The present invention relates to an engine sound processing system that processes an engine sound of a vehicle (automobile) to reproduce the processed engine sound in an interior of the vehicle.
In the related art, the quiet is required of the interior of the vehicle. In particular, as with the engine sound, such a design is adopted that the engine sound does not escape into the interior of the vehicle to the utmost, by interposing the thick noise insulation material between the engine room and the interior of the vehicle, or the like.
However, it is impossible to say that the interior space of the vehicle in the above high quiet is always the most comfortable driving circumstances for the passenger of the vehicle. In other words, in some cases the driver as the driving fan, or the like feels more comfortable in the situation that such driver can hear the moderate engine sound in the interior of the vehicle as the driving circumstances.
In order to realize the taste of such driving fan, the systems for producing artificially the engine sound in the quiet interior of the vehicle were proposed.
As such system, for example, there were the system for capable of sounding the engine sound while emphasizing a part of the frequency band by generating the sinusoidal or pulse sound, which agrees with the number of revolution of the engine (which synchronizes with the engine sound), to emit into the interior of the vehicle and then adding such sinusoidal or pulse sound to the engine sound that actually escapes into the interior of the vehicle (e.g., see Patent Literature 1, Patent Literature 2), the system for sounding a desired engine sound in the interior of the vehicle by recording a desired engine sound previously and then reproducing this recorded engine sound in response to the number of revolution of the engine (e.g., see Patent Literature 3), and others.
However, the systems set forth in Patent Literatures 1, 2, 3 also generates another sound that is different from the actual engine sound of the vehicle. Therefore, even if the driving conditions are sensed by using other types of sensors, the sound on which the actual engine sound is reflected exactly in response to the driving conditions cannot be always produced.
It is an object of the present invention to provide an engine sound processing system capable of generating an engine sound, which is processed with sterling reality, in an interior of a vehicle by collecting the actual engine sound and processing/ outputting the engine sound.
In order to solve the aforesaid object, the invention is characterized by having the following arrangement.
(1) An engine sound processing system comprising:
(2) The engine sound processing system according to (1), wherein the signal processing portion includes a sound insulating characteristic filter which simulates a sound insulating characteristic of a wall of the interior and an active filter characteristic of which is varied according to the driving condition.
(3) The engine sound processing system according to (1) further comprising a mixer that mixes engine sounds collected respectively by the plurality of microphones, and outputs it to the signal processing portion.
(4) The engine sound processing system according to (1), wherein the signal processing portion separately processes the engine sounds collected by the plurality of microphones.
(5) The engine sound processing system according to (1), wherein the plurality of sensors include at least one of a sensor for sensing an engine revolution, a sensor for sensing an accelerator opening angle, and a sensor for sensing a speed of the vehicle.
(6) The engine sound processing system according to (1), wherein the plurality of microphones are provided at at least one of an intake port, an exhaust port and a wall of an engine room.
(7) The engine sound processing system according to (1), wherein the microphones comprises a sound microphone or a vibration sensor.
In the present invention, the audio circuit for outputting the engine sound processed by the signal processing portion into the interior of the vehicle via the speaker may be provided in the engine sound processing system, otherwise the processed engine sound may be output via the existing vehicle audio device such as the vehicle stereo, or the like connected to the engine sound processing system.
In the present invention, the actual engine sound on which the driving conditions at that time are reflected exactly is collected, and then such engine sound is processed to emphasize further the driving conditions at that time. As a result, the actual engine sound that is emphasized further in response to the driving conditions at that time can be output into the interior of the vehicle, and also the interior space of the vehicle in which the driving fan feels comfortable can be produced.
As described above, according to the present invention, the actual engine sound is collected by a microphone installed outside the interior of the vehicle, and the engine sound capable of emphasizing the driving conditions by processing the actual engine sound can be output into the interior of the vehicle. Therefore, the realistic engine sound effect can be produced by the easy process, and also the interior space of the vehicle in which the driving fan feels comfortable can be produced.
Further, the engine sounds corrected by each microphone can be processed individually, effect of the engine sound can be changed to create comfortable vehicle interior space in response to preference of the driving fun.
An engine sound processing system as an embodiment of the present invention will be described with reference to the drawings hereinafter.
As shown in
Incidentally, since the microphones arranged at the respective positions can collect the different sounds depending on each arranged position, the system may be structured so that plural microphones are arranged at the respective arranged position and the collected sounds are mixed. For example, the microphone arranged at a wall surface of an engine room at the interior side can collect an operating sounds of difference portions of the engine depending on the arranged position. Therefore, the microphones may arranged at the wall surface of the engine room at the interior side and the sounds collected by the respective microphone are mixed. A mixing ratio is adjusted on the basis of the necessary sound quality and the engine operating noise is collected.
