Abstract: A measuring cell for recording an electrical potential of an analyte situated on the measuring cell. The measuring cell has a sensor, a layer arranged above the sensor and electrically insulating the analyte from the sensor, and an amplifier circuit connected to the sensor on a substrate and having an input stage containing a field-effect transistor or a bipolar transistor, the sensor being at least indirectly connected to a control terminal of the field-effect transistor or of the bipolar transistor. An operating point of the amplifier circuit is set by means of a voltage or a current applied at the control terminal of the field-effect transistor or of the bipolar transistor of the input stage of the amplifier circuit.

Abstract: Biosensor circuit arrangement including a substrate, a sensor element formed in or on a surface region of the substrate with a physical parameter, which is coupled to a substance to be examined, the type of coupling having a resistive component, the sensor element having an electrically conductive sensor electrode that is coupled to the substance to be examined, the sensor element having a measuring transistor the gate terminal of which is coupled to the electrically conductive sensor electrode, and the physical parameter being the threshold voltage of the measuring transistor, and a calibration device formed in or on the substrate, the calibration device being set up such that it is used to at least partly compensate for an alteration of the value of the physical parameter of the sensor element.

Abstract: A sensor arrangement and method of operating the sensor arrangement are described. The sensor arrangement has sensor devices formed on or in a substrate and a calibration device for calibrating a respective sensor device. Each sensor device has an electrical signal converter which is a field-effect transistor (FET) having a gate terminal coupled to a sensor element that is coupled to the signal converter, a device that keeps constant the electrical voltage between source and drain terminals of the FET, and a device for detecting the value of the electric current flowing through the signal converter. The sensor element characteristically influences the electrical conductivity of the signal converter on account of a sensor event on the sensor element. The calibration device brings the gate region of the FET to an electrical calibration potential such that the electric current is independent of parameter fluctuations of the FET.

Abstract: The circuit configuration and the associated method allow reducing the 1/f noise of MOSFETs in an electronic circuit, especially in an integrated circuit with one or more MOSFETs. At least one direct current and/or at least one direct voltage source for adjusting constant working point(s) of the MOSFET(s) is/are assigned to one or more or all MOSFETs. At least one periodically oscillating current and/or voltage source is assigned to one or more or all MOSFETs so that the respective working points periodically oscillate about the constant working point(s) in such a manner that impurity states in the oxide of the MOSFET, which are recharged under the condition of a constant working point according to the principles of statistics such that they determine the 1/f noise signal, are no longer recharged statistically but at a lower probability due to the modulatory frequency of the periodically oscillating sources.

Abstract: A biosensor array having a substrate, a plurality of biosensor zones arranged on the substrate, each of which has a first terminal and a second terminal, at least one drive line and at least one detection line, the at least one drive line being electrically insulated from the at least one detection line. In each case the first terminal of each biosensor zone is coupled to precisely one of the at least one drive line and the second terminal of each biosensor zone is coupled to precisely one of the at least one detection line, and at least one of the at least one drive line and at least one of the at least one detection line is coupled to at least two of the biosensor zones.

Abstract: Sensor arrangement, set up as an integrated circuit, having a substrate, at least three sensor electrodes arranged on the substrate such that, in an operating state in which an electrically conductive substance is introduced into the sensor arrangement, the sensor electrodes are coupled to one another by means of the electrically conductive substance, capture molecules immobilized on at least a portion of the sensor electrodes, wherein molecules to be detected can hybridize with the capture molecules, a control circuit for applying a first electrical signal to a selected sensor electrode and simultaneously applying a second electrical signal to at least two of the other sensor electrodes, the first electrical signal being a first temporally variable electrical signal and/or the second electrical signal being a second temporally variable electrical signal, a detection device, which is set up such that, in a first operating state, in which a reference liquid is introduced into the sensor arrangement, a referenc

Abstract: Biochip for capacitive stimulation and/or detection of biological tissues. The biochip has a carrier structure, at least one stimulation and/or sensor device, which is arranged in or at the carrier structure, and at least one dielectric layer, one layer area of which is arranged at the stimulation and/or sensor device and the opposite layer area of which forms a stimulation and/or sensor area for capacitive simulation and/or detection of biological tissues, wherein the dielectric layer comprises TiO2.

Abstract: In a first phase a first sensor signal, essentially comprising the current offset signal of the sensor, is applied to the input of an electronic circuit. The first sensor signal is fed to a first signal path and stored therein. In a second phase a second sensor signal, comprising the current offset signal and a time-dependent measured signal, is applied to the input and the stored first sensor signal is fed to the input by means of the first signal path, such that essentially the time dependent measured signal is fed by means of a second signal path coupled to the input.

Abstract: The invention relates to a label identification system comprised of a transmitting-receiving unit and of identification labels on which the identification information is stored in the form of a digital identification information word. The provision of a circuit on the identification label in the form of a circuit arrangement, which is prefabricated using a polymer technique and on which the identification information is subsequently placed by the offset printing of conductor tracks, enables the provision of an identification label involving a minimal consumption of energy during inexpensive mass production. The bulk of the identification information processing is transferred to the transmitting-receiving unit.

