WO2011092833A1 - 擬似音発生装置及び擬似音発生方法 - Google Patents
擬似音発生装置及び擬似音発生方法 Download PDFInfo
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- WO2011092833A1 WO2011092833A1 PCT/JP2010/051189 JP2010051189W WO2011092833A1 WO 2011092833 A1 WO2011092833 A1 WO 2011092833A1 JP 2010051189 W JP2010051189 W JP 2010051189W WO 2011092833 A1 WO2011092833 A1 WO 2011092833A1
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- 238000000034 method Methods 0.000 title claims description 41
- 230000008859 change Effects 0.000 claims abstract description 50
- 238000009795 derivation Methods 0.000 claims abstract description 27
- 230000001133 acceleration Effects 0.000 claims abstract description 24
- 230000007246 mechanism Effects 0.000 claims abstract description 11
- 230000005236 sound signal Effects 0.000 claims description 57
- 230000009467 reduction Effects 0.000 claims description 38
- 230000008569 process Effects 0.000 claims description 31
- 238000003860 storage Methods 0.000 claims description 16
- 238000004364 calculation method Methods 0.000 claims description 9
- 238000012545 processing Methods 0.000 description 73
- 238000012937 correction Methods 0.000 description 31
- 238000005259 measurement Methods 0.000 description 24
- 238000006243 chemical reaction Methods 0.000 description 16
- 230000003321 amplification Effects 0.000 description 10
- 238000003199 nucleic acid amplification method Methods 0.000 description 10
- 230000007704 transition Effects 0.000 description 9
- 238000004088 simulation Methods 0.000 description 8
- 238000010586 diagram Methods 0.000 description 7
- 238000002474 experimental method Methods 0.000 description 7
- 238000007796 conventional method Methods 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 230000004048 modification Effects 0.000 description 2
- 238000012986 modification Methods 0.000 description 2
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60Q—ARRANGEMENT OF SIGNALLING OR LIGHTING DEVICES, THE MOUNTING OR SUPPORTING THEREOF OR CIRCUITS THEREFOR, FOR VEHICLES IN GENERAL
- B60Q5/00—Arrangement or adaptation of acoustic signal devices
- B60Q5/005—Arrangement or adaptation of acoustic signal devices automatically actuated
- B60Q5/008—Arrangement or adaptation of acoustic signal devices automatically actuated for signaling silent vehicles, e.g. for warning that a hybrid or electric vehicle is approaching
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
- G10K15/00—Acoustics not otherwise provided for
- G10K15/02—Synthesis of acoustic waves
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L2270/00—Problem solutions or means not otherwise provided for
- B60L2270/42—Means to improve acoustic vehicle detection by humans
Definitions
- the present invention relates to a pseudo sound generating device, a pseudo sound generating method, a pseudo sound generating program, and a recording medium on which the pseudo sound generating program is recorded.
- Patent Document 1 a technique for generating a pseudo engine sound corresponding to the traveling state of the vehicle in the passenger compartment has been proposed (see Patent Document 1: hereinafter referred to as “conventional example”).
- this conventional technique when generating pseudo engine sound based on travel information such as engine speed, throttle opening (accelerator opening), and vehicle speed, the volume is adjusted according to the sound collection result of the sound in the passenger compartment. It comes to adjust.
- the present invention has been made in view of the above circumstances, and provides a simulated sound generating apparatus and a simulated sound generating method capable of generating a simulated sound that does not cause discomfort to passengers in a vehicle interior. With the goal.
- the present invention is a pseudo-sound generator mounted on a vehicle including a drive mechanism, the acquisition unit acquiring travel information reflecting the operation state of the drive mechanism; A derivation unit that derives pseudo sound related information including rotation speed information corresponding to the engine speed based on the running information; a generation unit that generates a pseudo sound signal having a waveform corresponding to the derived pseudo sound related information; A reduction in which the level of the pseudo sound signal is reduced at a first time change rate when a state in which the change in the rotation speed information included in the derived pseudo sound related information is within a predetermined range continues for a predetermined time; A control unit that performs designation; an adjustment unit that adjusts a level of the pseudo sound signal according to a designation from the control unit; and a scan unit that outputs a pseudo sound according to the pseudo sound signal whose level is adjusted by the adjustment unit.
- a pseudo-sound generating apparatus comprising: a; and over months.
- an adjustment unit that adjusts a level of a pseudo sound signal according to level designation; and a speaker that outputs a pseudo sound according to the pseudo sound signal whose level is adjusted by the adjustment unit.
- a dummy sound generating method characterized by comprising a; and a control step performs reduction designation of reducing by 1 hour rate of change.
- the present invention is a pseudo sound generation program characterized in that the pseudo sound generation method of the present invention is executed by a calculation unit.
- the present invention is a recording medium in which the pseudo sound generation program of the present invention is recorded so as to be readable by an arithmetic unit.
