A human machine interface (HMI) system and method of operating. The system includes capacitive measurement circuitry coupled to one or more capacitive touch elements, and piezoelectric measurement circuit including interface circuitry coupled to one or more piezoelectric touch elements. The capacitive measurement circuitry includes a gain stage configured to amplify a signal corresponding to a capacitance at the one or more capacitor input terminals by a gain level for communication to processing circuitry. Gain control circuitry is configured to increase the gain level of the gain stage of the capacitive measurement circuitry responsive to the piezoelectric measurement circuitry receiving a user input from at least one of the piezoelectric touch elements. Implementations that further include piezoelectric drive circuitry for haptic output and clearing debris from the keypad are also disclosed.

A sensor (1) which consists of a first electrode (3a), a ferroelectric layer (2) and a second electrode (3b) is described. The second electrode (3b) is connected to ground and the ferroelectric layer (2) is arranged between the first and second electrodes (3a, 3b).

A sensor device comprising at least a first substrate, a capacitive sensor for recording the approach of an object, a piezoelectric sensor for recording a pressure, wherein the capacitive sensor is arranged on a first side of the first substrate and the piezoelectric sensor is arranged on a second side of the first substrate, wherein the second side is opposite the first side, or wherein the capacitive sensor and the piezoelectric sensor are arranged on the same side of the substrate.

A steering wheel assembly includes a steering rim and a steering housing connected to the steering rim. The steering wheel assembly also includes at least one pressure sensitive component disposed within the steering housing. The at least one pressure sensitive component generates electric signals in response to force applied on the steering housing. The at least one pressure sensitive component may include any one of at least one piezoelectric switch, a piezoelectric sensor, and a capacitive array. Further, at least one pressure sensitive component may provide a haptic feedback. Additionally, a Printed Circuit Board (PCB) disposed within the steering housing is electrically connected to the at least one pressure sensitive component. The PCB includes a controller that determines a user input or a gesture made by a user on the steering housing based on the electric signals received from the at least one pressure sensitive component.

In a driver for a piezo-electric transducer, when a converter circuit and a sensing circuit are the same circuit, many limitations exist on the accuracy of the sensing, due to multiple parasitic effects arising from the interconnection of the power devices. These limitations may limit viability of the sensing for many applications, in particular an accurate determination of when the force on the piezo-electric transducer is fully removed. Providing an additional switch in the sensing circuit configured to repeatedly zero the sensed voltage across the piezo-electric transducer each time the sensed voltage reaches a threshold voltage generates a plurality of voltage segments between zero and the threshold voltage. Accordingly, a controller may then be configured to generate a digital reconstruction of the sensed voltage across the piezo-electric transducer by adding the plurality of voltage segments.

A control circuit and an electronic device are provided, to reduce power consumption of the electronic device. The electronic device includes a sensor and a control circuit. The sensor is configured to: detect a force or a deformation of a shell, and output a force sensing signal S.sub.f. The control circuit is configured to: receive the force sensing signal S.sub.f and determine, based on the force sensing signal S.sub.f, whether to send a drive signal S.sub.d to the sensor. The drive signal S.sub.d is used to drive the sensor to drive the shell to vibrate. The sensor is further configured to: detect vibration of the shell and output a vibration sensing signal S.sub.z. The control circuit is further configured to: receive the vibration sensing signal S.sub.z, and determine, based on the vibration sensing signal S.sub.z, whether to trigger an event.

A sensor includes a plurality of piezoresistive elements and a plurality of electrical connection terminals. The plurality of piezoresistive elements are fabricated on a first side of a substrate. A second side of the substrate is configured to be coupled to an object where a physical disturbance is to be detected. A plurality of electrical connection terminals are coupled to the first side of the substrate.

A touch detection device includes a touch panel, a piezoelectric sensor mounted on the touch panel for detecting a tap event applied to the touch panel, and a control circuit board in electrical communication with the piezoelectric sensor. The control circuit board includes a signal processing circuit for processing a detection signal output from the piezoelectric sensor, and a controller for determining whether the tap event is a correct human finger tap event based on the processed detection signal.

A method of making an actuator switch is disclosed. One method including: receiving a threshold amount of pressure on a top surface of a flexible film; in response to receiving the threshold amount of pressure, contacting a first electrode with a second electrode; in response to receiving the threshold amount of pressure, generating i) a first capacitive connection between a row electrode and the second electrode and ii) a second capacitive connection between a column electrode and the second electrode; in response to the first electrode contacting the second electrode, generating, by a piezoelectric actuator, haptic feedback; and in response to the generating the first capacitive connection and the second capacitive connection, providing an input detection signal.

The present disclosure relates to a press sensing assembly and a terminal device. The press sensing assembly includes: an emitting element including a first side and a second side thereopposite and emitting an ultrasonic wave; a receiving element disposed adjacent to the emitting element, receiving a reflected wave of the reflected ultrasonic wave; and a reflecting pad disposed the first side and the receiving element, and a first surface of the reflecting pad abutting the emitting element and the receiving element, wherein when the second side and/or the receiving element are/is pressed, a region of the reflecting pad corresponding to the pressed region deforms, and a medium density in a deforming region increases.