JPH0456643A - Exhaust noise improving device for automobile - Google Patents

Abstract

PURPOSE:To generate proper exhaust noise with high responsiveness by providing an equalizer to precorrect a sound pressure level at each frequency passing a constant sound pressure device in consideration of characteristics wherein the properties of noise sounded through a speaker are changed until the noise is collected by a second microphone. CONSTITUTION:The sound pressure level of a noise signal passing through a first rotation synchronizing filter 63 to decompose a noise signal, outputted from a first microphone 61 collecting exhaust noise right after it is exhausted from an engine, at each degree component is converted to a specified level at each frequency by means of a constant sound pressure device 68. After that, the noise signal is sounded from a speaker 71 through an amplifier 69. A second microphone 75 to collect synthesized noise produced by synthesizing noise from the speaker 71 and exhaust noise is provided, and an equalizer 76 to precorrect a sound pressure level at each constant sound frequency is provided. A sound pressure level at the degree peak of a noise signal passing through a second rotation synchronizing filter 77 after the passage of it through a second microphone 75 is compared with a target exhaust discharge noise sound pressure level by a control device 79 to control the gain of the amplifier 69.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an automobile exhaust tone improvement device for improving the tone of exhaust sound emitted from an automobile exhaust system.

[Conventional technology]

In general, automobiles are equipped with a muffler or the like in the exhaust system in order to prevent environmental damage caused by exhaust noise emitted from the exhaust system, thereby reducing the exhaust noise to below a regulatory level.

By the way, while a car is running, noise is generated due to engine operation, vibration of the car body, etc. Among the noises heard by the driver inside the car, there are some sounds that are particularly unpleasant. Yes, such unpleasant noises are
For example, in-vehicle noise has been improved by an in-vehicle sound improvement device as disclosed in Japanese Patent Application Laid-Open No. 60-143157.

However, in such conventional cars, although the speed, acceleration, etc. are different when the accelerator is fully depressed and when it is not, the exhaust sound does not correspond to the driving situation, and therefore the speed, acceleration feeling, etc. There has been a problem in that the driver and the like may feel unsatisfied.

On the other hand, it has been extremely difficult to create exhaust noise that corresponds to such driving conditions by rearranging silencers and the like.

In order to solve these problems, the present inventor invented an automobile exhaust tone improvement device.

FIG. 10 shows this exhaust tone improvement device for an automobile, and in the figure, reference numeral 11 indicates an engine mounted on the vehicle.

An exhaust system 13 is connected to this engine 11 to discharge exhaust gas, and this exhaust system 13 includes a catalytic converter 15 for purifying the exhaust gas, a bridge muffler 17 for reducing exhaust noise. Muffler 19 is installed.

The exhaust system 13 extends to the rear of the vehicle, and its rear end is opened toward the rear of the vehicle.

On the upstream side of the exhaust system 13, a first microphone 21 is arranged to collect exhaust sound immediately after being exhausted from the engine 11 and convert it into an audio signal.

The first microphone 21 is connected to a first rotation synchronization filter 23 that blocks the passage of audio signals other than frequency components of a specific order determined by the rotational speed of the engine 11 and decomposes the audio signal into each order component.

Further, a rotation speed sensor 25 that measures the rotation speed of the engine 11 is connected to the engine 11, and a converter 27 that converts a pulse signal from the rotation speed sensor 25 into voltage is connected to the rotation speed sensor 25. This converter 27 is connected to the first rotation synchronous filter 23.

This first rotational synchronous filter 23 is connected to a constant sound pressure device 28 that converts the sound pressure level of the audio signal from the first rotational synchronous filter 23 to a constant level for each frequency.

In this constant sound pressure device 28, the sound pressure levels at the same frequency that have passed through the first rotation synchronous filter 23 are converted to the same level. That is, as shown in FIG. 11, the sound pressure level of the audio signal of the same frequency, which fluctuates greatly over time,
Even when input to the first rotation synchronization filter 23, the sound pressure level of the audio signal at the same frequency output from the constant sound pressure device 28 is maintained at a constant level over time, as shown in FIG.

As shown in FIG. 10, the constant sound pressure device 28 is connected to an amplifier 29 that increases or decreases the sound pressure level of the audio signal at a predetermined order.

This amplifier 29 is connected to a speaker 31 that converts an audio signal into sound and produces sound, and the sound from this speaker 31 is synthesized with the exhaust sound from the exhaust system 13 of the automobile.

This speaker 31 is arranged at the rear end of the exhaust system 13. Further, an acoustic conduit 73 is formed in the speaker 31, and the tip of this acoustic conduit 33 is opened in the same direction as the rear end of the exhaust system 13.

A second microphone 3 is installed in the acoustic conduit 33 of the speaker 31 and collects a synthesized sound obtained by combining the sound from the speaker 31 and the exhaust sound from the exhaust system 13 of the automobile, and converts it into an audio signal.
5 is fixed.

The second microphone 35 is connected to the engine 1 out of the audio signal.
It is connected to a second rotary synchronization filter 37 that blocks the passage of audio signals other than frequency components of a specific order determined by the number of rotations of 1 and decomposes the audio signal into each order component.

The second rotation synchronous filter 37 and the first rotation synchronous filter 23 are, for example, voltage-tuned filters. It consists of a bandpass filter that passes 3rd order frequency components and a bypass filter that passes 0.5th order or higher frequency components.

Further, the second rotation synchronous filter 37 is connected to the converter 27 that converts the rotation speed of the engine 11 into voltage, and allows the same order component as the first rotation synchronous filter 23 to pass therethrough.

Furthermore, the audio signal of a predetermined order from the second rotation synchronous filter 37 is input to the second rotation synchronous filter 37, and the order peak determined from the sound pressure level at the order peak of the audio signal and the engine load and rotation speed. The target exhaust discharge sound pressure level is compared with the amplifier 29.
A control device 39 is connected to control the gain of.

Between the second rotation synchronous filter 37 and the control device 39,
An A/D converter 41 is arranged, and a second microphone 35
An audio signal from the controller 39 is input to the control device 39 as numerical data.

Further, the control device 39 is connected to a boost pressure sensor or the like connected to the engine 11, which senses the engine load. Furthermore, the converter 27 and a control device 39 are connected, and the engine rotation speed is introduced into the control device 39.

Further, the control device 39 takes in as data a target exhaust discharge sound pressure level determined by the engine speed and engine load.

Note that the target exhaust discharge sound pressure level does not necessarily need to be taken in as data in the control device 39 (for example, it can be derived by substituting the rotation speed of the engine 11 and the engine load into the calculation formula in the control device 39). That's fine.

