IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
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출원번호 |
US-0738428
(2007-04-20)
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등록번호 |
US-7307394
(2007-12-11)
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발명자
/ 주소 |
- Denen,Dennis J.
- Young,Neil P.
- Moreau,Gary L.
- Pierson,Martin
- Grubba,Robert
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출원인 / 주소 |
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대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
4 인용 특허 :
94 |
초록
▼
A control and motor arrangement in accordance with the present invention includes a motor configured to generate a locomotive force for propelling the model train. The control and motor arrangement further includes a command control interface configured to receive commands from a command control uni
A control and motor arrangement in accordance with the present invention includes a motor configured to generate a locomotive force for propelling the model train. The control and motor arrangement further includes a command control interface configured to receive commands from a command control unit wherein the commands correspond to a desired speed. The control and motor arrangement still further includes a plurality of detectors configured to detect speed information of the motor, and a process control arrangement configured to receive the speed information from the sensors. The process control arrangement is further configured and arranged to generate a plurality of motor control signals based on the speed information for controlling the speed of said motor. The control and motor arrangement yet still further includes a motor control arrangement configured to cause power to be applied to the motor at different times in response to the motor control signals.
대표청구항
▼
What is claimed is: 1. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor adapted to detect speed of the model trai
What is claimed is: 1. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor adapted to detect speed of the model train; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; and a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the detected speed; wherein the controller further includes a memory storing data to be accessed upon a loss of power to the model train. 2. The model train of claim 1, wherein the sensor is further adapted to detect a rotational speed of the motor, and the sound generator is further adapted to generate the selected sound effect in correspondence with the rotational speed. 3. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor adapted to detect speed of the model train; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; and a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the detected speed; wherein the sensor is further adapted to detect a rotational position of the motor, and the sound generator is further adapted to generate the selected sound effect in correspondence with the rotational position. 4. The model train of claim 1, wherein the sound generator is further adapted to generate the selected sound effect reflecting an increased load condition upon detection of an increased amount of power provided to the motor. 5. The model train of claim 1, wherein the sound generator is further adapted to generate the selected sound effect reflecting a decreased load condition upon detection of a decreased amount of power provided to the motor. 6. The model train of claim 1, wherein the controller is adapted to detect the model train traveling up a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 7. The model train of claim 1, wherein the controller is adapted to detect the model train traveling down a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 8. The model train of claim 1, wherein the at least one command designates the desired speed of the model train. 9. The model train of claim 1, wherein the at least one command designates a desired operating condition of the model train. 10. The model train of claim 1, wherein the at least one command designates a desired direction of travel of the model train. 11. The model train of claim 1, wherein the at least one command designates the selected sound effect. 12. The model train of claim 1, further comprising a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator. 13. The model train of claim 12, wherein the power circuit is adapted to determine the level of the AC voltage between the respective track rails. 14. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor adapted to detect speed of the model train; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; and a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the detected speed; wherein the controller regulates the amount of power provided to the motor in order to simulate effects of inertia and the sound generator is adapted to generate the selected sound effect corresponding thereto. 15. The model train of claim 1, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired acceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 16. The model train of claim 1, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired deceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 17. The model train of claim 1, wherein the controller regulates the amount of power provided to the motor in order to maintain a constant speed of the model train. 18. The model train of claim 1, wherein the motor further comprises a DC motor. 19. The model train of claim 1, wherein the sensor further comprises an optical sensor. 20. The model train of claim 1, wherein the sensor further comprises at least one Hall effect detector. 21. The model train of claim 1, wherein the remote control interface further comprises a radio control interface. 22. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor operatively coupled to the motor to detect a rotational speed of the motor; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected rotational speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the amount of power provided to the motor; and a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator; wherein the controller further includes a memory storing data defining a relationship between the rotational speed of the motor and corresponding speed of the model train. 23. The model train of claim 22, wherein the memory further comprises a non-volatile memory. 24. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor operatively coupled to the motor to detect a rotational speed of the motor; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected rotational speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the amount of power provided to the motor; and a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator; wherein the controller further includes a memory storing data to be accessed upon a loss of power to the model train. 25. The model train of claim 22, wherein the sound generator is further adapted to generate the selected sound effect in correspondence with the rotational speed of the motor. 26. The model train of claim 22, wherein the sensor is further adapted to detect a rotational position of the motor, and the sound generator is further adapted to generate the selected sound effect in correspondence with the rotational position. 27. The model train of claim 22, wherein the sound generator is further adapted to generate the selected sound effect reflecting an increased load condition upon detection of an increased amount of power provided to the motor. 28. The model train of claim 22, wherein the sound generator is further adapted to generate the selected sound effect reflecting a decreased load condition upon detection of a decreased amount of power provided to the motor. 29. The model train of claim 22, wherein the controller is adapted to detect the model train traveling up a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 30. The model train of claim 22, wherein the controller is adapted to detect the model train traveling down a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 31. The model train of claim 22, wherein the at least one command designates the desired speed of the model train. 