A multi-axis adjustable machine handle may comprise a handle assembly and a handle mounting assembly. The handle mounting assembly may comprise a clamping assembly including an elongate clamp with first and second sides rotatably engaging the handle assembly and first and second cup-shaped members slidably engaging the elongate clamp. The handle mounting assembly may further comprise a locking assembly extending through the first cup-shaped member, second cup-shaped member, and elongate clamp to selectively prevent relative movement. Finally, the handle mounting assembly may also comprise a support brace engaging the second cup-shaped member.

A peripheral device may include a body. The device may include a scroll wheel rotatably coupled with the body. The scroll wheel may include a ferromagnetic rotor. The rotor may be generally annular and may define an open interior. The rotor may define a first plurality of teeth arranged about a periphery of the open interior. The device may include a stator disposed within the open interior. The stator may define a second plurality of teeth that are alignable with the first plurality of teeth. The stator may include a plurality of electro-permanent magnets. Each of the electro-permanent magnets may be disposed within a conductive coil. The device may include a position sensor that is configured to detect an angular position of the rotor. The device may include control circuitry that controls delivery of current to the electro-permanent magnets of the stator to controls a speed of the scroll wheel.

A peripheral device may include a body. The device may include a scroll wheel rotatably coupled with the body. The scroll wheel may include a ferromagnetic rotor. The rotor may be generally annular and may define an open interior. The rotor may define a first plurality of teeth arranged about a periphery of the open interior. The device may include a stator disposed within the open interior. The stator may define a second plurality of teeth that are alignable with the first plurality of teeth. The stator may include a plurality of electro-permanent magnets. Each of the electro-permanent magnets may be disposed within a conductive coil. The device may include a position sensor that is configured to detect an angular position of the rotor. The device may include control circuitry that controls delivery of current to the electro-permanent magnets of the stator to controls a speed of the scroll wheel.

A peripheral device may include a body. The device may include a scroll wheel rotatably coupled with the body. The scroll wheel may include a ferromagnetic rotor. The rotor may be generally annular and may define an open interior. The rotor may define a first plurality of teeth arranged about a periphery of the open interior. The device may include a stator disposed within the open interior. The stator may define a second plurality of teeth that are alignable with the first plurality of teeth. The stator may include a plurality of electro-permanent magnets. Each of the electro-permanent magnets may be disposed within a conductive coil. The device may include a position sensor that is configured to detect an angular position of the rotor. The device may include control circuitry that controls delivery of current to the electro-permanent magnets of the stator to controls a speed of the scroll wheel.

A method of determining the state of a pedal actuator system within a vehicle includes receiving a position sensor signal indicative of a position of an actuator pedal within the pedal actuator system, receiving a force sensor signal indicative of a compressive force applied to the actuator pedal, and determining, with a processor, a state of the actuator pedal based on the position sensor signal and the force sensor signal. The state of the actuator pedal is one of a normal operating state and a fault state

A lighting control console for controlling a lighting system includes digital adjusting commands being generated in the lighting control console that are transmitted to the lighting system via data links. The lighting control console includes at least one slide control for inputting operating commands via linear displacement of a control knob protruding from the upper side of the console housing. The upper side of the console housing includes a slit for each slide control. The control knob is connected to the slide control via the slit. A tactile sensor system provided at the slide control can detect when the user touches the control knob.

A lighting control console for controlling a lighting system includes digital adjusting commands being generated in the lighting control console that are transmitted to the lighting system via data links. The lighting control console includes at least one slide control for inputting operating commands via linear displacement of a control knob protruding from the upper side of the console housing. The upper side of the console housing includes a slit for each slide control. The slide control is fastened to said electronic circuit board and not to any fastening point on the console housing.

A multiple Hirth joint for permitting linear and angular adjustment of an upper control arm with respect to a lower control arm. The joint includes a multiple Hirth interface having a slot through it, a confronting single Hirth interface, and an actuator. The actuator permits manual loosening and tightening of the multiple Hirth interface and single Hirth interface to permit linear and angular adjustment. Loosening of the actuator simultaneously permits linear and angular adjustment and tightening of the actuator simultaneously lock the joint into the selected linear and angular position.

Method, apparatus, and computer readable media are disclosed for position control touchscreens for vehicles. An example vehicle includes a center console touchscreen for controlling vehicle settings, a seat, a seat motor coupled to the seat, a position control touchscreen adjacent to the seat for controlling seat settings, and a position adjuster communicatively coupled to the position control touchscreen. The position adjuster is to receive a seat adjustment command from the position control touchscreen and adjust the seat, via the seat motor, based on the seat adjustment command.

Aspects hereof relate to control devices for controlling features or functions of apparatuses and devices. At a high level, the control devices described herein provide an input locus that is positioned within a handle of the control devices. The input locus may have a fixed position such that the control device may resist movement in response to forces applied to the handle in force vectors passing through the input locus. Further, the handle may pivot or rotate about the input locus in response to forces applied to the handle in force vectors that are offset from the input locus to generate inputs and/or controls.