IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0451924
(2012-04-20)
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등록번호 |
US-8710777
(2014-04-29)
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발명자
/ 주소 |
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출원인 / 주소 |
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대리인 / 주소 |
Amin, Turocy & Watson, LLP
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인용정보 |
피인용 횟수 :
6 인용 특허 :
31 |
초록
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Systems and methods for estimating an inertia and a friction coefficient for a controlled mechanical system are provided. In one or more embodiments, an inertia estimator can generate a torque command signal that varies continuously over time during a testing sequence. The velocity of a motion syste
Systems and methods for estimating an inertia and a friction coefficient for a controlled mechanical system are provided. In one or more embodiments, an inertia estimator can generate a torque command signal that varies continuously over time during a testing sequence. The velocity of a motion system in response to the time-varying torque command signal is measured and recorded during the testing sequence. The inertia estimator then estimates the inertia and/or the friction coefficient of the motion system based on the torque command data sent to the motion system and the measured velocity data. In some embodiments, the inertia estimator estimates the inertia and the friction coefficient based on integrals of the torque command data and the velocity data.
대표청구항
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1. A method for estimating parameters of a motion system, comprising: generating a torque command signal that varies continuously over a time the time range comprising an acceleration phase and a deceleration phase;measuring velocity data for a motion device representing a velocity of the motion sys
1. A method for estimating parameters of a motion system, comprising: generating a torque command signal that varies continuously over a time the time range comprising an acceleration phase and a deceleration phase;measuring velocity data for a motion device representing a velocity of the motion system over the time range in response to the torque command signal; anddetermining an inertia of the motion system based on a product of an integral of the velocity data over the acceleration phase and an integral of the torque command signal over the deceleration phase. 2. The method of claim 1, wherein the generating the torque command signal comprises adjusting the torque command signal in accordance with a predefined testing sequence. 3. The method of claim 1, wherein the determining comprises: integrating the torque command signal and the velocity data over the acceleration phase to yield Uacc and Vacc, respectively;integrating the torque command signal and the velocity data over the deceleration phase to yield Udec and Vdec, respectively; anddetermining the inertia or as a function of Uacc, Vacc, Udec, and Vdec,where: Uacc=∫uacc(t),Vacc=∫vacc(t),Udec=∫udec(t),Vdec=∫Vdec(t),uacc(t) is a portion of the torque command signal corresponding to the acceleration phase,vacc(t) is a portion of the velocity data corresponding to the acceleration phase,udec(t) is a portion of the torque command signal corresponding to the deceleration phase, andvdec(t) is a portion of the velocity data corresponding to the deceleration phase. 4. The method of claim 1, further comprising determining at least one controller gain coefficient for the motion system based on the inertia. 5. The method of claim 2, wherein the adjusting the torque command signal comprises changing at least one of a direction or a rate of change of the torque command signal in response to the velocity of the motion system reaching a predefined velocity checkpoint. 6. The method of claim 3, wherein the determining the inertia comprises determining the inertia according to: J=UdecVacc-UaccVdecΔvdec(t)Vacc-Δvacc(t)Vdec, where: J is the inertia,Δvacc(t) is a difference between a velocity of the motion system at an end of the acceleration phase and a velocity of the motion system at a beginning of the acceleration phase, andΔvdec(t) is a difference between a velocity of the motion system at an end of the deceleration phase and a velocity of the motion system at a beginning of the deceleration phase. 7. The method of claim 3, further comprising: determining a friction coefficient of the motion system according to: B=Δvdec(t)Uacc-ΔvaccUdecΔvdec(t)Vacc-Δvacc(t)Vdec, where: B is the friction coefficient,Δvacc(t) is a difference between a velocity of the motion system at an end of the acceleration phase and a velocity of the motion system at a beginning of the acceleration phase, andΔvdec(t) is a difference between a velocity of the motion system at an end of the deceleration phase and a velocity of the motion system at a beginning of the deceleration phase. 8. The method of claim 4, wherein the determining the at least one controller gain coefficient comprises determining the at least one controller gain coefficient further based on a manually adjustable control system bandwidth. 