JPH0847099A - Setting method for speaker delay time - Google Patents

Abstract

PURPOSE:To provide the setting method for a speaker delay time by which an arrival time detection error of an impulse reply signal from each speaker is suppressed small and a delay time of delay devices is more accurately set in comparison with a conventional delay time setting method. CONSTITUTION:In the case of setting a speaker delay time, a detection control means 34 switches a changeover means 23 to the position of terminals 23b-23c and an impulse signal generated from a sound source 11 is inputted as it is to a woofer 21. Then the arrival time of the reply signal with respect to the impulse signal outputted from the woofer 21 is detected and the delay time is set respectively by delay devices 13-15 is set based on the detection result.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of setting a speaker delay time, and more particularly, to a speaker in an audio system provided with a plurality of speakers arranged in a passenger compartment or the like.
F. Regarding the method of setting the delay time.

[0002]

2. Description of the Related Art As an example, a method of setting a speaker delay time in an audio system provided in a vehicle compartment and provided with three speakers will be briefly described. Figure 5 shows the above
It is a plane sectional view showing roughly a vehicle equipped with a Dio system. As shown in FIG. 5, generally, a speaker is often arranged in the front left door 71, the front right door 72, and the rear parcel tray 74 in the vehicle compartment. In the case of such a three-speaker system, the front left door 71 is a full range speaker and a speaker for the front Lch (hereinafter,
FL speakers 19), front front right door 72 are full range speakers, front Rch speakers (hereinafter referred to as FR speakers) are attached to the inside of the vehicle, respectively. -The cell tray 74 has a low-range woofer-
A fast speaker (hereinafter referred to as a woofer) 21 is attached.

An operator in which each speaker is arranged as described above.
When measuring and setting the speaker delay time in the Dio system, one or a plurality of microphones (not shown) are arranged at the listening position of the driver's seat 73, and the microphones output signals from the respective speakers. A signal sound is recorded and the arrival time of the signal sound is measured. Then, based on the speaker having the latest arrival time as a reference (delay time is set to zero), the arrival time of each remaining speaker is equal to the arrival time of the latest speaker, The delay time of each of the remaining speakers is set. Next, the above content will be specifically described with reference to FIG.

FIG. 6 is a schematic diagram showing a signal waveform when an impulse signal generated by a sound source is output from each speaker, with the vertical axis representing amplitude and the horizontal axis representing time. (A) is FR
The signal waveform of the speaker 20 is shown, (b) shows the signal waveform of the FL speaker 19, and (c) shows the signal waveform of the woofer 21. As shown in FIG. 6, FR speaker 2
The signal sound from 0 reaches the listening position fastest, the signal sound from the FL speaker 19 arrives next, and finally the signal sound from the woofer 21 arrives. Therefore, in this case, the woofer 21 serves as a reference, and the delay time thereof is set to zero. Then, the delay time of the FL speaker 19 is set to A and the delay time of the FR speaker 20 is set to B.

[0005]

However, when the delay time is set based on the signal waveform output from each speaker according to the frequency characteristic of each speaker as described above,
There is a problem that it is difficult to set the delay time accurately. The reason will be described with reference to FIG. (A) is a waveform diagram schematically showing the impulse response signals of the full-speaker FL speakers 19 and FR speakers 20, and (b) is the impulse response signal of the woofer 21. 3 is a waveform diagram schematically showing FIG.

When measuring the arrival time of the impulse response signal from each speaker, the threshold level C _th is set in order to avoid erroneous detection due to the noise levels C _N0 and C _N1 as shown in FIG. Then, the time when the impulse response signal reaches the threshold level C _th is detected as the arrival time of the response signal. However, in that case, in the FL speaker 19 and the FR speaker 20, although the actual time is t ₀ , the time t ₁ is detected as the arrival time of the response signal, and the time T _01. A detection error will occur. Further, in the woofer 21, although the actual time is t ₂ , the time t ₃ is detected as the arrival time of the response signal, which causes a detection error of time T ₂₃ . In the case of the woofer 21, since the high frequency band is cut and the impulse response signal has a gentle waveform, the detection error becomes considerably large. On the other hand, in the case of the full range speaker such as the FL speaker 19 and the FR speaker 20, the detection error is relatively small because the impulse response signal rises quickly. However, even in the case of a full range speaker, the detection error increases as the range extends to the lower range.

