IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0920379
(2004-08-18)
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우선권정보 |
JP-2003-207685(2003-08-18) |
발명자
/ 주소 |
- Iwasaki,Katsuya
- Koyama,Kotaro
- Kubo,Jun
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출원인 / 주소 |
|
대리인 / 주소 |
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인용정보 |
피인용 횟수 :
9 인용 특허 :
7 |
초록
▼
In a vehicle attitude control system of an automotive vehicle employing a pump-and-motor assembly, and a hydraulic actuator that regulates fluid pressures in wheel-brake cylinders of road wheels of the vehicle, independently of each other, a control unit is electronically connected to at least a mot
In a vehicle attitude control system of an automotive vehicle employing a pump-and-motor assembly, and a hydraulic actuator that regulates fluid pressures in wheel-brake cylinders of road wheels of the vehicle, independently of each other, a control unit is electronically connected to at least a motor of the pump-and-motor assembly and the hydraulic actuator, for executing vehicle attitude control by controlling a discharge pressure of the motor-driven pump and by controlling the fluid pressures in the wheel-brake cylinders to respective desired fluid pressures independently of each other. A processing unit of the control unit is programmed to determine a duty ratio of a drive signal of the motor, based on the desired fluid pressure of at least one of the wheel-brake cylinders.
대표청구항
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What is claimed is: 1. A vehicle attitude control system of an automotive vehicle comprising: a hydraulic pump and motor assembly comprising at least one hydraulic pump and a motor driving the pump; a hydraulic actuator that regulates fluid pressures in wheel-brake cylinders of road wheels of the v
What is claimed is: 1. A vehicle attitude control system of an automotive vehicle comprising: a hydraulic pump and motor assembly comprising at least one hydraulic pump and a motor driving the pump; a hydraulic actuator that regulates fluid pressures in wheel-brake cylinders of road wheels of the vehicle, independently of each other; and a control unit being configured to be electronically connected to at least the motor and the hydraulic actuator, for executing vehicle attitude control by controlling a discharge pressure of the motor-driven pump and by controlling the fluid pressures in the wheel-brake cylinders to respective desired fluid pressures independently of each other; the control unit comprising a processor programmed to: determine a duty ratio of a drive signal of the motor, based on the desired fluid pressure of at least one of the wheel-brake cylinders; calculate duty ratios, needed for motor drive control, based on the respective desired fluid pressures of the wheel-brake cylinders of the road wheels; select a highest duty ratio of the duty ratios as the duty ratio of the drive signal of the motor; calculate a road-surface friction factor dependent duty-ratio maximum value based on a road-surface friction factor (μ); and execute a road-surface μ dependent duty-ratio limiter processing for limiting an upper limit value of the duty ratio of the drive signal of the motor to the road-surface μ dependent duty-ratio maximum value, wherein the road-surface μ dependent duty-ratio limiter processing comprises a select-low process by which a lower duty ratio of the selected highest duty ratio and the road-surface μ dependent duty-ratio maximum value is selected as the duty ratio of the drive signal of the motor. 2. The vehicle attitude control system as claimed in claim 1, wherein the processor is further programmed to: execute a traction-control period duty-ratio upper limiter processing for limiting an upper limit value of the duty ratio of the drive signal of the motor to a predetermined traction-control period duty-ratio maximum value. 3. The vehicle attitude control system as claimed in claim 2, wherein the traction-control period duty-ratio upper limiter processing comprises a select-low process by which a lower duty ratio of the predetermined traction-control period duty-ratio maximum value and the lower duty ratio of the selected highest duty ratio and the road-surface μ dependent duty-ratio maximum value is selected as the duty ratio of the drive signal of the motor. 