A capacitance to digital converter, CDC, has a first and a second reference terminal for receiving first and second reference voltages, a reference block comprising one or more reference charge stores and being coupled to the first and second reference terminals via a first switching block, a scaling block for providing at third and fourth reference terminals downscaled voltages from the first and second reference voltages depending on a scaling factor, first and second measurement terminals for connecting a capacitive sensor element, the first measurement terminal being coupled to the third and fourth reference terminals via a second switching block, and a processing block coupled to the reference block and to the second measurement terminal and being configured to determine a digital output signal based on a charge distribution between the sensor element and the reference block and based on the scaling factor, the output signal representing a capacitance value of the sensor element.

The invention relates to a method for the contactless tapping of communication signals that are exchanged between two communication units, in particular a sensor or actuator and a digital evaluating or control unit, wherein the communication signals are transmitted on a line (2) of a multi-core cable (1) as voltage signals. According to the invention, in order that the communication signals can be tapped also in the case of multi-core cables without the line having to be interrupted for this purpose, the communication signals are tapped capacitively, wherein at least two electrodes (10a, 10b), which lie on the cable sheath and the angular position of which in relation to the cable axis is variable, are used for the tapping and the angular position at which the differential signal between the two electrodes (10a, 10b) is maximized is determined, wherein the at least two electrodes (10a, 10b), each consisting of a plurality of individual electrodes (E1-E8), are designed as collection electrodes and the various angular positions of the collection electrodes (10a, 10b) are achieved in that the association of the individual electrodes (E1-E8) with the at least two collection electrodes (10a, 10b) is sequentially changed by means of a controller (26). The invention further relates to an assembly for performing said method.

The invention relates to a method for the contactless tapping of communication signals that are exchanged between two communication units, in particular a sensor or actuator and a digital evaluating or control unit, wherein the communication signals are transmitted on a line (2) of a multi-core cable (1) as voltage signals. According to the invention, in order that the communication signals can be tapped also in the case of multi-core cables without the line having to be interrupted for this purpose, the communication signals are tapped capacitively, wherein at least two electrodes (10a, 10b), which lie on the cable sheath and the angular position of which in relation to the cable axis is variable, are used for the tapping and the angular position at which the differential signal between the two electrodes (10a, 10b) is maximized is determined, wherein the at least two electrodes (10a, 10b), each consisting of a plurality of individual electrodes (E1-E8), are designed as collection electrodes and the various angular positions of the collection electrodes (10a, 10b) are achieved in that the association of the individual electrodes (E1-E8) with the at least two collection electrodes (10a, 10b) is sequentially changed by means of a controller (26). The invention further relates to an assembly for performing said method.

A sensor has a strip resonator filter that energizes an emitter patch which emits an electric field out from the strip resonator filter (away from the strip resonator filter). The capacitance of the filter, or specifically the coupling capacitance and radiation pattern of the slotted patch, is altered when an object such as a finger is near the sensor. Resulting changes in a signal outputted by the filter can be used to determine how close the object is to the sensor. The strip resonator filter may be a half wavelength strip resonator coupled filter having three separate strips. The patch may have a slot and two accompanying strips. An arrangement of multiple sensors may detect the position of an object in two or three dimensions.

A probe assembly for capacitive testing electrical connections of a low profile component to a circuit assembly. The probe assembly is configured to reduce coupling of noise signals from the circuit assembly to the capacitive probe. The probe assembly includes a sensing member with a geometry that allows the probe to preferentially couple to test signals from the pins of a component under test rather than conductive structures on the circuit assembly, such as pads, and signal traces to which those pins are attached. The sensing member may be a vertical capacitive sense plate such that coupling is to an edge of the plate. The sensing member alternatively may be a horizontal capacitive sense plate with an active area of the probe surrounded by an isolation ring. Measurements made with such capacitive probes may provide test measurements that yield a reliable discrimination between a properly attached pin and an open pin.

A probe assembly for capacitive testing electrical connections of a low profile component to a circuit assembly. The probe assembly is configured to reduce coupling of noise signals from the circuit assembly to the capacitive probe. The probe assembly includes a sensing member with a geometry that allows the probe to preferentially couple to test signals from the pins of a component under test rather than conductive structures on the circuit assembly, such as pads, and signal traces to which those pins are attached. The sensing member may be a vertical capacitive sense plate such that coupling is to an edge of the plate. The sensing member alternatively may be a horizontal capacitive sense plate with an active area of the probe surrounded by an isolation ring. Measurements made with such capacitive probes may provide test measurements that yield a reliable discrimination between a properly attached pin and an open pin.

A capacitance to digital converter, CDC, has a first and a second reference terminal for receiving first and second reference voltages, a reference block comprising one or more reference charge stores and being coupled to the first and second reference terminals via a first switching block, a scaling block for providing at third and fourth reference terminals downscaled voltages from the first and second reference voltages depending on a scaling factor, first and second measurement terminals for connecting a capacitive sensor element, the first measurement terminal being coupled to the third and fourth reference terminals via a second switching block, and a processing block coupled to the reference block and to the second measurement terminal and being configured to determine a digital output signal based on a charge distribution between the sensor element and the reference block and based on the scaling factor, the output signal representing a capacitance value of the sensor element.

A test system for measuring electrical current consumption of a device under test (DUT) includes a capacitor with power and ground terminals; a voltage regulator with input and output terminals; first and second switching elements; and a controller. The voltage regulator generates a DUT operating voltage based on its input voltage. The first switching element is arranged between a direct current (DC) voltage source and the regulator input, and the second switching element is arranged between the DC voltage source and the capacitor. The controller operates the switching elements to charge the capacitor, and to configure the test system for measuring operating current of the DUT using the capacitor as the power source.

A test system for measuring electrical current consumption of a device under test (DUT) includes a capacitor with power and ground terminals; a voltage regulator with input and output terminals; first and second switching elements; and a controller. The voltage regulator generates a DUT operating voltage based on its input voltage. The first switching element is arranged between a direct current (DC) voltage source and the regulator input, and the second switching element is arranged between the DC voltage source and the capacitor. The controller operates the switching elements to charge the capacitor, and to configure the test system for measuring operating current of the DUT using the capacitor as the power source.

During frequency detection, a constant current source outputs an output current to charge a variable capacitor for multi-period. In a calibration mode, according to a comparison result between a cross voltage of the variable capacitor and a reference voltage, a capacitance value of the variable capacitor is adjusted. In a monitor mode, according to a reference frequency and the cross voltage of the variable capacitor, a frequency under test of a circuit under test is detected.