System for improving timekeeping and saving energy on long-haul trains
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G05B-013/02
G05B-019/18
출원번호
UP-0515946
(2003-05-20)
등록번호
US-7822491
(2010-11-15)
우선권정보
AU-PS 2411(2002-05-20)
국제출원번호
PCT/AU2003/000604
(2003-05-20)
§371/§102 date
20060223
(20060223)
국제공개번호
WO03/097424
(2003-11-27)
발명자
/ 주소
Howlett, Philip George
Pudney, Peter John
출원인 / 주소
Ausrail Technologies Pty Limited
대리인 / 주소
Bose McKinney & Evans LLP
인용정보
피인용 횟수 :
14인용 특허 :
5
초록▼
A method and system for the operation of trains on a rail network, and particularly in the context of long-haul rail networks. The invention provides a method and system which monitors the progress of a train on a long-haul network, calculates efficient control profiles for the train, and displays d
A method and system for the operation of trains on a rail network, and particularly in the context of long-haul rail networks. The invention provides a method and system which monitors the progress of a train on a long-haul network, calculates efficient control profiles for the train, and displays driving advice to the train crew. The system calculates and provides driving advice that assists to keep the train on time and reduce the energy used by the train by: (i) monitoring the progress of a journey to determine the current location and speed of the train; (ii) estimating some parameters of a train performance model; (iii) calculating or selecting an energy-efficient driving strategy that will get the train to the next key location as close as possible to the desired time; and (iv) generating and providing driving advice for the driver.
대표청구항▼
The invention claimed is: 1. A method of monitoring the progress of a train on a rail network and providing driving advice in real time to an operator of the train, said method comprising: (i) estimating or determining parameters of the train; (ii) determining, by an optimal control algorithm emplo
The invention claimed is: 1. A method of monitoring the progress of a train on a rail network and providing driving advice in real time to an operator of the train, said method comprising: (i) estimating or determining parameters of the train; (ii) determining, by an optimal control algorithm employing an adjoint variable, an optimal journey profile for a journey from the train's current location to a target location that results in the train arriving at the target location as close as possible to a desired time and with minimum energy usage; said optimal journey profile including a speed profile for the train, sequence of discrete control modes for the train, and associated switching points between the control modes; the optimal journey profile being determined by solving a system of differential equations for the speed profile of the train and for the value of the adjoint variable and wherein the sequence of discrete control modes is a function of the value of the adjoint variable and is determined as the speed profile is calculated, and wherein drive, hold, coast and brake control modes are each utilizable as one of the control modes in said sequence of discrete control modes; (iii) monitoring the current state of the train as it progresses to said target location; and (iv) generating said driving advice for the train operator by comparing the current state of the train to a corresponding state on said optimal journey profile and displaying said advice for the train operator that will keep the train close to said optimal journey profile. 2. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein steps (i) to (iv) are performed as required so that said driving advice automatically adjusts to compensate for any operational disturbances encountered by the train. 3. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein said parameters include train mass and mass distribution. 4. The method of monitoring the progress of a train on a rail network as claimed in claim 3, wherein said parameters further include maximum tractive efforts and maximum braking effort as functions of speed. 5. The method of monitoring the progress of a train on a rail network as claimed in claim 3, wherein said parameters further include coefficient(s) of rolling resistance. 6. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein said driving advice is generated and displayed by a computer located on the train. 7. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein step (iii) involves processing data from a GPS unit and train controls to determine the location and speed of the train. 8. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein said optimal journey profile specifies the time, speed and control at each location between the current train location and the next target location on the network. 9. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein said optimal journey profile is precomputed. 10. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein the discrete control modes for the train include drive, hold, coast and brake modes. 11. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein the adjoint variable evolves according to a differential equation along with the position and speed of the train. 12. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein the value of the adjoint variable is calculated directly from the speed of the train. 13. The method of monitoring the progress of a train on a rail network as claimed in claim 1, wherein a numerical method is used to solve the system of differential equations for the speed profile of the train and for the value of the adjoint variable. 14. A method of monitoring the progress of a train on a rail network and providing information on the progress of the train in real time to an operator of the train, said method comprising: (i) estimating or determining parameters of the train; (ii) determining, by an optimal control algorithm employing an adjoint variable, an optimal journey profile for a journey from the train's current location to a target location that results in the train arriving at the target location as close as possible to a desired time and with minimum energy usage; said optimal journey profile including a speed profile for the train, sequence of discrete control modes for the train, and associated switching points between the control modes; the optimal journey profile being determined by solving a system of differential equations for the speed profile of the train and for the value of the adjoint variable and wherein the sequence of discrete control modes is a function of the value of the adjoint variable and is determined as the speed profile is calculated, and wherein drive, hold, coast and brake control modes are each utilizable as one of the control modes in said sequence of discrete control modes; (iii) monitoring the current state of the train as it progresses to said target location; and (iv) generating said information for the train operator by comparing the current state of the train to a corresponding state on said optimal journey profile and displaying said information for the train operator to assist in keeping the train close to said optimal journey profile. 15. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein steps (i) to (iv) are performed as required so that said driving advice automatically adjusts to compensate for any operational disturbances encountered by the train. 16. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein said parameters include train mass and mass distribution. 17. The method of monitoring the progress of a train on a rail network as claimed in claim 16, wherein said parameters further include maximum tractive efforts and maximum braking effort as functions of speed. 18. The method of monitoring the progress of a train on a rail network as claimed in claim 16, wherein said parameters further include coefficient(s) of rolling resistance. 19. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein said information is generated and displayed by a computer located on the train. 20. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein step (iii) involves processing data from a GPS unit and train controls to determine the location and speed of the train. 21. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein said optimal journey profile specifies the time, speed and control at each location between the current train location and the next target location on the network. 22. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein said optimal journey profile is precomputed. 23. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein the discrete control modes for the train include drive, hold, coast and brake modes. 24. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein the adjoint variable evolves according to a differential equation along with the position and speed of the train. 25. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein the value of the adjoint variable is calculated directly from the speed of the train. 26. The method of monitoring the progress of a train on a rail network as claimed in claim 14, wherein a numerical method is used to solve the system of differential equations for the speed profile of the train and for the value of the adjoint variable. 27. A method of controlling the progress of a train on a rail network, said method comprising: (i) estimating or determining parameters of the train; (ii) determining, by an optimal control algorithm employing an adjoint variable, an optimal journey profile for a journey from the train's current location to a target location that results in the train arriving at the target location as close as possible to a desired time and with minimum energy usage; said optimal journey profile including a speed profile for the train, sequence of discrete control modes for the train, and associated switching points between the control modes; the optimal journey profile being determined by solving a system of differential equations for the speed profile of the train and for the value of the adjoint variable and wherein the sequence of discrete control modes is a function of the value of the adjoint variable and is determined as the speed profile is calculated, and wherein drive, hold, coast and brake control modes are each utilizable as one of the control modes in said sequence of discrete control modes; (iii) monitoring the current state of the train as it progresses to said target location; and (iv) comparing the current state of the train to a corresponding state on the optimal journey profile and then controlling the train to keep the train close to the optimal journey profile. 28. The method of controlling the progress of a train on a rail network as claimed in claim 27, wherein the discrete control modes for the train include drive, hold, coast and brake modes. 29. The method of controlling the progress of a train on a rail network as claimed in claim 27, wherein the adjoint variable evolves according to a differential equation along with the position and speed of the train. 30. The method of controlling the progress of a train on a rail network as claimed in claim 27, wherein the value of the adjoint variable is calculated directly from the speed of the train. 31. The method of controlling the progress of a train on a rail network as claimed in claim 27, wherein a numerical method is used to solve the system of differential equations for the speed profile of the train and for the value of the adjoint variable. 32. The method of controlling the progress of a train on a rail network as claimed in claim 27, wherein steps (i) to (iv) are performed as required so as to automatically adjust to compensate for any operational disturbances encountered by the train. 33. The method of controlling the progress of a train on a rail network as claimed in claim 27, wherein said parameters include train mass and mass distribution. 34. The method of controlling the progress of a train on a rail network as claimed in claim 33, wherein said parameters further include maximum tractive efforts and maximum braking effort as functions of speed. 35. The method of controlling the progress of a train on a rail network as claimed in claim 33, wherein said parameters further include coefficient(s) of rolling resistance. 36. The method of controlling the progress of a train on a rail network as claimed in claim 27, wherein step (iii) involves processing data from a GPS unit and train controls to determine the location and speed of the train. 37. The method of controlling the progress of a train on a rail network as claimed in claim 27, wherein said optimal journey profile specifies the time, speed and control at each location between the current train location and the next target location on the network. 38. The method of controlling the progress of a train on a rail network as claimed in claim 27, wherein said optimal journey profile is precomputed.
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