A resonant drive circuit for a capacitive sensor device includes a resonant LC stage, a signal source, and an amplifier stage. The resonant LC stage includes an inductorless floating gyrator circuit electrically connected to a sense capacitor. The inductorless floating gyrator circuit is configured to synthesize a fixed inductance. The resonant LC stage is configured to output a sensed capacitance signal based on the fixed inductance and a change in capacitance of the sense capacitor. The signal source is configured to output a reference signal. The amplifier stage is configured to receive the sensed capacitance signal and the reference signal and output a measured capacitance signal that indicates a difference in one or more of amplitude and phase between the sensed capacitance signal and the reference signal.

A touch detection device includes: an electrostatic capacitance detection device of each touch sensor; and a touch detection device to each touch sensor. The touch determination device obtains a maximum electrostatic capacitance, a minimum electrostatic capacitance and an intermediate electrostatic capacitance, and determines that the touch operation with respect to the touch sensor having the maximum change amount is performed when both of a first condition that a difference between the maximum electrostatic capacitance and the intermediate electrostatic capacitance exceed a second determination value and a second condition that a difference between the intermediate electrostatic capacitance and the minimum electrostatic capacitance is smaller than a third determination value are satisfied, and determines that a change of the electrostatic capacitance is caused by a noise when at least one of the first condition and the second condition is not satisfied.

A capacitive sensor device comprises a first sensor electrode, a second sensor electrode, and a processing system coupled to the first sensor electrode and the second sensor electrode. The processing system is configured to acquire a first capacitive measurement by emitting and receiving a first electrical signal with the first sensor electrode. The processing system is configured to acquire a second capacitive measurement by emitting and receiving a second electrical signal, wherein one of the first and second sensor electrodes performs the emitting and the other of the first and second sensor electrodes performs the receiving, and wherein the first and second capacitive measurements are non-degenerate. The processing system is configured to determine positional information using the first and second capacitive measurements.

An apparatus, such as a set-top box, includes at least one capacitive touch button with a guard feature that provides, among other things, the ability to detect and reject false touches. According to an exemplary embodiment, the apparatus includes a first conductive element that is capacitively isolated from ground, and a second conductive element that is capacitively isolated from ground and located adjacent to the first conductive element. A first sensor is coupled to the first conductive element and measures a change in capacitance between the first conductive element and ground due to a change in physical environment. A second sensor is coupled to the second conductive element and measures a change in capacitance between the second conductive element and ground due to the change in physical environment. A controller is coupled to the first sensor and the second sensor and determines a difference between the measured changes in capacitance of the first sensor and the second sensor.

An appliance, including an interface and input chassis is provided. Appliance may include a contact plate, a conductive spring, and a support wall. The input chassis may define a connection aperture extending therethrough. The contact plate may be disposed above the connection aperture of the input chassis. The contact plate may include a top surface facing away from the input chassis and a bottom surface facing toward the input chassis. The conductive spring may be coupled the contact plate at the bottom surface of the contact plate. The conductive spring may extend through the connection aperture. The support wall may be attached to the input chassis and disposed about the conductive spring between the contact plate and the connection aperture of the input chassis.

A computing device can include an enclosure that defines an internal volume and an external surface. An input component can be positioned at the external surface. A processing unit and a memory can be communicatively coupled and disposed within the internal volume. A singular input/output port can be positioned at an orifice defined by the enclosure. The singular input/output port can be communicatively coupled to the processing unit and the memory. The singular input/output port can be configured to receive data and power and configured to output data from the processing unit. The computing device can include an air-moving apparatus to move air along an airflow pathway. The enclosure can include a thermally conductive base.

A fingerprint sensing module has a fingerprint sensor and a cover. The main color layer and the pattern layer are arranged between the cover and the fingerprint sensor. The pattern layer constitutes a predetermined pattern that is used to present the pattern of the button. The both sides of the main color layer are flush with both sides of the pattern layer, so that the capacitance variations in the corresponding pattern layer and the main color layer pass through the medium with the same thickness, and have an approximate capacitance variation mode. Thus, the sensed fingerprint image truly reflect the detected fingerprint image without being affected by the preset pattern, and a pattern layer with a certain thickness is used to enhance the color saturation presented by the predetermined pattern.

A plurality of detection patterns are formed as conductive patterns directly on a back surface of a panel substrate to which an operation object such as a finger comes in proximity from a front surface side thereof. By independently detecting a change in capacitance in the plurality of detection patterns caused by proximity of the operation object from the front surface side, proximity of the operation object to the panel substrate is detected.

Touch sensors form various controls for a touch controller of a blender. The controls are arranged on the touch controller such that a user holding the blender can operate the blender by articulating their thumbs. In one example, button controls for preset programs are arranged in an arcuate manner on one side of the touch controller, the curvature of the arcuate shape being open to the side of the blender. A button for a pulsating function may be located inside the curvature opening. Start and stop buttons may be located near the bottom in the middle of the touch controller. A vertical sliding speed control may be located on the side of the touch controller opposite the button controls. The touch controller may also have an LED or LCD screen.

A touch key of an interface for an aircraft avionics system. The touch key includes a button, a mechanical switch, and a sensor. The mechanical switch is configured to be actuated when the button is pressed. Actuation of the mechanical switch sends a switch signal to the aircraft avionics system. The sensor is configured to detect when the button is being touched independent of whether the button is being pressed. The sensor sends a touch signal indicating that the button is being touched to the aircraft avionics system.