There is provided a frame rate adjusting method of a navigation device including: counting a frame period using a clock of a local oscillator of the navigation device; counting a polling period using the same clock; calculating a difference between the frame period and the polling period; adjusting a frame rate of the navigation device when the difference is smaller than a predetermined margin.

An input device comprises a depressible element with two switches including a first switch configured to generate a first signal when the depressible element is depressed by a threshold distance and a second switch configured to generate a second signal indicating when the depressible element is depressed by the threshold distance and the second switch is in an active state. One or more processors may be configured to receive the first signal from the first switch; configure the second switch to change from an inactive state to an active state in response to receiving the first signal; receive the second signal from the second switch in the active state; determine whether the second signal indicates that the depressible element is depressed by the threshold distance; and generate event data confirming that the depressible element is depressed by the threshold distance in response to receiving the second signal.

In certain embodiments, an input device includes a housing, a processor disposed in the housing, and an image sensor to track a movement of the input device with respect to an underlying surface. The image sensor includes a pixel array and operates in two modes of operation including a first mode of operation where the processor causes the image sensor to utilize a first plurality of pixels in the pixel array when tracking the movement of the input device or a second mode of operation where the processor causes the image sensor to utilize a second plurality of pixels in the pixel array when tracking the movement of the input device, where the second plurality of pixels has fewer pixels than the first plurality of pixels.

Systems and techniques are described for robust radar-based gesture-recognition. A radar system (104) detects radar-based gestures on behalf of application subscribers. A state machine (2000) transitions between multiple states based on inertial sensor data. A no-gating state (2002) enables the radar system (104) to output radar-based gestures to application subscribers. The state machine (2000) also includes a soft-gating state (2004) that prevents the radar system (104) from outputting the radar-based gestures to the application subscribers. A hard-gating state (2006) prevents the radar system (104) from detecting radar-based gestures altogether. The techniques and systems enable the radar system (104) to determine when not to perform gesture-recognition, enabling user equipment (102) to automatically reconfigure the radar system (104) to meet user demand. By so doing, the techniques conserve power, improve accuracy, or reduce latency relative to many common techniques and systems for radar-based gesture-recognition.

A mouse pad that is adapted to a wireless charging transmitter and operates in cooperation with a wireless mouse is provided. The mouse pad includes a main body and a secondary resonant coil circuit disposed inside the main body. The secondary resonant coil circuit wirelessly receives a first electromagnetic energy provided by the wireless charging transmitter arranged outside the main body, and then converts the first electromagnetic energy into a working power for the secondary resonant coil circuit. The secondary resonant coil circuit relays the working power, converts the working power into the second electromagnetic energy, and then wirelessly outputs a second electromagnetic energy to the wireless mouse.

An information handling system wirelessly interfaces with a peripheral device, such as a keyboard or mouse, through a primary radio and communication protocol, such as Bluetooth. A secondary radio interfaces with the primary radio to provide a low power wake and sleep using a wake signal sent between the secondary radios. An information handling system may wake the peripheral, such as at system power up, or the peripheral may wake the information handling system, such as at detection of an input at the peripheral for communication to the information handling system.

An information handling system wirelessly interfaces with a peripheral device, such as a keyboard or mouse, through a primary radio and communication protocol, such as Bluetooth. A secondary radio interfaces with the primary radio to provide a low power wake and sleep using a wake signal sent between the secondary radios. An information handling system may wake the peripheral, such as at system power up, or the peripheral may wake the information handling system, such as at detection of an input at the peripheral for communication to the information handling system.

There is provided a frame rate adjusting method of a navigation device including: counting a frame period using a clock of a local oscillator of the navigation device; counting a polling period using the same clock; calculating a difference between the frame period and the polling period; adjusting a frame rate of the navigation device when the difference is smaller than a predetermined margin.

There is provided a frame rate adjusting method of a navigation device including: counting a frame period using a clock of a local oscillator of the navigation device; counting a polling period using the same clock; calculating a difference between the frame period and the polling period; adjusting a frame rate of the navigation device when the difference is smaller than a predetermined margin.

A hand-held device with a sensor for providing a signal indicative of a position of the hand-held device relative to an object surface enables power to the sensor at a first time interval when the hand-held device is indicated to be in a position that is stationary and adjacent relative to the object surface, enables power to the sensor at a second time interval shorter than the first time interval when the hand-held device is indicated to be in a position that is moving and adjacent relative to the object surface, and enables power to the sensor at a third time interval when the hand-held device is determined to be in a position that is removed relative to the object surface.