As can be seen from the above, when the arrival time is detected on the basis of the signal waveform output according to the frequency characteristics of each speaker and the delay time is set based on the detection result, There is a problem that the delay time cannot be set accurately. If the delay time of each speaker cannot be accurately set, the frequency characteristics may be disturbed or the sound image may be biased due to the difference in the arrival times of voices.

The present invention has been made in view of the above-mentioned problems, and it is possible to suppress the arrival time detection error of the response signal from each speaker to be small, and the delay time for each speaker can be reduced as compared with the conventional setting method. It is an object of the present invention to provide a method for setting the speaker delay time that can set the value more accurately.

[0009]

In order to achieve the above object, the method (1) for setting the speaker delay time according to the present invention is as follows.
Emits M-sequence signals or impulse signals from the sound source,
The response signal from each speaker to the signal is recorded by the microphone arranged at the listening position, and the arrival time of the response signal is detected after detecting the arrival time of the response signal from each speaker to the microphone. In the speaker delay time setting method for setting the delay time of the delay device in each speaker so that the values become equal, a speaker that cuts high frequencies such as woofers is used.
It is characterized in that the signal emitted from the sound source is directly input to the power source without being cut in the high frequency range, the arrival time is detected, and the speaker delay time is set based on the detection result.

In the method (2) of setting the speaker delay time according to the present invention, the M-sequence signal or the impulse signal is emitted from the sound source, and the microphone arranged at the listening position outputs the signal from each speaker to the signal. After recording the response signal and detecting the arrival time of the response signal from each of the speakers to the microphone, the delay time of the delay device of each speaker is set so that the arrival times of the response signals become equal. Speed
In the method of setting the delay time, the signal emitted from the sound source is input to a speaker that cuts high frequencies such as a woofer through a filter other than the LPF to detect the arrival time, and the detection is performed. It is characterized in that the speaker delay time is set based on the result.

In the method (3) of setting the speaker delay time according to the present invention, the M-sequence signal or the impulse signal is emitted from the sound source, and the microphone arranged at the listening position outputs the signal from each speaker to the signal. After recording the response signal and detecting the arrival time of the response signal from each of the speakers to the microphone, the delay time of the delay device of each speaker is set so that the arrival times of the response signals become equal. Speed
In the method for setting the delay time, a signal that is emitted from the sound source is input to a speaker that handles a mid range such as a squaker and a full range by detecting a arrival time through a filter other than an LPF, and the detection time is detected. It is characterized in that the speaker delay time is set based on the result.

[0012]

[Action]

Speaker delay time setting method (1) Normally, LP is used for a speaker that cuts high frequencies such as woofers.
A signal emitted from a sound source is input through F (low-pass filter). On the other hand, the speed according to the above method
In the case of the power delay time setting method (1), the signal emitted from the sound source is directly input to the speaker that cuts the woofer high frequency range without passing through the LPF.
As a response signal to the above signal, a response signal substantially equal to that in the case of a full range or a squaker speaker is output from the fa. That is, in the conventional speaker delay time setting method, the response signal in the woofer is as shown in FIG.
Although the waveform has a gentle waveform as shown in (b), in the speaker delay time setting method (1), the response signal is a full range or a squeeze speaker even in the case of a woofer.
As in the case of (f), the waveform has a steep rise as shown in FIG. This makes it possible to reduce the detection error of the arrival time and more accurately set the delay time for each speaker.