The microphone is not limited to a sound microphone. For example, a vibration sensor capable of picking up a vibration of audio frequency band can be employed, for example. by arranging the vibration sensor on the engine, the vibration of the audio frequency band of the engine can be directly collected, that is, the vibration of the engine before it is transformed into sound can be collected. Namely, the vibration sensor does not detect a vibration pulse of the engine but picks up a signal as a sound source of the engine. By arranging the vibration sensor at the intake port, the sound such as wind noise which is not related to the engine revolutions is not collected and only the intake sound can be collected. On the other hand, a sound microphone is arranged at the vicinity of the mounting portion of the muffler and an exhaust sound having a frequency peak corresponding to the engine revolution degree. Accordingly, the sound microphone and the vibration microphone can be arranged according to the arranged position.
Four speakers 41, i.e., front left and right speakers and rear left and right speakers, are provided in the interior of the vehicle. These speakers 41 are used commonly in the audio device, and are not originally designed for the engine sound processing system. In other words, in this engine sound processing system, the engine sound is collected and processed, then the audio signal is input into a vehicle audio device 5, and then the engine sound is output into the interior of the vehicle via the vehicle audio device 5.
In
The signals, a frequency band and a signal level of which are limited by the filter 13 and the filter 23 respectively, are input into a signal processing portion 2. The signal processing portion 2 applies two-step filtering process to both the intake noise collected via the microphone 10 and the engine sound on the wall surface of the engine room collected via the microphone 20 in separate systems respectively. In this case, this filtering process may be executed in one system after both signals are mixed.
In the signal processing portion 2, a filter 14 and a filter 24 are filters that simulate the noise insulating characteristic of the wall surface of the interior of the vehicle. In other words, since the microphone 10 and the microphone 20 collect directly the sound in the engine room, the sound signal contains the mechanical noise in a high frequency range at a high level and thus is widely different from the engine sound that is heard in the interior of the vehicle by the passenger such as the driver, or the like. Therefore, in order to put this sound signal close to the quality of sound (frequency distribution) similar to the engine sound that is heard in the interior of the vehicle, the sound signal is processed into the sound, in which the high tone range is cut and the low tone range is left, by simulating the noise insulating characteristic of the wall surface of the interior of the vehicle by the filters 14, 24. This noise insulating characteristic may not be always detected by simulating the noise insulating characteristic of the vehicle into which this system is installed, and may be detected by simulating the noise insulating characteristic of the sports car or the high-class automobile.
In this case, the filter characteristic (noise insulating characteristic) of the filter 14 and the filter 24 maybe fixed, but their settings may be varied to change the sounding way of the engine sound.
Filter 15 and filter 25 of subsequent-stage are active filters the characteristics of which are changed in response to the driving conditions, and process the engine sound (the intake noise and the engine explosion sound collected by the microphone 10 and the microphone 20) in response to the driving conditions. Therefore, the filters 15, 25 are constituted by the active filter whose characteristic is changed in real time in response to the driving conditions. The change in the filter characteristic will be described later.
The intake noise and the engine explosion sound output from two-stage filter 14-filter 15 and a filter 24—a filter 25 are mixed into a sound signal in one system by a mixer 16, then is converted into analog audio signal by the D/A converter 17, and then is output to the audio device 5. The sound signal of this 1 system includes stereo outputs (L/R).
As the sensor for sensing the driving conditions, an engine revolution sensor 30 for sensing an engine revolution, an accelerator opening angle sensor 31 for sensing an opening angle of an accelerator, and a speed sensor 32 for sensing a speed of the vehicle are provided. Sensed values of respective sensors are input into a control portion 3 via an interface 33. An A/D converter is built in the interface 33 as the case may be. When the engine revolution sensor 30 and the speed sensor 32 are constituted by an encoder that outputs pulses in response to the revolution of the engine or the revolution of the axle, the control portion 3 may calculate the number of revolution of the engine and the speed based on an integrated value of the pulses or a pulse interval.
The control portion 3 determines parameters that define filter characteristics of the filter 15 and the filter 25 and a mixing ratio thereof according to the output of the sensors. The control portion 3 outputs the determined parameters and mixing ratio to the signal processing portion 2 to control the filter 15, the filter 25 and the mixer 16.
An operating portion 4 is connected to the control portion 3. This operating portion 4 maybe shared with the vehicle audio device 5, or the signal may be input from the operation portion of the audio device. The user (driver) sets control characteristics of the filters 15, 25 and the mixer 16 by operating the operating portion 4 in response to the driving conditions (outputs from the sensors 30, 31, 32). The user (driver) sets the filter characteristic (noise insulating characteristic) of the filters 14, 24 by operating the operating portion 4.