This target exhaust exhaust sound sound pressure level is determined as the sound pressure level at the target order peak of the sound emitted from the rear of the car, and the sound pressure level at the order peak of the sound emitted from the rear of the car is the target exhaust exhaust sound pressure level. When it comes to the sound pressure level of exhaust sound, exhaust sound is generated in response to driving conditions such as speed and acceleration, and the sound pressure level is determined to be an exhaust sound level that satisfies the driver and the like.

Furthermore, the order components of the audio signals passing through the first rotation synchronization filter 23 and the second rotation synchronization filter 37 are the order components of the order in which the target exhaust discharge sound sound pressure level exists.

In FIG. 10, solid lines indicate transmission paths of electrical signals based on sound, and broken lines indicate transmission paths of electrical signals based on other information.

In the automobile exhaust tone improvement device configured as described above, as shown in FIG. , a target exhaust discharge sound pressure level corresponding to the engine speed and engine load is derived.

This target exhaust discharge sound pressure level varies to various values depending on the engine speed and load.

On the other hand, the exhaust sound immediately after being emitted from the engine 11 is the first
The audio signal is collected by the microphone 21 and converted into an audio signal, and the first rotational synchronization filter 23 blocks passage of audio signals other than frequency components of a specific order determined by the engine rotation speed among the audio signals from the first microphone 21. , the audio signal is decomposed into each order component.

Then, the audio signal of a predetermined order decomposed by the first rotation synchronous filter 23 is input to the constant sound pressure device 28,
This constant sound pressure device 28 converts the sound pressure level of audio signals having the same frequency into a constant level.

The sound signal that has passed through this foot sound pressure device 28 is transmitted to the control device 3.
The sound pressure level of the audio signal is increased or decreased by the amplifier 29 whose gain is controlled by the speaker 31, and the audio signal is converted into sound and produced by the speaker 31, which outputs the exhaust system 1
It is synthesized with the exhaust sound from 3.

Furthermore, a synthesized sound obtained by combining the sound from the speaker 31 and the exhaust sound from the exhaust system 13 of the automobile is collected by the second microphone 35 and converted into an audio signal.

Among the audio signals from the second microphone 35, the passage of audio signals other than frequency components of a specific order determined by the rotation speed of the engine 11 is blocked by the second rotation synchronization filter 37, and the audio signal is decomposed into each order component. Ru. That is, the audio signal from the second microphone 35 is decomposed into components of the same order as the audio signal from the first microphone 21.

The audio signal at a predetermined order from the second rotation synchronous filter 37 is input as numerical data to the control device 39, and within this control device 39, the sound pressure level at the order peak of the audio signal, engine load and rotation speed are determined. The target exhaust discharge sound sound pressure level at the determined order peak is compared, and the gain of the amplifier 29 is adjusted so that the sound pressure level at the order peak of the audio signal from the second microphone 35 approaches the target exhaust discharge sound sound pressure level. is controlled, and the sound pressure level of the audio signal from the first microphone 21 passing through the amplifier 29 is increased or decreased.

That is, the control device 39 increases the gain of the amplifier 29 when the target exhaust discharge sound sound pressure level is larger, and increases the gain of the amplifier 29 when the target exhaust discharge sound sound pressure level is smaller. The sound pressure level of the synthesized sound obtained by combining the sound from the speaker 31 and the exhaust sound from the exhaust system 13 of the automobile is controlled so that it approaches the target exhaust discharge sound sound pressure level.

Therefore, the sound pressure level increases over time due to the silencing characteristics of the exhaust system (even if a fluctuating audio signal is recorded by the first microphone 21, if it passes through the constant sound pressure device 28, the sound pressure level will increase over time). It is assumed that the sound pressure level of the audio signal is constant, and the reference sound pressure level that is increased or decreased by the amplifier 29 is
As shown in FIG. 12, since the sound pressure level of the synthesized sound is constant, the sound pressure level of the synthesized sound approaches the target exhaust discharge sound sound pressure level, that is,
The time required for the sound pressure level of the synthesized sound to decay to the target exhaust discharge sound pressure level can be significantly shortened.

That is, as in the conventional case, the first microphone 21
Even if an exhaust sound is recorded in which the sound pressure level at the same frequency fluctuates greatly over time due to the influence of the muffler 1719 etc. placed in the exhaust system 13, the sound pressure level at the same frequency is kept constant by the constant sound pressure device 28. Therefore,
A constant sound pressure level serving as a reference is increased or decreased by the amplifier 29, and can be quickly controlled by the control device 39 so that the sound pressure level of the synthesized sound becomes the same sound pressure level as the target exhaust discharge sound sound pressure level. .

Furthermore, by adding sound to the exhaust sound emitted from the exhaust system 13 to create a synthesized sound, it is possible to create an exhaust tone that corresponds to the driving condition, thereby giving the driver a sense of speed, acceleration, etc. It can make you feel.

[Problem to be solved by the invention]

However, in such an automobile exhaust tone improvement device, sound is emitted by the speaker 31 and this sound is collected by the second microphone 35 via the acoustic conduit 33, so the characteristics of the speaker 31 and the characteristics of the speaker 31 and the There is a problem in that the sound pressure level for each frequency changes due to the resonance effect between the two microphones 35 and the like.

Therefore, the control device 39 controls the second microphone 35
Even if the gain of the amplifier 29 is controlled so that the sound pressure level of the audio signal from the
The sound emitted from the speaker 31 is altered before being recorded by the second microphone 35, and it takes some time for the sound pressure level of the synthesized sound to attenuate to the target exhaust discharge sound sound pressure level. There has been a problem in that it is not possible to attenuate in a short enough time to satisfy the driver and the like.

For example, frequency 2 of the sound emitted from the speaker 31
If the sound pressure level of 007 resonates in the acoustic conduit 33 and increases by 5 dB, this 5 dB louder sound will be synthesized with the exhaust sound, and the frequency 20070 sound pressure level in the synthesized sound will be the target exhaust discharge sound. There is a problem in that it takes time for the sound pressure level of the synthesized sound to attenuate to the target exhaust discharge sound sound pressure level.

Therefore, for example, when the accelerator is suddenly fully depressed, it is not possible to quickly respond to the situation, and there is a problem in that the driver becomes angry at the lack of satisfaction.

The present invention has been made to solve the above-mentioned problems, and provides an automobile exhaust tone that can significantly shorten the time for the sound pressure level of the synthesized sound to decay to the target exhaust discharge sound pressure level. The purpose is to provide an improved device.