Speaker delay time setting method (2) The signal emitted from the sound source is input to the speaker that cuts the woofer iso-high range through a filter other than the LPF, and the woofer The signal from the sound source is input to the without being cut in the middle and high frequencies. As a result, the
The response signal of the signal from the signal signal has a steep rising waveform as shown in FIG. 7A as in the case of the method (1) of setting the speaker delay time. It is possible to reduce the detection error of the arrival time of the above, and it is possible to more accurately set the delay time for each speaker.

Speaker delay time setting method (3) For a speaker handling a mid range such as a speaker and a full range, L is set.
A signal emitted from the sound source is input through a filter other than PF. Therefore, the low-frequency cut signal from the signal emitted from the sound source is input to the speaker that handles the mid-range such as the speaker and the full range. This further assures a steep rise in the response signal to the signal emitted from the sound source of the speaker that handles the midrange such as the speaker and the full range.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a method for setting a speaker delay time according to the present invention will be described below with reference to the drawings. FIG. 1 shows each speaker using the method for setting the speaker delay time according to the first embodiment.
It is the block diagram which showed roughly the delay time setting system 100 which sets the delay time of power. The delay time setting system 100 shows a case where a signal emitted from a sound source is processed in analog.

In FIG. 1, reference numeral 11 denotes a sound source such as a CD, and the L signal and the R signal are outputted from the sound source 11, and the L signal is outputted from the FL speaker 19 through the delay device 13 and the amplifier 16. The R signal is output from the FR speaker 20 via the delay device 14 and the amplifier 17. Further, the adder 12 sums the L signal and the R signal, and the output side of the adder 12 is connected to the delay device 15. The output side of the delay device 15 is connected to the terminal 23b of the switching means 23 and the LPF 22 is connected.
Is also connected to the terminal 23a of the switching means 23 via
The terminal 23c of the switching means 23 is connected to the woofer 21 via the amplifier 18.

On the other hand, the FL speakers 19 and F are provided at the listening position.
A microphone 33 for recording a (sound) signal output from the R-speaker 20 and the woofer 21 is arranged, and the signal recorded by the microphone 33 is output from each speaker based on the signal. The detection / control means 34 which detects the arrival time of the signal and sets the delay times of the delay devices 13 to 15 based on the detection result is input. Also,
The detection / control means 34 also controls switching of the switching means 23.

In the delay time setting system 100 configured as described above, when the system 100 is used as a normal audio system, the detection / control means 3 is used.
The switching means 23 is switched to the terminals 23a-23c side by 4 and the LPF 2 is provided between the delay device 15 and the amplifier 18.
2 is inserted. Therefore, in a normal case, since the audio signal output from the sound source 11 is transmitted from the delay unit 15 to the amplifier 18 and the woofer 21 via the LPF 22, a high-frequency cut audio signal from the audio signal is amplified by the amplifier 18.
After being amplified by, it is output from the woofer 21.

On the other hand, in the delay time setting mode, the detecting / controlling means 34 switches the switching means 23 to the terminals 23b-23c side. Therefore, in this case, the signal output from the sound source 11 is output from the delay device 15 to the LP.
It is transmitted to the amplifier 18 through the through without passing through the F22, and is output from the amplifier 18 to the woofer 21. Therefore, when an impulse signal is emitted from the sound source 11, the signal is directly input to the woofer 21.
The response signal to the above signal has a waveform with a steep rise, which is almost the same as the response signals in the FL speaker 19 and the FR speaker 20. Thereby, the arrival time detection error of the response signal in the woofer 21 can be reduced. The arrival time of the response signal at the woofer 21 thus detected and the FL speaker 19 and the FR speaker 20 detected in the same manner as in the conventional case.
The detection / control means 34 sets the delay time in each of the delay devices 13 to 15 so that the arrival times of the respective speakers are equal based on the response signals in FIG. Therefore, if the delay time of each delay device is set based on the speaker delay time setting method according to the first embodiment, the delay time in the delay devices 13 to 15 can be set more accurately than in the conventional setting method. Therefore, it is possible to more appropriately correct the disturbance of the frequency characteristic and the bias of the sound image caused by the difference in the arrival time of the sound from each speaker.

