are arranged at positions where they can see each other, and a wall or the like considered as the reflection object 400 is viewed from the audio signal processing device 100. It is assumed that the remote control device 300 is located farther away. For this reason, since the reflected pulse signal that becomes an obstacle tends to be received after the desired response pulse signal, it is easy to detect the desired response pulse signal.

  Further, it is conceivable that the response pulse signal returned from the speaker 200 or the remote control device 300 is reflected by the reflector 400 and reaches the audio signal processing device 100, but is reflected by the audio signal processing device 100 and arrives. Since the response pulse signal is received later in time than the response pulse signal that arrives directly, the audio signal processing apparatus 100 refers to the response pulse signal detected earliest in time for position measurement. Good.

  Further, in the audio signal processing apparatus 100, when the identification information of the speaker 200 that is the target of position measurement is known in advance, the correlation between the signal received by the transmitting / receiving unit 102 and the pulse train corresponding to the identification information of the target speaker 200 By performing calculation or the like, it is possible to easily detect the reception timing of the response pulse signal, and therefore it is possible to easily detect the time t3 required for the pulse transmission with the device that is the position measurement target. On the other hand, when the identification information of the speaker 200 whose position is to be measured is not known in advance in the audio signal processing device 100, the audio signal processing device 100 corresponds to the speaker 200 and the remote control device 300 under the acoustic system 20B. By storing the response pulse signal pattern to be stored and correlating the signal received by the signal transmission / reception unit 102 with all the stored response pulse signal patterns, the response pulse signal transmitted from any device is obtained. It is possible to determine whether there is any, and it is possible to easily detect the time t3 required for pulse transmission with the device whose position is to be measured.

  As described above, in the audio system 20B according to the present embodiment, the audio signal processing apparatus 100 detects a response time until a pulse signal is transmitted to the speaker 200 and a response pulse signal to the pulse signal is received. Based on the response time, a separation distance between the transmission / reception unit 102 and the speaker 200 is calculated. The speaker 200 transmits a pulse signal having a pattern different from that of the pulse signal from the audio signal processing apparatus 100 as a response pulse signal.

  Therefore, since the pulse signal transmitted from the audio signal processing apparatus 100 is reflected by the reflecting object and the pattern of the response pulse signal is different from the pattern of the reflected pulse signal received by the audio signal processing apparatus 100, the reflected pulse The signal and the response pulse signal can be distinguished easily and accurately. As a result, the response time can be accurately detected, so that the position information of the speaker 200 can be accurately grasped.

  Furthermore, by changing the pattern of the pulse signal and the response pulse signal and assigning a unique (unique) pattern to each speaker 200 that is the transmission source of the response pulse signal with respect to the pattern of the response pulse signal, the audio signal processing device In 100, the reflected pulse signal and the response pulse signal can be distinguished easily and accurately, and the response pulse signal transmitted from which speaker 200 is easily determined by referring to the pattern of the response pulse signal. Can do.

(Embodiment 4)
The acoustic system 20C of the fourth embodiment shown in FIG. 8 has the same overall configuration as the acoustic system according to the first to third embodiments. However, as illustrated in FIG. 9, the speaker 200 </ b> C in the acoustic system 20 </ b> C further includes a pulse signal generation unit 211, a detection unit 212, and a calculation unit 213.

  As shown in FIG. 9, the pulse signal generation unit 211 generates a pulse signal based on the control signal from the audio signal processing device 100 and sends it to the transmission / reception unit 201.

  The transmission / reception unit 201 transmits the pulse signal from the pulse signal generation unit 211 to the device that is the target of the measurement distance, and receives the response pulse signal from the device.

  The detection unit 212 transmits a pulse signal, detects a response time until the response pulse signal, and notifies the audio signal processing apparatus 100 via the transmission / reception unit 201.

  As shown in FIG. 8, there is a shield 401 that prevents wireless transmission. The audio signal processing apparatus 100 grasps in advance the number of all the speakers 200C and the identification numbers of each speaker, attempts direct wireless communication with each speaker 200C, and transmits and receives the speaker 200C from the transmission / reception unit 102. The position is measured directly from the response time from transmission of the pulse signal to reception of the response pulse signal. For the speaker 200C that cannot communicate, measurement of the position is attempted through the speaker 200C that can communicate.