- FIG. 1 is a block diagram schematically showing a configuration of a pseudo engine sound generating apparatus according to a first embodiment of the present invention. It is a block diagram which shows the structure of the digital processing part of FIG. It is a figure which shows the example of the gear shift table of FIG. It is a figure which shows the example of the waveform table of FIG. It is a figure which shows the transition of the operation mode in the level control part of FIG. It is a block diagram which shows the structure of the analog process part of FIG. It is a flowchart for demonstrating the derivation
- FIG. (1) for demonstrating the time change of a level designation
- FIG. (2) for demonstrating the time change of a level designation
- FIG. 6 is a diagram (No. 3) for describing a temporal change in a level specification value.
- FIG. (4) for demonstrating the time change of a level designation
- FIG. (5) for demonstrating the time change of a level designation
- It is a block diagram which shows roughly the structure of the pseudo
- FIG. 1 is a block diagram showing a schematic configuration of a pseudo engine sound generating apparatus 100A as a pseudo sound generating apparatus according to the first embodiment.
- the pseudo engine sound generating device 100A is mounted on a vehicle CR.
- the pseudo engine sound generation device 100A includes an acquisition unit 110A, a digital processing unit 120A, an analog processing unit 130, and a speaker 140.
- the acquisition unit 110A described above includes an acceleration sensor, and measures the acceleration acting on the vehicle CR. Then, the acquisition unit 110A converts the measurement result obtained by the acceleration sensor into a signal ACD that can be processed by the digital processing unit 120A, and sends the acceleration information to the digital processing unit 120A.
- the acquisition unit 110A receives the measurement signal SPS sent from the vehicle speed sensor 910 installed in the vehicle CR. Then, the acquiring unit 110A transmits the vehicle speed information to the digital processing unit 120A by converting the measurement signal SPS into a signal SPD in a form that can be processed by the digital processing unit 120A and sending the signal SPD to the digital processing unit 120A.
- the acquisition unit 110A sends the acceleration information and the vehicle speed information of the vehicle CR to the digital processing unit 120A as the traveling information of the vehicle CR.
- the digital processing unit 120A receives the signals ACD and SPD sent from the acquisition unit 110A. Then, the digital processing unit 120A generates a pseudo engine sound signal PED based on the signals ACD and SPD, and calculates a level designation value LVC. The pseudo engine sound signal PED generated in this way and the calculated level designation value LVC are sent to the analog processing unit 130. Details of the configuration of the digital processing unit 120A will be described later.
- the analog processing unit 130 receives the pseudo engine sound signal PED and the level designation value LVC sent from the digital processing unit 120A.
- the analog processing unit 130 generates an output sound signal AOS that has a level according to the level designation value LVC and is an analog signal having a waveform reflecting the pseudo engine sound signal PED.
- the output sound signal AOS generated in this way is sent to the speaker 140. Details of the configuration of the analog processing unit 130 will be described later.
- the speaker 140 receives the output sound signal AOS sent from the analog processing unit 130. Then, the speaker 140 outputs a pseudo engine sound according to the output sound signal AOS.
- the digital processing unit 120A includes a storage unit 121A, a derivation unit 122A, a generation unit 123, and a level control unit 124 as a control unit.
- the above storage unit 121A stores various information data used by the digital processing unit 120A.
- the information data thus stored in the storage unit 121A includes a gear shift table GST as a first storage unit and a waveform table WFT as a second storage unit.
- the gear shift position is registered in association with the vehicle speed.
- the gear shift position GSD is registered in association with the range of the vehicle speed V.
- the relationship between the vehicle speed and the gear shift position is an average relationship for the vehicle type of the vehicle CR, which is obtained in advance based on experiments, experiences, and the like.
- the waveform pattern of the pseudo engine sound is registered in association with the combination of the rotational speed information corresponding to the engine rotational speed and the accelerator information corresponding to the accelerator opening angle.
- a waveform pattern is registered in association with each combination of the range of the rotation speed information ER and the range of the accelerator information AR.
- the relationship between the combination of the range of the rotational speed information ER and the range of the accelerator information AR and the waveform pattern is an average relationship with respect to the vehicle type of the vehicle CR obtained in advance based on experiments, experiences, and the like. .
- the derivation unit 122A derives the accelerator information AR and the rotational speed information ER based on the signals ACD and SPD sent from the acquisition unit 110A. In such derivation, the derivation unit 122A first specifies the vehicle speed and acceleration of the vehicle CR based on the signals ACD and SPD.
- the deriving unit 122A derives accelerator information AR corresponding to the accelerator opening angle based on the specified vehicle speed and acceleration.
- the derived accelerator information AR is sent to the generation unit 123.
- the derivation unit 122A reads the gear shift position data GSD registered in the gear shift table GST in association with the specified vehicle speed. Then, the deriving unit 122A derives the rotational speed information ER corresponding to the engine rotational speed based on the read data GSD and the specified vehicle speed. The rotation speed information ER derived in this way is sent to the generation unit 123 and the level control unit 124.
