To alleviate information-dependent behavior by using a mobile terminal of a user of the mobile terminal. A mobile terminal including a first signal generator that generates a frequency signal in the audible band, a second signal generator that generates a high-frequency signal in a frequency band higher than the audible band, a speaker that converts the high-frequency signal into a corresponding high-frequency sound, and a timing controller that controls timing of the generation of the high-frequency signal to be a timing that does not correlate with the timing of the generation of the frequency signal in the audible band is provided.

Panel structure includes a substrate, a piezoelectric material layer and a thin film transistor. The piezoelectric material layer is disposed under the substrate, in which the piezoelectric material layer is configured to generate human recognizable sound waves by vibrating at a human audible frequency in a first time interval, and the piezoelectric material layer is configured to generate ultrasonic waves by vibrating at an ultrasonic frequency in a second time interval. The piezoelectric material layer is used for recognizing human fingerprints when it vibrates at the ultrasonic frequency. The thin film transistor is positioned under and electrically connected to the piezoelectric material layer.

A signal generator has a generator output. The signal generator is configured to generate first and second signals at the generator output. The first signal has a first frequency, and the second signal has a second frequency. Switching circuitry has a circuitry input and a circuitry output. The circuitry input is coupled to the generator output. The circuitry output is adapted to be coupled to an ultrasonic transducer mechanically coupled with a surface. The switching circuitry is configured to: provide the first signal to the ultrasonic transducer at the first frequency to reduce a fluid droplet on the surface from a first size to a second size; and provide the second signal to the ultrasonic transducer at the second frequency to reduce the fluid droplet from the second size to a third size.

This disclosure relates to systems and methods for ultrasonic lens cleaning. In an example, an ultrasonic lens cleaning system can be configured to apply sequences that include at least one driver signal adapted to drive a transducer adaptively coupled to a top cover. The transducer can be excited based on the sequences to vibrate the top cover to remove a contaminant from a surface of the top cover. The applying of the sequences can include applying a first sequence to the transducer based on a first set of sequence parameters, applying a second sequence to the transducer based on a second set of sequence parameters, and applying a third sequence to the transducer based on a third set of sequence parameters.

A vibration device includes a vibration body including a light-transmitting portion including first and second main surfaces opposing each other and a vibration portion that is continuous with the light-transmitting portion and vibrates with a main vibration together with the light-transmitting portion, and a piezoelectric vibrator fixed to the vibration portion. Localized vibration portions which generate a localized vibration different from the main vibration are provided at a position not overlapping with a center or approximate center of the light-transmitting portion.

Lens cleaning systems, drivers and methods to detect faults or degradation in a lens cleaning system, including a controller to control a lens transducer drive signal frequency to vibrate the lens in a frequency range of interest and measure frequency response values according to driver feedback signals, and to compare the measured frequency response values to baseline frequency response values for a healthy system, and to selectively determine the existence of a fault or degradation in the lens cleaning system according to dissimilarities between the measured frequency response values and the baseline frequency response values.

Methods and apparatus for using two stage ultrasonic lens cleaning for water removal are disclosed. An apparatus can expel fluid from a droplet on an optical surface using an ultrasonic transducer mechanically coupled to the optical surface and having first and second resonant frequency bands. A signal generator can generate a first signal including a first frequency to be coupled with the ultrasonic transducer mechanically coupled to the surface, and can generate a second signal including a second frequency to be coupled with the ultrasonic transducer mechanically coupled to the surface. Switching circuitry can activate the ultrasonic transducer at the first frequency to reduce the droplet from a first size to a second size, and to activate the ultrasonic transducer at the second frequency to reduce the droplet from the second size to a third size.

A characterization device for non-destructively characterizing a material includes emitter/receiver cells, each cell being able, in an emit mode, to emit ultrasound waves towards the material for characterizing, and, in a receive mode, to receive ultrasound waves that have been transmitted through the material. The non-destructive characterization device includes a ring made up of a plurality of adjacent angular sectors, each angular sector including ultrasound cells stacked in a radial direction of the ring.

Various embodiments are directed to a method of driving an end effector coupled to an ultrasonic drive system of a surgical instrument. The method comprises generating at least one electrical signal. The at least one electrical signal is monitored against a first set of logic conditions. A first response is triggered when the first set of logic conditions is met. A parameter is determined from the at least one electrical signal.

A treatment system includes a control apparatus having respective first and second output sources that supplies respective high-frequency power defined by a first electrical energy and a second electrical energy. The control apparatus includes a processor configured to acquire a first value based on the first electrical energy and a second value based on the second electrical energy. Based on the first value, the processor determines influence given to the second value by the first electrical energy. Based on the influence given to the second value, the processor adjusts an output instruction value to the second output source by the first electrical energy and the second value based on the second electrical energy. The control apparatus is configured to properly calculate a physical quantity relating to the first and second electrical energies even when an electrical noise is generated in a state in which multiple electrical energies are simultaneously supplied.