A particle occurrence sensing circuit for microfluidic particle sensing includes a set of particle event indicators, each of which includes: a Coulter counter having a sensing electrode exposable to a fluid within a microfluidic channel and configured for providing a particle sensing signal; an input stage configured for providing an extracted particle sensing signal; and a particle event detector configured for providing a set of particle event occurrence signals. Each of the set of particle event occurrence signals indicates a sensed occurrence of a particle greater than or equal to a given reference particle size during fluid flow through the microfluidic channel to which the sensing electrode is exposed. The particle event detector includes a successive approximation (SA) analog-to-digital converter (ADC) configured for generating a plurality of reference particle size threshold values and successively comparing the extracted particle sensing signal amplitude with reference particle size threshold values.

An electric wave type biosensor includes: an electromagnetic wave irradiation unit; and a reflected wave receiving unit which receives a reflected wave and obtains an I signal obtained by multiplying the irradiated electromagnetic wave signal and the received reflected signal, and a Q signal obtained by delaying the I signal only by a predetermined phase. The electric wave type biosensor further includes: a differentiation calculation unit which differentiates the I signal and the Q signal and calculates an I signal differential value and a Q signal differential value; and an angular velocity calculation unit which calculates an angular velocity of the I signal and the Q signal, based on the I signal and the Q signal and the I signal differential value and the Q signal differential value.

Biosensor systems including a measurement device and test sensors including at least three independently addressable electrodes, with at least two of the electrodes being substantially chemically isolated are disclosed. One or more working electrodes may be combined with two or more counter electrodes. The two or more counter electrodes may operate at different potentials to provide for multi-analyte electrochemical analysis. Analysis methods are provided to perform multi-analyte electrochemical analysis and test sensors are provided having resistance to chemical mixing between secondary analysis regions.

The present disclosure provides a method for analyzing a microRNA using a tunneling current. The present disclosure provides a method for identifying the base sequence and/or modification state of a microRNA using a tunneling current, and a system and a program to be used in the method. Furthermore, the present disclosure provides a method for analyzing the conditions of a subject, said method comprising determining the base sequence and/or modification state of a microRNA using a tunneling current. For example, methylation modification can be analyzed thereby.

A sensor element for detecting a physical property of a gas includes: a solid electrolyte film; a first end area and a second end area situated diametrically opposite in the longitudinal direction; a functional element in the first end area in the interior which is electrically conductively connected to a contact surface situated in the second end area on the outer surface, the electrically conductive connection having a strip conductor running essentially in the longitudinal direction in the interior of the sensor element; and a reference gas channel running essentially in the longitudinal direction of the sensor element communicating with a reference gas outside of the sensor element via a reference gas opening, the strip conductor and the reference gas channel being situated in such a way that at least a partial overlap occurs between them.

A method for operating an ignition device for an internal combustion engine, in which via a rotating magnetic pole wheel a voltage signal with a number of positive and negative half-waves is produced in at least one coil arrangement that is located on a core leg of an iron core during each rotation of the magnetic pole wheel, wherein the voltage signal is used to determine the gap width of the air gap between the magnetic pole wheel and the core leg.

A method for operating an ignition device for an internal combustion engine, in which via a rotating magnetic pole wheel a voltage signal with a number of positive and negative half-waves is produced in at least one coil arrangement that is located on a core leg of an iron core during each rotation of the magnetic pole wheel, wherein the voltage signal is used to determine the gap width of the air gap between the magnetic pole wheel and the core leg.

Disclosed is a system for interacting with polyisoprene based products to enhance sensing features. The system includes a hub unit and one or more electronic circuitries operably configured with the polyisoprene based product. The hub unit includes a controller for contactless powering and communicating data with the polyisoprene based product, a generator for generating a frequency, a resonator for increasing voltage level of the frequency, a first electrode for emitting the alternating electric field, a second electrode for receiving the alternating electric field from the polyisoprene based product, an analog digital converter connected to the second electrode to digitize information received from the polyisoprene based product under the influence of the alternating electric field. The one or more electronic circuitries senses the condition of the polyisoprene based product and communicates further to the hub unit for processing and communicating processed information over a communication network.

Disclosed is a system for interacting with polyisoprene based products to enhance sensing features. The system includes a hub unit and one or more electronic circuitries operably configured with the polyisoprene based product. The hub unit includes a controller for contactless powering and communicating data with the polyisoprene based product, a generator for generating a frequency, a resonator for increasing voltage level of the frequency, a first electrode for emitting the alternating electric field, a second electrode for receiving the alternating electric field from the polyisoprene based product, an analog digital converter connected to the second electrode to digitize information received from the polyisoprene based product under the influence of the alternating electric field. The one or more electronic circuitries senses the condition of the polyisoprene based product and communicates further to the hub unit for processing and communicating processed information over a communication network.

A semiconductor sensor includes an insulating substrate, a semiconductor sheet on the insulating substrate and including graphene or carbon nanotubes, a source electrode and a drain electrode, each being provided on the insulating substrate and electrically coupled to the semiconductor sheet, an oxide film extending over a surface of the semiconductor sheet and including silica, alumina, or a composite oxide of silica and alumina, and a receptor at a surface of the oxide film.