- the generation unit 123 receives the accelerator information AR and the rotation speed information ER sent from the derivation unit 122A. Subsequently, the generation unit 123 reads the waveform pattern data WFD registered in the waveform table WFT in association with the combination of the accelerator information AR and the rotation speed information ER. And the production
- the level control unit 124 receives the rotation speed information ER sent from the deriving unit 122A. Then, the level control unit 124 calculates the level designation value LVC based on the rotation speed information ER.
- the level control unit 124 has a normal level control mode MD1 (hereinafter referred to as “mode MD1”) and a level-reducing control mode MD2 (hereinafter referred to as “mode MD2”) as operation modes. ), A reduced level control MD3 (hereinafter referred to as “mode MD3”) and a level increasing control mode MD4 (hereinafter referred to as “mode MD4”).
- mode MD1 normal level control mode
- mode MD2 level-reducing control mode MD2
- mode MD4 level increasing control mode MD4
- the operation mode is changed in accordance with the temporal change mode of the engine speed ER sent from the derivation unit 122A.
- level control unit 124 calculates level designation value LVC (T) [dB] corresponding to rotation speed information ER (T) at time T using the following equation (1).
- LVC (T) K 0 ⁇ ER (T) (1)
- K 0 Constant
- the constant K 0 is determined in advance based on experiments, simulations, experiences, and the like from the viewpoint of generating effective pseudo engine sound corresponding to the vehicle type of the vehicle CR.
- the predetermined time T TH is preliminarily determined based on experiments, simulations, experiences, etc., corresponding to the type of vehicle CR, from the viewpoint of the degree of user discomfort caused by continuous reproduction of substantially the same engine sound level. Determined.
- constant, K D from the viewpoint of reducing the discomfort caused by the lowering of the sound volume level, in response to vehicle type CR, experiments, simulations, are predetermined based on experience and the like.
- level control unit 124 calculates level designation value LVC (T) [dB] corresponding to rotation speed information ER (T) at time T using the following equation (3).
- LVC (T) K 0 ⁇ ER (T) ⁇ VC
- the maximum reduction correction amount ⁇ VC is preliminarily determined based on experiments, simulations, experiences, etc., corresponding to the vehicle type of the vehicle CR, from the viewpoint of reducing user discomfort by continuously reproducing the pseudo engine sound at substantially the same level. Determined.
- level control unit 124 uses level (4) below to specify the level corresponding to rotation speed information ER (T) at time T.
- LVC (T) [dB] is calculated.
- LVC (T) K 0 ⁇ ER (T) + K U ⁇ (T ⁇ T S2 ) ⁇ LVC (T S2 ) (4) K U : positive constant
- the constant K U in view of the rapid increase in volume level, corresponding to the vehicle type CR, experiments, simulations, are predetermined based on experience and the like.
- the level control unit 124 calculates the level designation value LVC based on the rotation speed information ER.
- the level designation value LVC calculated in this way is sent to the analog processing unit 130.
- the analog processing unit 130 includes a DA (Digital-to-Analogue) conversion unit 131, a level adjustment unit 132 as an adjustment unit, and a power amplification unit 133.
- DA Digital-to-Analogue
- the DA conversion unit 131 includes a DA converter.
- the DA converter 131 receives the pseudo engine sound signal PED sent from the digital processor 120A.
- the DA conversion unit 131 converts the pseudo engine sound signal PED into an analog signal.
- An analog conversion signal as a conversion result by the DA conversion unit 131 is sent to the level adjustment unit 132.
- the level adjusting unit 132 includes an electronic volume element or the like.
- the level adjustment unit 132 performs level adjustment processing on the analog conversion signal sent from the DA conversion unit 131 in accordance with the level designation value LVC sent from the digital processing unit 120A.
- a level adjustment signal that is an adjustment result by the level adjustment unit 132 is sent to the power amplification unit 133.
- the power amplification unit 133 includes a power amplifier.
- the power amplification unit 133 receives the level adjustment signal sent from the level adjustment unit 132.
- the power amplification unit 133 power-amplifies the level adjustment signal.
- An output sound signal AOS that is an amplification result by the power amplifier 133 is sent to the speaker 140.
- the acquisition unit 110A measures the acceleration of the vehicle CR using an acceleration sensor provided therein. Then, the acquiring unit 110A converts the acceleration measurement result into a signal ACD in a form that can be processed by the digital processing unit 120A, and sends the signal ACD to the digital processing unit 120A (see FIG. 1).
- the acquisition unit 110A receives the measurement signal SPS sent from the vehicle speed sensor 910. Then, the acquisition unit 110A converts the measurement signal SPS into a signal SPD in a form that can be processed by the digital processing unit 120A, and sends the signal SPD to the digital processing unit 120A (see FIG. 1).
