Systems and methods are disclosed for a smart mouse that may include transmitting, by the mechanical switch of the smart mouse, a signal to a microcontroller unit of the smart mouse in response to a movement of the smart mouse caused by a user, the movement causing the mechanical switch to be in a closed position, the signal indicating that the mechanical switch is in the closed position; receiving, by the microcontroller unit, the signal indicating that the mechanical switch is in the closed position; and in response to receiving the signal: causing, by a power switch of the smart mouse, at least one battery of the smart mouse to provide power to an optical unit of the smart mouse, the provided power causing the optical unit to be in an on state, the on state of the optical unit causing the smart mouse to be electrically enabled for use.

A method includes determining a physical location of each of a plurality of peripheral devices communicatively coupled to a host computing device, the each of the plurality of peripheral devices including a computer mouse; generating a lighting sequence configured to activate visual output elements on the each of the plurality of peripheral devices; and modifying the lighting sequence based on the physical location of the computer mouse relative to at least one of the other plurality of peripheral devices. In some aspects, the plurality of peripheral devices further includes a mouse pad, and modifying the lighting sequence for the computer mouse is based on the location of the computer mouse relative to its position on the mouse pad. In some cases, modifying the lighting sequence for the computer mouse is based on the location of the computer mouse relative to its position to the other plurality of peripheral devices.

A method, a computer readable medium, and an apparatus for wireless communication are provided. The apparatus may receive, via a radio frequency channel, a first data from a first human interface device at a first time slot of a frame. The apparatus may transmit the first data to a computing device. The apparatus may receive, via the radio frequency channel, a second data from a second human interface device at a second time slot of the frame. The apparatus may transmit the second data to the computing device. The apparatus may transmit, via the radio frequency channel at a third time slot of the frame, at least one of a first acknowledgment to the first data, a first lighting effect configuration data for the first human interface device, a second acknowledgment to the second data, or a second lighting effect configuration data for the second human interface device.

A method, a computer readable medium, and an apparatus for wireless communication are provided. The apparatus may receive, via a radio frequency channel, a first data from a first human interface device at a first time slot of a frame. The apparatus may transmit the first data to a computing device. The apparatus may receive, via the radio frequency channel, a second data from a second human interface device at a second time slot of the frame. The apparatus may transmit the second data to the computing device. The apparatus may transmit, via the radio frequency channel at a third time slot of the frame, at least one of a first acknowledgment to the first data, a first lighting effect configuration data for the first human interface device, a second acknowledgment to the second data, or a second lighting effect configuration data for the second human interface device.

A mouse adjusting device of a mouse used to adjust the height of a sensing module of the mouse includes a slidable base, a sensor carrier, and an adjusting element. The moving base is movably disposed in the mouse. The bottom portion of the slidable base has at least a ramp portion. The sensor carrier is disposed in the mouse and below the slidable base. The sensor carrier with the sensing module is liftable and lowerable in the mouse. The top portion of the sensor carrier has at least a block portion abutting against the ramp portion of the slidable base. The adjusting element has a drive screw and a drive nut. The drive nut is embedded in the slidable base. An end of the drive screw is rotatably bolted to the drive nut, and another end of the driving screw is rotatably exposed outside the mouse.

A power saving method for a peripheral device in a wireless operation mode is provided. The power saving method at least includes the steps of allowing the peripheral device to enter an idle mode and judging whether the peripheral device receives a startup trigger event. In the idle mode, the light source in an operation region of the peripheral device is in an on state or a high-brightness state. If the peripheral device receives the startup trigger event, the peripheral device is switched from the idle mode to a power saving mode. In the power saving mode, the light source in the operation region of the peripheral device is in an off state or a low-brightness state. The peripheral device in the power saving mode consumes less electric power than the peripheral device in the idle mode.

A mouse device includes a casing, a light-transmissible element and at least one light-emitting element. The casing has an opening. The light-transmissible element is disposed within the casing. A portion of the light-transmissible element is exposed outside the opening of the casing. The light-transmissible element includes plural scattering patterns. The at least one light-emitting element is disposed within the casing and located beside the light-transmissible element. The at least one light-emitting element emits a light beam to an internal portion of the light-transmissible element. After the light beam is transmitted through the plural scattering patterns, the light beam is scattered by the plural scattering patterns, and the scattered light beam is transmitted through the opening of the casing and outputted.

An information handling system mouse includes a position sensor that detects movement and a push button that detects button press inputs for communication to an information handling system. An indicator light exposed at an upper surface of the mouse provides an indication of power state, such as by illuminating a product logo. The position sensor detects positions with a focus aided by a resolution illumination light, such as a laser. The push button detects button press inputs with a scan performed at a processing resource, such as an MCU. The processing resource configures power on and off the resolution illumination light and the indicator light based upon position sensor focus and button press inputs by an end user that predict the end user's hand position on the mouse.

A mouse device is provided. The mouse device includes a battery module, a casing, and a control circuit. The battery module includes a first connection interface. The casing includes a second connection interface. The control circuit is disposed inside the casing and is electrically connected to the second connection interface. The battery module is detachably mated with the second connection interface through the first connection interface, and the battery module is exposed outside of the casing when being mated with the second connection interface. The control circuit obtains a power supply from the battery module through the second connection interface when the battery module is mated with the second connection interface.

A mouse device includes a casing, a light-transmissible element and at least one light-emitting element. The casing has an opening. The light-transmissible element is disposed within the casing. A portion of the light-transmissible element is exposed outside the opening of the casing. The light-transmissible element includes plural scattering patterns. The at least one light-emitting element is disposed within the casing and located beside the light-transmissible element. The at least one light-emitting element emits a light beam to an internal portion of the light-transmissible element. After the light beam is transmitted through the plural scattering patterns, the light beam is scattered by the plural scattering patterns, and the scattered light beam is transmitted through the opening of the casing and outputted.