[Means to solve the problem]

The exhaust tone improvement device for an automobile according to claim 1 includes a first microphone that collects the exhaust sound immediately after being emitted from the engine and converts it into an audio signal, and a first microphone that collects the exhaust sound just after it is discharged from the engine and converts it into an audio signal, and a rotational speed of the engine among the audio signals from the first microphone. A first rotary synchronous filter that blocks the passage of audio signals other than frequency components of a specific order determined by the filter and decomposes the audio signal into each order component; a constant sound pressure device that converts the sound pressure to a constant level;
An amplifier that increases or decreases the sound pressure level of an audio signal of a predetermined order from this constant sound pressure device, and a speaker that converts the audio signal that has passed through this amplifier into sound, produces it, and synthesizes it with the exhaust sound from the car's exhaust system. a second microphone that collects a synthesized sound obtained by combining the sound from this speaker and the exhaust sound from the exhaust system of the automobile and converts it into an audio signal; an equalizer that corrects the level in advance by taking into account the characteristic that the sound emitted from the speaker changes in quality before it is collected by the second microphone; A second rotary synchronous filter that blocks the passage of audio signals other than frequency components of a predetermined specific order and decomposes the audio signal into each order component, and an audio signal of a predetermined order from this second rotary synchronous filter is input. A control device that controls the gain of the amplifier by comparing the sound pressure level at the order peak of the audio signal and the target exhaust discharge sound sound pressure level at the order peak determined from the engine load and rotation speed. It is.

The exhaust tone improvement device for an automobile according to claim 2 includes a first microphone that collects the intake sound of the intake system of the engine and converts it into an audio signal, and the audio signal from the first microphone is determined by the rotational speed of the engine. A first rotary synchronous filter that blocks the passage of audio signals other than frequency components of a specific order and decomposes the audio signal into each order component, and the sound pressure level of the audio signal from the first rotary synchronous filter is kept constant for each frequency. A constant sound pressure device that converts the sound pressure level into a level, an amplifier that increases or decreases the sound pressure level of the audio signal at a predetermined order from the constant sound pressure device, and converts the audio signal that has passed through this amplifier into sound and generates a sound. a speaker that synthesizes the exhaust sound from the exhaust system; a second microphone that collects a synthesized sound obtained by synthesizing the sound from the speaker and the exhaust sound from the exhaust system of the vehicle and converts it into an audio signal; an equalizer that corrects in advance the sound pressure level of each frequency that has passed through the pressure device, taking into account the characteristic that the sound emitted from the speaker changes in quality before being collected by the second microphone; a second rotary synchronous filter that blocks the passage of audio signals other than frequency components of a specific order determined by the rotation speed of the engine among the audio signals and decomposes the audio signal into each order component; An audio signal at a predetermined order is input, and the gain of the amplifier is determined by comparing the sound pressure level at the order peak of this audio signal with the target exhaust discharge sound sound pressure level at the order peak determined from the engine load and rotation speed. The device also includes a control device for controlling the device.

The automobile exhaust tone improvement device according to claim 3 is provided in claim 1.
or 2. In the vehicle exhaust tone improvement device according to 2, the control device includes a target value calculation device that calculates a target exhaust discharge sound sound pressure level at an order peak from the engine load and rotation speed, and a predetermined order output from the second rotation synchronous filter. The audio signal and target exhaust discharge sound pressure level are input,
The system comprises an analog computer that calculates the gain of the amplifier by comparing the sound pressure level at the order peak of the audio signal with the target exhaust discharge sound sound pressure level.

[For production]

In the automobile exhaust tone improvement device according to claim 1, engine speed and engine load are input to the control device, and a target exhaust discharge sound sound pressure level corresponding to the engine speed and engine load is derived within this control device. .

This target exhaust exhaust sound sound pressure level is determined as the sound pressure level at the target order peak of the sound emitted from the rear of the car, and the sound pressure level at the order peak of the sound emitted from the rear of the car is the target exhaust exhaust sound pressure level. When it comes to the sound pressure level of exhaust sound, exhaust sound is generated in response to driving conditions such as speed and acceleration, and the sound pressure level is determined to be an exhaust sound level that satisfies the driver and the like.

On the other hand, the exhaust sound immediately after being emitted from the engine is collected by the first microphone and converted into an audio signal. Among the audio signals from the first microphone, audio other than the frequency component of a specific order determined by the engine rotation speed is Passage of the signal is blocked by the first rotary synchronous filter, and the audio signal that has passed through this filter is decomposed into each order component.

The audio signal of a predetermined order decomposed by the first rotation synchronization filter is input to a constant sound pressure device, and the sound pressure device converts the sound pressure level of the audio signal at the same frequency to a constant level.

Then, the sound pressure level of each frequency of the audio signal that has passed through the constant sound pressure device is corrected in advance by an equalizer, taking into account the characteristic that the sound emitted from the speaker changes before being collected by the second microphone. be done.

In other words, the sound emitted from the speaker depends on the speaker characteristics,
The quality changes due to the resonance effect between the speaker and the second microphone, but this amount of change is measured in advance,
The sound pressure level of the audio signal that has passed through the constant sound pressure device is corrected by that amount. For example, if the sound pressure level of frequency 2007 of the sound emitted from the speaker is 5 dB higher and recorded by the second microphone due to the resonance effect, the sound pressure level of frequency 2007 that has passed through the sound pressure constant device will be: It is corrected to become smaller by 5 dB.

The audio signal corrected by the equalizer is input to an amplifier whose gain is controlled by a control device, the sound pressure level of the audio signal is increased or decreased, the audio signal is converted into sound by a speaker, and is emitted from the exhaust system of the car. is synthesized with the exhaust sound.

A synthesized sound obtained by combining the sound from the speaker and the exhaust sound from the exhaust system of the automobile is collected by the second microphone and converted into an audio signal.

Among the audio signals from the second microphone, passage of audio signals other than frequency components of a specific order determined by the engine rotation speed is blocked by a second rotational synchronous filter,
The audio signal is decomposed into each order component.

The audio signal at a predetermined order from this second rotary synchronous filter is input to the control device, and within this control device, the sound pressure level at the order peak of the audio signal and the target exhaust gas at the order peak of the same order as this sound pressure level are determined. The gain of the amplifier is controlled so that the sound pressure level at the order peak of the sound signal from the second microphone approaches the target exhaust sound pressure level. The sound pressure level of the audio signal from the microphone is increased or decreased.