- step S11 the derivation unit 122A determines whether or not it has newly received travel information. If the result of this determination is negative (step S11: N), the process of step S11 is repeated.
- step S11 If the derivation unit 122A newly receives travel information and the result of the determination in step S11 is affirmative (step S11: Y), the process proceeds to step S12.
- step S12 the derivation unit 122A specifies the vehicle speed and acceleration based on the travel information newly sent from the acquisition unit 110A.
- step S13 the deriving unit 122A derives the accelerator information AR and the rotation speed information ER based on the specified vehicle speed and acceleration.
- the deriving unit 122A derives the accelerator information AR based on the identified vehicle speed and acceleration.
- the accelerator information AR thus derived is sent to the generation unit 123.
- the deriving unit 122A In deriving the rotation speed information ER, the deriving unit 122A reads the gear shift position data GSD registered in the gear shift table GST in association with the specified vehicle speed. Then, the deriving unit 122A derives the rotation speed information ER based on the read data GSD and the specified vehicle speed. The rotation speed information ER derived in this way is sent to the generation unit 123 and the level control unit 124 (see FIG. 2). Then, the process returns to step S11.
- the rotational speed information ER is derived based on the vehicle speed and considering the gear shift position. For this reason, the derived rotational speed information ER does not increase monotonously as the vehicle speed increases, but changes as shown in FIG. 8 as the vehicle speed V increases.
- step S21 the generation unit 123 determines whether or not the accelerator information AR and the rotation speed information ER are newly received. If the result of this determination is negative (step S21: N), the process of step S21 is repeated.
- step S21 If the generation unit 123 newly receives the accelerator information AR and the rotation speed information ER and the result of determination in step S21 is affirmative (step S21: Y), the process proceeds to step S22.
- step S22 the generation unit 123 reads the waveform pattern data WFD registered in the waveform table WFT in association with the combination of the accelerator information AR and the rotation speed information ER newly sent from the derivation unit 122A.
- step S23 the generation unit 123 determines whether or not the waveform pattern should be changed by determining whether or not the newly read waveform pattern has changed from the current waveform pattern. If this determination is negative (step S23: N), the processing returns to step S21.
- step S23 the process proceeds to step S24.
- step S24 the generation unit 123 starts generating the pseudo engine sound signal PED based on the newly read waveform pattern.
- the pseudo engine sound signal PED generated in this way is sent to the analog processing unit 130 (see FIG. 2). Then, the process returns to step S21.
- step S24 The generation process of the pseudo engine sound signal PED based on the newly read waveform pattern started in step S24 is continued until the next step S24 is executed.
- step S31 the level control unit 124 determines whether or not it has newly received the rotation speed information ER. If the result of this determination is negative (step S31: N), the process of step S31 is repeated.
- step S31 If the level control unit 124 receives the rotation speed information ER newly and the determination result in step S31 is affirmative (step S31: Y), the process proceeds to step S32.
- step S32 the generation unit 123 calculates the level designation value LVC while transitioning between the modes MD1 to MD4 as described above, based on the rotation speed information ER newly sent from the derivation unit 122A.
- step S33 the level control unit 124 sends the newly calculated level designation value LVC to the analog processing unit 130 (see FIG. 2). Then, the process returns to step S31.
- the operation mode is changed to the mode MD2. That is, if the state in which the rotational speed information ER (T) is substantially constant continues for the time T TH during the operation in the mode MD1, the above-described condition 1 is satisfied, and the operation mode transitions to the mode MD2.
- the level control unit 124 uses the following equation (6) in which LVC (T S2 ) is ⁇ VC and time T S2 is time T 4 in the above equation (4).
- LVC (T) K 0 ⁇ ER (T) + K U ⁇ (T ⁇ T 4 ) ⁇ VC (6)
- the operation mode Transits to mode MD1.
- the level control unit 124 calculates the level designation value LVC (T) at each time with the level reduction correction amount set to “0” using the above-described equation (1).
- FIG. 12 shows the level designation value LVC (T) when the rotational speed information ER (T) exceeds the value (ER C1 + ⁇ ER) and changes toward the value ER C2 (> ER C1 + ⁇ ER).
- FIG. 13 also shows the level designation value LVC (T) when the rotational speed information ER (T) exceeds the value (ER C1 ⁇ ER) and changes toward the value ER C3 ( ⁇ ER C1 ⁇ ER). ) Is a time change example.
- the level control unit 124 calculates the level designation value LVC (T) at each time with the level reduction correction amount set to “0” using the above-described equation (1).
- FIG. 14 the level designation value LVC (T) when the rotation speed information ER (T) exceeds the value (ER C1 + ⁇ ER) and changes toward the value ER C4 (> (ER C1 + ⁇ ER)).
- FIG. 15 also shows the level designation value LVC when the rotation speed information ER (T) exceeds the value (ER C1 ⁇ ER) and changes toward the value ER C5 ( ⁇ (ER C1 ⁇ ER)).
