Methods and devices related to current sensing are provided. Magnetoresistive sensor elements are provided on opposite sides of a conductor.

Suppress a measurement error due to a change in an ambient temperature, in a strain gage for a multi-axis force sensor. The base member 121 has a sensitive area 121s configured to be attached to a flexure area of a flexure member and a non-sensitive area 121n1, 121n2 configured to be arranged outside of the flexure area, the flexure area being configured to be strained under a load; a first Wheatstone bridge circuit BC11 configured to detect a load applied to the flexure member in a first direction is constructed by a first-direction strain sensitive element X11, X12 and a first-direction fixed resistance element RX11, RX12; a second Wheatstone bridge circuit BC12 configured to detect a load applied to the flexure member in a second direction orthogonal to the first direction is constructed by a second-direction strain sensitive element Y11, Y12 and a second-direction fixed resistance element RY11, RY12; the first-direction strain sensitive element and the second-direction strain sensitive element are formed in the sensitive area and the first-direction fixed resistance element or the second-direction fixed resistance element is formed in the non-sensitive area and is formed of a material same as a material of the strain sensitive element.

Embodiments described herein are directed to a system having a processor and a bridge circuit. The bridge circuit includes a pair of differential voltage sources, a first pair of sensing elements and a second pair of sensing elements. The first pair of sensing elements generate a pair of measurement signals. The pair of measurement signals are independent of one another and based on the respective sensing element. The second pair of sensing elements communicatively coupled to first pair of sensing elements. The second pair of sensing elements define a first divider. The pair of measurement signals are input into the respective second sensing element of the second pair of sensing elements. The first divider is configured to output a first output signal to the processor. The first output signal is a first differential signal of the first pair of sensing elements.

An electric current sensor includes a substrate, a first sloped surface, a second sloped surface, at least one conductive wire, a first anisotropic magnetoresistor (AMR) unit, a second AMR unit, a first magnetization direction setting device, and a second magnetization direction setting device. The first sloped surface and the second sloped surface are disposed on the substrate and arranged in a first direction. The at least one conductive wire extends along a second direction and is disposed beside the substrate. The first AMR unit is disposed on the first sloped surface. The second AMR unit is disposed on the second sloped surface. The first magnetization direction setting device and the second magnetization direction setting device are configured to set magnetization directions of the AMR units.

An electric current sensor includes a substrate, a conductive wire, a first anisotropic magnetoresistor (AMR) unit, a second AMR unit, a third AMR unit, a fourth AMR unit, a first magnetization direction setting device, and a second magnetization direction setting device. The conductive wire has a first conductive segment and a second conductive segment respectively disposed below a first end and a second end opposite to the first end of the substrate. The first AMR unit and the second AMR unit are disposed above the first end of the substrate. The third AMR unit and the fourth AMR unit are disposed above the second end of the substrate. The first magnetization direction setting device and the second magnetization direction setting device are configured to set magnetization directions of the AMR units.

Apparatus, systems, and methods for progressive corrosion detection are disclosed. An example apparatus includes a query generator to query a multiplexer channel to receive an output voltage, the multiplexer channel linked to a fin group of an electrode array, the fin group forming an open circuit in the absence of conductive crystal formation, a quantifier to determine, using a reference voltage, a difference between the reference voltage and the output voltage from the queried multiplexer channel, and a contamination level comparator to identify presence of conductive crystal formation based on the difference between the reference voltage and the output voltage.

The present invention relates to a half-bridge signal processing circuit comprising a first and a second branch. The first branch comprises a first stimulus responsive sense element and a first current source arranged to provide a current to the first sense element. The second branch comprises a second stimulus responsive sense element and a second current source arranged to provide a current to said second sense element. The first and the second branch have a terminal in common. The first branch comprises a first node between said the current source and the first stimulus responsive sense element configured to generate a first signal related to a voltage over the first sense element. The second branch comprises a second node between the second current source and the second stimulus responsive sense element configured to generate a second signal related to a voltage over the second sense element.

A pressure sensing apparatus comprising a pressure sensor configured to sense a pressure and a controller. The controller is configured to supply a reverse bias voltage to the pressure sensor or to not supply a bias voltage to the pressure sensor in a time duration in which pressure sensing of the pressure sensor is not performed.

Methods, apparatuses and systems for providing offset calibration and fault monitoring are disclosed herein. An example controller component may comprise: a resistance-based bridge circuit; a signal conditioning circuit configured to condition an output of the resistance-based bridge circuit; a first diagnostic circuit coupled to the signal conditioning circuit configured to monitor an output of a first branch of the resistance-based bridge circuit; and a second diagnostic circuit coupled to the signal conditioning circuit configured to monitor an output of a second branch of the resistance-based bridge circuit.

A Gas Chromatograph (GC) detector comprises a first circuit, a second circuit, a digital subtractor and a digital logic shared between one to many detector channels to provide a GC measurement in a digital form. The first circuit includes a first counter circuitry to provide a first counter output. The second circuit includes a second counter circuitry to provide a second counter output. The GC detector includes a digital subtractor to subtract the first counter output from the second counter output and provide a digital subtractor output. The GC detector further includes a digital logic shared between one to many detector channels to implement at least a portion of the first counter circuitry and the second counter circuitry. The digital logic to receive the digital subtractor output and provides the GC measurement in the digital form. The GC detector may be based on a Thermal Conductivity Detector (TCD) in which an integrator of a Sigma-Delta (-) A/D converter is eliminated and the/factor of the Sigma-Delta (-) A/D converter is accomplished in a digital form.