A flexible thin film transistor tactile sensor includes a piezoelectric semiconductor thin film channel of material whose conductivity can be electrostatically controlled connected with source and drain metals and sandwiched between bottom and top thin film insulators and at least one of a bottom and top gate metal, the sensor being supported on a flexible substrate. The piezoelectric property of the used material transduces pressure to electronic charge. The semiconductor property of the used material permits electrostatic modulation of the conductivity in TFT device architecture such that the device can be switched on and off. Transistor action provides gain for input signals, i.e., a modulation of the gate voltage induces strong current change between the source and drain, which can be leveraged to amplify the response to input pressure. The transistor forms the basis for sensor arrays, which are readily scalable to large size.

A system includes a surface, an actuator, and a controller. The surface has a fluid flowing over the surface. The actuator is coupled to the surface to move the surface relative to the fluid. The controller causes the actuator to cause the surface to generate a surface wave that modifies drag in the fluid. The actuator can cause the surface to generate a Love wave.

Example systems described herein are configured to limit inadvertent actuations of a touchpad. The system may include a touchpad, mechanically-activated switch(es), a locking assembly, and a controller. The touchpad is configured to receive a touch input from a user. The mechanically-activated switch(es) are adjacent to the touchpad. The mechanically-activated switch(es) are configured to be activated when a depression force associated with the touch input exceeds a force threshold. The locking assembly is configured to selectively inhibit the touchpad from depressing the mechanically-activated switch(es) depending on whether one or more inhibiting criteria are satisfied. For instance, the inhibiting criteria may take into consideration an inferred intent of the user, an input mode of the touch input, and/or the depression force associated with the touch input.

This method for manufacturing a piezoelectric film includes: a coating step of obtaining a coated film by coating a coating solution on a substrate, wherein the coating solution includes at least lead, zirconium, and titanium, a content ratio of the zirconium and the titanium is in a range of 54:46 to 40:60 in terms of molar ratio, and a perovskite crystal phase is generated by heating the coating solution at a temperature equal to or higher than a crystallization initiation temperature; a drying step of obtaining a dried film by drying the coated film; a first calcining step of obtaining a first calcined film; a second calcining step of obtaining a second calcined film; and a main firing step of obtaining a piezoelectric film by heating the second calcined film at a main firing temperature.

Disclosed is a piezoelectric washer intended for an accelerometer sensor having a ceramic body and a conductive electrode on each of two opposing faces, an electrical resistance being to be established between the two conductive electrodes. The ceramic body has, on its outer contour, a resistive path connecting the conductive electrodes to one another with a predetermined length and cross-section of the resistive path according to the resistance to be established between the two conductive electrodes.

An active cooling system and method for using the active cooling system are described. The active cooling system includes a cooling element having a first side and a second side. The first side of the cooling element is distal to a heat-generating structure and in communication with a fluid. The second side of the cooling element is proximal to the heat-generating structure. The cooling element is configured to direct the fluid using a vibrational motion from the first side of the cooling element to the second side such that the fluid moves in a direction that is incident on a surface of the heat-generating structure at a substantially perpendicular angle and then is deflected to move along the surface of the heat-generating structure to extract heat from the heat-generating structure.

An active cooling system and method for using the active cooling system are described. The active cooling system includes a cooling element having a first side and a second side. The first side of the cooling element is distal to a heat-generating structure and in communication with a fluid. The second side of the cooling element is proximal to the heat-generating structure. The cooling element is configured to direct the fluid using a vibrational motion from the first side of the cooling element to the second side such that the fluid moves in a direction that is incident on a surface of the heat-generating structure at a substantially perpendicular angle and then is deflected to move along the surface of the heat-generating structure to extract heat from the heat-generating structure.

A piezoelectric device includes: a base having at least one hole, a heat conductive portion disposed in the at least one hole and in contact with a wall of the at least one hole, and at least one piezoelectric sensor disposed on the base. A thermal conductivity of the heat conductive portion is greater than a thermal conductivity of the base. Each piezoelectric sensor includes: a first electrode, a piezoelectric pattern made of a piezoelectric material and a second electrode that are sequentially stacked in a thickness direction of the base.

A drive circuit for charging a printhead for ejecting drops of ink is provided, the printhead having a capacitance. The drive circuit comprises a power supply comprising a first connection and a second connection. An inductor is connected to the first connection of the power supply, wherein the inductor is connected to a first drive connection of the printhead to provide a charge path for current to charge the capacitance. The second connection of the power supply is connected to a second drive connection of the printhead. The drive circuit also comprises means for applying a plurality of charging voltage pulses to the inductor to provide a single charge of the capacitance for a single cycle of ink ejection from the printhead. A method of operating the drive circuit is also provided.

A backing panel for a transducer of an ultrasound scanner probe, comprising a core layer sandwiched by a first skin layer and a second skin layer. The transducer may comprise a front portion and a rear portion, where the front portion points to a direction of a target for the ultrasound scanner probe, and the first skin layer is adjacent to the rear portion of the transducer.