In the first embodiment described above, detection /
The case where the delay times of the delay devices 13 to 15 are automatically set by the control means 34 has been shown, but in another embodiment, detection / detection
The delay time of the delay devices 13 to 15 may be manually set based on the arrival time from each speaker detected by the control means 34.

Next, a method of setting the speaker delay time according to the second embodiment will be described. FIG. 2 is a block diagram schematically showing a delay time setting system 200 for setting the delay time of each speaker using the method for setting the speaker delay time according to the second embodiment. The delay time setting system 200 shows a case where a signal emitted from a sound source is processed digitally.

An L signal and an R signal are output from a sound source 11 such as a CD, and the L signal and the R signal are output from the A / D converter 4.
After being input to 1 and converted to a digital signal, DSP4
It is adapted to be inputted to an equalizer 43 and an equalizer 44 which are internally provided in FIG. Further, the adder 12 provided in the DSP 42 creates a sum signal of the digitally converted L signal and the digitally converted R signal, and the sum signal is input to the equalizer 45. There is. The L signal (or R signal) converted into the digital signal is equalized by the equalizer 43 (or the equalizer 4).
4) and D via the delay device 46 (or the delay device 47)
The signal is output from SP42, input to the D / A converter 39, and converted into an analog signal. On the other hand, the sum signal is
Equalizer 45, digital filter 49 and delay device 48
Is output from the DSP 42 via the D / A converter 3
9 is input and converted into an analog signal. The L signal converted into an analog signal by the D / A converter 39 is amplified by the amplifier 16 and then input to the FL speaker 19, where R
The signal is amplified by the amplifier 17 and then input to the FR speaker 20, and the sum signal is amplified by the amplifier 18 and then transmitted to the woofer 2.
1 is input.

The voices output from the FL speaker 19, the FR speaker 20, and the woofer 21 are recorded by the microphone 33 arranged at the listening position, and then, based on the signal received from the microphone 33. -The arrival time of the signal from the power source is detected, and the signal is input to the detection / control means 50 which sets the delay times of the delay units 46 to 48 based on the detection result. Further, the coefficient of the digital filter 49 is controlled by the detection / control means 50.

In the delay time setting system 200 configured as described above, when the system 200 is used as a normal audio system, the detection / control means 5 is used.
A value of 0 sets the coefficient of the digital filter 49 to the coefficient for LPF. Therefore, in a normal case, the audio signal from which the high frequency components are removed from the audio signal output from the sound source 11 is amplified by the amplifier 18 and then input to the woofer 21.

On the other hand, in the case of the delay time setting mode,
The equalizer 45 and the delay device 48 by the detection / control means 50.
The coefficient of the digital filter is set so that the area between and becomes transparent. Therefore, in the delay time setting mode, the paths from the generation of the sound source 11 to the output to each speaker are the same for the L signal, the R signal and the sum signal. As a result, when the impulse signal is generated from the sound source 11, the woofer 21 also causes the FL speakers 19 and F.
A response signal having substantially the same waveform as the response signal to the signal output from the R-speaker 20 is output. Since the waveform of the response signal has a steep rise as shown in FIG. 7A, the detection error of the arrival time of the response signal output from the woofer 21 is larger than that in the conventional detection method. Can be made smaller. Based on the arrival time of the response signal at the woofer 21 thus detected and the arrival time of the response signal at each of the FL speaker 19 and the FR speaker 20 detected in the same manner as in the prior art. So that the arrival times of the response signals from the respective speakers become equal, the detection / control means 50 delays the delay circuit 46.
A delay time of ~ 48 is set. Therefore, Example 2
If the delay time of each speaker is set by the speaker delay time setting method according to (1), the delay times of the delay units 46 to 48 can be set more accurately than in the case of setting by the conventional setting method. Therefore, it is possible to more appropriately correct the disturbance of the frequency characteristics and the deviation of the sound image caused by the difference in the arrival time of the sound from each speaker.