That is, a control system of the engine sound processing system is illustrated as shown in
In setting the filter characteristics and the mixing rate by the operating portion 4, one or plural parameters may be set in respective filters by the manual operation, or one or plural parameter sets are stored previously in the control portion 3 and then any of the parameter sets may be selected and set. In case a plurality of parameter sets are prepared, a parameter set to give the engine sound effect like a sports vehicle, a parameter set to give the engine sound effect like a cruising of a high-class motorcar, etc. are prepared previously and then the mode may be switched to a sports vehicle mode, a cruising mode, etc. In this case, of course it is possible that the engine sound effect should not be produced by turning OFF the function of the engine sound processing system.
The system may be provided with a connector for a flash memory and/or ROM pack, and a parameter set may be supplied from the flash memory and/or ROM pack. The parameter set may be supplied through a hard disc of a vehicle navigation system. The parameter set may be downloaded through an Internet. The system may be provided with a connector such as a LAN connector and structured so that the parameter set is supplied or an user can manually set the parameter through a computer (notebook-sized personal computer) connected to the system via the connector.
The arranged position of the microphones and the number of the microphones are not limited to the above embodiment.
The signals, frequency band and signal level of which are restricted by the filter 53 and the filter 63 are input to a mixer 70. The signals (intake sound and engine explosion sound), frequency band and signal level of which are restricted by the filter 13 and the filter 23 is output to an mixer 70 in the same manner. The mixer 70 outputs mixes the four signals and outputs to the signal processing portion 2 in two systems. The mixing ratio is controlled by the control portion 3. The signal processing portion 2 performs filtering process. The four signals may be output to the filter 14 and the filter 24 with a predetermined mixing ratio, and alternatively may be set by the user manually. For example, only a sound signal of the exhaust signal is input to the filter 14 and the other sound signals are input to the filter 24. The filter 14 and the filter 15 performs the filtering process only on the sound signal of the exhaust sound, and the filter 24 and the filter 25 performs the filtering process on the other signals. Therefore, the exhaust sound can be more emphasized than other sounds. As described above, the user can select the sound that the user wants to emphasize by changing mixing ration according to the user's preference.
Incidentally, the system may be structured so that filters are in response to a number of installed microphones and the filtering process is performed by each sound system.
Next,an example of the characteristic control of the filter 15 and the filter 25 will be explained with reference to
The horizontal axis of the graph shown in
In this case, the mixing rate is decided by a rate of the mixing weights of the mixing weight of the intake noise and the mixing weight of the wall surface noise. The above rules are decided based on the effect that “The low tone is emphasized to produce the engine atmosphere of the large engine capacity when the engine revolution is low, while the high tone is emphasized to emphasize the high-speed revolution of the engine when the engine revolution is high. Since the load is applied to the engine when the accelerator opening angle is large, not only the intake noise is increased but also the mixing rate of the intake noise is increased. Since the noises such as the wind noise, the tire noise, etc. except the engine sound are increased when the speed is high, the entire volume are increased.”, and this rule is applied to the sports car mode. The sports car mode employs the rule for emphasizing the driving conditions at the time in addition to the actual engine sound.
Another example of the characteristics control of the filter 15 and filter 26 will be described
The above rule is decided based on the effect that “when the engine revolution is low, the low tone is suppressed in order to emphasize a silent characteristic, and when the engine revolution is high, the low tone is emphasize into order to emphasize that a calm atmosphere that the high-class motorcar having large displacement engine have. When the accelerator opening angle is large, although a large load is normally applied to the engine and the intake sound is large, the low tone of the intake sound is suppressed in order to emphasize the silent characteristic. When the vehicle speed is high, although the entire volume and the engine explosion sound are large since the noise such as wind sound and the tire noise except the engine noise become large, the volume is increased by a small amount in view of importance of a silent characteristics. The mixing weight of the engine explosion sound and the intake sound are not changed depending on the engine revolution and the accelerator opening angle.”. This rule is applied to the cruising mode. The cruising mode employs this rule in order to provide a calm atmosphere to the user without emphasizing the engine sound as compared with the driving condition at that time.
In this case, center frequencies in the low tone range and the high tone range may be decided based on the frequency distribution of the engine sound. Normally the center frequency in the low tone range may be set to almost 500 Hz, and the center frequency in the high tone range may be set to almost 1000 Hz.
The control rules of the filter characteristics are not limited to the above rules.
In order to compose the filter characteristics on which the above rules are reflected exactly, for example, the filter characteristic curve may be derived by forming the function using respective sensor outputs as a variable and then inputting the sensor output into the function, or the filter characteristic curve may be derived by the fuzzy inference. The concerned filter characteristic may be read by formulating previously a table to decide the filter characteristic every predetermined steps of respective sensor outputs and then searching the table based on the sensor outputs. In any case, suppose that the information used to derive the filter characteristic based on the sensor outputs are contained in the above parameter sets that are set by the user.
Number | Date | Country | Kind |
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2004-067799 | Mar 2004 | JP | national |
2005-013330 | Jan 2005 | JP | national |