A scrolling shifter assembly having a housing rotatably supporting a scrolling wheel having a knurled exterior edge accessible to a vehicle operator, the scrolling wheel also including an annular side detent profile. A magnet is positioned in proximity to a sensor mounted to a printed circuit board (PCBA) within the housing and displaces relative to the sensor in response to rotation of the scrolling wheel. A display component is mounted in proximity to the PCBA. At least one haptic biasing component including any of spring loaded pawl or wave spring is supported within the housing and biases against the detent profile such that, and upon the operator actuating the scrolling wheel, the pawl is caused to displace relative to the profile in order to incrementally rotate the wheel, the magnet rotating relative to the PCBA sensor to cause an associated processor to electronically instruct a shift change to an engine control unit.

A multi-gear brightness adjustment circuit board, and a multi-gear battery holder structure, which through adding the automatic control gear AUTO conductive contact piece and a light spot dot-circle pattern composite conductive contact piece on the circuit board, the gear can be automatically adjusted when the solar cell is used for power supply. Ensuring that the output light power meets the needs of ambient light, rationally use electric energy, which is conducive to energy saving; at the same time, the mode switching of the shooting target is integrated, which reduces the parts of the sight and makes the sight more compact.

An electronic equipment has a rotational operation member that can be downsized and has high detection reliability. The electronic equipment includes a rotational operation member, a click mechanism providing a click feeling at each predetermined rotation angle, and a magnetic field generating member. A first magnetic field detecting part detects variation of a first direction-related magnetic field generated by the magnetic field generating member, and a second magnetic field detecting part detects a variation of a second direction-related magnetic field generated by the magnetic field generating member. A rotation amount and a rotation direction of the rotational operation member are calculated based on the variations of the first direction-related magnetic field and the second direction-related magnetic field caused by a change in a positional relation of the first and second magnetic field detecting parts with the magnetic field generating member due to the rotation of the rotational operation member.

An electronic equipment has a rotational operation member that can be downsized and has high detection reliability. The electronic equipment includes a rotational operation member, a click mechanism providing a click feeling at each predetermined rotation angle, and a magnetic field generating member. A first magnetic field detecting part detects variation of a first direction-related magnetic field generated by the magnetic field generating member, and a second magnetic field detecting part detects a variation of a second direction-related magnetic field generated by the magnetic field generating member. A rotation amount and a rotation direction of the rotational operation member are calculated based on the variations of the first direction-related magnetic field and the second direction-related magnetic field caused by a change in a positional relation of the first and second magnetic field detecting parts with the magnetic field generating member due to the rotation of the rotational operation member.

The present disclosure provides an intelligent lighting control system. The lighting control system detects a temperature reading from a temperature sensor of each light control module in a plurality of light control modules. Each light control module in the plurality of light control modules is configured to cause a transmission of a quantity of electrical energy to a lighting circuit of a light fixture electrically connected to the respective lighting control module. The lighting control system controls at least one of a heating and an air conditioning system to adjust heating or cooling based on the temperatures detected by the temperature sensor of the light control module.

The present disclosure provides an intelligent lighting control system. The lighting control system detects a temperature reading from a temperature sensor of each light control module in a plurality of light control modules. Each light control module in the plurality of light control modules is configured to cause a transmission of a quantity of electrical energy to a lighting circuit of a light fixture electrically connected to the respective lighting control module. The lighting control system controls at least one of a heating and an air conditioning system to adjust heating or cooling based on the temperatures detected by the temperature sensor of the light control module.

An input detecting device includes an input section where position input is performed, a position detecting section included in the input section and detecting an input position regarding at least the position input, a rotary member mounted on the input section so as to be rotatable and including an operation surface on an outer peripheral surface thereof with which a rotating operation is performed, a rotation detection section that is rotatable together with the rotary member with respect to the input section and a position of which is detected by the position detecting section, and an extended section extending laterally from the operation surface so as to be disposed between the operation surface and the input section.

A system and method for connecting supply power to motor control components includes use of a motor control center subunit with moveable supply power contacts. After a motor control center subunit is secured into a motor control center compartment, the supply power contacts may be advanced to engage supply power buses. For disconnection, the supply power contacts may be retracted and isolated from the buses before physical removal of the subunit.

A system and method for connecting supply power to motor control components includes use of a motor control center subunit with moveable supply power contacts. After a motor control center subunit is secured into a motor control center compartment, the supply power contacts may be advanced to engage supply power buses. For disconnection, the supply power contacts may be retracted and isolated from the buses before physical removal of the subunit.

A rotary knob for operating an electronically actuable deadbolt is described herein. According to some embodiments, the rotary knob includes a chassis, an outer wall rotatably coupled to the chassis about a central axis of the knob, a cantilevered beam attached to an inner surface of the outer wall and extending towards the central axis of the knob such that the beam is configured to rotate with the outer wall about the central axis, a circuit board coupled to the chassis, the circuit board including signal traces, and an electrical contact extending from the cantilevered beam in a direction toward the signal traces and electrically connectable with the signal traces. A controller of the rotary knob is configured to determine a position of the deadbolt based on at least the state of the electrical connection between the electrical contact and the signal traces.