The present application belongs to the technical field of monitoring of durability of concrete, and particularly relates to a method for optimizing a structure of an electrical capacitance tomography sensor and analyzing an electromagnetic field. A specific process of the method includes eight steps: parameter setting, geometric setting, material setting, mesh generation, physical field setting, solution, sensor structure optimization and calculation of electromagnetic field distribution. The method proposes a new concept for solving a forward problem of an ECT system based on COMSOL software. After modeling is completed, uniformity of a sensitive field of the ECT sensor is analyzed according to calculation results, and structural parameter values of components of the ECT sensor are adjusted to seek an optimal design scheme.

An inductive-capacitive resonant sensor architecture includes an inductively-coupled extender (ICE) that can both increase read range and lessen the effects of reader/sensor misalignment. The ICE can include a first coil configured with respect to a resonant sensor and a second coil separated from the first coil and coupled to the first coil by electrical wires. An external reader can be arranged with respect to the second coil. This architecture can nearly eliminate misalignment issues between the external reader and the resonant sensor. The ICE can be implemented with a closed circuit design. Additional apparatus, systems, and methods are disclosed.

Described examples include a sensor device having at least one conductive elongated first pillar positioned on a central pad of a first conductor layer over a semiconductor substrate, the first pillar extending in a first direction normal to a plane of a surface of the first conductor layer. Conductive elongated second pillars are positioned in normal orientation on a second conductor layer over the semiconductor substrate, the conductive elongated second pillars at locations coincident to via openings in the first conductor layer. The second conductor layer is parallel to and spaced from the first conductor layer by at least an insulator layer, the conductive elongated second pillars extending in the first direction through a respective one of the via openings. The at least one conductive elongated first pillar is spaced from surrounding conductive elongated second pillars by gaps.

A batteryless, chipless, sensor is disclosed which includes a substrate, at least two conductive strips disposed on the substrate, a passivation layer encasing the substrate and the at least two conductive strips, wherein the conductive strips are adapted to respond to an interrogation signal from a reader having a first polarization, with a response signal at a second polarization different than the first polarization.

Disclosed are a soil monitoring sensor and a method of operating the same. The soil monitoring sensor includes a first probe formed to extend in a first direction, and including a first electrode and a second electrode; a first resonance circuit connected to the first electrode and the second electrode of the first probe, and configured such that a first AC signal is applied thereto; a second resonance circuit having the same impedance as the first resonance circuit, and configured such that a second AC signal is applied thereto; and a determination circuit configured to receive a first electrical signal formed in the first resonance circuit, to receive a second electrical signal formed in the second resonance circuit, and to generate a first determination value for the state of the soil based on the first resonant frequency and the second resonant frequency.

In one or more embodiments, one or more systems, one or more methods, and/or one or more processes may measure at least one of a first height value and a first width value of a first eye diagram of a first signal; measure at least one of a second height value and a second width value of a second eye diagram of a second signal; determine at least one of a height difference value and a width difference value respectively between the at least one of the first height value and the first width value of the first eye diagram and the at least one of the second height value and the second width value of the second eye diagram; and determine that the at least one of the height difference value and the width difference value respectively meets or exceeds a height threshold value or a width threshold value.

A probe for penetrating and measuring electrical properties of a soil comprises a probe tip connected, via a coaxial cable, to electrical circuitry. The probe tip is convex and includes first and second electrodes with an electrode insulator therebetween. The first electrode is tubular and includes an interior surface defining a central opening extending through the first electrode. The second electrode includes a convex section extending away from the first electrode, and the convex section is configured for insertion into soil. The one end of the coaxial cable is disposed within the central opening of the first electrode, and the inner conductive core of one end of the coaxial cable connected to the second electrode, and the conductive shield of the one end of the coaxial cable connected to the first electrode.

A sensor system for collecting data regarding sub-surface material characteristics may include a multitude of sensor nodes, a data gateway, and a controller. Each sensor node may include a power supply and a communication device and the multitude of sensor nodes may include sensors distributed between underground sensor nodes and/or partially-exposed sensor nodes to collect data regarding sub-surface material characteristics. The data gateway may be coupled with any combination of the sensor nodes through wireless transmission data pathways and may receive and store at least some of the data collected by the one or more sensors. The controller may receive the data generated by the one or more sensors from the data gateway and display at least a portion of the data.

A system and related methods include a durable component, an indicator component including an indicator zone comprising at least one colorimetric analyte sensing element, at least one moisture sensor, and a fluid collection reservoir. The durable component contains at least one spectrophotometer, a computing system, and means for electronic communication between the computing system and at least one external device. The indicator component includes at least one colorimetric analyte sensing element and a fluid transport layer in fluid communication with the indicator zone, and it is arranged and configured for attachment to the durable component. In addition, the moisture sensor is arranged and configured to communicate the presence of moisture to initiate a predetermined delay in measuring the concentration of at least one analyte. The fluid collection reservoir is releasable from at least one of the indicator components and the durable component at a predetermined breaking point for clinical analysis.

Systems and methods are provided for detecting water within an electronic power steering assembly. A sensor assembly includes a resistor and a water-sensitive capacitor arranged to provide a series resistor-capacitor (RC) network having a cut-off frequency that is a function of a capacitance of the water-sensitive capacitor. An oscillator provides an excitation to the series RC network having a known frequency, such that the series RC network provides an output in response to the excitation. An envelope detector receives the output of the series RC network and generates an output representing an amplitude of the output of the series RC network. A microcontroller determines if water is present within the electronic power steering assembly from the amplitude of the output of the series RC network.