The present disclosure provides an intelligent lighting control system. The lighting control system includes a base module including a base housing forming a well and including a first electrical connector positioned in the well. A depressible switch is housed in the well that includes a spring biasing the depressible switch into an extended position that opens an electrical circuit between the power terminal and the first electrical connector. The lighting control system also includes a light switch module configured for nesting, at least in part, in the well of the base module. The light switch module includes a module housing configured to press the depressible switch into a retracted position upon nesting in the well and thereby close the electrical circuit between the power terminal and the first electrical connector and release the depressible switch into the extended position when unnested from the well of the base module.

A multi-directional operation switch device that can smoothly move a slider that is movable in four directions back to a neutral position is provided. The multi-directional operation switch device includes: a slider movable in the four directions; four push switches provided in the four directions to detect a movement of the slider; and four pressing members provided between the slider and the push switches. The slider includes four side face portions, each intersecting a first axis or a second axis, each axis extending in at least one of the four directions. Each side face portion includes a sloped region sloped toward a center of the slider. The push switches include movable portions, each movable portion self-returning and moving to an original position when pressing is released. Each pressing member is in contact with a corresponding one of the movable portions and a corresponding one of the side face portions.

A foot pedal system for controlling a surgical robotic system, the foot pedal system comprising a foot pedal assembly movably coupled to a foot pedal assembly platform. The foot pedal assembly having a foot pedal base, a foot pedal pivotally coupled to the foot pedal base, and a foot pedal platform, the foot pedal base operable to slide across the foot pedal platform along an x-axis and a y-axis to an arrangement of activation positions. The foot pedal platform operable to translate and rotate with respect to the foot pedal assembly platform to any position along the foot pedal assembly platform, and the foot pedal platform is operable to engage or disengage with the foot pedal assembly platform at the any position along the foot pedal assembly platform.

Methods, systems, apparatuses, and computer program products are provided for a user input device, such as a game controller, that includes a finger-pressable (tactile) switch. The switch is adjustable to change the amount of force used to actuate the switch. In an example implementation, a tactile switch comprises a housing, a button interposer, a dome switch, and an adjustment mechanism. A user or other entity may press the button interposer. The dome switch is contained in the housing, and is actuated by the button interposer being pressed. The adjustment mechanism is contained at least partially in the housing, and is configured to enable an amount of force used to press the button interposer to actuate the dome switch to be adjusted.

A robot teaching device allowing a user to operate an enable switch provided on the robot teaching device in a similar manner regardless of the user's dominant hand. A hand-held robot teaching device includes an enable switch built-in includes a main body including a holding portion that is configured to be held by one hand, and an enable switch operating section that is provided on the holding portion and is configured to be operated by a reference switching motion of a hand holding the holding portion in a reference position. The enable switch operating section includes a switching motion specifying mechanism that makes the reference switching motion in the reference position easier than another motion.

The present disclosure provides an intelligent lighting control system. The lighting control system includes a base module including a base housing forming a well and including a first electrical connector positioned in the well. A depressible switch is housed in the well that includes a spring biasing the depressible switch into an extended position that opens an electrical circuit between the power terminal and the first electrical connector. The lighting control system also includes a light switch module configured for nesting, at least in part, in the well of the base module. The light switch module includes a module housing configured to press the depressible switch into a retracted position upon nesting in the well and thereby close the electrical circuit between the power terminal and the first electrical connector and release the depressible switch into the extended position when unnested from the well of the base module.

A multidirectional input device includes a case, and a movable body that is restrained from rotating relative to the case, disposed so as to face the case, and mounted on the case so as to be movable in directions with a predetermined neutral position as a base point. The multidirectional input device further includes a first position detector that outputs a first signal in response to a position of the movable body, and a cam part formed on one of a surface, facing the case, of the movable body, and a surface, facing the movable body, of the case. The multidirectional input device further includes a restraint member having a tip which is in elastic contact with the cam part to urge the movable body to the neutral position, and a second position detector that outputs a second signal in response to a position of the restraint member.

An electronic device includes: a camera module, a camera window formed to cover the camera module and installed in a first opening, a bracket receiving the camera window and the camera module and adhered to a rear cover by a third waterproof member, a fourth waterproof member adhering the window cover and the bracket, a second opening formed in the bracket and connected to the inside of the middle frame, and a filter member disposed in the second opening and blocking movement of water and forming a movement path of air, wherein a gap is formed between an edge of the rear cover forming the first opening and an edge of the camera window and a movement region is formed by a space between the rear cover and the bracket and connected to the second opening, such that air and water are introduced.

A switch mechanism for a vehicle interior is disclosed. The switch mechanism may comprise a slide within a carrier, at least one pin movable within the slide to center the slide in the carrier and a spring to move the pin within the slide. The pin may comprise a protrusion movable against the slide to guide pin movement. The slide may comprise a rib; the protrusion may slide against the rib to guide pin movement. The rib may comprise two ribs; the protrusion may move between the two ribs. The spring may be contained within an opening in the slide; the rib may extend beyond the opening. The pin may comprise first and second guides to slide along first and second slide walls to guide pin movement. The vehicle interior component may be at least one of a console, an overhead console, a vehicle system actuator, a sunroof actuator.

An electronic device controller assembly for ergonomic dual-handed control of the electronic device includes a housing. At least one circuit board is positioned in the housing. The at least one circuit board is configured to selectively and operationally couple to the electronic device. Each of a pair of sticks is pivotally coupled to and extends between the upper face of the housing and a bottom of a respective plate. Each plate is configured to position a respective hand of a user. A plurality of first buttons is coupled to the plates. The sticks and the first buttons are operationally coupled to the at least one circuit board. Each first button is configured to be depressed to selectively control a respective function of the electronic device. Each plate is positioned to compel an associated stick to pivot relative to the housing to signal a directional movement.