An apparatus and method for detecting failed electronics using acoustics. The method comprising directing an acoustic wave toward a circuit component to be tested such that the acoustic wave is reflected off the circuit component, receiving the reflected acoustic wave, amplifying the reflected acoustic wave, and comparing the reflected acoustic wave with known acoustic waves to determine if the circuit component is operating properly. The apparatus comprising a data acquisition system for acquiring data, an X-Y-Z positioner to position two transducers and to hold the circuit component, and software to post-process and analyze the data. The data acquisition system further includes an oscilloscope, a pulser-receiver, two air-coupled transducers, and an amplifier.

An apparatus and method for detecting failed electronics using acoustics. The method comprising directing an acoustic wave toward a circuit component to be tested such that the acoustic wave is reflected off the circuit component, receiving the reflected acoustic wave, amplifying the reflected acoustic wave, and comparing the reflected acoustic wave with known acoustic waves to determine if the circuit component is operating properly. The apparatus comprising a data acquisition system for acquiring data, an X-Y-Z positioner to position two transducers and to hold the circuit component, and software to post-process and analyze the data. The data acquisition system further includes an oscilloscope, a pulser-receiver, two air-coupled transducers, and an amplifier.

The invention relates, in a first aspect, to a method for inspecting an object, in particular a pipeline, for flaws, comprising: emitting a first signal toward the object in a first direction by means of a first ultrasonic transducer; and receiving a first response signal coming from the object from a second direction by means of a second ultrasonic transducer, wherein the first direction and the second direction are different from each other.

The invention relates, in a first aspect, to a method for inspecting an object, in particular a pipeline, for flaws, comprising: emitting a first signal toward the object in a first direction by means of a first ultrasonic transducer; and receiving a first response signal coming from the object from a second direction by means of a second ultrasonic transducer, wherein the first direction and the second direction are different from each other.

An apparatus for improving transmission directivity according to an embodiment of the present invention includes a phased array probe including a channel 1 transducer and a channel 2 transducer which are arranged at intervals corresponding to a quarter wavelength at a center frequency of a guided wave pulse for long-range ultrasonic testing, and a drive unit which supplies electric pulses with opposite phases to the channel 1 transducer and the channel 2 transducer of the channel 1 transducer and the channel 2 transducer, which is disposed on the front end on the basis of an intended transmission direction, is driven with delay by a time corresponding to a quarter frequency of the center frequency than the other transducer disposed on the rear end.

An apparatus for improving transmission directivity according to an embodiment of the present invention includes a phased array probe including a channel 1 transducer and a channel 2 transducer which are arranged at intervals corresponding to a quarter wavelength at a center frequency of a guided wave pulse for long-range ultrasonic testing, and a drive unit which supplies electric pulses with opposite phases to the channel 1 transducer and the channel 2 transducer of the channel 1 transducer and the channel 2 transducer, which is disposed on the front end on the basis of an intended transmission direction, is driven with delay by a time corresponding to a quarter frequency of the center frequency than the other transducer disposed on the rear end.

Systems, apparatuses, methods, and non-transitory computer-readable media for assessing signal quality of a signal are described herein, including determining a signal quality assessment (SQA) metric of the signal based on at least one energy function of the signal, determining whether the SQA metric is above a threshold, and in response to determining that the SQA metric is above the threshold, performing additional signal processing of the signal.

Systems, apparatuses, methods, and non-transitory computer-readable media for assessing signal quality of a signal are described herein, including determining a signal quality assessment (SQA) metric of the signal based on at least one energy function of the signal, determining whether the SQA metric is above a threshold, and in response to determining that the SQA metric is above the threshold, performing additional signal processing of the signal.

The present application provides systems and methods for measuring cell function or tissue function. More particularly, the present application provides systems and methods for determining cell or tissue contractility using ultrasound; systems and methods for measuring the effect an agent has on cell or tissue contractility using ultrasound; and systems and methods for determining material properties of a material using ultrasound.

The present application provides systems and methods for measuring cell function or tissue function. More particularly, the present application provides systems and methods for determining cell or tissue contractility using ultrasound; systems and methods for measuring the effect an agent has on cell or tissue contractility using ultrasound; and systems and methods for determining material properties of a material using ultrasound.