- a time change example of (T) is shown.
- the pseudo engine sound signal PED and the level designation value LVC which are the results of the generation process of the pseudo engine sound signal PED and the calculation process of the level designation value LVC performed as described above, are sent from the digital processing unit 120A to the analog processing unit 130. It is done.
- the analog processing unit 130 When the analog processing unit 130 receives the pseudo engine sound signal PED and the level designation value LVC sent from the digital processing unit 120A, the analog processing unit 130 generates an output sound signal AOS. In generating the output sound signal AOS, in the analog processing unit 130, the DA conversion unit 131 that has received the pseudo engine sound signal PED performs DA conversion on the pseudo engine sound signal PED. Then, the DA conversion unit 131 sends an analog conversion signal, which is a result of the DA conversion, to the level adjustment unit 132 (see FIG. 6).
- the level adjustment unit 132 that has received the analog conversion signal sent from the DA conversion unit 131 performs level adjustment processing on the analog conversion signal in accordance with the level designation value LVC sent from the digital processing unit 120A. Then, the level adjustment unit 132 sends a level adjustment signal, which is a result of the level adjustment process, to the power amplification unit 133 (see FIG. 6).
- the power amplification unit 133 Upon receiving the level adjustment signal sent from the level adjustment unit 132, the power amplification unit 133 performs power amplification of the level adjustment signal. Then, the power amplifying unit 133 sends an output sound signal AOS, which is a result of power amplification, to the speaker 140 (see FIG. 6).
- the speaker 140 that has received the output sound signal AOS sent from the analog processing unit 130 outputs a pseudo engine sound in accordance with the output sound signal AOS. As a result, a pseudo engine sound based on the measurement result by the vehicle speed sensor 910 is output.
- the acquisition unit 110A uses the measurement result by the vehicle speed sensor 910 and the acceleration sensor in the acquisition unit 110A as travel information reflecting the operation state of the drive mechanism of the vehicle CR. Get the measurement results.
- the deriving unit 122A derives the accelerator information AR corresponding to the accelerator opening based on the vehicle speed information and the acceleration information.
- the deriving unit 122A derives the rotation speed information ER corresponding to the engine rotation speed while referring to the gear shift table GST in the storage unit 121A based on the vehicle speed information.
- the generation unit 123 refers to the waveform table WFT in the storage unit 121A based on the derived accelerator information AR and rotation speed information ER, and corresponds to the combination of the accelerator information AR and the rotation speed information ER. Specify the waveform pattern. Then, a pseudo engine sound signal having the specified waveform pattern is generated.
- the level control unit 124 calculates the level designation value LVC based on the derived rotational speed information ER.
- the level control unit 124 limits the maximum reduction correction amount ⁇ VC (> 0) to the maximum when the state where the change in the rotation speed information ER is within the predetermined range continues for the predetermined time T TH .
- the output sound level is reduced at the time change rate “ ⁇ K D ”.
- the discomfort caused by the fact that the pseudo engine sound having the same waveform pattern and constant volume continues to ring in the vehicle interior. Can be prevented.
- the level reduction correction amount is changed relatively slowly when increasing the level reduction correction amount because the state where the change in the rotation speed information ER is within the predetermined range has continued for a predetermined time. As a result, the uncomfortable feeling due to the change in the level reduction correction amount is prevented.
- the level reduction correction amount is set to the time change rate “ ⁇ K U ” using the level reduction correction amount at that time as a starting value.
- the output sound level is increased with the time rate of change“ K D ”.
- FIG. 16 schematically shows the configuration of a pseudo engine sound generating apparatus 100B according to the second embodiment.
- the acquisition unit 110B is provided instead of the acquisition unit 110A
- the digital processing unit 120B is provided instead of the digital processing unit 120A. Is different. Hereinafter, description will be given mainly focusing on these differences.
- the acquisition unit 110B receives the measurement signal AAS sent from the accelerator information sensor 920 installed in the vehicle CR and the measurement signal ERS sent from the rotation speed information sensor 930. Then, the acquisition unit 110B converts the measurement signal AAS into a signal AAD in a form that can be processed by the digital processing unit 120B, and sends the signal AAD to the digital processing unit 120B. In addition, the acquisition unit 110B converts the measurement signal ERS into a signal ERD that can be processed by the digital processing unit 120B, and sends the signal to the digital processing unit 120B.
- an accelerator information sensor 920 such as an accelerator opening sensor and a rotation speed information sensor 930 such as an engine speed mounted on the vehicle CR, and an ECU (Electrical Control Unit) that controls the traveling of the vehicle CR.
- an ECU Electronic Control Unit
- the measurement signals AAS and ERS are obtained.
- the data is supplied to the acquisition unit 110B.
- the digital processing unit 120B includes a storage unit 121B instead of the storage unit 121A as compared with the digital processing unit 120A described above, and a derivation unit 122B instead of the derivation unit 122A. Is different.
