An acoustic cleaving system are described for initiating and controlling crack propagation. In an embodiment, the system includes an acoustic generator that includes a piezoelectric device; a high-voltage power supply; and an acoustic cleaving circuit. The acoustic cleaving circuit includes a push-pull circuit coupled to the piezoelectric device and coupled to the high-voltage power supply, and a capacitor bank that includes one or more capacitors coupled in parallel to the push-pull circuit. In one embodiment, the push-pull circuit is for receiving at least one input signal and for producing an amplified output signal to drive the piezoelectric device.

An acoustic system is described that includes a piezoelectric device; an alternating current (AC) power supply for supplying an AC voltage; an AC-to-direct current (DC) converter coupled to the AC power supply for converting the AC voltage supplied by the AC power supply into DC voltage; a function generator for producing an input signal at a resonant frequency of the piezoelectric device; and an amplifier coupled to the AC-to-DC converter, the function generator, and the piezoelectric device, where the amplifier is for producing an output signal by amplifying the input signal according to the DC voltage and driving the piezoelectric device using the output signal.

[Problem]

Provided are a highly reliable automatic analyzer and an abnormality determination method for the same.

[Solution]

The automatic analyzer comprises: a stirring unit that stirs a sample and a reagent by irradiating a reaction container with ultrasonic waves; a power amplifier that applies a voltage to a piezoelectric element of the stirring unit; an impedance measuring unit that measures an electric impedance of the piezoelectric element of the stirring unit; an analyzing unit that makes component analysis of a reaction liquid of the sample and the reagent; and a control unit that controls the stirring unit, the power amplifier, the impedance measuring unit, and the analyzing unit. The automatic analyzer has a plurality of stirring units as mentioned above. The control unit determines a connection condition between the stirring unit and the power amplifier or the impedance measuring unit, or an inclination condition of the automatic analyzer according to the electric impedance measured by the impedance measuring unit for the stirring units.

A device has a piezoelectric or ferroelectric substrate on which ice is deposited. Electrodes are connected to the substrate. A vector network analyzer is connected to the electrodes and configured to determine the resonant frequency of the substrate. An excitation module including a function generator communicates with the vector network analyzer and is connected to an amplifier. The amplifier is connected to the electrodes. The excitation module uses an automatic switch to apply to the electrodes an AC electrical signal having a frequency coinciding with the resonant frequency measured in the vector network analyzer and which changes gradually as the ice melts.

A miniature rangefinder includes a housing, a micromachined ultrasonic transducer, and signal processing circuitry. The housing includes a substrate and a lid. The housing has one or more apertures and the micromachined ultrasonic transducer is mounted over an aperture. The micromachined ultrasonic transducer may function as both a transmitter and a receiver. An integrated circuit is configured to drive the transducer to transmit an acoustic signal, detect a return signal, and determine a time of flight between emitting the acoustic signal and detecting the return signal.

Delay line memory device, systems and methods are disclosed. In one aspect, a delay line memory device includes a substrate; an electronic unit disposed on the substrate and operable to receive, amplify, and/or synchronize data signals into a bit stream to be transmitted as acoustic pulses carrying data stored in the delay line memory device; a first and a second piezoelectric transducer disposed on the substrate and in communication with the electronic unit, in which the first piezoelectric transducer is operable to transmit the data signals to the acoustic pulses that carry the data through the bulk of the substrate, and the second piezoelectric transducer is operable to transduce the received acoustic pulses to intermediate electrical signals containing the data, which are transferred to the electronic unit via an electrical interconnect to cause refresh of the data in the delay line memory device.

A system for processing biological or other samples includes an array of transducer elements that are positioned to align with sample wells in a microplate. Each transducer element produces ultrasound energy that is focused towards a well of the microplate with sufficient acoustic pressure to cause inertial cavitation. In one embodiment, the transducers are configured to direct ultrasound energy into cylindrical wells. In other embodiments, the transducer elements are configured to direct ultrasound energy into non-cylindrical wells of a microplate.

A miniature rangefinder includes a housing, a micromachined ultrasonic transducer, and signal processing circuitry. The housing includes a substrate and a lid. The housing has one or more apertures and the micromachined ultrasonic transducer is mounted over an aperture. The micromachined ultrasonic transducer may function as both a transmitter and a receiver. An integrated circuit is configured to drive the transducer to transmit an acoustic signal, detect a return signal, and determine a time of flight between emitting the acoustic signal and detecting the return signal.

Delay line memory device, systems and methods are disclosed. In one aspect, a delay line memory device includes a substrate; an electronic unit disposed on the substrate and operable to receive, amplify, and/or synchronize data signals into a bit stream to be transmitted as acoustic pulses carrying data stored in the delay line memory device; a first and a second piezoelectric transducer disposed on the substrate and in communication with the electronic unit, in which the first piezoelectric transducer is operable to transmit the data signals to the acoustic pulses that carry the data through the bulk of the substrate, and the second piezoelectric transducer is operable to transduce the received acoustic pulses to intermediate electrical signals containing the data, which are transferred to the electronic unit via an electrical interconnect to cause refresh of the data in the delay line memory device.

The present invention relates to the technical field of physiotherapeutic apparatuses and devices for locating or stimulating reflex points in the body of a patient. Specifically, it provides a sensory band comprising a frame having two arched arms, two antennas, a pair of ultrasonic transducers, three vibrators, and a microcontroller operatively connected to said pair of ultrasonic transducers, and to said three vibrators. The present invention further provides a method for obstacle detection that comprises said sensory band, wherein said method comprises the steps of transmitting an ultrasonic wave by means of said pair of ultrasonic transducers; measuring the reflection of said ultrasonic wave by means of said pair of ultrasonic transducers; providing vibrations to said three vibrators, from the reflection characteristics of said ultrasonic wave; wherein said vibration varies depending on the reflection characteristics of said ultrasonic wave.