32. The model train of claim 22, wherein the at least one command designates a desired operating condition of the model train. 33. The model train of claim 22, wherein the at least one command designates a desired direction of travel of the model train. 34. The model train of claim 22, wherein the at least one command designates the selected sound effect. 35. The model train of claim 22, wherein the power circuit is adapted to determine the level of the AC voltage between the respective track rails. 36. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor operatively coupled to the motor to detect a rotational speed of the motor; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected rotational speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the amount of power provided to the motor; and a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator; wherein the controller regulates the amount of power provided to the motor in order to simulate effects of inertia and the sound generator is adapted to generate the selected sound effect corresponding thereto. 37. The model train of claim 22, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired acceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 38. The model train of claim 22, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired deceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 39. The model train of claim 22, wherein the motor further comprises a DC motor. 40. The model train of claim 22, wherein the sensor further comprises an optical sensor. 41. The model train of claim 22, wherein the sensor further comprises at least one Hall effect detector. 42. The model train of claim 22, wherein the remote control interface further comprises a radio control interface. 43. The model train of claim 22, wherein the controller regulates the amount of power provided to the motor in order to maintain a constant speed of the model train. 44. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor operatively coupled to the motor to detect a rotational speed of the motor; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected rotational speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the rotational speed of the motor; and a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator; wherein the controller further includes a memory storing data defining a relationship between the rotational speed of the motor and corresponding speed of the model train. 45. The model train of claim 44, wherein the memory further comprises a non-volatile memory. 46. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor operatively coupled to the motor to detect a rotational speed of the motor; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected rotational speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the rotational speed of the motor; and a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator; wherein the controller further includes a memory storing data to be accessed upon a loss of power to the model train. 47. The model train of claim 44, wherein the sound generator is further adapted to generate the selected sound effect in correspondence with the amount of power applied to the motor. 48. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor operatively coupled to the motor to detect a rotational speed of the motor; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected rotational speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the rotational speed of the motor; and a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator; wherein the sensor is further adapted to detect a rotational position of the motor, and the sound generator is further adapted to generate the selected sound effect in correspondence with the rotational position. 49. The model train of claim 44, wherein the sound generator is further adapted to generate the selected sound effect reflecting an increased load condition upon detection of an increased amount of power provided to the motor. 50. The model train of claim 44, wherein the sound generator is further adapted to generate the selected sound effect reflecting a decreased load condition upon detection of a decreased amount of power provided to the motor. 51. The model train of claim 44, wherein the controller is adapted to detect the model train traveling up a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 52. The model train of claim 44, wherein the controller is adapted to detect the model train traveling down a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 53. The model train of claim 44, wherein the at least one command designates the desired speed of the model train. 54. The model train of claim 44, wherein the at least one command designates a desired operating condition of the model train. 55. The model train of claim 44, wherein the at least one command designates a desired direction of travel of the model train. 56. The model train of claim 44, wherein the at least one command designates the selected sound effect. 57. The model train of claim 44, wherein the power circuit is adapted to determine the level of the AC voltage between the respective track rails. 58. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor operatively coupled to the motor to detect a rotational speed of the motor; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected rotational speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the rotational speed of the motor; and a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator; wherein the controller regulates the amount of power provided to the motor in order to simulate effects of inertia and the sound generator is adapted to generate the selected sound effect corresponding thereto. 59. The model train of claim 44, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired acceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 60. The model train of claim 44, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired deceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 61. The model train of claim 44, wherein the motor further comprises a DC motor. 62. The model train of claim 44, wherein the sensor further comprises an optical sensor. 63. The model train of claim 44, wherein the sensor further comprises at least one Hall effect detector. 64. The model train of claim 44, wherein the remote control interface further comprises a radio control interface. 65. The model train of claim 44, wherein the controller regulates the amount of power provided to the motor in order to maintain a constant speed of the model train. 66. A model train, comprising: a train car including a wheeled carriage adapted to travel on a track; a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor operatively coupled to the motor to detect a rotational speed of the motor; a remote control interface adapted to receive at least one user command; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting an operating condition for the model train, the controller using the detected rotational speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train in a manner that simulates effects of inertia; and a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the amount of power provided to the motor. 67. The model train of claim 66, wherein the controller further includes a memory storing data defining a relationship between the rotational speed of the motor and corresponding speed of the model train. 68. The model train of claim 67, wherein the memory further comprises a non-volatile memory. 69. The model train of claim 66, wherein the controller further includes a memory storing data to be accessed upon a loss of power to the model train. 70. The model train of claim 66, wherein the sound generator is further adapted to generate the selected sound effect in correspondence with the rotational speed of the motor. 71. The model train of claim 66, wherein the sensor is further adapted to detect a rotational position of the motor, and the sound generator is further adapted to generate the selected sound effect in correspondence with the rotational position. 72. The model train of claim 66, wherein the sound generator is further adapted to generate the selected sound effect reflecting an increased load condition upon detection of an increased amount of power provided to the motor. 