A brush cleaner control device includes a housing disposed with an adapter. The adapter is disposed with a brush. A control circuit is disposed in the housing, and the control circuit includes a power supply, a MCU based controller, a switch control circuit, a driving circuit, a speed adjustment circuit, a vibration control circuit and a vibration motor. The power supply is used to supply the MCU based controller with power, the MCU based controller is used to control the driving circuit through the switch control circuit, the driving circuit is used to drive the vibration control circuit through the speed adjustment circuit, and the vibration control circuit is used to control the vibration motor. Therefore, the brush cleaner control device is with high intelligence, diverse functions, flexible control, easy to use and can be controlled wirelessly.

Multifunctional ultrasound systems and methods for body section registration and mapping of microbubble dynamics. A system is provided that includes one or more micromachined ultrasonic transducer arrays (MUTAs) configured to capture a high-resolution image of at least a portion of a body section using ultrasound and monitor microbubble activity during ultrasound treatment. The system includes an image registration module configured to spatially register the high-resolution image with a reference image. The system includes electronics configured to control one or more of drive signal amplitude, frequency filtering, multiplexing, and DC bias voltage. The system can be configured to control ultrasound treatment based on the monitoring of the microbubble activity during treatment.

Described herein are methods and systems for testing transducers and associated integrated circuits. In some cases, a method or system described herein can comprise modulating a bias voltage using a test signal in order to produce a modulated bias voltage signal useful in testing a plurality of transducers of a transducer array in parallel.

A piezoelectric film includes a substrate having flexibility, and at least two piezoelectric elements provided to the substrate so as to be arranged at intervals of a first dimension along a first direction, the piezoelectric elements are each configured by stacking a first electrode film, a piezoelectric film made of an inorganic material, and a second electrode film along a thickness direction of the substrate, and an area between the piezoelectric elements adjacent to each other along the first direction forms a vibrational region which can be displaced in the thickness direction.

To provide a probe including a TGC circuit therein. The probe includes a plurality of receive circuits. Each receive circuit includes: an ultrasound transducer; a transmit/receive switch; a variable attenuator; a first capacitor; and an amplifier. The ultrasound transducer converts the receive signal into a ground level electric signal and outputs the ground level electric signal as a first output signal. The transmit/receive switch is connected to a first signal line, and switches depending on whether to output the first output signal output from the ultrasound transducer to the first signal line. The variable attenuator includes a control terminal and two terminals, and changes a resistance value between the two terminals other than the control terminal based on a control signal input to the control terminal. The amplifier has an input terminal connected to the first capacitor and includes at least an amplifier circuit configured to amplify an electric signal of the first signal line and output the amplified electric signal to a second signal line. In the variable attenuator, one of the two terminals other than the control terminal is connected to the first signal line, and the other terminal is connected to the ground via a second capacitor different from the first capacitor.

The invention provides a somatosensory vibration generating device comprising: an audio signal receiving module for receiving sound waves of external environmental sounds and converting the sound waves into a first audio frequency signal; a digital-to-analog conversion module for performing digital-to-analog conversion on the first audio frequency signal to generate and output a second audio frequency signal after digital-to-analog conversion; a digital signal processing module for converting the second audio frequency signal output by the digital-to-analog conversion module into a first vibration signal; an operational amplifier for performing gain processing on the first vibration signal and outputting a second vibration signal after gain processing; and at least one tactile transducer at least comprising a vibration element and a tactile transducer; and a frequency of the second audio frequency signal is less than 200 Hz.

Buildup of the combustion products of e-liquid residues can be mitigated through the use of an agitation system that applies a vibration to the e-liquid storage pod. This vibration induces agitation, which may be further supported by low levels of heating, to help fresh e-liquid to dissolve precipitate left over from vaporization. Dissolution of these precipitates prevents their buildup. This buildup can result in the generation of a residue that can interfere with the capillary action of the wick. Any residue is subjected to repeated heating which may result in the generation of combustion products.

A vibration device includes a vibrator including a cylinder including an opening, a light-transmissive cover directly or indirectly coupled to the cylinder to cover the opening of the cylinder, and a piezoelectric element to vibrate the light-transmissive cover, and including an opening end portion, an elastic member holding the opening end portion of the vibrator, and a case connected to the elastic member.

An ultrasonic sensor includes a vibration plate that includes a vibration portion and is formed of a resin; a wall portion that is provided on the vibration plate, surrounds the vibration portion and is formed of a resin; and a piezoelectric element that is provided in the vibration portion of the vibration plate. Accordingly, the wall portion surrounding the vibration portion can suppress a frequency variation of an ultrasonic wave output from the ultrasonic sensor and can deform the ultrasonic sensor into a shape corresponding to a surface of an object having various shapes.

Aspects of the technology described herein relate to ultrasound transducer devices including capacitive micromachined ultrasonic transducers (CMUTs) and methods for forming CMUTs in ultrasound transducer devices. Some embodiments include forming a cavity of a CMUT by forming a first layer of insulating material on a first substrate, forming a second layer of insulating material on the first layer of insulating material, and then etching a cavity in the second insulating material. A second substrate may be bonded to the first substrate to seal the cavity. The first layer of insulating material may include, for example, aluminum oxide. The first substrate may include integrated circuitry. Some embodiments include forming through-silicon vias (TSVs) in the first substrate prior to forming the first and second insulating layers (TSV-Middle process) or subsequent to bonding the first and second substrates (TSV-Last process).