Abstract: A passive acoustic wave sensor system for monitoring the quality of liquids, such as engine oil, is disclosed. The sensor system has an acoustic wave sensing device for generating a propagating acoustic wave and for detecting changes in frequency or other propagation characteristics of the acoustic wave caused by acousto-electric interactions between the liquid and the wave at an interactive region of the device. An antenna is integrated in the sensing device for receiving an interrogation signal and for transmitting the output response of the sensing device. The output response can be analyzed to determine the conductivity, pH or other electrical characteristics of the liquid. One or more reference devices may be utilized to compensate for mechanical effects of the liquid and temperature or other environmental effects. The sensing and reference devices can be configured as SH-SAW, SH-APM, FPM devices or other acoustic wave devices.

Abstract: An acoustic wave acceleration sensor comprises an acoustic wave device including a plate that functions as a propagation medium and at least one interdigital transducer configured upon the plate. One or more antennas can be integrated with the acoustic wave device, wherein the antenna(s) communicates with interdigital transducers. Such antennas can receive wireless interrogation signals and transmit signals indicative of acceleration data.

Abstract: An acoustic wave sensor system for monitoring the etch rate or etchability of a selective material has an acoustic wave sensing device having a piezoelectric substrate and at least one electrode coupled to the substrate for generating a propagating acoustic wave and for detecting changes in frequency or other propagation characteristics of the acoustic wave. A selective material is disposed on the substrate. Changes in propagation characteristics of the wave caused by etching of the selective material by an etchant can be analyzed to evaluate the etching rate or etchability of the selective material. The sensing system can have a wireless sensing device which device is mountable in an oil filter system for monitoring the corrosion of the engine. The sensing device can be configured as BAW, SH-SAW, SH-APM, FPM devices or other acoustic wave devices.

Abstract: Many mechanical systems contain rotating parts used to transfer power from one part of the system to another. The system's efficiency and longevity can be increased by measuring the speed and loading of the rotating parts. Passive wireless sensors are ideal for instrumenting rotating parts because they require no connecting wires and no stored energy. The sensor measurements contain read errors when the stationary interrogation circuit and the rotating sensor are not ideally aligned. The read errors are a function of the angular offset between the stationary interrogation circuit and the passive sensor. As such, the read errors are deterministic. A measurement of the angular offset between the stationary interrogation circuit and the passive sensor is used to determine a correction factor that cancels out the read error to produce a compensated sensor signal.

Abstract: An acoustic wave flow sensor includes a piezoelectric substrate and a heater located immediately below the acoustic wave substrate. A heating element can be deposited in association with a plurality of acoustic wave components upon the acoustic wave substrate. The acoustic wave components, the piezoelectric substrate, the heater and the heating element operate in a high-condensation environment, such that the plurality of acoustic wave components are heated directly by the heater and/or the heating element, thereby promoting a desorption of water in the high-condensation environment in order to achieve accurate and reliable flow sensing data thereof.

Abstract: A cooking oil quality sensing apparatus and system includes an acoustic wave sensor comprising one or more acoustic wave transducers configured upon a piezoelectric substrate such that when the acoustic wave sensor is in contact with cooking oil, the sensor generates acoustic wave data indicative of the quality of the cooking oil. An antenna can be integrated with the acoustic wave sensor, such that the antenna receives data an external source and transmits the acoustic wave data indicative of the quality of the cooking oil to the external source. An oscillator can be integrated with the acoustic wave sensor, such that the output of the oscillator contains data indicative of the quality of the cooking oil. The acoustic wave sensor can be coated with a material that is selectively sensitive and/or reactive to one or more fatty acids associated with or contained in the cooking oil.

Abstract: One embodiment of the present invention provides a system and method for appending server-side glossary definitions to transient Web content in a networked computing environment. A glossary database stores a glossary, which includes a plurality of structured records. Each structured record is keyed by a unique identifier derived from a key word and contains a definition associated with the key word. A parser receives Web content, which includes text in transit to a Web client, and parses the text into one or more tokens corresponding to one such key word. A comparator module matches the tokens against each unique identifier in the glossary and retrieves each structured record containing a matching unique identifier. A constructor inserts a hyperlink in place of the text corresponding to each matched token and references the definition contained in the retrieved structured record for the matching unique identifier.

Abstract: A lubricity sensor includes a flexural plate wave device and a face shear mode bulk acoustic wave device, which is associated with and located proximate to the flexural plate wave device. The face shear mode bulk acoustic wave device and the flexural plate wave device form a lubricity sensor wherein acoustic wave data produced by the flexural plate device together with the face shear mode bulk acoustic wave device when the lubricity sensor is exposed to a liquid relates directly to a lubricity of the liquid thereby providing lubricity measurement data associated with the liquid. The acoustic wave data can comprises the oscillation gain compensation, the frequency, amplitude and/or phase velocity associated with the flexural plate device and the shear mode bulk acoustic wave device such that the oscillation gain compensation, the frequency, amplitude and/or phase velocity provide an indication of the lubricity of the liquid.

Abstract: A method and system for measuring liquid conductivity utilizing an acoustic wave sensor. In general, an acoustic wave device can be provided with one or more interdigital transducers, including at least a first interdigital transducer and at least a second interdigital transducer having a cavity formed therebetween, wherein liquid comes into contact with the cavity. For example, a liquid, such as oil, may flow through the cavity. A measurement of the resistance and/or frequency of the acoustic wave device next to the cavity can be performed in order to obtain data indicative of the conductivity of the liquid.