- the storage unit 121B is different from the storage unit 121A described above in that the gear shift table GST is not stored. Further, the deriving unit 122B derives the accelerator information AR based on only the signal AAD sent from the obtaining unit 110B without referring to the gear shift table GST, as compared with the deriving unit 122A described above, and from the obtaining unit 110B. The difference is that the rotational speed information ER is derived based only on the transmitted signal ERD.
- the acquisition unit 110B receives the measurement signal AAS sent from the accelerator information sensor 920 and the measurement signal ERS sent from the rotation speed information sensor 930. Then, the acquisition unit 110B generates a signal AAD obtained by converting the measurement signal AAS into a form that can be processed by the digital processing unit 120B, and a signal ERD obtained by converting the measurement signal ERS into a form that can be processed by the digital processing unit 120B. Then, the generated signals AAD and ERD are sent to the digital processing unit 120B (see FIG. 16).
- the derivation unit 122B When the derivation unit 122B receives the signals AAD and ERD sent from the acquisition unit 110B, the derivation unit 122B derives the accelerator information AR based on the signal AAD and derives the rotation speed information ER based on the signal ERD.
- the derived accelerator information AR is sent to the generation unit 123 as in the case of the first embodiment.
- the derived rotation speed information ER is sent to the generation unit 123 and the level control unit 124 as in the case of the first embodiment (see FIG. 17).
- the generating unit 123 When receiving the accelerator information AR and the rotation speed information ER newly derived by the deriving unit 122B, the generating unit 123 performs the same process as the process of FIG. 9 described above, as in the first embodiment. A pseudo engine sound signal PED is generated. The pseudo engine sound signal PED generated in this way is sent to the analog processing unit 130 (see FIG. 17).
- the level control unit 124 when receiving the rotational speed information ER newly derived by the deriving unit 122B, the level control unit 124 performs the same process as the process of FIGS. 10 to 15 described above, as in the case of the first embodiment. Then, the level designation value LVC is calculated. The level designation value LVC newly calculated in this way is sent to the analog processing unit 130 (see FIG. 17).
- the analog processing unit 130 When the analog processing unit 130 receives the pseudo engine sound signal PED and the level designation value LVC sent from the digital processing unit 120B, the analog processing unit 130 generates the output sound signal AOS in the same manner as in the first embodiment.
- the output sound signal AOS generated in this way is sent to the speaker 140 (see FIG. 16).
- the speaker 140 that has received the output sound signal AOS sent from the analog processing unit 130 outputs a pseudo engine sound in accordance with the output sound signal AOS.
- the pseudo engine sound generated based on the measurement results by the accelerator information sensor 920 and the rotation speed information sensor 930 is output.
- the acquisition unit 110B acquires the measurement results by the accelerator information sensor 920 and the rotation speed information sensor 930 as travel information reflecting the operation state of the drive mechanism of the vehicle CR.
- the deriving unit 122B that has received these acquisition results derives the accelerator information AR corresponding to the accelerator opening based on the accelerator information sensor 920.
- the deriving unit 122B derives the rotation speed information ER corresponding to the engine rotation speed based on the measurement result of the rotation speed information sensor 930.
- the generation unit 123 refers to the waveform table WFT in the storage unit 121B on the basis of the derived accelerator information AR and rotation speed information ER in the same manner as in the first embodiment, and the accelerator opening AR And a waveform pattern corresponding to the combination of the rotation speed information ER. Then, a pseudo engine sound signal PED having the specified waveform pattern is generated.
- the level control unit 124 calculates the level designation value LVC based on the derived rotational speed information ER in the same manner as in the first embodiment.
- the level control unit 124 performs the maximum reduction correction when the state where the change in the rotation speed information ER is within the predetermined range continues for the predetermined time T TH as in the case of the first embodiment.
- the level reduction correction amount is increased due to the state where the change in the rotation speed information ER is within the predetermined range for a predetermined time, as in the case of the first embodiment, it is relatively slow. And the level reduction correction amount is changed. As a result, the uncomfortable feeling due to the change in the level reduction correction amount is prevented.
- the level reduction correction amount is set using the level reduction correction amount at that time as a starting value, as in the first embodiment.
- the output sound level is increased at the time change rate “K D ” by reducing the amount by the time change rate “ ⁇ K U ” (K U > K D ).
- the acceleration of the vehicle CR is measured by the acceleration sensor, but the acceleration of the vehicle CR may be calculated from the time change of the vehicle speed of the vehicle CR.
- working control of vehicle CR is used as a pseudo engine sound generator using a detection harness. It was made to supply to 100B.
- an accelerator depression amount sensor prepared separately from the accelerator information sensor 920 may be used, and the measurement result by the accelerator depression amount sensor may be used instead of the measurement result by the accelerator information sensor 920.
