An input device includes a sensor and a housing. The sensor is adapted to provide cursor control on a display based on relative movement between the sensor and a reference surface. The housing at least partially contains the sensor and is adapted to be selectively manipulable relative to the reference surface into a first position to cause operation of the sensor at a first precision level and into a second position to cause operation of the sensor at a second precision level different from the first precision level.

A mouse including a housing, an image sensing element, a lens, or a laser Doppler cursor positioning sensor; a light-transmitting hole is located where the housing is intersected with a third plane, the third plane is defined by an edge intersecting a first plane and a second plane and a halving line of an angle of the first plane and the second plane; a light source is provided and configured to emit a light beam from the light-transmitting region to the working surface, and the lens is configured to focus a reflected light of the light beam on the working surface to be transmitted to the image sensing element through the light-transmitting hole; or the laser Doppler cursor positioning sensor is configured to project a light from the light-transmitting region to the working surface, and a reflected light is also fed back to the sensor through the light-transmitting hole.

In some embodiments, an input device includes a housing having a top surface, a touch sensor disposed on the top surface of the housing, and a processor disposed in the housing. The touch sensor can be configured to detect a contact by a hand on the top surface of the housing and generate touch data corresponding to the detected contact by the hand. The processor can be configured to control operation of the touch sensor and receive the touch data, determine an orientation of the hand with respect to the housing based on the touch data, and calibrate a detected movement of the input device based on the determined orientation of the hand with respect to the housing. An image sensor and/or one or more IMUs can be used to detect 2D and/or 3D movement of the input device.

A computer input device system that includes a finger-wearable input unit that is capable of providing inputs in a two-dimensional plane or in three-dimensional space. The inventive subject matter also includes a mouse frame that receives the finger-wearable unit, allowing a user to quickly transition from the finger-wearable unit to the mouse frame for traditional table-top mouse operation and back. The mouse frame includes features that allow for simple, easy and precise docking and undocking of the finger-wearable unit. The finger-wearable unit can be made up of separable modules and links that allow for reconfiguration of the finger-wearable unit according to a users needs.

An electronic erase device includes at least three electromagnetic signal emission elements, and after a touch panel detects a pattern formed by at least three electromagnetic signal emission elements, the touch panel can erase handwriting upon a user-defined erase area. As a result, it is excessively-high convenient to write and erase on touch panel by using stylus and electronic erase device alternatively in meeting, teaching and working application.

A system and method for dictation using a peripheral device includes a voice recognition mouse. The voice recognition mouse includes a microphone, a first button, a processor coupled to the microphone and the first button, and a memory coupled to the processor. The memory stores instructions that, when executed by the processor, cause the processor to detect actuation of the first button and in response to detecting actuation of the first button, invoke the microphone for capturing audio speech from a user. The captured audio speech is streamed to a first module. The first module is configured to invoke a second module for converting the captured audio speech into text and forward the text to the first module for providing to an application expecting the text, the application being configured to display the text on a display device.

In some embodiments, an input device includes a housing having a top surface, a touch sensor disposed on the top surface of the housing, and a processor disposed in the housing. The touch sensor can be configured to detect a contact by a hand on the top surface of the housing and generate touch data corresponding to the detected contact by the hand. The processor can be configured to control operation of the touch sensor and receive the touch data, determine an orientation of the hand with respect to the housing based on the touch data, and calibrate a detected movement of the input device based on the determined orientation of the hand with respect to the housing. An image sensor and/or one or more IMUs can be used to detect 2D and/or 3D movement of the input device.

A three-dimensional control system includes an input device, a computing device, and a tracking assembly. The input device can include an input sensor, an inertial measurement unit sensor, and an ultrasonic speaker. The tracking assembly can include a plurality of ultrasonic microphones and an inertial measurement unit disposed on or with the computing device. The plurality of ultrasonic microphones can include three microphones in a first plane and at least one other ultrasonic microphone disposed out of the first plane. The ultrasonic microphones can be configured to detect ultrasonic waves output by the speaker of the input device and the computing device can triangulate the position of the input device relative to the computing device in space.

A computer input system includes a mouse including a housing having an interior surface defining an internal volume and a sensor assembly disposed in the internal volume. A processor is electrically coupled to the sensor assembly and a memory component having electronic instructions stored thereon that, when executed by the processor, causes the processor to determine an orientation of the mouse relative to a hand based on a touch input from the hand detected by the sensor assembly. The mouse can also have a circular array of touch sensors or lights that detect hand position and provide orientation information to the user.

An input device can include a housing defining an internal volume and a lower portion, the lower portion defining an aperture, an input sensor disposed in the internal volume, and a haptic assembly disposed in the internal volume. The haptic assembly can include an actuator and a foot coupled to the actuator and aligned with the aperture. The actuator can be configured to selectively extend the foot through the aperture to vary a sliding resistance of the input device on a support surface.