A driving system for a vehicle includes drive source, a driven portion, a unidirectional power transmitting unit provided on a power transmission path between the drive source and the driven portion, and having a first member, a second member, and an engaging element interposed between the first member and the second member, and an eccentricity acquiring unit adapted to acquire an eccentricity, the eccentricity being a magnitude of deviation between the rotational axis of the first member and the rotational axis of the second member.

A driving system for a vehicle includes drive source, a driven portion, a unidirectional power transmitting unit provided on a power transmission path between the drive source and the driven portion, and having a first member, a second member, and an engaging element interposed between the first member and the second member, and an eccentricity acquiring unit adapted to acquire an eccentricity, the eccentricity being a magnitude of deviation between the rotational axis of the first member and the rotational axis of the second member.

Provided is an engagement position storage device capable of detecting a clutch engagement position of a vehicle finely and a brake system including such a device. In an engagement position storage device 2b that stores an engagement position of a clutch to engage and disengage power of a vehicle, when the vehicle becomes a traveling state in predetermined duration after acceleration in a front-back direction of the vehicle changes, the engagement position storage device 2b stores a clutch engagement position based on a clutch position detected when the acceleration changes. A brake system 1 includes a wheel latching mechanism 5 that latches wheels of a vehicle by driving a propelling member 5a by driving devices 3 and 4; and a controller 2 that controls driving of the propelling member 5a of the wheel latching mechanism 5 based on a clutch engagement position stored in the engagement position storage device 2b.

Provided is an engagement position storage device capable of detecting a clutch engagement position of a vehicle finely and a brake system including such a device. In an engagement position storage device 2b that stores an engagement position of a clutch to engage and disengage power of a vehicle, when the vehicle becomes a traveling state in predetermined duration after acceleration in a front-back direction of the vehicle changes, the engagement position storage device 2b stores a clutch engagement position based on a clutch position detected when the acceleration changes. A brake system 1 includes a wheel latching mechanism 5 that latches wheels of a vehicle by driving a propelling member 5a by driving devices 3 and 4; and a controller 2 that controls driving of the propelling member 5a of the wheel latching mechanism 5 based on a clutch engagement position stored in the engagement position storage device 2b.

Control systems and methods for facilitating human control of complex systems, including complex mechanical systems, are provided. The control system can include one or more user input devices adapted to receive user inputs in various forms. Electronic signals generated by the user input devices in response to the user inputs are provided to a controller, which processes the signals, validates and prioritizes those signals, and generates appropriate control signals. The control signals are then provided to the controlled system. User feedback regarding the operation of the control system, the controlled system, an operating environment, or the like, can be delivered to the user through the control system.

Control systems and methods for facilitating human control of complex systems, including complex mechanical systems, are provided. The control system can include one or more user input devices adapted to receive user inputs in various forms. Electronic signals generated by the user input devices in response to the user inputs are provided to a controller, which processes the signals, validates and prioritizes those signals, and generates appropriate control signals. The control signals are then provided to the controlled system. User feedback regarding the operation of the control system, the controlled system, an operating environment, or the like, can be delivered to the user through the control system.

Systems and methods for vehicle mode scheduling with learned user preferences include monitoring vehicle data when a vehicle changes from a first mode to a second mode. The method also includes analyzing the vehicle data to identify a preference for the second mode during a driving context. Additionally, the method includes generating a recommendation on whether to switch to the second mode while traversing a route based on the vehicle data, and the driving context, and presenting the recommendation to the driver.

Systems and methods for vehicle mode scheduling with learned user preferences include monitoring vehicle data when a vehicle changes from a first mode to a second mode. The method also includes analyzing the vehicle data to identify a preference for the second mode during a driving context. Additionally, the method includes generating a recommendation on whether to switch to the second mode while traversing a route based on the vehicle data, and the driving context, and presenting the recommendation to the driver.

Network buses in vehicles and other assets are monitored in order to obtain information and calculate alternate values of parameters relating to components connected to the bus and to send them to a management server. The device includes main code, which is common to the different vehicles or assets in a group, and a script, which is specific to each type of vehicle or asset. The script, which may be customizable, is responsible for defining the parameters to obtain and for defining how the values of the parameters are to be calculated. The script compensates for differences in the way different buses and components operate in different assets, which means that the values of like parameters obtained from different sources are all in conformance with each other. The script can be updated without interrupting the operation of the main code and the monitoring of the bus.

Network buses in vehicles and other assets are monitored in order to obtain information and calculate alternate values of parameters relating to components connected to the bus and to send them to a management server. The device includes main code, which is common to the different vehicles or assets in a group, and a script, which is specific to each type of vehicle or asset. The script, which may be customizable, is responsible for defining the parameters to obtain and for defining how the values of the parameters are to be calculated. The script compensates for differences in the way different buses and components operate in different assets, which means that the values of like parameters obtained from different sources are all in conformance with each other. The script can be updated without interrupting the operation of the main code and the monitoring of the bus.