- the vehicle speed sensor 910 is used as a sensor that is standardly equipped on the vehicle CR.
- either the accelerator information sensor 920 or the rotation speed information sensor 930 can be easily used. If possible, derivation of either the accelerator information AR or the rotation speed information ER may be simplified by using the available sensors together.
- the level designation value may be increased at a constant rate of change until the level designation value when the level reduction correction is not performed is reached.
- the level specification value was increased.
- the level designation value may be reduced at a constant time change rate with the level designation value as a limit up to a predetermined constant value.
- the present invention is applied to the generation of the pseudo engine sound.
- the pseudo engine sound such as the running sound when the train travels on the rail is different from the pseudo engine sound.
- the present invention can also be applied to the generation of sound.
- the digital processing unit in the first and second embodiments is configured as a computer system including a central processing unit (CPU: Central : Processor Unit) and a DSP (Digital Signal Processor). It can be realized by executing a program. These programs may be acquired in a form recorded on a portable recording medium such as a CD-ROM or DVD, or may be acquired in a form distributed via a network such as the Internet. Good.
- CPU Central : Processor Unit
- DSP Digital Signal Processor
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- Audiology, Speech & Language Pathology (AREA)
- General Health & Medical Sciences (AREA)
- Multimedia (AREA)
- Mechanical Engineering (AREA)
- Fittings On The Vehicle Exterior For Carrying Loads, And Devices For Holding Or Mounting Articles (AREA)
- Electric Propulsion And Braking For Vehicles (AREA)
- Circuit For Audible Band Transducer (AREA)
Abstract
Description
まず、本発明の第1実施形態を、図1~図15を参照して説明する。
図1には、第1実施形態に係る擬似音発生装置としての擬似エンジン音発生装置100Aの概略的な構成が、ブロック図にて示されている。この図1に示されるように、擬似エンジン音発生装置100Aは、車両CRに搭載されている。そして、擬似エンジン音発生装置100Aは、取得部110Aと、デジタル処理部120Aと、アナログ処理部130と、スピーカ140とを備えている。
LVC(T)=K0・ER(T) …(1)
K0:定数
LVC(T)=K0・ER(T)-KD・(T-TS1) …(2)
KD:正の定数
LVC(T)=K0・ER(T)-ΔVC …(3)
LVC(T)=K0・ER(T)+KU・(T-TS2)-LVC(TS2) …(4)
KU:正の定数
次に、上記のように構成された擬似エンジン音発生装置100Aの動作について、デジタル処理部120Aにおける処理、すなわち、アクセル情報AR及び回転数情報ERの導出処理、擬似エンジン音信号PEDの生成処理及びレベル指定値LVCの算出処理に主に着目して説明する。
アクセル情報AR及び回転数情報ERの導出処理は、デジタル処理部120Aの導出部122Aが行う。かかる導出処理に際しては、図7に示されるように、まず、ステップS11において、導出部122Aが、新たに走行情報を受けたか否かを判定する。この判定の結果が否定的であった場合(ステップS11:N)には、ステップS11の処理が繰り返される。
擬似エンジン音信号PEDの生成処理は、デジタル処理部120Aの生成部123が行う。かかる生成処理に際しては、図9に示されるように、まず、ステップS21において、生成部123が、新たにアクセル情報AR及び回転数情報ERを受けたか否かを判定する。この判定の結果が否定的であった場合(ステップS21:N)には、ステップS21の処理が繰り返される。
レベル指定値LVCの算出処理は、デジタル処理部120Aのレベル制御部124が行う。かかる算出処理に際しては、図10に示されるように、ステップS31において、レベル制御部124が、新たに回転数情報ERを受けたか否かを判定する。この判定の結果が否定的であった場合(ステップS31:N)には、ステップS31の処理が繰り返される。