73. The model train of claim 66, wherein the sound generator is further adapted to generate the selected sound effect reflecting a decreased load condition upon detection of a decreased amount of power provided to the motor. 74. The model train of claim 66, wherein the controller is adapted to detect the model train traveling up a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 75. The model train of claim 66, wherein the controller is adapted to detect the model train traveling down a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 76. The model train of claim 66, wherein the at least one command designates a desired speed of the model train. 77. The model train of claim 66, wherein the desired operating condition includes at least a desired direction of travel of the model train. 78. The model train of claim 66, wherein the at least one command designates the selected sound effect. 79. The model train of claim 66, further comprising a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator. 80. The model train of claim 79, wherein the power circuit is adapted to determine the level of the AC voltage between the respective track rails. 81. The model train of claim 66, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired acceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 82. The model train of claim 66, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired deceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 83. The model train of claim 66, wherein the motor further comprises a DC motor. 84. The model train of claim 66, wherein the sensor further comprises an optical sensor. 85. The model train of claim 66, wherein the sensor further comprises at least one Hall effect detector. 86. The model train of claim 66, wherein the remote control interface further comprises a radio control interface. 87. The model train of claim 66, wherein the controller regulates the amount of power provided to the motor in order to maintain a constant speed of the model train. 88. A model train set, comprising: a train track layout; a transformer operatively coupled to the train track layout to supply electrical power thereto; a remote control unit adapted to communicate at least one user command; and a train car including a wheeled carriage adapted to travel on the train track layout, the train car further comprising: a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor adapted to detect speed of the model train; a remote control interface adapted to receive the at least one user command from the remote control unit; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; and a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the detected speed; wherein the controller further includes a memory storing data to be accessed upon a loss of power to the model train. 89. The model train set of claim 88, wherein the sensor is further adapted to detect a rotational speed of the motor, and the sound generator is further adapted to generate the selected sound effect in correspondence with the rotational speed. 90. A model train set, comprising: a train track layout; a transformer operatively coupled to the train track layout to supply electrical power thereto; a remote control unit adapted to communicate at least one user command; and a train car including a wheeled carriage adapted to travel on the train track layout, the train car further comprising: a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor adapted to detect speed of the model train; a remote control interface adapted to receive the at least one user command from the remote control unit; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; and a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the detected speed; wherein the sensor is further adapted to detect a rotational position of the motor, and the sound generator is further adapted to generate the selected sound effect in correspondence with the rotational position. 91. The model train set of claim 88, wherein the sound generator is further adapted to generate the selected sound effect reflecting an increased load condition upon detection of an increased amount of power provided to the motor. 92. The model train set of claim 88, wherein the sound generator is further adapted to generate the selected sound effect reflecting a decreased load condition upon detection of a decreased amount of power provided to the motor. 93. The model train set of claim 88, wherein the controller is adapted to detect the model train traveling up a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 94. The model train set of claim 88, wherein the controller is adapted to detect the model train traveling down a grade and the sound generator is adapted to generate the selected sound effect corresponding thereto. 95. The model train set of claim 88, wherein the at least one command designates the desired speed of the model train. 96. The model train set of claim 88, wherein the at least one command designates a desired operating condition of the model train. 97. The model train set of claim 88, wherein the at least one command designates a desired direction of travel of the model train. 98. The model train set of claim 88, wherein the at least one command designates the selected sound effect. 99. The model train set of claim 88, wherein the electrical power applied by the transformer further comprises an AC voltage, and the train car further comprises a power circuit operatively coupled to the track, the power circuit including a rectifier adapted to convert an AC voltage between respective track rails to a DC voltage supplied to at least one of the motor, the controller, and the sound generator. 100. The model train of claim 99, wherein the power circuit is adapted to determine the level of the AC voltage between the respective track rails. 101. A model train set, comprising: a train track layout; a transformer operatively coupled to the train track layout to supply electrical power thereto; a remote control unit adapted to communicate at least one user command; and a train car including a wheeled carriage adapted to travel on the train track layout, the train car further comprising: a motor operatively coupled to the carriage to thereby cause the train car to travel along the track in at least one direction; a sensor adapted to detect speed of the model train; a remote control interface adapted to receive the at least one user command from the remote control unit; a controller operatively coupled to the motor, the sensor and the remote control interface, the controller being responsive to the at least one user command in selecting a desired speed for the model train, the controller using the detected speed in a closed feedback loop to regulate an amount of power provided to the motor in order to propel the model train at the desired speed; and a sound generator operatively coupled to the controller, the sound generator adapted to generate a selected sound effect in correspondence with the detected speed; wherein the controller regulates the amount of power provided to the motor in order to simulate effects of inertia and the sound generator is adapted to generate the selected sound effect corresponding thereto. 102. The model train of claim 88, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired acceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 103. The model train of claim 88, wherein the controller regulates the amount of power provided to the motor in order to simulate a desired deceleration rate and the sound generator is adapted to generate the selected sound effect corresponding thereto. 104. The model train of claim 88, wherein the controller regulates the amount of power provided to the motor in order to maintain a constant speed of the model train. 105. The model train of claim 88, wherein the motor further comprises a DC motor. 106. The model train of claim 88, wherein the sensor further comprises an optical sensor. 107. The model train of claim 88, wherein the sensor further comprises at least one Hall effect detector. 108. The model train of claim 88, wherein the remote control interface further comprises a radio control interface.
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