9. A system for estimating mechanical parameters of a motion system, comprising: a memory; a processor configured to execute computer-executable components stored on the memory, the computer-executable components comprising:a torque command generator configured to generate a torque command signal that varies continuously over time during a testing sequence, the testing sequence comprising an acceleration phase and a deceleration phase;a velocity monitoring component configured to obtain velocity data representing a velocity of a motion system over time in response to the torque command signal; and an inertia component configured to estimate an inertia of the motion system based on a product of an integral of the velocity data over the acceleration phase and an integral of the torque command signal over the deceleration phase. 10. The system of claim 9, wherein the torque command generator is further configured to control the torque command signal in accordance with a torque function u(t), where U(t) is based on a set of predefined instructions associated with respective phases of the testing sequence. 11. The system of claim 9, wherein the inertia component is further configured to estimate the inertia as a function of Uacc, Vacc, Udec, and Vdec, where: Uacc=∫uacc(t),Vacc=∫vacc(t),Udec=∫udec(t),Vdec=∫Vdec(t),uacc(t) is a portion of the torque command signal corresponding to the acceleration phase of the testing sequence,vacc(t) is a portion of the velocity data corresponding to the acceleration phase,udec(t) is a portion of the torque command signal corresponding to the deceleration phase of the testing sequence, andvdec(t) is a portion of the velocity data corresponding to the deceleration phase. 12. The system of claim 9, further comprising an interface component configured to receive input specifying at least one of a limiting value for the torque command signal or velocity checkpoint used by the torque command generator to control the torque command signal. 13. The system of claim 9, further comprising a tuning component configured to generate at least one controller gain coefficient as a function of the inertia. 14. The system of claim 9, further comprising a friction coefficient component configured to estimate a friction coefficient of the motion system based on the torque command signal and the velocity data. 15. The system of claim 10, wherein the respective phases are triggered in response to the velocity of the motion system reaching respective defined velocity checkpoint values. 16. The system of claim 11, wherein the inertia component is further configured to estimate the inertia based on: J=UdecVacc-UaccVdecΔvdec(t)Vacc-Δvacc(t)Vdec, where: J is the inertia,Δvacc(t) is a difference between a velocity of the motion system at an end of the acceleration phase and a velocity of the motion system at a beginning of the acceleration phase, andΔvdec(t) is a difference between a velocity of the motion system at an end of the deceleration phase and a velocity of the motion system at a beginning of the deceleration phase. 17. The system of claim 11, further comprising a friction coefficient component configured to estimate a friction coefficient of the motion system based on: B=Δvdec(t)Uacc-ΔvaccUdecΔvdec(t)Vacc-Δvacc(t)Vdec, where, B is the friction coefficient,Δvacc(t) is a difference between a velocity of the motion system at an end of the acceleration phase and a velocity of the motion system at a beginning of the acceleration phase, andΔvdec(t) is a difference between a velocity of the motion system at an end of the deceleration phase and a velocity of the motion system at a beginning of the deceleration phase. 18. A non-transitory computer-readable medium having stored thereon computer-executable instructions that, in response to execution, cause a computer system to perform operations, comprising: generating a torque command signal that varies continuously over a time interval comprising an acceleration phase and a deceleration phase;obtaining velocity data from a controlled mechanical system; andestimating an inertia of the controlled mechanical system based on a product of an integral of the velocity data over the acceleration phase and an integral of the torque command signal over the deceleration phase. 19. The non-transitory computer-readable medium of claim 18, wherein the estimating comprises: integrating the torque command signal and the velocity data over the acceleration phase of the time interval to yield Uacc and Vacc, respectively;integrating the torque command signal and the velocity data over the deceleration phase of the time interval to yield Udec and Vdec, respectively; andestimating the inertia as a function of Uacc, Vacc, Udec, and Vdec,where: Uacc=∫uacc(t),Vacc=∫vacc(t),Udec=∫udec(t),Vdec=∫Vdec(t),uacc(t) is a portion of torque command signal corresponding to the acceleration phase,vacc(t) is a portion of the velocity data corresponding to the acceleration phase,udec(t) is a portion of the torque command signal corresponding to the deceleration phase, andvdec(t) is a portion of the velocity data corresponding to the deceleration phase. 20. The non-transitory computer-readable medium of claim 19, wherein the operations further comprise estimating of the controlled mechanical system as a function of Uacc, Vacc, Udec and Vdec.
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