Abstract: An acoustic wave flow sensor is disclosed, which includes a sensor substrate and an acoustic wave diaphragm etched upon the sensor substrate, wherein mechanical stress or strain is concentrated in the acoustic wave diaphragm. One or more interdigital transducers can be configured upon the acoustic wave diaphragm, wherein the sensor substrate, the acoustic wave diaphragm and the interdigital transducer(s) form an acoustic wave flow sensor, such that when the interdigital transducer and the acoustic wave diaphragm are exposed to a fluid in flow, the fluid in flow causes the acoustic wave diaphragm to experience a change in the mechanical stress or strain resulting in a detectable frequency and/or phase change in order to provide an indication of fluid flow.

Abstract: A method and system for detecting oil quality. The quality of engine oil can be determined utilizing an acoustic wave sensor to obtain viscosity and corrosivity data associated with the engine oil. The acoustic wave sensor is coated with a material that selectively reacts to at least one type of an acid in order to provide data indicative of the presence of the acids in the engine oil. The etch rate or the corrosivity of the engine oil can be determined based on the frequency data obtained as a result of the frequency measurement utilizing the acoustic wave sensor. The viscosity of the engine oil can additionally be obtained based on a measurement of phase and amplitude obtained from the data utilizing the acoustic wave sensor. The etch rate and the viscosity measurement provide data indicative of the quality of the engine oil.

Abstract: A rotation rate sensing apparatus is configured from an acoustic wave device comprising a plurality of interdigital transducers for the SAW configuration or electrodes for vibration beams configuration. Such sensors are configured upon an elastic substrate. In the SAW configuration, the plurality of interdigital transducers includes a first interdigital transducer, a second interdigital transducer and a third interdigital transducer. A generator(s) can be formed from the first and third interdigital transducers, wherein the generator generates a standing wave subject to a Coriolis force by adding two progressive waves at each of the first and third interdigital transducers. In the vibration beams configuration, a drive beam(s) and pickup beam(s) can be implemented such that the vibration beams are excited through an RF signal and a Coriolis force excites the pickup beam(s) in order to obtain angular/rotation rate data.

Abstract: A method of testing a portable x-ray device includes sensing an environmental stimulus experienced by the portable x-ray device, transmitting a signal related to the environmental stimulus to a processing unit, determining whether the signal meets an alert threshold, activating a detector of the portable x-ray device if the signal meets the alert threshold, producing a gray image through the activating step, comparing the gray image produced through the activating step with a control gray image corresponding to a properly functioning detector.

Abstract: A multiple-mode acoustic wave sensor apparatus includes an acoustic wave device comprising a piezoelectric substrate and at least one electrode on the substrate. When such sensor is used in a wireless configuration, a plurality of antennas can be configured on the substrate in association with the acoustic wave device, wherein each antenna among the plurality of antennas is responsive to varying interrogation signals transmitted wirelessly to the plurality of antennas in order to excite multiple frequency modes via at least one interdigital transducer on the substrate and thereby passively detect multiple and varying parameters of a sensed material utilizing the acoustic wave device.

Abstract: A wireless oil filter sensing system includes an oil filter and a sensing mechanism that is connectable to the oil filter. The sensing mechanism includes one or more acoustic wave sensing elements and at least one antenna that communicate with the acoustic wave sensing element(s). An external interrogation system could excite the acoustic wave sensing element(s) wireless and passively. When the acoustic wave sensing elements are in contact with oil contained in the oil filter, the acoustic wave sensing elements detect acoustic waves associated with the oil in response to an excitation of the acoustic wave sensing elements, thereby generating data indicative of the quality of the oil for wireless transmission through the antenna(s).

Abstract: A SH-SAW based fluid flow sensor module is disclosed. The sensor module is inexpensive and disposable because it does not include any of the circuitry required for driving, powering, or reading the sensor module. The sensor module can be driven, powered, and read using either wired or wireless connections. Additionally, other sensor types, such as SAW based pressure or chemical sensors, can be integrated into the sensor module.

Abstract: A latch-up-free ESD protection circuit using SCR is disclosed, in which an SCR is connected between the input pad and the negative power supply; a turn-on switch and a turn-off switch are connected between the positive power supply VDD (or the input pad) and the SCR; and a transistor gating circuit is connected to the turn-on switch and the turn-off switch to direct the operation of the SCR. When overvoltage stress develops over the input pad in the fast-transient mode, the turn-on switch enables the NPN transistor to switch on the SCR to form a discharging path for electrostatic discharge; and when overvoltage stress is released, the turn-off switch enables the PNP transistor to switch off the SCR, thus making it immune to any latch-up after the overvoltage stress is released, and having the advantages of fast triggering, low trigger voltage, no latch-up, and full ESD protection in the active and passive modes.

Abstract: Certain embodiments of the present invention include a method, system, and apparatus for improved stabilization in solid state x-ray detectors. A method for detecting x-rays includes providing a top layer including an exterior surface and interior surface. The interior surface of the top layer is substantially electrically non-dissipative. The method also includes providing an electrical ground path and an electrically dissipative layer adjacent to the interior surface of the top layer. The electrically dissipative layer is capable of facilitating discharge of static charge from the interior surface of the top layer to the electrical ground path.

Abstract: Quartz crystal microbalance (QCM) replaces the SAW device used in the gas chromatograph (GC) systems could result in better performance. The use of multiple vibration modes, variable vibration amplitude and overtones could make the sensor detector with self-temperature compensation capability, higher sensitivity and longer sensor life due to reduced aging rate.

Abstract: In one embodiment, a method comprises storing parameters that are related to switch error correction terms of a vector network analyzer (VNA), and applying a calibration process of a TRL group of calibration processes to the VNA to generate calibration measurements, wherein the calibration process generates calibration measurements, calculates a switch error correction matrix using the stored parameters and a subset of the calibration measurements, and applies the switch error correction matrix to calibration measurements before solving for eight-systematic error terms associated with the calibration process.