A method for detecting a degree of hydrogenation of a liquid comprises one or more liquid hydrogen carriers, which can be hydrogenated, comprising: detecting a material property of the liquid and determining the degree of hydrogenation of the liquid on the basis of the detected material property of the liquid.

Apparatus and associated methods relate to determining liquid-water concentration in a cloud atmosphere based on a frequency of resonance of a magnetostrictive resonator and/or a temporal variation of the resonant frequency of the magnetostrictive resonator. The magnetostrictive resonator is configured to resonate at a resonant frequency indicative of a measure of ice accumulation upon an exterior surface of the magnetostrictive resonator. When in liquid-water ambient, however, the magnetostrictive resonator has a resonant frequency less than a baseline resonant frequency. When in the liquid-water ambient, the magnetostrictive resonator also has temporal variations in resonant frequency that exceed one part in ten thousand. Using one or both of these resonant-frequency responses to liquid-water ambient, a signal indicative of liquid-water content can be generated.

Methods and systems are provided for conducting measurements of relative humidity using an ultrasonic sensor. In one example, a plurality of ultrasonic signals having different frequencies are transmitted from a single sensor, and attenuation values of reflected signals are determined only for those signals determined to have the same transit time from transmission to receipt, and where frequency of the plurality of ultrasonic signals may be changed responsive to an indication that the signals may be below a signal-to-noise threshold. In this way, by determining a difference between attenuation values between pairs of signals, where the signals comprise different frequencies and where the signals comprise the same transit times, relative humidity may be accurately determined.

Methods and systems are provided for conducting measurements of relative humidity via the use of either an ultrasonic sensor positioned on the vehicle, or via another sensor. In one example, responsive to a request for a relative humidity measurement and an indication of fueled engine operation, the ultrasonic sensor may be utilized, whereas responsive to an indication of non-fueled engine operation, another sensor may be utilized. In this way, robust measurement of relative humidity with desired accuracy may be actively determined, rather than opportunistically, and such measurements of relative humidity may be utilized to adjust vehicle operating parameters, which may improve overall vehicle operation.

A method includes acoustically exciting a rotating component over a range of frequencies. The method further includes measuring the resulting frequency response of the rotating component in response to the acoustic excitation. The method also includes processing the frequency response to determine whether a frequency response has shifted in comparison a prior frequency response. The method includes determining an amount of wear and tear of the rotating component based on the determined shift in the frequency response.

A system includes an acoustic transmitter, an acoustic receiver, a memory component, and a processor. The acoustic transmitter transmits an acoustic signal into a material with an unknown moisture level and changes into an acoustic response signal after passing through the material. The acoustic receiver receives the acoustic response signal associated with the material with the unknown moisture level. The memory component stores data comprising moisture levels associated with acoustic speeds of acoustic response signals. The processor is coupled to the acoustic receiver and to the memory and determines a speed of the acoustic response signal associated with the material with the unknown moisture level, and further determines an actual moisture level of the unknown moisture level of the material by associating the speed of the acoustic response signal associated with the material with the unknown moisture level to the data in the memory component.

Among other things, a heating jacket configured for heating a mechanical testing instrument having a probe is disclosed herein. The heating jacket includes a heating element including a jacket wall, and the jacket wall extends around a probe recess, the jacket wall is configured to receive a probe of a mechanical testing instrument within the probe recess, and the heating element is mechanically isolated from the probe with a probe gap. Additionally, a system to correct for thermomechanical drift in a mechanical testing assembly is disclosed herein. The system isolates the mechanical testing instrument from thermomechanical drift of a system frame using a determined difference between, for instance, a probe displacement and a sample displacement.

Methods and systems are provided for conducting measurements of relative humidity via the use of an ultrasonic sensor. In one example, the ultrasonic sensor for conducting the relative humidity measurement is selected from a plurality of ultrasonic sensors positioned at various locations on the vehicle, and where the selecting is accomplished in some examples via the use of one or more onboard cameras configured to identify suitable objects that are stationary with respect to the vehicle. In this way, robustness and accuracy of relative humidity measurements may be improved, lifetime of individual ultrasonic sensors may be extended, and vehicle operating conditions that depend on accurate relative humidity measurements may be improved.

Technologies are generally described for measuring hair moisture using a hair moisture measuring device including a vibrator, a sound wave detector, a heater, and/or a processor. The vibrator may generate and propagate first sound waves through a strand of hair, which may be detected by the sound wave detector. The processor may then measure a first time-delay between the first sound waves and the first driving signals. After heating the hair by the heater, the vibrator may generate and propagate second sound waves through the strand of hair, which may be detected by the sound wave detector. The processor may measure a second time-delay between the second sound waves and the second driving signals, and also measure an amount of the moisture by calculating a time-delay difference between the first time-delay and the second time-delay.

In a method for detecting moisture on a road surface used by a vehicle, wherein at least one acoustic signal resulting from the moisture on the road surface is captured by at least one sensor device arranged on said vehicle, and wherein the captured acoustic signal is analysed via at least one analyser associated with said vehicle, it is provided according to the invention that at least one energy value of at least one signal portion of the captured acoustic signal is calculated for the analysis, that the effective value of the at least one signal portion is calculated, that a shape factor of the at least one signal portion is calculated from the quotient of the effective value and the energy value, that the minimum of the energy value in the at least one signal portion is calculated, that the maximum of the shape factor in the at least one signal portion is determined, that a quotient of the minimum of the energy value and the maximum of the shape factor is created and that said quotient is associated with a degree of wetness of the road surface.