That is, the control device increases the gain of the amplifier when the target exhaust discharge sound sound pressure level is higher, and decreases the gain of the amplifier when the target exhaust discharge sound sound pressure level is lower. The sound pressure level of a synthesized sound obtained by combining the sound from the speaker and the exhaust sound from the exhaust system of the automobile is controlled so as to approach the target exhaust discharge sound sound pressure level.

Therefore, even if an audio signal whose sound pressure level fluctuates greatly over time due to the silencing characteristics of the exhaust system is recorded by the first microphone, when it passes through the constant sound pressure device,
The sound pressure level of audio signals having the same frequency is assumed to be constant, and the reference sound pressure level corrected by the equalizer is assumed to be constant.

In addition, the sound emitted from the speaker may vary depending on the speaker characteristics,
Even if the quality of the audio signal is changed due to the resonance effect between the speaker and the second microphone, the sound pressure level of each frequency that has passed through a constant sound pressure device and has a constant sound pressure level for each frequency will be changed by the equalizer. Since the sound emitted from the speaker is corrected in advance by taking into account the characteristics that change in quality before it is collected by the second microphone, the gain of the amplifier is adjusted by the control device so that it approaches the target exhaust discharge sound pressure level. When the sound pressure level of the audio signal is set and the amplifier increases or decreases the sound pressure level of the audio signal, the sound pressure level of the synthesized sound becomes a value closer to the target exhaust discharge sound sound pressure level, and the sound pressure level of the synthesized sound becomes the target exhaust discharge sound sound pressure level. The time it takes to decay to a pressure level is significantly reduced.

In the automobile exhaust tone improvement device according to claim 2, engine speed and engine load are input to the control device, and a target exhaust discharge sound sound pressure level corresponding to the engine speed and engine load is derived within the control device. It will be destroyed.

This target exhaust exhaust sound sound pressure level is determined as the sound pressure level at the target order peak of the sound emitted from the rear of the car, and the sound pressure level at the order peak of the sound emitted from the rear of the car is the target exhaust exhaust sound pressure level. When it comes to the sound pressure level of exhaust sound, exhaust sound is generated in response to driving conditions such as speed and acceleration, and the sound pressure level is determined to be an exhaust sound level that satisfies the driver and the like.

On the other hand, the intake sound of the intake system of the engine is collected by the first microphone and converted into an audio signal, and the audio signal other than the frequency component of a specific order determined by the engine rotation speed is detected from the audio signal from the first microphone. Passage is blocked by a first rotary synchronous filter, and the audio signal that has passed through this filter is decomposed into order components.

The audio signal of a predetermined order decomposed by the first rotation synchronization filter is input to a constant sound pressure device, and the sound pressure device converts the sound pressure level of the audio signal at the same frequency to a constant level.

Then, the sound pressure level of each frequency of the audio signal that has passed through the constant sound pressure device is corrected in advance by an equalizer, taking into account the characteristic that the sound emitted from the speaker changes before being collected by the second microphone. be done.

In other words, the sound emitted from the speaker depends on the speaker characteristics,
The quality changes due to the resonance effect between the speaker and the second microphone, but this amount of change is measured in advance,
The sound pressure level of the audio signal that has passed through the foot sound pressure device is corrected by that amount. For example, a sound produced from a speaker with a frequency of 200 and a sound pressure level of 5 is caused by resonance.
Assuming that the data is recorded by the second microphone dB larger,
The frequency 20070 sound pressure level that passed through the constant sound pressure device is
It is corrected to become smaller by 5 dB.

The audio signal corrected by the equalizer is input to an amplifier whose gain is controlled by a control device, the sound pressure level of the audio signal is increased or decreased, the audio signal is converted into sound by a speaker, and is emitted from the exhaust system of the car. is synthesized with the exhaust sound.

A synthesized sound obtained by combining the sound from the speaker and the exhaust sound from the exhaust system of the automobile is collected by the second microphone and converted into an audio signal.

Among the audio signals from the second microphone, passage of audio signals other than frequency components of a specific order determined by the engine rotation speed is blocked by a second rotational synchronous filter,
The audio signal is decomposed into each order component.

The audio signal at a predetermined order from this second rotary synchronous filter is input to the control device, and within this control device, the sound pressure level at the order peak of the audio signal and the target exhaust gas at the order peak of the same order as this sound pressure level are determined. The gain of the amplifier is controlled so that the sound pressure level at the order peak of the sound signal from the second microphone approaches the target exhaust sound pressure level. The sound pressure level of the audio signal from the microphone is increased or decreased.

That is, the control device increases the gain of the amplifier when the target exhaust discharge sound sound pressure level is higher, and decreases the gain of the amplifier when the target exhaust discharge sound sound pressure level is lower. The sound pressure level of a synthesized sound obtained by combining the sound from the speaker and the exhaust sound from the exhaust system of the automobile is controlled so as to approach the target exhaust discharge sound sound pressure level.

Therefore, even if an audio signal whose sound pressure level fluctuates greatly over time due to various influences such as the silencing characteristics of the exhaust system is recorded by the first microphone, when it passes through a constant sound pressure device, the same frequency signal will be recorded. The sound pressure level of the audio signal is assumed to be constant, and the reference sound pressure level corrected by the equalizer is assumed to be constant.

In addition, the sound emitted from the speaker may vary depending on the speaker characteristics,
Even if the quality of the audio signal is changed due to the resonance effect between the speaker and the second microphone, the sound pressure level of each frequency that has passed through a constant sound pressure device and has a constant sound pressure level for each frequency will be changed by the equalizer. Since the sound emitted from the speaker is corrected in advance by taking into account the characteristics that change in quality before it is collected by the second microphone, the gain of the amplifier is adjusted by the control device so that it approaches the target exhaust discharge sound pressure level. When the sound pressure level of the audio signal is set and the amplifier increases or decreases the sound pressure level of the audio signal, the sound pressure level of the synthesized sound becomes a value closer to the target exhaust discharge sound sound pressure level, and the sound pressure level of the synthesized sound becomes the target exhaust discharge sound sound pressure level. The time it takes to decay to a pressure level is significantly reduced.

In the automobile exhaust tone improvement device according to claim 3, in the automobile exhaust tone improvement device according to claim 1 or 2,
Since the control device is composed of a target value calculation device and an analog computer, the target exhaust discharge sound pressure level calculated by the target value calculation device and the audio signal at a predetermined order from the second rotation synchronous filter can be used as analog signals. The signal is input to an analog computer, and within this analog computer, the target exhaust discharge sound sound pressure level and the sound pressure level at the order peak of the audio signal are compared, and the gain of the amplifier is calculated.