  More specifically, first, the audio signal processing apparatus 100 tries to perform wireless communication with all the speakers 200 </ b> C and performs position measurement processing. However, the pulse signal transmitted from the audio signal processing apparatus 100 cannot reach the speaker 200C-3 by the shield 401, and the audio signal processing apparatus 100 directly measures the position of the speaker 200C-3. I can't. On the other hand, the positions of speaker 200C-1 and speaker 200C-2 that were able to communicate can be measured by the method described in Embodiments 1 to 3.

  Therefore, next, the audio signal processing apparatus 100 controls the speaker 200C-1 to transmit and receive the short pulse signal and the response pulse signal to and from the speaker 200C-3.

  Then, the speaker 200C-1 measures a response time until the speaker 200C-3 transmits a pulse signal and receives a response pulse signal, and notifies the audio signal processing apparatus 100 of the response time. Similarly, the speaker 200C-2 also measures the response time with the speaker 200C-3 and notifies the audio signal processing apparatus 100 of the response time.

  The audio signal processing apparatus 100 calculates the separation distance d4 between the speakers 200C-1 and 200C-3 and the separation distance d5 between the speakers 200C-2 and 200C-3 based on the notified response time.

  Since the audio signal processing apparatus 100 can grasp the position coordinates of the speakers 200C-1 and 200C-2 and can calculate the separation distance d4 and the separation distance d5, the separation distance between the speakers 200C-1 and 200C-2. The position coordinates of the speaker 200-3C can be measured based on the separation distance d4 and the separation distance d5.

  In the acoustic system 20C according to the present embodiment, the speaker 200C capable of direct communication measures the response time in order to measure the position of the speaker 200C to which the audio signal processing device 100 cannot directly communicate, It has been described that the audio signal processing apparatus 100 calculates the separation distance based on the response time. However, the present invention is not limited to this, and the calculation unit 213 included in the speaker 200C calculates the separation distance based on the response time, and notifies the audio signal processing apparatus 100 of the calculated separation distance. Also good.

  When the audio signal processing device 100 cannot directly communicate with the remote control device 300, the position of the remote control device 300 is measured by the same method as that for measuring the position of the speaker 200C-3. can do.

  Similarly to the speaker 200 </ b> C, the remote control device 300 is also provided with a pulse signal generation unit, a detection unit, and a calculation unit. It is possible to control to notify the response time or the separation distance as in the case of the speaker 200C-1 and the speaker 200C-2.

  As described above, in the acoustic system 20C of the present embodiment, the speaker 200C detects the response time until the pulse signal is transmitted to the other speaker 200C and the response pulse signal for the pulse signal is received. Then, in the audio signal processing device 100, a separation distance between the speaker 200C and another speaker 200C is obtained based on the response time detected by the speaker 200C.

  Therefore, for example, even when there is a speaker 200C in which the audio signal processing apparatus 100 cannot directly communicate pulse signals and the position information cannot be obtained directly, the audio signal processing apparatus 100 By obtaining the separation distance from the other speaker 200C that can communicate directly with each other, it is possible to obtain the positional information of the speaker 200C that cannot communicate directly with the audio signal processing device 100.

  INDUSTRIAL APPLICABILITY The acoustic system, the audio signal processing device, and the speaker of the present invention have an effect that a more realistic sound field can be automatically formed, and a theater system, an audio system, and a personal computer system having a multimedia function. And a sound system constructed in a concert hall or the like, an audio signal processing device constituting these, and a speaker.

1 is an overall configuration diagram of an acoustic system according to Embodiment 1 of the present invention. The block diagram which shows the structure of the audio | voice signal processing apparatus of FIG. The block diagram which shows the structure of the speaker of FIG. The block diagram which shows the structure of the remote control apparatus of FIG. Diagram for explaining the measurement method of the separation distance (A) The figure which shows the partial structure of the acoustic system which concerns on Embodiment 2, (b) The figure which uses for description of the measuring method of two-dimensional position information The figure which uses for the description of the partial structure of the acoustic system which concerns on Embodiment 3, and its operation | movement The figure which uses for the description of the partial structure of the acoustic system which concerns on Embodiment 4, and its operation | movement. The block diagram which shows the structure of the speaker of FIG. Overall configuration diagram of a conventional acoustic system

