Embodiments shown and described herein relate, in general, to systems and methods for driving ultrasonic transducers and, more particularly, to systems and methods for controlling the output of high power ultrasonic transducers and improving performance of ultrasonic systems.

An ultrasonic device includes a substrate, first ultrasonic elements having a resonance characteristic of a first frequency, and second ultrasonic elements having a resonance characteristic of a second frequency lower than the first frequency. The first ultrasonic elements are arranged along a first direction to make a first to an n-th high-frequency ultrasonic element lines. The second ultrasonic elements are arranged along the first direction to make a first to an n-th low-frequency ultrasonic element lines. The first to the n-th high-frequency ultrasonic element lines and the first to the n-th low-frequency ultrasonic element lines are arranged along a second direction. The first and second ultrasonic elements have an opening, a vibrating membrane, and a piezo element part. A length in the second direction of the opening of the first ultrasonic element is shorter than a length in the second direction of the opening of the second ultrasonic element.

A processing device that performs a process of transmitting and receiving an ultrasonic wave includes an ultrasonic device, a transmitter, a receiver, and a controller. The transmitter is configured to output a driving signal to the ultrasonic device. The ultrasonic device includes a high-frequency ultrasonic element line and a low-frequency ultrasonic element line. The high-frequency ultrasonic element line is configured to arrange a plurality of ultrasonic elements having a resonance characteristic of a first frequency. The low-frequency ultrasonic element line is configured to arrange a plurality of ultrasonic elements having a resonance characteristic of a second frequency. The transmitter is configured to output the driving signal of a sine wave to the high-frequency ultrasonic element line in a first mode. The transmitter is configured to output the driving signal of a square wave to the low-frequency ultrasonic element line in a second mode.

A multi-resonance flextensional low frequency acoustic projector of the present disclosure includes a piezoelectric actuator; a plurality of staves attached to an outer surface of the piezoelectric actuator to convert longitudinal vibration generated by the piezoelectric actuator into lateral vibration perpendicular to the outer surface of the piezoelectric actuator; and an acoustic window surrounding an exterior of the staves and water-tightening the inside of the projector. The plurality of staves is configured in shapes different from each other to generate two or more types of resonance vibration modes, so there is an effect of allowing low frequency acoustic transmission in a wide frequency band.

One or more systems, devices, computer-implemented methods and/or computer program products of use provided herein relate to ultrasound coexistence in an FMS. A system can comprise a memory that can store computer-executable components. The system can further comprise a processor that can execute the computer-executable components stored in the memory, wherein the computer-executable components can comprise a frequency generation component that can use a variable frequency generator circuitry to generate electronic signals at one or more different frequencies in at least one fetal sensor device (FSD) of a fetal monitoring system (FMS), wherein the electronic signals can cause a transducer of the at least one FSD to generate ultrasound signals at the one or more different frequencies.

An amplifier circuit to be used in a sonar is described. The amplifier circuit includes a transducer and a matching circuit. The transducer has an impedance characteristic having a resonance frequency and an anti-resonance frequency higher than the resonance frequency. The matching circuit is connected to the transducer. The impedance characteristic of the transducer connected to the matching circuit has a first resonance frequency and a second resonance frequency higher than the first resonance frequency.

An ultrasonic device, comprising an ultrasonic transducer (400) comprising: a membrane (405) suspended above a cavity (403) arranged on the upper surface side of a substrate (401); a piezoelectric layer (407) attached to a surface of the membrane (405); a first electrode (E1) arranged on the lower surface side of the cavity (403); and a second electrode (E3) arranged on the upper surface side of the cavity (403), in contact with the piezoelectric layer (407), the device further comprising a control circuit (CTRL) connected to the first (E1) and second (E3) electrodes and capable of applying a first control voltage (VDC) on the first electrode (E1), and a second control voltage (VAC) different from the first voltage on the second electrode (E3).

An acoustic foreign matter removal device includes a stage, an acoustic head, and a movement mechanism. The acoustic head has a plurality of ultrasonic speakers and a casing22. A plurality of ultrasonic waves generated from the plurality of ultrasonic speakers are concentrated in a gap between the casing and a holding surface of the stage to form a low pressure region; and foreign matter adhering to a surface of an electronic component is sucked into the low pressure region to remove the foreign matter from the surface.

A fluid device drive method for a fluid device including a reference setting step of setting a reference position of a node or an antinode of a standing wave, a first search step of searching within a predetermined range from the reference position for a first frequency of the first standing wave at which a node or an antinode is located, a second search step of searching within the range from the reference position for a second frequency of the second standing wave at which a node or an antinode is located, and a drive step of driving a first ultrasonic element at the first frequency and driving a second ultrasonic element at the second frequency.

An ultrasonic device includes a driving circuit to provide drive power, a first transducer array to generate ultrasonic waves, the first transducer array being connected to receive power from the driving circuit, and a second transducer array to detect reflected or elicited ultrasonic waves incident on the device from a target and generate a signal based on those waves, the second transducer array being acoustically transmissive and disposed over the first transducer array such that the generated ultrasonic waves pass through the second transducer array. The second array is tuned to operate on top of the first. The functions of the two arrays may be reversed and the array tuned to operate with the first array receiving and the second array transmitting.