〔Example〕

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, details of the present invention will be described with reference to embodiments shown in the drawings.

FIG. 1 shows an embodiment of the automobile exhaust tone improvement device of the present invention, and in the figure, reference numeral 51 indicates an engine mounted on the vehicle.

An exhaust system 53 is connected to this engine 51 to discharge exhaust gas, and this exhaust system 53 includes a catalytic converter 55 for purifying the exhaust gas, a bridge muffler 57 for reducing exhaust noise. Muffler 59 is installed.

The exhaust system 53 extends to the rear of the vehicle, and its rear end is opened toward the rear of the vehicle.

A first microphone 61 is arranged on the upstream side of the exhaust system 53 to collect exhaust sound immediately after being exhausted from the engine 51 and convert it into an audio signal.

The first microphone 61 is connected to a first rotation synchronization filter 63 that blocks the passage of audio signals other than frequency components of a specific order determined by the rotational speed of the engine 51 and decomposes the audio signal into each order component.

Further, a rotation speed sensor 65 that measures the rotation speed of the engine 51 is connected to the engine 51, and a converter 67 that converts a pulse signal from the rotation speed sensor 65 into a voltage is connected to the rotation speed sensor 65. This converter 67 is connected to the first rotation synchronous filter 63.

This first rotational synchronous filter 63 is connected to a footstep sound pressure device 68 that converts the sound pressure level of the audio signal from the first rotational synchronous filter 63 into a constant level for each frequency.

In this constant sound pressure device 68, the sound pressure levels at the same frequency that have passed through the first rotation synchronous filter 63 are converted to the same level. In other words, as shown in FIG. The sound pressure level of the audio signal at each frequency remains at a constant level over time, as shown in FIG.

As shown in FIG.
9 is connected.

This amplifier 69 is connected to a speaker 71 that converts an audio signal into sound and produces sound, and the sound from this speaker 71 is synthesized with the exhaust sound from the exhaust system 53 of the automobile.

This speaker 71 is arranged at the rear end of the exhaust system 53. Further, an acoustic conduit 73 is formed in the speaker 71, and the tip of this acoustic conduit 73 is opened in the same direction as the rear end of the exhaust system 53.

A second microphone 7 is connected to the acoustic conduit 73 of the speaker 71 and collects a synthesized sound obtained by combining the sound from the speaker 71 and the exhaust sound from the exhaust system 53 of the automobile, and converts it into an audio signal.
5 is fixed.

Between the constant sound pressure device 68 and the amplifier 69, the sound pressure level of each frequency that has passed through the constant sound pressure device 68 is collected by the second microphone 75. An equalizer 76 is arranged to perform correction in advance in consideration of changing characteristics.

This equalizer 76 is configured to adjust the sound emitted from the speaker 71 depending on the speaker characteristics and the speaker and second microphone 7.
5 is measured in advance, and the audio signal that has passed through the constant sound pressure device 68 is corrected by that amount.

For example, frequency 2 of the sound emitted from the speaker 71
If the sound pressure level of 00 Hz is recorded by the second microphone 75 as 5 dB larger due to resonance, the sound pressure level of frequency 200 70 that has passed through the foot sound pressure device 68 is corrected by the equalizer 76 so that it is reduced by 5 dB. Ru.

The second microphone 75 is connected to the engine 5 out of the audio signal.
It is connected to a second rotary synchronous filter 77 that blocks the passage of audio signals other than frequency components of a specific order determined by the number of rotations of 1 and decomposes the audio signal into each order component.

The second rotation synchronous filter 77 and the first rotation synchronous filter 63 are, for example, voltage-tuned filters. It consists of a bandpass filter that passes 3rd order frequency components and a bypass filter that passes 0.5th order or higher frequency components.

Further, the second rotational periodic filter 77 is connected to a converter 67 that converts the rotational speed of the engine 51 into voltage, and passes the same order component as the first rotational periodic filter 63.

Furthermore, the audio signal of a predetermined order from the second rotational periodic filter 77 is inputted to the second rotational periodic filter 77, and the frequency is determined from the f pressure at the order peak of the audio signal, the engine load, and the rotation speed. The amplifier 69 compares the target exhaust discharge sound sound pressure level at the order peak.
A control device 79 is connected to control the gain of.

Between the second rotating periodic filter 77 and the control device 79,
An A/D converter 81 is arranged, and a second microphone 75
An audio signal from the controller 79 is input to the control device 79 as numerical data.

Further, the control device 79 is connected to, for example, a boost pressure sensor connected to the engine 51 that senses the engine load. Furthermore, the motor/vertical rotor 7 is connected to a control device 79, and the engine speed is input to the control device 79.

Further, the control device 79 takes in as data a target exhaust discharge sound pressure level determined by the engine speed and engine load.

Note that the target exhaust discharge sound sound pressure level does not necessarily have to be taken into the control device 79 as data, and can be derived in the control device 79 by, for example, substituting the rotation speed and engine load of the engine 51 into a calculation formula. Good.

This target exhaust exhaust sound sound pressure level is determined as the sound pressure level at the target order peak of the sound emitted from the rear of the car, and the sound pressure level at the order peak of the sound emitted from the rear of the car is the target exhaust exhaust sound pressure level. When it comes to the sound pressure level of exhaust sound, exhaust sound is generated in response to driving conditions such as speed and acceleration, and the sound pressure level is determined to be an exhaust sound level that satisfies the driver and the like.

Furthermore, the order components of the audio signal passing through the first rotation periodic filter 63 and the second rotation period filter 77 are the order components of the order in which the target exhaust discharge sound sound pressure level exists.

In FIG. 1, solid lines indicate transmission paths of electrical signals based on sound, and broken lines indicate transmission paths of electrical signals based on other information.

In the automobile exhaust tone improvement device configured as described above, as shown in FIG. , a target exhaust discharge sound pressure level corresponding to the engine speed and engine load is derived.

This target exhaust discharge sound pressure level is varied to various values depending on the engine rotation speed and load, as shown in FIGS. 5 to 7, for example.

On the other hand, the exhaust sound immediately after being emitted from the engine 51 is the first
The first rotational periodic filter 63 blocks the passage of audio signals other than frequency components of a specific order determined by the engine rotation speed among the audio signals collected by the microphone 61 and converted into audio signals. The audio signal is decomposed into each order component.

