A method for determining at least one parameter of interest of a material comprises directing, using a radio frequency (RF) applicator, one or more RF energy pulses into a region of interest, the region of interest comprising a material having a parameter of interest and at least one reference, the material and the reference separated by at least one boundary; detecting, using an acoustic receiver, at least one multi-polar acoustic signal generated in the region of interest in response to the RF energy pulses; processing the at least one multi-polar acoustic signal to determine an electric field strength at the boundary; calculating a voltage standing wave ratio (VSWR) of the one or more RF energy pulses; and determining the at least one parameter of interest of the material based at least on the determined electric field strength and the VSWR.

Systems and methods relate to testing and/or monitoring acoustic emissions detected at composite structures, such as carbon fiber structures, intended for use in extreme conditions, such as in high pressure conditions, high or low temperature conditions, conditions in which the composite structure is subjected to mechanical impacts, or the like. The systems and protocols are suitable for use with composite structures comprising, e.g., carbon fiber structures, such as hollow or partially hollow structures used in submersible vehicles, spacecraft, gas-fillable storage containers, pressure vessels, and the like, that are subjected to extreme conditions during use. Systems and methods disclosed herein are directed to collecting and analyzing data, determining background conditions, differentiating and classifying signals, conditioning or curing a material or structure, assessing, rating and/or validating the “health” of a material or structure in real-time, determining alarm conditions, predicting failure conditions, and the like.

Certain embodiments of the present disclosure are directed to a method that may include identifying at least one metric for a fluid flowing through a line from a vessel to a dispenser. The method may include identifying a reference value for the at least one metric for the fluid. The method may include performing an analysis of the fluid based on the at least one metric for the fluid. The method may include comparing results of the analysis with the reference value. The method may include performing at least one action based on determining that there has been a change in the at least one metric relative to the reference value.

A measurement method performed by a semiconductor manufacturing apparatus including a chamber is provided. In the measurement method, first measurement data including a signal of a resonance frequency of the chamber is acquired as reference data, in response to transmitting an electrical signal into the chamber while a jig capable of performing wireless communication is not placed in the chamber. Subsequently, second measurement data including the signal of the resonance frequency of the chamber and including a signal of a resonance frequency of a sensor installed in the jig is acquired, in response to transmitting an electrical signal into the chamber while the jig is placed in the chamber. By subtracting the reference data from the second measurement data, third measurement data is calculated.

A system for determining gas characteristics at high altitudes in embodiments of the present invention may have one or more of the following features: (a) a high-altitude balloon having one or more of the following features: (a) a balloon, (b) a balloonsat operably coupled to the balloon, (c) an air path chamber wherein gas at a high altitude can occupy the air path chamber, (d) a first speaker located on a substrate within the air path chamber, wherein the first speaker takes an electrical signal input and creates a first sound wave, and (e) a second speaker located on the substrate facing opposite of the first speaker located outside of the air path chamber, wherein the second speaker takes the electrical signal and creates a second sound wave.

Systems and methods for analyzing physical characteristics of a battery include arrangements of two or more transducers coupled to the battery. A control module controls one or more of the two or more transducers to transmit acoustic signals through at least a portion of the battery, and one or more of the two or more transducers to receive response acoustic signals. Distribution of physical properties of the battery is determined based at least on the transmitted acoustic signals and the response acoustic signals.

A measurement system for measuring an inhomogeneity of a medium in a vessel includes: a first ultrasound emitter for sending a first ultrasound signal along a first path; a second ultrasound emitter for sending a second ultrasound signal along a second path different from the first path; a first ultrasound receiver for receiving the first ultrasound signal and measuring a first measurement parameter p1 of the received first ultrasound signal; a second ultrasound receiver for receiving the second ultrasound signal and measuring a second measurement parameter p2 of the received second ultrasound signal; and a control unit: receives the first measurement parameter p1 from the first ultrasound receiver, receives the second measurement parameter p2 from the second ultrasound receiver, and determines a ratio p1/p2 of the first measurement parameter p1 to the second measurement parameter p2.

One or more embodiments relates a single port surface acoustic wave sensor (SAW) device adapted for use in a wide range of operational temperatures and gas phase chemical species. The device includes a piezoelectric crystal substrate; at least one interdigitated electrode/transducer (IDT) positioned on the piezoelectric crystal substrate; and at least one conducting metal oxide film positioned on the piezoelectric crystal substrate and in communication with at least the IDT.

A method and system for grading pistons with deposits is disclosed. In an embodiment, a piston with an outer surface and deposits upon the outer surface is increased in temperature and thermally scanned. The deposits are identified based on the temperature differences measured with respect to the temperature of the outer surface of the piston. Deposit characteristics can be generated from the identified locations of deposits and the magnitude of temperature difference with respect to the outer surface. The deposit characteristics are recorded and used to grade the pistons.

A thermoacoustic probe with an electromagnetic (EM) energy applicator, a thermoacoustic transducer, and a housing containing the applicator and thermoacoustic transducer and enabling an EM exit window and a transducer front face to be held flush with respect to each other. A first acoustic absorbing material is placed between the EM applicator and the transducer, between the EM applicator and the housing, and between the transducer and the housing as spacers; and a second acoustic absorbing material is injected between the EM applicator and the transducer, between the EM applicator and the housing, and between the transducer and the housing in the spaced gaps, wherein the first acoustic absorbing material and the second acoustic absorbing material are combined to form a sleeve covering the applicator sides and the transducer sides. The acoustic absorbing materials mitigate sound artifacts and noise resulting in cleaner signal data. In a preferred embodiment the applicator is a radio-frequency applicator, the transducer is a piezoelectric transducer, and the probe is utilizable for tissue imaging.