4. The vehicle attitude control system as claimed in claim 3, wherein the processor is further programmed to: execute a vehicle dynamics control (VDC) period duty-ratio upper limiter processing for limiting an upper limit value of the duty ratio of the drive signal of the motor to a predetermined VDC period duty-ratio maximum value. 5. The vehicle attitude control system as claimed in claim 4, wherein the VDC period duty-ratio upper limiter processing comprises a select-low process by which a lower duty ratio of the predetermined VDC period duty-ratio maximum value and the lower duty ratio of the selected highest duty ratio and the road-surface μ dependent duty-ratio maximum value is selected as the duty ratio of the drive signal of the motor. 6. The vehicle attitude control system as claimed in claim 4, wherein the predetermined VDC period duty-ratio maximum value is set to be different from the predetermined traction-control period duty-ratio maximum value. 7. The vehicle attitude control system as claimed in claim 4, wherein the predetermined VDC period duty-ratio maximum value is switched between a predetermined understeer-control period duty-ratio maximum value suited for understeer control and a predetermined oversteer-control period duty-ratio maximum value suited for oversteer control, depending on whether the VDC is the understeer control or the oversteer control. 8. The vehicle attitude control system as claimed in claim 7, wherein the predetermined understeer-control period duty-ratio maximum value is set to be different from the predetermined oversteer-control period duty-ratio maximum value. 9. The vehicle attitude control system as claimed in claim 2, wherein the processor is further programmed to: execute a traction-control period duty-ratio lower limiter processing for limiting a lower limit value of the duty ratio of the drive signal of the motor to a predetermined traction-control period duty-ratio minimum value. 10. The vehicle attitude control system as claimed in claim 4, wherein the processor is further programmed to: execute a VDC period duty-ratio lower limiter processing for limiting a lower limit value of the duty ratio of the drive signal of the motor to a predetermined VDC period duty-ratio minimum value. 11. A vehicle attitude control system of an automotive vehicle for executing at least vehicle dynamics control (VDC), the system comprising: a hydraulic pump and motor assembly comprising at least one hydraulic pump and a motor driving the pump; a hydraulic actuator that regulates fluid pressures in wheel-brake cylinders of road wheels of the vehicle, independently of each other; and a control unit being configured to be electronically connected to at least the motor and the hydraulic actuator, for executing VDC by controlling a discharge pressure of the motor-driven pump and by controlling the fluid pressures in the wheel-brake cylinders to respective desired fluid pressures independently of each other; the control unit comprising a processor programmed to: determine a duty ratio of a drive signal of the motor, based on the desired fluid pressure of at least one of the wheel-brake cylinders during VDC, wherein the VDC is configured to control a yawing motion of the vehicle to reduce undesirable understeer or oversteer tendencies, and wherein the processor is programmed to determine the duty ratio of the drive signal of the motor, based on the desired fluid pressure of at least one of the wheel-brake cylinders by: (a) calculating a feedforward-control controlled variable EFFout(t) as a linear combination of a proportional term and a derivative term; the proportional term PF×EFFin(t) being obtained by multiplying an input signal EFFin(t) indicative of the desired fluid pressure with a feedforward proportional gain PF, and the derivative term DF×{dEFFin(t)/dt} being obtained by multiplying a derivative dEFFin(t)/dt of the input signal E FFin(t) with a feedforward derivative gain DF; (b) calculating a feedback-control controlled variable E FBout(t) as a linear combination of a proportional term and a derivative term; the proportional term PB×EFBin(t) being obtained by multiplying a deviation signal EFBin(t) between the input signal EFFin(t) indicative of the desired fluid pressure and a signal indicative of an actual wheel-brake cylinder pressure with a feedback proportional gain PB, and the derivative term DB×{dEFBin (t)/dt} being obtained by multiplying a derivative dEFBin(t)/dt of the deviation signal EFBin(t) with a feedback derivative gain DB; (c) calculating a sum EFFout(t)+EFBout(t) of the feedforward-control controlled variable EFFout(t) and the feedback-control controlled variable EFBout(t); and (d) determining the duty ratio of the drive signal of the motor based on the sum EFFout(t)+EFBout(t). 