A vehicle switch device has a selection switch having an operation part that, when operated, selects at least one of a plurality of driving target vehicle components mounted on a vehicle, and an operation switch that is separately operable from the selection switch, and drives the selected driving target vehicle component when operated. The operation switch has a single holding operation knob that swings so as to have a front portion thereof pushed down or pulled up. The single holding operation knob is structured to allow a palm of a hand to be placed on an upper face thereof, and fingers of the hand other than a thumb to be placed on the front portion. The operation part is disposed on a side face of the holding operation knob.

Disclosed are a rocker device and a controller. The rocker device includes a mounting base and a rocker assembly, the mounting base is provided with a first accommodating cavity with an opening, the mounting base is configured to connect with the controller, the rocker assembly is provided in the first accommodating cavity and snapped with the mounting base, the rocker assembly is configured to electrically connect with the controller to achieve multi-directional control.

A power window switch apparatus includes: a switch housing; a first knob pivotally mounted on the switch housing by a first pivot pin; and a second knob pivotally mounted on the switch housing by a second pivot pin. In particular, a top surface of the second knob is located higher than a top surface of the first knob.

Disclosed are a capacitor rocker device and a remote control. The capacitor rocker device includes a shell, a rocker arm assembly, a rocker assembly, two capacitor assemblies and a control assembly. Each capacitor assembly includes a first electrode sheet, a second electrode sheet and a third electrode sheet. A first facing distance is provided between the first electrode sheet and the second electrode sheet to form a first capacitor, and a second facing distance is provided between the first electrode sheet and the third electrode sheet to form a second capacitor. The rocker assembly is configured to push the rocker arm to swing and drive the swing member to swing within the first facing distance and the second facing distance, and a capacitance value of the first capacitor and a capacitance value of the second capacitor change with the swing of the swing member.

Disclosed are a capacitor rocker device and a remote control. The capacitor rocker device includes a shell, a rocker arm assembly, a rocker assembly, two capacitor assemblies and a control assembly. Each capacitor assembly includes a first electrode sheet, a second electrode sheet and a third electrode sheet. A first facing distance is provided between the first electrode sheet and the second electrode sheet to form a first capacitor, and a second facing distance is provided between the first electrode sheet and the third electrode sheet to form a second capacitor. The rocker assembly is configured to push the rocker arm to swing and drive the swing member to swing within the first facing distance and the second facing distance, and a capacitance value of the first capacitor and a capacitance value of the second capacitor change with the swing of the swing member.

A manual control for an electronic apparatus includes a manually activated rocker actuator mechanism coupled to a magnet source. The magnet source is in a rest position relative to a Variable Hall effect sensor device when the rocker actuator mechanism is in a rest position. A variable output signal from the sensor device is substantially at a minimum value when the magnet source is in the rest position relative to the sensor device. The magnet source is in a maximum position relative to the sensor device when the rocker actuator mechanism is in a maximum position. The variable output signal is substantially at a maximum value when the magnet source is in the maximum position relative to the sensor device.

The present disclosure relates to a vehicle door switch actuating apparatus (100). The apparatus includes an actuating element (104) having an actuating surface (110), a mechanical switch (112), and a mechanism for transferring a compressive force applied by a user to the actuating surface (110) onto the mechanical switch (112) in order to flip the mechanical switch (112). The mechanism includes: a first component (102) on which the mechanical switch (112) is fixed at least in the switching direction; and a lever (120) pivotally supported about a pivot axis (124) relative to the first component (102) or the first component group and connected to the actuating element (104) via a first bearing on a first side (111) of the actuating surface (110). The actuating element (104) is supported on the first component (102) or the first component group via a second bearing on a second side (113) of the actuating surface (110). The actuating element (104) is flexibly configured such that, when manual pressure is applied to the actuating surface (110), it flexibly bends, thereby causing a change in the distance between the first bearing and the second bearing, in particular a shortening or lengthening of the distance, and thus causes the lever to pivot about the pivot axis (124). The mechanical switch (112) is arranged such that, by pivoting the lever, the mechanical switch (112) is flipped. The lever (120) extends substantially parallel to the first side (111) of the actuating surface (110).