A shifter assembly for a vehicle that includes a shift lever connected to a shifter in communication with the vehicle and a transmission. A display is positioned on the shift lever indicating data of the vehicle or transmission. A start button is positioned on the shift lever and is linked with an ignition of the vehicle.

Methods and apparatus to control architectural opening covering assemblies are disclosed herein. An architectural covering assembly including an architectural covering; a tube to which the architectural covering is coupled; a manual controller operatively coupled to the tube to rotate the tube; a motor including a motor housing and a motor shaft; and a clutch assembly including a clutch and a clutch housing in which the clutch is disposed, the motor shaft coupled to the clutch and the clutch coupled to the manual controller to hold the motor shaft substantially stationary when the architectural covering is moved under an influence of the motor to cause the motor housing to rotate with the clutch housing and the tube.

A shift device according to one embodiment includes a case having a cylindrical portion; a shift lever configured to include a base portion provided to be rotatable inside the cylindrical portion, with which an operator performs a rotation operation; a shift position holding mechanism configured to hold the shift lever at a predetermined shift position; and an elastic member configured to protrude from one of the cylindrical portion or the base portion so as to face another of the cylindrical portion or the base portion, and contact either an outer circumferential surface of the base portion or an inner circumferential surface of the cylindrical portion, to impose a rotational load on the shift lever.

A selector assembly includes a housing having a spherical cavity and a detent cavity that form a continuous selector cavity. A selector slidably operates within the selector cavity and about a center point of the spherical cavity. The selector includes a spheroid member that is contained within the spherical cavity and slidably engages a guide surface that defines the spherical cavity. A first pivot includes a first rotational axis that extends through the center point of the spherical cavity. A second pivot includes a second rotational axis that extends through the center point of the spherical cavity. A detent pin is biased toward a detent surface of the detent cavity and slidably engages the detent surface to define a plurality of selector positions of the selector.

An operation device for a vehicle transmission is configured to include: a base bracket that is fixed to a vehicle body of a vehicle; a slider lever that is slidably supported by the base bracket and includes a shift knob; and a main gear, which is rotatably supported by the base bracket and includes gear teeth at an outer circumferential portion, to which an end portion of a shift wire of the vehicle transmission is connected at a position separated from a gear support shaft of the base bracket, the slider lever including a rack gear that is formed along a sliding direction of the slider lever and is engaged with the gear teeth of the main gear, and gear change of the transmission being performed by causing the main gear to rotate with sliding of the slider lever and pushing and pulling the shift wire.

Disclosed is a throttle quadrant arrangement utilizing a throttle lever mechanically connected to three Rotary Variable Differential Transformers (RVDTs). The signals from the RVDTs are monitored by a process where the processing component. More specifically, RVDT outputs are monitored by the engine control system to determine if they are outside a predetermined range of operability. If an RVDT is not operable, the engine control system establishes a thrust output using the signal from one of the functional two. If only one or none are within the range, the system moves on to a default mode.

In a shift device (10), a base portion (42) of a collar (40) is accommodated in a mounting hole (50) of a support portion (34), and a thin plate portion (52) of the support portion (34) is disposed at an upper side of an upper face (42A) of the base portion (42). When an impact load of at least a predetermined value is applied to a shift lever, the thin plate portion (52) of the support portion (34) is broken by the base portion (42) and the support portion (34) moves while being guided by the base portion (42). Thus, the impact load is absorbed. Consequently, an impact load absorption mode may be made consistent.

In a shift device, as a result of a rotor cam being rotated in a positive direction, and transmitting surfaces of the rotor cam pressing rotation surfaces of an urging cylinder, the urging cylinder is rotated in the positive direction, and a lever is moved rotationally towards a front side. Here, in a case in which a load towards the rear side is applied to the lever, the rotation surfaces are rotated in an opposite direction relative to the transmitting surfaces. As a result, the load towards the rear side being applied to the lever can be released.

An equipment control apparatus for a vehicle has: a motor for vibrating that imparts, via a shift knob that contacts a vehicle occupant, vibrations as a stimulus that the vehicle occupant can feel by a somatic sensation; an electrostatic capacity sensor that detects electrostatic capacity as a state of contact of the vehicle occupant with the shift knob; and a control section that controls driving of the motor for vibrating so as to impart, to the vehicle occupant, vibrations of a strength that is determined in advance in accordance with the electrostatic capacity detected by the electrostatic capacity sensor.

A shifter assembly selects a first mode and a second mode of a transmission for a vehicle. The shifter assembly includes a housing and a shift lever movably coupled to the housing and pivotable relative to the housing. The shift lever includes a body and a cap defining an aperture and being coupled to the body. The cap is rotatable relative to the body between a first and a second orientations. The shift lever further includes a toggle device partially received by the cap in the aperture with at least a portion of the toggle device being moveably coupled to the body between a rest and a depressed positions. The shift lever further includes an element mounted to the toggle device and rotatable with the cap between the first and the second orientations. The shift lever further includes a sensor system configured to interact with the element to detect rotation of the cap between the first and the second orientations.