12. A vehicle attitude control method of simultaneously executing motor noise control and vehicle dynamics control (VDC) by controlling a discharge pressure of a pump driven by a motor of a vehicle and by controlling fluid pressures in wheel-brake cylinders of road wheels to respective desired fluid pressures independently of each other by a hydraulic actuator, the method comprising the steps of: determining a duty ratio of a drive signal of the motor, based on the desired fluid pressure of at least one of the wheel-brake cylinders during VDC, wherein the VDC is configured to control a yawing motion of the vehicle to reduce undesirable understeer or oversteer tendencies; calculating duty ratios, needed for motor drive control, based on the respective desired fluid pressures of the wheel-brake cylinders of the road wheels; selecting a highest duty ratio of the duty ratios; calculating a road-surface friction factor dependent duty-ratio maximum value based on a road-surface friction factor (μ); executing a road-surface μ dependent duty-ratio limiter processing for limiting an upper limit value of the duty ratio of the drive signal of the motor to the road-surface μ dependent duty-ratio maximum value by selecting a lower duty ratio of the selected highest duty ratio and the road-surface μ dependent duty-ratio maximum value; executing a traction-control period duty-ratio upper limiter processing for limiting the upper limit value of the duty ratio to a predetermined traction-control period duty-ratio maximum value by selecting a lower duty ratio of the predetermined traction-control period duty-ratio maximum value and the lower duty ratio of the selected highest duty ratio and the road-surface μ dependent duty-ratio maximum value; and executing a VDC period duty-ratio upper limiter processing for limiting the upper limit value of the duty ratio to a predetermined VDC period duty-ratio maximum value by selecting a lower duty ratio of the predetermined VDC period duty-ratio maximum value and the lower duty ratio of the selected highest duty ratio and the road-surface μ dependent duty-ratio maximum value. 13. A vehicle attitude control method of simultaneously executing motor noise control and vehicle dynamics control (VDC) by controlling a discharge pressure of a pump driven by a motor of a vehicle and by controlling fluid pressures in wheel-brake cylinders of road wheels to respective desired fluid pressures independently of each other by a hydraulic actuator, the method comprising the steps of: determining a duty ratio of a drive signal of the motor, based on the desired fluid pressure of at least one of the wheel-brake cylinders during VDC, wherein the VDC is configured to control a yawing motion of the vehicle to reduce undesirable understeer or oversteer tendencies, and wherein the step of determining the duty ratio of the drive signal of the motor, based on the desired fluid pressure of at least one of the wheel-brake cylinders, comprises: (a) calculating a feedforward-control controlled variable EFFout(t) as a linear combination of a proportional term and a derivative term; the proportional term PF×EFFin(t) being obtained by multiplying an input signal EFFin(t) indicative of the desired fluid pressure with a feedforward proportional gain PF, and the derivative term DF×{dEFFin(t)/dt} being obtained by multiplying a derivative dEFFin(t)/dt of the input signal E FFin(t) with a feedforward derivative gain DF; (b) calculating a feedback-control controlled variable E FBout(t) as a linear combination of a proportional term and a derivative term; the proportional term PB×EFBin(t) being obtained by multiplying a deviation signal EFBin(t) between the input signal EFFin(t) indicative of the desired fluid pressure and a signal indicative of an actual wheel-brake cylinder pressure with a feedback proportional gain PB, and the derivative term DB×{dEFBin (t)/dt} being obtained by multiplying a derivative dEFBin(t)/dt of the deviation signal EFBin(t) with a feedback derivative gain DB; (c) calculating a sum EFFout(t)+EFBout(t) of the feedforward-control controlled variable EFFout(t) and the feedback-control controlled variable EFBout(t); and (d) determining the duty ratio of the drive signal of the motor based on the sum EFFout(t)+EFBout(t).
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