Abstract: Apparatus for measuring neural network activity with a textured semiconductor substrate. Sensor elements have a respective detection electrode on the substrate surface for detecting neural network signals, and the detected neural signals are a basis for outputting electrical sensor output signals via respective sensor element outputs. Each amplifier element has an input and an output. Each of the sensor elements has associated therewith one of the amplifier elements whose input is connected to the sensor output of the respective sensor element. The amplified sensor output signal is output the amplifier output as an amplifier output signal. An activity evaluator has an input, which is connected to at least one of the amplifier outputs, and an output. The activity evaluation device produces an activity signal, which is a measure of activity of the neural network, based on the amplifier output signal, and outputs the amplifier output signal via the evaluation output.

Abstract: Circuit arrangement having a sensor electrode, a first circuit unit, which is electrically coupled to the sensor electrode, and a second circuit unit, which has a first capacitor. The first circuit unit holds an electrical potential of the sensor electrode in a predetermined first reference range around a predetermined electrical desired potential by coupling the first capacitor and the sensor electrode such that there is a matching of their electrical potentials. If the second circuit unit detects the electrical potential of the first capacitor being outside a second reference range, the second circuit unit brings the first capacitor to a first electrical reference potential.

Abstract: The invention relates to a test circuit configuration. Every gate terminal of a transistor to be tested is coupled to a gate voltage source in such a manner that the gate voltage can be measured and adjusted individually on every gate terminal. The source terminal of every transistor to be tested can be coupled to the source voltage source in such a manner that the source voltage can be measured and adjusted individually on every source terminal.

Abstract: A circuit configuration for assessing capacitances in a matrix, which has a number of rows with at least one capacitance in at least one dimension, includes a test arm connected to first electrodes of each of the capacitances to be assessed and by which two different potentials can be applied to the first electrodes, a measurement arm connected to second electrodes of each of the capacitances to be assessed and that has a first measurement path and a second measurement path connected to a common potential. The first measurement path has an instrument for assessing the capacitances and the first and second measurement paths can be connected to the second electrodes. The circuit configuration has a drive device that connects each of the capacitances to be assessed individually to the two different potentials.

Abstract: A sensor array is provided including transistors that are coupled together. The transistors are designed as sensors and wherein the sensor array has switching devices for selecting a transistor and wherein the selected transistor's condition may be detected. The sensor array is set up so that the selected transistor is driven as a source follower and at least some of the transistors are MOS field effect transistors that are configured so that at least some of the transistors are capable of detecting biological material.

Abstract: Sensor arrangement having row and column lines arranged in first and second directions, respectively, sensor arrays arranged in crossover regions of the row and column lines, a detector, and a decoding device. The sensor arrays have a coupling device for electrically coupling respective row and column lines, and a sensor element to influence electric current flow through the coupling device. The detector is electrically coupled to a respective end section of at least a portion of the row and column lines, and detects a respective accumulative current flow from the individual electrical current flows provided by the sensor arrays of the respective lines. The decoding device is coupled to the row and column lines, and evaluates at least a portion of the accumulative electric current flows fed to the decoding device via the row and column lines to determine at which of the sensor elements a sensor signal is present.

Abstract: Biosensor circuit arrangement including a substrate, a sensor element formed in or on a surface region of the substrate with a physical parameter, which is coupled to a substance to be examined, the type of coupling having a resistive component, the sensor element having an electrically conductive sensor electrode that is coupled to the substance to be examined, the sensor element having a measuring transistor the gate terminal of which is coupled to the electrically conductive sensor electrode, and the physical parameter being the threshold voltage of the measuring transistor, and a calibration device formed in or on the substrate, the calibration device being set up such that it is used to at least partly compensate for an alteration of the value of the physical parameter of the sensor element.

Abstract: Circuit element having a first layer composed of an electrically insulating substrate material, a first electrically conductive material which is in the form of at least one discrete area, such that it is embedded in or applied to the substrate material, a second layer having a second electrically conductive material, and a monomolecular layer, which is composed of electrically active molecules which transports charge carriers, arranged between the first layer and the second layer. The monomolecular layer is immobilized and makes electrical contact with the second layer. Each of the electrically active molecules has a first unit, which is used as an electron donor, a second unit, which is used as an electron acceptor, wherein the electron donor and the electron acceptor form a diode, and at least one redox-active unit, by means of which a variable resistance is formed, arranged between the first unit and the second unit.

Abstract: A magnetoresistive memory includes a control circuit with a first pole that, via a reading distributor, can be individually connected to first ends of bit lines by switching elements. The control circuit also has a second pole, which supplies power to an evaluator, and has a third pole that is connected to a reference voltage source. The readout circuit additionally includes a third voltage source having a voltage, which is approximately equal to the voltage of the first reading voltage source and which can be individually connected to second ends of the bit lines by means of switching elements. Finally, the readout circuit includes a fourth voltage source, which can be individually connected to second ends of the word lines by means of switching elements.

Abstract: An apparatus and method for testing a plurality of electrical components that are coupled to one another. Further, an electrical selection unit, coupled to the electrical components to be tested, is provided for selecting at least one electrical component to be tested. A parasitic voltage drop in the testing circuit can be at least partially compensated using a control element coupled to the electrical components to be tested. The invention makes it possible, for testing of electrical components on a wafer over a large distance, i.e., several millimeters, to permit automated compensation of interference influences which occur as a result of the lines coupling or connecting the components to be tested.

Abstract: Fluorescence biosensor chip having a substrate, at least one electromagnetic radiation detection device arranged in or on the substrate, an optical filter layer arranged on the substrate, and an immobilization layer, which is arranged on the optical filter layer and immobilizes capture molecules. The electromagnetic radiation detection device, the optical filter layer, and the immobilization layer are integrated in the fluorescence biosensor chip.