The audio signal of a predetermined order decomposed by the first rotating periodic filter 63 is input to a constant sound pressure device 68, and this constant sound pressure device 68 converts the sound pressure level of the audio signal having the same frequency to a constant level. Ru.

The sound pressure level of each frequency of the sound signal that has passed through the footstep sound pressure device 68 is changed by the equalizer 76, taking into consideration the characteristic that the sound produced from the speaker 71 is altered by the time it is collected by the second microphone 75. is corrected in advance.

That is, the sound emitted from the speaker 71 is altered due to the speaker characteristics and the resonance effect between the speaker 71 and the second microphone 75, but the amount of this change is measured in advance, and the constant sound pressure is adjusted by that amount. The audio signal passed through device 68 is corrected.

For example, if the sound pressure level of frequency 20070 is recorded in the second microphone 75 with a 5 dB increase due to resonance, the sound pressure level of frequency 200 Hz that has passed through the sound pressure constant device 68 is corrected so that it is reduced by 5 dB. be done.

FIG. 8 shows the correction function by the equalizer 76, and the dashed-dotted line indicates the amount of sound pressure level that changes for each frequency due to the speaker characteristics and the resonance effect between the speaker 71 and the second microphone 75. The solid line is the sound pressure level amount for each frequency corrected by the equalizer 76, which is symmetrical to this changing sound pressure level amount.

The audio signal that has passed through the equalizer 76 is input to an amplifier 69 whose gain is controlled by a control device 79, where the sound pressure level of the audio signal is increased or decreased, and the audio signal is converted into sound by the speaker 71 and is emitted. It is synthesized with the exhaust sound from the exhaust system 53.

Further, a synthesized sound obtained by combining the sound from the speaker 71 and the exhaust sound from the exhaust system 53 of the automobile is collected by the second microphone 75 and converted into an audio signal.

Among the audio signals from the second microphone 75, the passage of audio signals other than frequency components of a specific order determined by the rotation speed of the engine 51 is blocked by the second rotation synchronization filter 77, and the audio signal is decomposed into each order component. Ru.

That is, the audio signal from the second microphone 75 is
The audio signal from the microphone 61 is decomposed into components of the same order.

The audio signal at a predetermined order from the second rotation synchronization filter 77 is input as numerical data to the control device 79, and within this control device 79, the sound pressure level at the order peak of the audio signal, the engine load and the rotation speed are determined. The target exhaust discharge sound sound pressure level at the determined order peak is compared, and the gain of the amplifier 69 is adjusted so that the sound pressure level at the order peak of the audio signal from the second microphone 75 approaches the target exhaust discharge sound sound pressure level. is controlled, and the sound pressure level of the audio signal from the first microphone 61 passing through the amplifier 69 is increased or decreased.

That is, the control bag W79 increases the gain of the amplifier 69 when the target exhaust discharge sound sound pressure level is larger, and increases the gain of the amplifier 69 when the target exhaust discharge sound sound pressure level is smaller. The sound pressure level of the synthesized sound obtained by combining the sound from the speaker 71 and the exhaust sound from the exhaust system 53 of the automobile is controlled so as to approach the target exhaust discharge sound sound pressure level. For example, if the target exhaust discharge sound pressure level is 90 dB and the sound pressure level passing through the second rotation synchronous filter 77 is 85 dB, the control device 79
A voltage of the amplifier 69 corresponding to 90 dB-85 dB=5 dB, for example, 1.sup. is applied.

Therefore, even if an audio signal whose sound pressure level fluctuates greatly over time due to the influence of the silencing characteristics of the exhaust system is recorded by the first microphone 61, when it passes through the constant sound pressure device 68, the sound pressure level shown in FIG. As shown, the sound pressure level of audio signals of the same frequency is assumed to be constant.

Further, even if the sound emitted from the speaker 71 is altered due to speaker characteristics or resonance between the speaker 71 and the second microphone 75, the constant sound pressure device 68
The sound pressure level of the sound pressure level for each frequency is changed by the equalizer 76 until the sound emitted from the speaker 71 is collected by the second microphone 75. Since the gain of the amplifier 69 is corrected in advance in consideration of the changing characteristics, the control device 79 adjusts the gain of the amplifier 69 so that it approaches the target exhaust discharge sound pressure level.
is set, and when the sound pressure level of the audio signal is increased or decreased by the amplifier 69, the sound pressure level of the synthesized sound is set to a value closer to the target exhaust discharge sound sound pressure level, and the sound pressure level of the synthesized sound is set to a value closer to the target exhaust discharge sound sound pressure level. The time required for the sound to decay to the sound pressure level can be significantly shortened.

Furthermore, by adding sound to the exhaust sound emitted from the exhaust system 53, it is possible to create an exhaust tone that corresponds to the driving condition, thereby giving the driver a sufficient sense of speed, acceleration, etc. I can do it.

FIG. 9 shows another embodiment of the automobile exhaust tone improvement device of the present invention. In this embodiment, the control device 85 determines the target exhaust discharge sound pressure level at the order peak from the engine load and rotation speed. A target value calculation device 87 for calculating,
The audio signal at a predetermined order from the second rotation synchronous filter 89 and the target exhaust discharge sound sound pressure level are input, and the sound pressure level at the order peak of the audio signal and the target exhaust discharge sound sound pressure level are compared. It is composed of an analog computer 93 that calculates the gain.

In the automobile exhaust tone improvement device configured as described above, the engine load and rotation speed are input to the target value calculation device 87, the target value calculation device 87 calculates the target exhaust discharge sound sound pressure level, and the digital signal The target exhaust discharge sound sound pressure level is converted into an analog signal by the D/A converter 95 and input to the analog computer 93.

Then, the audio signal at a predetermined order from the second rotary synchronous filter 89 is sent to the analog computer 9 as an analog signal.
3, and the gain of the amplifier 91 is calculated at once in this analog computer 93. Therefore, the control device 8
By reducing the burden on the controller 85, processing within the control device 85 can be carried out quickly, and the time required for the synthesized sound to attenuate to the target exhaust discharge sound sound pressure level can be further shortened.

In the above embodiment, an example was described in which the exhaust sound immediately after being exhausted from the engine 51 was recorded by the first microphone 61 arranged on the upstream side of the exhaust system 53.
The present invention is not limited to the above-mentioned embodiments, and substantially the same effects as in the above-described embodiments can be obtained even if the first microphone collects intake noise from the intake system of the engine.

In this case, it is possible to prevent the first microphone from being affected by heat more than placing it in the exhaust system.