In the method of setting the speaker delay time according to the second embodiment, the case where the detection / control means 50 automatically sets the delay time in the delay units 46 to 48 has been described. In another embodiment, the detection / control means 50
Alternatively, the delay times of the delay units 46 to 48 may be manually set based on the arrival time of the response signal detected by the respective speakers.

Next, a method of setting the speaker delay time according to the third embodiment will be described. FIG. 3 is a delay time setting system 300 using the speaker delay time setting method according to the third embodiment.
It is the block diagram which showed roughly. The delay time setting system 300 shows the case where the audio signal output from the sound source is processed in analog.

The configuration of the delay time setting system 300 is shown in FIG.
The difference from the configuration of the delay time setting system 100 shown in FIG. A BPF (bandpass filter) 51 and a switching unit 55 are provided between the delay unit 13 and the amplifier 16, the output side of the delay unit 13 is connected to a terminal 55a of the switching unit 55, and the switching unit is also provided via the BPF 51. It is also connected to the terminal 55b of 55. In addition, the BPF 52 is provided between the delay device 14 and the amplifier 17.
And the switching means 56 is interposed, the output side of the delay device 14 is connected to the terminal 56a of the switching means 56, and
It is also connected to the terminal 56b of the switching means 56 via the BPF 52. Further, a BPF 53 is interposed between the output side of the delay device 15, the switching means 23 and the terminal 23b. In addition, the detection / control means 34 is a detection / control means 35.
And the delay devices 13 to 15 and the switching means 55 to 5
6. The switching means 23 is controlled by the detection / control means 35.

In the delay time setting system 300 configured as described above, when the system 300 is used as a normal audio system, the detection / control means 3 is used.
5, the switching means 55 moves to the terminals 55a-55c side,
The switching means 56 is switched to the terminals 56a-56c side, and the switching means 23 is switched to the terminals 23a-23c side. That is, the circuit configuration is exactly the same as the normal case in the delay time setting system 100.

On the other hand, in the delay time setting mode,
The detection / control means 35 causes the switching means 55 to change to the terminal 55.
The switching means 56 has terminals 56b-56 on the b-55c side.
Switching to the c side, a BPF 51 is interposed between the delay device 13 and the amplifier 16, and a BPF 52 is interposed between the delay device 14 and the amplifier 17. Further, the detection / control means 35
The switching means 23 is switched to the terminals 23b-23c side by the BPF 53 between the delay device 15 and the amplifier 18.
Is installed. Therefore, the delay time setting system 300
In the case of, when an impulse signal is generated from the sound source 11,
FL speaker 19, FR speaker 20, and woofer 21
A signal from which the low-frequency components have been removed by the BPFs 51 to 54 is input to each of the. This allows the FL speaker 19 and the FR speaker 2 for the impulse signal.
A steep rise of the response signal of 0 is ensured, and a response signal having a steep rise is output from the woofer 21 as in the case of the FL speaker 19 and the FR speaker 20. To be done. Therefore, the detection / control means 35 can suppress the detection error when detecting the arrival time of the response signal from each speaker. Based on the arrival times from the respective speakers thus detected, the detection / control means 35 sets the delay times of the delay devices 13 to 15 so that the arrival times become equal. Therefore, if the delay time of each delay device is set by the method for setting the speaker delay time according to the third embodiment, the detection error can be suppressed to be smaller than that of the conventional setting method. Since the delay time of 15 can be set more accurately, it is possible to more appropriately correct the disturbance of the frequency characteristics and the deviation of the sound image caused by the difference in the arrival time of the sound from each speaker.