Explanation of symbols

20, 20A, 20B, 20C Acoustic system 100 Audio signal processing device 101, 211 Pulse signal generation unit 102, 102A, 102B, 201, 302 Transmission / reception unit 103 Position detection processing unit 105, 212 Detection unit 107, 213 Calculation unit 109 Sound field Arithmetic processing unit 200, 200C Speaker 202, 303 Reply interval adjustment unit 203 Voice reproduction unit 300 Remote control device 301 Control instruction unit

Claims (16)

A signal generation means for generating a pulse signal; a transmission / reception means for wirelessly transmitting the pulse signal as a transmission signal; receiving a response pulse signal for the transmission signal; and A loudspeaker position measuring device comprising: detecting means for detecting response time; and calculating means for calculating a separation distance between the transmitting / receiving means and the speaker based on the response time;
A speaker having receiving means for receiving the transmission signal and response signal transmitting means for wirelessly transmitting the response pulse signal;
An audio system comprising: an audio signal supply device that supplies an audio signal to a speaker based on speaker position information obtained by the speaker position measurement device. The transmission / reception means includes first and second transmission / reception means arranged at a known interval from each other,
The acoustic system according to claim 1, wherein the calculation unit calculates a two-dimensional position of a speaker based on the response time in the first and second transmission / reception units. The speaker is
Means for adjusting a reply interval between reception of the transmission signal and transmission of the response pulse signal to a predetermined time;
The acoustic system according to claim 1, wherein the calculation unit calculates the separation distance based on the response time and the reply interval. A plurality of the speakers are provided,
Each speaker has transmission means for wirelessly transmitting a pulse signal;
Detecting means for detecting a response time until the pulse signal is transmitted and a response pulse signal is received;
Notifying means for notifying the response time to the speaker position measuring device;
The acoustic system according to claim 1, comprising:   The acoustic system according to claim 1, wherein the response signal transmission unit wirelessly transmits a pulse signal having a pattern different from the transmission signal from the speaker position measurement device as the response pulse signal.   The response signal transmitting means wirelessly transmits, as the response pulse, a unique pulse signal to each speaker having a pattern different from that of the transmission signal from the speaker position measurement device. Acoustic system. A remote control device further comprising: a remote control unit for remotely controlling the audio signal supply device; a receiving unit for receiving the transmission signal; and a transmission unit for transmitting a response signal for wirelessly transmitting the response pulse signal;
The calculation means calculates a two-dimensional position of the remote control device in addition to a two-dimensional position of a speaker based on the response times in the first and second transmission / reception means. Item 3. The acoustic system according to Item 2. The speaker position measurement device is mounted on the audio signal supply device,
2. The acoustic system according to claim 1, wherein a transmitting means among the transmitting / receiving means is shared to transmit the audio signal and the pulse signal.   The acoustic system according to any one of claims 1 to 8, wherein the signal generating unit generates a short pulse signal having a time width of several nanoseconds as the pulse signal.   The acoustic system according to claim 9, wherein the signal generation unit generates the short pulse signal with an interval of at least several tens of nanoseconds. An audio signal processing device for forming an audio signal to be supplied to a speaker,
A signal generation means for generating a pulse signal; a transmission / reception means for wirelessly transmitting the pulse signal as a transmission signal; receiving a response pulse signal for the transmission signal; and A speaker position measuring unit comprising: a detecting unit that detects a response time; and a calculation unit that calculates a separation distance between the transmission / reception unit and the speaker based on the response time;
An audio signal processing apparatus comprising: an audio signal supply unit that supplies an audio signal to the speaker based on the speaker position information obtained by the speaker position measurement unit. The transmission / reception means includes first and second transmission / reception means arranged at a known interval from each other,
12. The audio signal processing apparatus according to claim 11, wherein the calculating unit calculates a two-dimensional position of a speaker based on the response times in the first and second transmitting / receiving units.   The audio signal processing apparatus according to claim 11, wherein a transmission unit of the transmission / reception unit is shared to transmit the audio signal and the pulse signal. Receiving means for receiving a known pulse signal;
And a response signal transmitting means for wirelessly transmitting the response pulse signal after a predetermined time from receiving the pulse signal.   The speaker according to claim 14, wherein the response signal transmission unit wirelessly transmits a pulse signal having a pattern different from the known reception pulse as the response pulse. Transmitting means for wirelessly transmitting the known pulse signal to another speaker;
Detecting means for detecting a response time until the known pulse signal is transmitted to the other speaker and the response pulse signal is received;
Notification means for notifying the response time;
The speaker according to claim 14, comprising:

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