〔Effect of the invention〕

In the automobile exhaust tone improvement device according to claim 1, engine speed and engine load are input to the control device, and a target exhaust discharge sound sound pressure level corresponding to the engine speed and engine load is derived within this control device. .

On the other hand, the exhaust sound immediately after being emitted from the engine is collected by the first microphone and converted into an audio signal. Among the audio signals from the first microphone, audio other than the frequency component of a specific order determined by the engine rotation speed is Passage of the signal is blocked by the first rotary synchronous filter, and the audio signal that has passed through this filter is decomposed into each order component.

The audio signal of a predetermined order decomposed by the first rotary synchronous filter is input to the constant sound pressure device, and this constant sound pressure device converts the sound pressure level of the audio signal at the same frequency to a constant level. The audio signal that has passed through
The sound pressure level for each frequency is corrected in advance by an equalizer, taking into consideration the characteristics of the sound emitted from the speaker being degraded before being collected by the second microphone.

In other words, the sound emitted from the speaker depends on the speaker characteristics,
The quality changes due to the resonance effect between the speaker and the second microphone, but this amount of change is measured in advance,
The sound pressure level of the audio signal that has passed through the constant sound pressure device is corrected by that amount.

The audio signal corrected by the equalizer is input to an amplifier whose gain is controlled by a control device, the sound pressure level of the audio signal is increased or decreased, the audio signal is converted into sound by a speaker, and is emitted from the exhaust system of the car. The synthesized sound, which is a combination of the sound from the speaker and the exhaust sound from the exhaust system of the car, is collected by a second microphone and converted into an audio signal. Among them, passage of the audio signal other than frequency components of a specific order determined by the engine rotation speed is blocked by the second rotation synchronization filter, and the audio signal is decomposed into each order component.

The audio signal at a predetermined order from this second rotary synchronous filter is input to the control device, and within this control device, the sound pressure level at the order peak of the audio signal and the target exhaust gas at the order peak of the same order as this sound pressure level are determined. The gain of the amplifier is controlled so that the sound pressure level at the order peak of the sound signal from the second microphone approaches the target exhaust sound pressure level. The sound pressure level of the audio signal from the microphone is increased or decreased.

That is, the control device increases the gain of the amplifier when the target exhaust discharge sound sound pressure level is higher, and decreases the gain of the amplifier when the target exhaust discharge sound sound pressure level is lower. The sound pressure level of a synthesized sound obtained by combining the sound from the speaker and the exhaust sound from the exhaust system of the automobile is controlled so as to approach the target exhaust discharge sound sound pressure level.

Therefore, even if an audio signal whose sound pressure level fluctuates greatly over time due to the silencing characteristics of the exhaust system is recorded by the first microphone, when it passes through the constant sound pressure device,
The sound pressure level of audio signals having the same frequency is assumed to be constant, and the reference sound pressure level corrected by the equalizer is assumed to be constant.

In addition, the sound emitted from the speaker may vary depending on the speaker characteristics,
Even if the quality of the audio signal is changed due to the resonance effect between the speaker and the second microphone, the sound pressure level of each frequency that has passed through a constant sound pressure device and has a constant sound pressure level for each frequency will be changed by the equalizer. Since the sound emitted from the speaker is corrected in advance by taking into account the characteristics that change in quality before it is collected by the second microphone, the gain of the amplifier is adjusted by the control device so that it approaches the target exhaust discharge sound pressure level. When the sound pressure level of the audio signal is set and the amplifier increases or decreases the sound pressure level of the audio signal, the sound pressure level of the synthesized sound becomes a value closer to the target exhaust discharge sound sound pressure level, and the sound pressure level of the synthesized sound becomes the target exhaust discharge sound sound pressure level. The time required for the pressure to decay to the pressure level can be significantly shortened.

In the automobile exhaust tone improvement device according to claim 2, engine speed and engine load are input to the control device, and a target exhaust discharge sound sound pressure level corresponding to the engine speed and engine load is derived within the control device. It will be destroyed.

On the other hand, the intake sound of the intake system of the engine is collected by the first microphone and converted into an audio signal, and the audio signal other than the frequency component of a specific order determined by the engine rotation speed is detected from the audio signal from the first microphone. Passage is blocked by a first rotary synchronous filter, and the audio signal that has passed through this filter is decomposed into order components.

The audio signal of a predetermined order decomposed by the first rotary synchronous filter is input to the foot sound pressure device, and this sound pressure device converts the sound pressure level of the audio signal at the same frequency to a constant level. The audio signal that has passed through
The sound pressure level for each frequency is corrected in advance by an equalizer, taking into consideration the characteristics of the sound emitted from the speaker being degraded before being collected by the second microphone.

In other words, the sound emitted from the speaker depends on the speaker characteristics,
The quality changes due to the resonance effect between the speaker and the second microphone, but this amount of change is measured in advance,
The sound pressure level of the audio signal that has passed through the constant sound pressure device is corrected by that amount.

The audio signal corrected by the equalizer is input to an amplifier whose gain is controlled by a control device, the sound pressure level of the audio signal is increased or decreased, the audio signal is converted into sound by a speaker, and is emitted from the exhaust system of the car. The synthesized sound, which is a combination of the sound from the speaker and the exhaust sound from the exhaust system of the car, is collected by a second microphone and converted into an audio signal. Among them, passage of the audio signal other than frequency components of a specific order determined by the engine rotation speed is blocked by the second rotation synchronization filter, and the audio signal is decomposed into each order component.

The audio signal at a predetermined order from this second rotary synchronous filter is input to the control device, and within this control device, the sound pressure level at the order peak of the audio signal and the target exhaust gas at the order peak of the same order as this sound pressure level are determined. The gain of the amplifier is controlled so that the sound pressure level at the order peak of the sound signal from the second microphone approaches the target exhaust sound pressure level. The sound pressure level of the audio signal from the microphone is increased or decreased.

That is, the control device increases the gain of the amplifier when the target exhaust discharge sound sound pressure level is higher, and decreases the gain of the amplifier when the target exhaust discharge sound sound pressure level is lower. The sound pressure level of a synthesized sound obtained by combining the sound from the speaker and the exhaust sound from the exhaust system of the automobile is controlled so as to approach the target exhaust discharge sound sound pressure level.

Therefore, even if an audio signal whose sound pressure level fluctuates greatly over time due to various influences such as the silencing characteristics of the exhaust system is recorded by the first microphone, when it passes through a constant sound pressure device, the same frequency signal will be recorded. The sound pressure level of the audio signal is assumed to be constant, and the reference sound pressure level corrected by the equalizer is assumed to be constant.