In the third embodiment, the detection / control means 35 automatically sets the delay times of the delay devices 13 to 15, but in another embodiment, the detection / control means 35 detects the delay time. The delay time may be manually set based on the arrival time from each of the speakers. In another embodiment, BPF51, BPF5
2 or BPF 53 may be partially or entirely replaced by HPF (high-pass filter).

Next, a method of setting the speaker delay time according to the fourth embodiment will be described. FIG. 4 is a delay time setting system 400 using the speaker delay time setting method according to the fourth embodiment.
It is the block diagram which showed roughly. The delay time setting system 400 shows a case where a signal output from a sound source is digitally processed.

The delay time setting system 400 is different from the delay time setting system 200 shown in FIG. 2 in the following points. The detection / control means 50 serves as the detection control means 65, the digital filter 49 serves as the digital filter 63, the digital filter 61 is interposed between the equalizer 43 and the delay device 46, and the digital filter 61 is provided between the equalizer 44 and the delay device 47. The filter 62 is interposed,
The digital filters 61 to 63 are controlled by the detection / control means 65. In addition, delay devices 46-4
8 is also controlled by the detection / control means 65.

In the delay time setting system 400 configured as described above, when the system 400 is used as an ordinary audio system, it is connected between the equalizer 43 and the delay device 46 and between the equalizer 44 and the delay device 47. The coefficients of the digital filter 61 and the digital filter 62 are set by the detection / control means 65 so that the space between them becomes transparent. In addition, the coefficient of the digital filter 63 is LP
It is set to the coefficient for F. That is, even in the delay time setting system 400, in the normal case, the settings are set so that the delay time setting system 200 has the same functional configuration as the normal case in the delay time setting system 200.

On the other hand, in the case of the delay time setting mode,
The detection / control means 65 controls the digital filters 61 to 63.
Are set so that each of them becomes BPF. Therefore, in the case of the delay time setting system 400, the sound source 11
The signals from which the low-frequency components have been removed by the digital filters 61 to 63, which have become BPF from the impulse signal generated in step S1, are input to each speaker. Thereby, the FL speaker 19 and the FR speaker for the impulse signal are
The steep rise of the response signal of the ker 20 is ensured, and the woofer 21 outputs a response signal having a steep rise as in the case of the FL speaker 19 and the FR speaker 20. . Therefore, the detection / control means 65 can reduce the detection error when detecting the arrival time of the response signal from each speaker. Based on the arrival times from the respective speakers thus detected, the detection / control means 65 sets the delay times of the delay units 46 to 48 so that the arrival times become equal. Therefore, if the delay time of each speaker is set by the method for setting the speaker delay time according to the fourth embodiment, the detection error can be suppressed to a small extent as compared with the case of setting by the conventional setting method. Since the delay times of the devices 46 to 48 can be set more accurately, it is more appropriate to correct the disturbance of the frequency characteristics and the deviation of the sound image caused by the difference in the arrival time of the sound output from each speaker. Can be done.

In the fourth embodiment described above, the case where the delay times of the delay units 46 to 48 are automatically set by the detection / control means 65 has been described, but in another embodiment, the detection / control means is provided. The delay time may be manually set based on the arrival time from each speaker detected at 65. Further, regarding the setting of the coefficient of the digital filter in the delay time setting mode, the case where the coefficient is set so that the digital filters 61 to 63 have the BPF is shown in the fourth embodiment, but in another embodiment, The coefficients may be set so that some or all of the digital filters 61 to 63 have HPF.

Further, in the above-described Embodiments 1 to 4, the case where one microphone 33 is used as a microphone for recording the response signal output from each speaker is shown, but another embodiment is shown. Then, two or more microphones may be arranged at the listening position to set the delay time.

Further, in the above-described Examples 1 to 4, the FL speaker 1 which is a full range speaker is used as the speaker.
9 and FR speaker 20 and woofer 21 for the low range are shown as an example of an audio system using three speakers, but the number of speakers is three. It is not limited to, and the types of speakers are also speakers and tweaks.
It is completely free to use data etc. In this case, the same effect can be obtained.

