In some examples, a device configured to determine an estimated remaining use of a brake assembly includes a magnet configured to move in response to movement of a wear pin indicator of the brake assembly, a sensor configured to generate an output signal based on a position of the magnet relative to the sensor, and processing circuitry configured to determine the estimated remaining use of the brake assembly based on the output signal generated by the sensor.

In some examples, a device configured to determine an estimated remaining use of a brake assembly includes a magnet configured to move in response to movement of a wear pin indicator of the brake assembly, a sensor configured to generate an output signal based on a position of the magnet relative to the sensor, and processing circuitry configured to determine the estimated remaining use of the brake assembly based on the output signal generated by the sensor.

A myodynamic measurement system is provided in the present invention. The myodynamic measurement system comprises a myodynamic measurement device and a controller. The myodynamic measurement device comprises a main body, a motor, a clutch, a rope, a handle, an accelerometer, and a displacement detector. The main body has an allocation space and a through hole. The motor is disposed in the allocation space. The clutch is disposed in the allocation space and engaged with the motor. The rope is engaged with the clutch and is extended from the through hole. The handle is fixed on the rope. The accelerometer is utilized for detecting acceleration change of the handle. The displacement detector is utilized for detecting a moving distance of the rope. The controller comprises a communication module and a control module. The control module is utilized for controlling the motor to provide a pulling force and controlling the clutch to engage with the motor and the rope through the communication module.

A myodynamic measurement system is provided in the present invention. The myodynamic measurement system comprises a myodynamic measurement device and a controller. The myodynamic measurement device comprises a main body, a motor, a clutch, a rope, a handle, an accelerometer, and a displacement detector. The main body has an allocation space and a through hole. The motor is disposed in the allocation space. The clutch is disposed in the allocation space and engaged with the motor. The rope is engaged with the clutch and is extended from the through hole. The handle is fixed on the rope. The accelerometer is utilized for detecting acceleration change of the handle. The displacement detector is utilized for detecting a moving distance of the rope. The controller comprises a communication module and a control module. The control module is utilized for controlling the motor to provide a pulling force and controlling the clutch to engage with the motor and the rope through the communication module.

A control knob assembly for a consumer appliance is provided. The control knob assembly provides a compact means for determining the angular position of the control knob and illuminating a plurality of indicators to communicate that angular position to a user of the appliance. More specifically, the control knob assembly includes an optical encoder disc that defines a plurality of teeth that are in operable communication with a plurality of optical sensors. The position of the sensors and the spacing of the plurality of teeth are configured to generate signals as the control knob is rotated that allow for the precise determination of the angular position of the control knob. Moreover, the optical encoder disc may fit inside a lighting assembly and may have a low profile, resulting in a compact control knob assembly that may easily fit within the area underneath the control knob and control panel.

A control knob assembly for a consumer appliance is provided. The control knob assembly provides a compact means for determining the angular position of the control knob and illuminating a plurality of indicators to communicate that angular position to a user of the appliance. More specifically, the control knob assembly includes an optical encoder disc that defines a plurality of teeth that are in operable communication with a plurality of optical sensors. The position of the sensors and the spacing of the plurality of teeth are configured to generate signals as the control knob is rotated that allow for the precise determination of the angular position of the control knob. Moreover, the optical encoder disc may fit inside a lighting assembly and may have a low profile, resulting in a compact control knob assembly that may easily fit within the area underneath the control knob and control panel.

Methods and systems are described for determining operation of an openable barrier and direction of movement of a person through an opening controlled by the barrier. A method includes detecting with a hinge sensor a closed position for the barrier, the hinge sensor being mounted to a hinge of the barrier, determining with the hinge sensor when the barrier changes position from the closed position to an open position, detecting with at least one motion sensor motion of an object in proximity to the opening, and determining a direction of movement of the object through the opening based on whether the motion is detected before or after detecting the change in position of the barrier.

A person support apparatus includes one or more thermal image sensors whose outputs are analyzed to perform one or more functions. Such functions include automatically turning on a brake, automatically turning on one or more lights, detecting when a patient associated with the person support apparatus has fallen, enabling a propulsion system of the patient support apparatus to be used, automatically controlling one or more environmental controls, and/or automatically arming an exit detection system after entry of a patient onto the person support apparatus. Multiple thermal images may be generated from multiple sensors to generate stereoscopic thermal images of portions of the person support apparatus and its surroundings.

A person support apparatus includes one or more thermal image sensors whose outputs are analyzed to perform one or more functions. Such functions include automatically turning on a brake, automatically turning on one or more lights, detecting when a patient associated with the person support apparatus has fallen, enabling a propulsion system of the patient support apparatus to be used, automatically controlling one or more environmental controls, and/or automatically arming an exit detection system after entry of a patient onto the person support apparatus. Multiple thermal images may be generated from multiple sensors to generate stereoscopic thermal images of portions of the person support apparatus and its surroundings.

A system for detecting the position of a steering wheel of a motor vehicle, the system includes: a matrix-array optical detecting device, of the type known as a time-of-flight camera, enabling three-dimensional detection, the device including an infrared light source and a matrix-array optical sensor; and optical reference elements arranged on the rim of the steering wheel, on the side opposite the driver, the matrix-array optical detecting device being arranged in an instrument panel of the vehicle, and being configured to detect the optical reference elements on the steering wheel, and to deduce therefrom the adjustment position of the steering wheel at least depthwise.