According to aspects of the disclosure, a sensing system includes at least one sensor configured to provide an output signal indicative of a sensed property, an interface configured to be coupled to a computing device, and a processor coupled to the interface, the processor being configured to provide, to the computing device via the interface, a first Transducer Electronic Data Sheet (TEDS) template indicative of a first variable of the sensed property, and provide, to the computing device via the interface, a second TEDS template indicative of a second variable of the sensed property.

An error diagnosis circuit includes a signal input for connection to a communication interface, configured to receive a first instruction and a second instruction for a device. A circuit is configured to compare the first instruction and the second instruction and to output an error signal if the first instruction and the second instruction differ from one another.

An apparatus comprises a load resistance connectable in series with the electronic sensor to form a series resistance of the load resistance and the internal impedance of the electronic sensor; an excitation circuit configured to apply a predetermined voltage to a circuit element; and a measurement circuit configured to: initiate applying the predetermined voltage to the series resistance and determining the series resistance; initiate applying the predetermined voltage to the load resistance and determining the load resistance; and calculate the internal impedance of the sensor using the determined series resistance and the load resistance, and provide the calculated internal impedance to a user or process.

Methods of performing diagnostic tests on electroencephalography (EEG) recording devices comprising at least one stimulator coupled with a plurality of EEG electrode recording channels and corresponding recording channel connectors are performed by a test fixture comprising a plurality of resistors coupled with one or more of the EEG electrode recording channels and corresponding recording channel connectors. The methods include performing an impedance test for determining if each EEG recording channel of the EEG recording device has a predefined impedance, performing a channel uniqueness test for each EEG recording channel, performing a test for verifying the state of a switch of the stimulator of the EEG recording device, and performing a test for verifying connector IDs of the recording channel connectors connecting the EEG electrodes to respective EEG recording channels.

A method for detecting errors or malfunctions in electrical or electronic components of circuits, wherein each of the circuits is located on a circuit board and wherein a plurality of circuit boards border one another on a circuit board panel, includes populating each of the circuit boards of the circuit board panel with electrical or electronic components corresponding to the circuits; for each of the analog, electrical or electronic components used for the construction of the circuits, placing a corresponding test component in an edge region of the circuit board panel; providing the analog, electrical or electronic test components placed in the edge region of the circuit board panel with test points; and checking for the correct function value and/or the correct poling of the analog, electrical or electronic test components provided with test points and located in the edge region of the circuit board panel.

A control apparatus controls a relay. The control apparatus includes a control element, a monitoring circuit, and a determination unit. An input signal is input to the control element. The control element outputs an output signal and a diagnostic signal. The monitoring circuit generates an output monitor signal indicating the level of the output signal. The determination unit determines whether or not the control apparatus has an abnormality, based on a relationship between the output monitor signal and the diagnostic signal. Here, the output signal is a signal for driving the relay. One terminal of the monitoring circuit is electrically connected to an output terminal of the control element for the output signal. The diagnostic signal is a signal for monitoring the state of an output destination of the output signal.

A system may include amplifier circuitry configured to drive an electromagnetic load with a driving signal and a processing system communicatively coupled to the electromagnetic load and configured to compensate for current-sensing error of the processing system caused by feedback circuitry of the amplifier circuitry.

Accelerated testing apparatuses for implants are described, as well as methods for accelerated testing implants. The accelerated testing apparatus includes a cabinet having multiple bays and a vessel insertable and removable from any of the multiple bays. The vessel includes a watertight basin, a radio-frequency (RF) transparent lid configured to mate with the basin, and a plurality of fixtures within the vessel. Each fixture is adapted to anchor a device-under-test while submersed within the vessel. The accelerated testing apparatus also includes a reservoir disposed within the cabinet, a heater connected with the reservoir, a pump configured to circulate liquid between the reservoir and the vessel, an antenna within the cabinet for communication with the device-under-test, and at least one computer server operatively connected with the antenna.

Methods and systems automatically detect, classify and/or mitigate sensor errors using partial qualitative and quantitative knowledge of the subsystems. In various examples, sensor fault detection is performed with a custom designed representation scheme covering causality, correlation, system of equality and inequalities, and an associated logic. The logic is described by a set of algorithmic steps to iteratively assign trustworthiness level of sensors. Sensor fault classification is performed by combining mathematical and statistical techniques that can be utilized to expose bias, drift, multiplicative calibration error, precision degradation and spike error. Sensor fault mitigation is also performed on identified bias, drift, multiplicative calibration error, precision degradation and spike error.

A computer-implemented method includes, by one or more processors in electronic communication with a tunneling magnetoresistive sensor, wherein the tunneling magnetoresistive sensor is a component of a magnetic storage drive configured to read magnetic data from a magnetic storage medium, detecting a short across the tunneling magnetoresistive sensor, measuring a change in resistance of the tunneling magnetoresistive sensor, measuring a change in voltage amplitude for the tunneling magnetoresistive sensor, and dividing said change in voltage amplitude by said change in resistance to yield a ratio. The computer-implemented method further includes, responsive to the ratio being greater than a predetermined ratio threshold, determining that the short is caused by a magnetic shunt. A corresponding computer program product and computer system are also disclosed.