[0039]

As described above in detail, the spin according to the present invention is
Even if any of the delay time setting methods (1) to (3) is used, the detection error of the arrival time of the response signal from each speaker can be suppressed to a small level as compared with the conventional setting method. , The delay time of each speaker can be set more accurately. As a result, it is possible to more appropriately correct the disturbance of the frequency characteristics, the deviation of the sound image, etc., which are caused by the difference in the arrival times of the sounds output from the respective speakers. Also, the speaker delay time setting methods (1) and (3) or the speaker delay time setting methods (2) and (3), etc.
(C) If the delay time setting methods (1) to (3) are optimally combined according to the audio system or vehicle type,
The delay time of each speaker can be set more accurately, and the disturbance of the frequency characteristics and the bias of the sound image can be corrected more appropriately.

[Brief description of drawings]

FIG. 1 is a block diagram schematically showing a delay time setting system using a speaker delay time setting method according to a first embodiment of the present invention.

FIG. 2 is a block diagram schematically showing a delay time setting system using the method for setting the speaker delay time according to the second embodiment of the present invention.

FIG. 3 is a block diagram schematically showing a delay time setting system using a speaker delay time setting method according to a third embodiment of the present invention.

FIG. 4 is a block diagram schematically showing a delay time setting system using a speaker delay time setting method according to a fourth embodiment of the present invention.

[Fig. 5] An opener consisting of three speakers including a woofer.
It is a plane sectional view showing roughly a vehicle carrying a Dio system.

FIG. 6 is a waveform diagram schematically showing the impulse response of each speaker.

FIG. 7 is a schematic diagram showing a method of detecting the arrival time of an impulse response signal from each speaker in the conventional method of setting the speaker delay time.

[Explanation of symbols]

11 sound source 13, 14, 15 delay device 19 FL speaker 20 FR speaker 21 woofer 22 LPF (low-pass filter) 23, 55, 56 switching means 33 microphone 34, 35, 50, 65 detection / control Means 46, 47, 48 Delay device 49, 61, 62 Digital filter 51, 52, 53 BPF (band pass filter) 100, 200, 300, 400 Delay time setting system

Claims (3)

[Claims] 1. An M-sequence signal or an impulse signal is emitted from a sound source, a response signal from each speaker to the signal is recorded by a microphone arranged at a listening position, and the signal from each speaker to the microphone is recorded. After the arrival time of the response signal is detected, the delay time of the delay device in each speaker is set so that the arrival times of the response signals become equal.
In the method of setting the delay time, the signal emitted from the sound source is directly input to the speaker that cuts the high frequency band such as a woofer without cutting the high frequency band, and the arrival time is detected. A method for setting the speaker delay time, which comprises setting the speaker delay time based on the above. 2. An M-sequence signal or an impulse signal is emitted from a sound source, a response signal from each speaker to the signal is recorded by a microphone arranged at a listening position, and the signal from each speaker to the microphone is recorded. After the arrival time of the response signal is detected, the delay time of the delay device in each speaker is set so that the arrival times of the response signals become equal.
In the method of setting the delay time, a signal emitted from the sound source is input to a speaker that cuts a high frequency band such as a woofer through a filter other than an LPF (low-pass filter). Is detected, and the speaker delay time is set based on the detection result. 3. An M-sequence signal or an impulse signal is emitted from a sound source, and a response signal from each speaker to the signal is recorded by a microphone arranged at a listening position, and a signal from each speaker to the microphone is recorded. After the arrival time of the response signal is detected, the delay time of the delay device in each speaker is set so that the arrival times of the response signals become equal.
In the method for setting the delay time, a signal that is emitted from the sound source is input to a speaker that handles a mid range such as a squaker and a full range by detecting a arrival time through a filter other than an LPF, and the detection time is detected. A method for setting a speaker delay time, comprising setting a speaker delay time based on a result.