In addition, the sound emitted from the speaker may vary depending on the speaker characteristics,
Even if the quality of the audio signal is changed due to the resonance effect between the speaker and the second microphone, the sound pressure level of each frequency that has passed through a constant sound pressure device and has a constant sound pressure level for each frequency will be changed by the equalizer. Since the sound emitted from the speaker is corrected in advance by taking into account the characteristics that change in quality before it is collected by the second microphone, the gain of the amplifier is adjusted by the control device so that it approaches the target exhaust discharge sound pressure level. When the sound pressure level of the audio signal is set and the amplifier increases or decreases the sound pressure level of the audio signal, the sound pressure level of the synthesized sound becomes a value closer to the target exhaust discharge sound sound pressure level, and the sound pressure level of the synthesized sound becomes the target exhaust discharge sound sound pressure level. The time required for the pressure to decay to the pressure level can be significantly shortened.

In the automobile exhaust tone improvement device according to claim 3, since the control device includes the target value calculation device and the analog computer, the target exhaust discharge sound sound pressure level calculated by the target value calculation device and the second rotation rotation The audio signal at a predetermined order from the filter is input as an analog signal to an analog computer, and within this analog computer, the target exhaust discharge sound sound pressure level and the sound pressure level at the order peak of the audio signal are compared, and the sound pressure level at the order peak of the amplifier is compared. The gain is calculated, reducing the burden on the control device and speeding up the processing within the control device, significantly reducing the time it takes to attenuate the sound pressure level of the synthesized sound to the target exhaust sound pressure level. can do.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram showing an embodiment of an automobile exhaust tone improvement device according to the present invention. Figure 2 shows the frequency of 200Hz before being input to the constant sound pressure device.
It is a graph which shows the audio signal of. FIG. 3 is a graph showing an audio signal having a frequency of 2007 after passing through a constant sound pressure device. FIG. 4 is a flowchart showing an example of control by the control device shown in FIG. FIGS. 5 to 7 are graphs showing target exhaust discharge sound pressure levels with respect to engine speed and engine load. FIG. 8 is a graph showing a comparison between the amount of sound pressure level corrected by the equalizer and the amount of sound pressure level that changes in quality before the sound from the speaker is collected by the second microphone. FIG. 9 is an explanatory diagram showing another embodiment of the automobile exhaust tone improvement device according to the present invention. FIG. 10 is an explanatory diagram showing an automobile exhaust tone improvement device invented by the present applicant. FIG. 11 is a graph showing the audio signal at a frequency of 2007 before being input to the constant sound pressure device of FIG. FIG. 12 is a graph showing the audio signal of frequency 2007 after passing through the footstep sound pressure device of FIG. FIG. 13 is a flowchart showing a control example of the control device of FIG. 10. [Explanation of symbols of main parts] 51...Engine 53...Exhaust system 61...First microphone 63...First rotation periodic filter 68...Constant sound pressure device 69.91...・Amplifier 71...Speaker 75...Second microphone 76...Equalizer 77.89...Second rotation periodic filter 79.85...
-Control device 87...Target value calculation device 93...Analog computer. Fig. f'a'%t (S) Fig. Date iF4t (s) Fig. Fig. ■ Wave number (H2) Fig. Zu Reihatsu's 2; (Ito figure clear time t (S) figure day q P stain t (s)

Claims (3)

[Claims] (1) A first microphone that collects the exhaust sound immediately after it is emitted from the engine and converts it into an audio signal, and audio other than the frequency component of a specific order determined by the engine speed among the audio signals from this first microphone. A first rotary synchronous filter that blocks signal passage and decomposes the audio signal into order components; and a constant sound pressure device that converts the sound pressure level of the audio signal from the first rotary synchronous filter to a constant level for each frequency. and an amplifier that increases or decreases the sound pressure level of the audio signal at a predetermined order from this constant sound pressure device, and converts the audio signal that has passed through this amplifier into sound, generates it, and synthesizes it with the exhaust sound from the car's exhaust system. a second microphone that collects a synthesized sound obtained by combining the sound from the speaker and the exhaust sound from the exhaust system of the automobile and converts it into an audio signal; an equalizer that corrects the sound pressure level in advance by taking into account the characteristic that the sound produced from the speaker changes in quality before it is collected by the second microphone; a second rotary synchronous filter that blocks the passage of audio signals other than frequency components of a specific order determined by the number and decomposes the audio signal into each order component; and an audio signal of a predetermined order from the second rotary synchronous filter is inputted. , a control device that controls the gain of the amplifier by comparing the sound pressure level at the order peak of the audio signal with a target exhaust discharge sound sound pressure level at the order peak determined from the engine load and rotation speed. An automobile exhaust tone improvement device characterized by: (2) A first microphone that collects the intake sound of the intake system of the engine and converts it into an audio signal; a first rotary synchronous filter that blocks passage and decomposes the audio signal into each order component; a constant sound pressure device that converts the sound pressure level of the audio signal from the first rotary synchronous filter to a constant level for each frequency; An amplifier that increases or decreases the sound pressure level of an audio signal of a predetermined order from this constant sound pressure device, and a speaker that converts the audio signal that has passed through this amplifier into sound, produces it, and synthesizes it with the exhaust sound from the car's exhaust system. a second microphone that collects a synthesized sound obtained by combining the sound from the speaker and the exhaust sound from the exhaust system of the vehicle and converts it into an audio signal; and a sound pressure for each frequency that has passed through the constant sound pressure device. an equalizer that corrects the level in advance by taking into account the characteristic that the sound emitted from the speaker changes in quality before it is collected by the second microphone; A second rotary synchronous filter that blocks the passage of audio signals other than frequency components of a predetermined specific order and decomposes the audio signal into each order component, and an audio signal of a predetermined order from this second rotary synchronous filter is input. and a control device that controls the gain of the amplifier by comparing the sound pressure level at the order peak of the audio signal and the target exhaust discharge sound sound pressure level at the order peak determined from the engine load and rotation speed. An automobile exhaust tone improvement device featuring: (3) The control device includes a target value calculation device that calculates a target exhaust discharge sound sound pressure level at an order peak from the engine load and rotation speed, and an audio signal and a target exhaust discharge sound sound at a predetermined order from the second rotation synchronous filter. 3. An analog computer that receives a pressure level as an analog signal and calculates the gain of the amplifier by comparing the sound pressure level at the order peak of the audio signal with the target exhaust discharge sound pressure level. The vehicle exhaust tone improvement device described above.