LVC(T)=K0・ER(T)-KD・(T-T2) …(5)
LVC(T)=K0・ER(T)+KU・(T-T4)-ΔVC …(6)
LVC(T)=K0・ER(T)+KU・(T-T6)-LVC(T6) …(7)
次に、本発明の第2実施形態を、図16,17を主に参照して説明する。本第2実施形態においても、第1実施形態の場合と同様に、擬似エンジン音発生装置を例示して説明する。
図16には、第2実施形態に係る擬似エンジン音発生装置100Bの構成が概略的に示されている。この図16に示されるように、上述した擬似エンジン音発生装置100Aと比べて、取得部110Aに代えて取得部110Bを備える点、及び、デジタル処理部120Aに代えてデジタル処理部120Bを備える点が異なる。以下、これらの相違点に主に着目して、説明する。
次に、上記のように構成された擬似エンジン音発生装置100Bの動作について、デジタル処理部120Bにおける処理に主に着目して説明する。
本発明は、上記の実施形態に限定されるものではなく、様々な変形が可能である。
Claims (14)
- 駆動機構を備える車両に搭載される擬似音発生装置であって、
前記駆動機構の動作状態を反映した走行情報を取得する取得部と;
前記取得された走行情報に基づいて、エンジン回転数に相当する回転数情報を含む擬似音関連情報を導出する導出部と;
前記導出された擬似音関連情報に対応した波形の擬似音信号を生成する生成部と;
前記導出された擬似音関連情報に含まれる前記回転数情報の変化が所定範囲内にある状態が所定時間にわたって継続した場合に、前記擬似音信号のレベルを第1時間変化率で低減させる低減指定を行う制御部と;
前記制御部からの指定に従って、前記擬似音信号のレベルを調整する調整部と;
前記調整部によりレベルが調整された擬似音信号に従って、擬似音を出力するスピーカと;
を備えることを特徴とする擬似音発生装置。 - 前記制御部は、前記導出された擬似音関連情報に含まれる前記回転数情報の変化が前記低減指定後に前記所定範囲から外れた場合に、前記擬似音信号のレベルを第2時間変化率で増加させる、ことを特徴とする請求項1に記載の擬似音発生装置。
- 前記第2時間変化率の絶対値は、前記第1時間変化率の絶対値よりも大きい、ことを特徴とする請求項2に記載の擬似音発生装置。
- 前記低減指定は、前記調整部に対して擬似音信号のレベルを所定値だけ低減させる指定である、ことを特徴とする請求項1~3のいずれか一項に記載の擬似音発生装置。
- 前記低減指定は、前記調整部に対して擬似音信号のレベルを所定値にまで低減させる指定である、ことを特徴とする請求項1~3のいずれか一項に記載の擬似音発生装置。
- 前記擬似音関連情報には、アクセル開度に相当するアクセル情報が更に含まれる、ことを特徴とする請求項1~5のいずれか一項に記載の擬似音発生装置。
- 前記走行情報には車両速度が含まれ、
前記導出部は、
前記取得された車両速度に基づいて、車両加速度を導出し、
前記取得された車両速度、及び、前記導出された車両加速度に基づいて、前記アクセル情報を導出する、
ことを特徴とする請求項6に記載の擬似音発生装置。 - 前記走行情報には車両速度及び車両加速度が含まれ、
前記導出部は、前記取得された車両速度及び車両加速度に基づいて、前記アクセル情報を導出する、
ことを特徴とする請求項6に記載の擬似音発生装置。 - 前記走行情報には車両速度が含まれ、
前記導出部は、前記取得された車両速度に基づいて、前記回転数情報を導出する、ことを特徴とする請求項1~8のいずれか一項に記載の擬似音発生装置。 - 前記車両速度とギアシフト位置とが関連付けられて記憶された第1記憶部を更に備え、
前記導出部は、前記第1記憶部において前記取得された車両速度に関連付けられているギアシフト位置を更に考慮して、前記回転数情報を導出する、
ことを特徴とする請求項9に記載の擬似音発生装置。 - 前記擬似音関連情報と、擬似音の信号波形情報とが関連付けられて記憶された第2記憶部を更に備え、
前記生成部は、前記第2記憶部を参照して、前記擬似音信号を生成する、
ことを特徴とする請求項1~10のいずれか一項に記載の擬似音発生装置。 - レベル指定に従って、擬似音信号のレベルを調整する調整部と;前記調整部によりレベルが調整された擬似音信号に従って、擬似音を出力するスピーカと;を備えて構成され、駆動機構を備える車両に搭載される擬似音発生装置において使用される擬似音発生方法であって、
前記駆動機構の動作状態を反映した走行情報を取得する取得工程と;
前記取得された走行情報に基づいて、エンジン回転数に相当する回転数情報を含む擬似音関連情報を導出する導出工程と;
前記導出された擬似音関連情報に対応した波形の擬似音信号を生成する生成工程と;
前記導出された擬似音関連情報に含まれる前記回転数情報の変化が所定範囲内にある状態が所定時間にわたって継続した場合に、前記擬似音信号のレベルを第1時間変化率で低減させる低減指定を行う制御工程と;
を備えることを特徴とする擬似音発生方法。 - 請求項12に記載の擬似音発生方法を演算部により実行させる、ことを特徴とする擬似音発生プログラム。
- 請求項13に記載の擬似音発生プログラムが、演算部により読取可能に記録されている、ことを特徴とする記録媒体。
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US13/575,739 US8955455B2 (en) | 2010-01-29 | 2010-01-29 | Device and method for pseudonoise generation |
JP2010534303A JP4669585B1 (ja) | 2010-01-29 | 2010-01-29 | 擬似音発生装置及び擬似音発生方法 |
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US20120323442A1 (en) | 2012-12-20 |
JPWO2011092833A1 (ja) | 2013-05-30 |
WO2011092961A1 (ja) | 2011-08-04 |
JP4669585B1 (ja) | 2011-04-13 |
US8955455B2 (en) | 2015-02-17 |
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