Techniques for corrosive substance detection for electronic devices are described herein. An aspect includes applying an electrical bias to a detector structure of a corrosive substance detector, wherein a layer of a hydrophilic gel is located over an electrode of the detector structure. Another aspect includes monitoring a resistance of the detector structure. Another aspect includes, based on determining that the resistance of the detector structure has dropped below a minimum resistance, indicating exposure to a corrosive substance by the corrosive substance detector.

The invention describes an electrical component (10) which at least comprises a section (12) configured as a sensor (sensor section) made of concrete and which contains electrically conductive aggregates (22) which are present in a region (24) near the surface of at least one outer surface (20) of the section (12) in a higher spatial density than in the remaining section (12). In addition, a method for its production and a use of the component (10) are described.

Tamper-respondent assemblies and methods of fabrication are provided which include at least one tamper-respondent sensor and a detector. The at least one tamper-respondent sensor includes conductive lines which form, at least in part, at least one tamper-detect network of the tamper-respondent sensor(s). The detector monitors the tamper-respondent sensor(s) by applying an electrical signal to the conductive lines of the at least one tamper-respondent sensor to monitor for a non-linear conductivity change indicative of a tamper event at the tamper-respondent sensor(s). For instance, the detector may monitor a second harmonic of the electrical signal applied to the conductive lines for the non-linear conductivity change indicative of the tamper event, such as an attempted shunt of one or more conductive lines of the tamper-respondent sensor(s).

A housing cladding module for a medical device is provided for collision identification. The module includes resistor elements, which are arranged in and/or on the surface and which are designed such that the resistor elements change their electrical resistance on expansion. The resistor elements are arranged in such a way that the resistor elements are expanded in the event of a collision with an object. The collision is identified easily, and the effective collision force may be ascertained.

A gas sensor package is configured such that an output change part is provided in the gas sensor package including a gas sensor so that a resistance output mode can be changed to a voltage output mode, thereby enabling the gas sensor to have a regular initial voltage value by compensating a resistance change value to an initial gas sensing material. According to embodiments of the present application, a gas sensor package is configured such that a gas moving separation part is formed between a gas sensing element and a substrate with regard to a structure in which a gas sensing element is mounted to the substrate in a flip chip bonding method so that gas can be smoothly moved and thus gas sensing efficiency can be maximized.

The disclosed technology generally relates to integrated circuit devices with wear out monitoring capability. An integrated circuit device includes a wear-out monitor device configured to record an indication of wear-out of a core circuit separated from the wear-out monitor device, wherein the indication is associated with localized diffusion of a diffusant within the wear-out monitor device in response to a wear-out stress that causes the wear-out of the core circuit.

A method for determination of the growth rate of biofilm (7) using an electrical impedance analyses is disclosed. The method comprises the steps of: bringing a culture medium fluid (3) in contact to an electrode structure (4a, 4b), having biofilm (7) grown within the fluid culture medium (3) with the biofilm (7) arranged in distance to the electrodes structure (4a, 4b), so that the fluid culture medium (3) is placed between the growing biofilm (7) and the electrode structure (4a, 4b); measuring the impedance of the electrodes structure (4a, 4b) over a monitoring time, and determining the growth rate of the biofilm (7) as a function of the reduction rate of the impedance values measured on the electrode structure (4a, 4b).

A full petrophysical rock characterization of a rock sample in a single workflow uses a separator containing two immiscible fluids. The fluids form a fluid interface. A video camera monitors the height of the fluid interface. Current electrodes and potential electrodes are electrically connected to the rock sample. An impedance meter makes measurements across the current electrodes and the potential electrodes. A tubing is attached to one end of the rock sample and to one end of the separator and transports one of the immiscible fluids therebetween. Another tubing is attached to the other end of the rock sample and to the separator and transports the other immiscible fluid therebetween. Yet another tubing transports an immiscible mixture of the immiscible fluids from the rock sample to the separator. Pressure gauges measures the pressures in the tubings. Pumps are disposed inline with the certain tubings.

Device and method for checking fuel rods with IFBA, their zirconium diboride coating. The device includes a variable magnetic field generator and a magnetic field pickup device, arranged in the vicinity of the rod, as well as a control system for comparing both fields in order to measure the electric conductivity of the rod. The method includes the steps of: arranging the rod to be measured between the generator and the pickup device; generation of a variable magnetic field in the generator; picking-up of the magnetic field; comparison between the generated magnetic field and the picked-up one in order to quantify the electric conductivity of the rod; if the electric conductivity differs from a reference value, consider the rod for checking or recycling.

Sensor stations and related systems and methods to monitor and measure properties of food products in food processing structures such as cure rooms, smokehouses, ovens, and related structures. The sensor stations allow real-time, local collection of product properties and their surrounding environmental conditions in order to improve efficiency, reduce product waste and guesswork, and to provide data-based analysis for decision making. Sensor stations can be mounted to food supports and can be in electronic communication with each other and with intermediate nodes that provide a connection to other external computing devices that provide analysis and alerts to users and technicians. Various non-destructive modeling systems for determining water activity and pH of changing products are also provided.