A vehicle includes a transmission having a first neutral with a first combination of engaged clutches and a second neutral with a second combination of engaged clutches. The second neutral has more engaged clutches than the first neutral. A vehicle controller is programmed to, in response to a request to shift from the first to the second neutral and a failed-on clutch being detected, inhibit the shift to remain in the first neutral.

A vehicle includes a transmission having a first neutral with a first combination of engaged clutches and a second neutral with a second combination of engaged clutches. The first neutral has more engaged clutches than the second. A controller is programmed to, in response to a request to shift from a drive gear to the first neutral and a clutch of the drive gear being failed-on, shift to the second neutral.

A sensor arrangement detects an angle of an actuator which is rotationally arranged on a support. The arrangement includes a first sensor element and a second sensor element. The first sensor element can be coupled to the actuator in order carry out a movement with respect to the support in accordance with a rotation of the actuator. The second sensor element can be rotationally fixed on the support and can be coupled to the first sensor element in order to produce, when rotating the actuator and a thus resulting movement between the first sensor element and the second sensor element, a sensor signal which is dependent on the rotation carried out by the actuator.

Electromechanical actuator to operate a component of a vehicle provided with a housing formed by a lower element and a lid; a transmission arranged inside the housing and comprising an output shaft provided with a first symmetry axis and an intermediate shaft, which meshes with the output shaft and is provided with a second symmetry axis transverse to the first symmetry axis; and a pair of electric motors also arranged inside the housing; wherein each of the two electric motors rotates the output shaft through the intermediate shaft and wherein the two electric motors are provided with respective rotation axes parallel to each other and transverse to the first symmetry axis.

A method is provided for checking a configuration safety of a coupling device for a gear box sliding gear. The gear box sliding gear is rotationally connected to a drive input shaft of the gearbox and is axially movable on the drive input shaft from an intermediate neutral position to either of two opposite positions of engagement with an idler pinion. The method defining a neutral configuration of the coupling device on based on a main information relating to the position of the slider gear and its movement setting, in which position the transmission of the torque to the wheel is effectively stopped, and in that the start of synchronization of the slider gear with a pinion is only allowed when the device is in this configuration.

An exemplary transmission system includes a first sensor configured to measure a quantity and output a first signal representative of the quantity measured. A second sensor is configured to separately measure the quantity measured by the first sensor and output a second signal representative of the quantity measured. A transmission control module in communication with the first sensor and the second sensor is configured to process the first signal along a primary processing path, process the second signal along a secondary processing path, compare the processed first signal to the processed second signal to determine if the primary processing path is reliable, and compare the processed first signal to the processed second signal to determine if the first sensor is reliable.

An exemplary transmission system includes a first sensor configured to measure a quantity and output a first signal representative of the quantity measured. A second sensor is configured to separately measure the quantity measured by the first sensor and output a second signal representative of the quantity measured. A transmission control module in communication with the first sensor and the second sensor is configured to process the first signal along a primary processing path, process the second signal along a secondary processing path, compare the processed first signal to the processed second signal to determine if the primary processing path is reliable, and compare the processed first signal to the processed second signal to determine if the first sensor is reliable.

Provided is an automotive transmission control device in which a shift range signal can be generated as accurately as possible and control of vehicle travel can be maintained even when a signal input port for a computation device develops a fault. The automotive transmission control device according to the present invention: is provided with three input ports for receiving shift range signals; and provisionally determines the shift range state by the majority decision of the input ports, estimates the shift range state on the basis of the travel state of the vehicle, and performs a final determination of the shift range state by using both the provisional determination and the estimation.

A range switching apparatus of a shift-by-wire system has: a main motor; a deceleration mechanism that amplifies torque generated by the main motor; an output shaft that outputs the torque amplified by the deceleration mechanism; an auxiliary motor; and an emergency drive mechanism. The emergency drive mechanism is disposed on the auxiliary motor shaft of the auxiliary motor, and that is connected to or disconnected from the deceleration mechanism by driving of the auxiliary motor. The emergency drive mechanism transfers output of the auxiliary motor to the deceleration mechanism, and rotates the output shaft by being connected to the deceleration mechanism.

A vehicle includes a transmission having a first neutral with a first combination of engaged clutches and a second neutral with a second combination of engaged clutches. The second neutral has more engaged clutches than the first neutral. A vehicle controller is programmed to, in response to a request to shift from the first to the second neutral and a failed-on clutch being detected, inhibit the shift to remain in the first neutral.