An analog-to-digital converter (ADC) includes an analog voltage sampler having an energy storage device, such as a capacitive element, configured to charge based on an analog input voltage. A timer determines an elapsed time for the energy storage device to discharge to a predetermined value. The ADC outputs a digital value representing the analog input voltage based on the determined elapsed time.

An A/D converter is provided with: an integrator that includes an operational amplifier provided with a first input terminal and an output terminal, and an integration capacitor; a quantizer that outputs a quantization result obtained by quantizing an output signal from the operational amplifier; and a DAC that is connected to the first input terminal and determines DAC voltage. The integrator has a feedback switch between the integration capacitor and the output terminal of the operational amplifier. An analog signal as an input signal is inputted between the integration capacitor and the feedback switch. The integration capacitor samples the analog signal. The quantizer performs the quantization based on the output of the operational amplifier. The DAC sequentially subtracts electric charge accumulated in the integration capacitor to thereby change the analog signal to a digital value.

An A/D converter is provided with: an integrator that includes an operational amplifier provided with a first input terminal and an output terminal, and an integration capacitor; a quantizer that outputs a quantization result obtained by quantizing an output signal from the operational amplifier; and a DAC that is connected to the first input terminal and determines DAC voltage. The integrator has a feedback switch between the integration capacitor and the output terminal of the operational amplifier. An analog signal as an input signal is inputted between the integration capacitor and the feedback switch. The integration capacitor samples the analog signal. The quantizer performs the quantization based on the output of the operational amplifier. The DAC sequentially subtracts electric charge accumulated in the integration capacitor to thereby change the analog signal to a digital value.

An electrical measurement device is described with an acquisition unit that is configured to receive an input signal, a post-processing unit, and a visualization unit. The acquisition unit comprises an acquisition trigger unit and an acquisition memory, the acquisition memory being configured to acquire sampled output data and to store the sampled output data by control of the acquisition trigger unit. The post-processing unit comprises a measurement unit that is configured to process at least parts of the sampled output data and to generate processed sampled output data. The post-processing unit further comprises a measurement trigger unit that is configured to evaluate the processed sampled output data in view of a measurement trigger condition, the measurement trigger unit being configured to output a measurement trigger event if the measurement trigger condition is met. The measurement trigger unit is further configured to control the visualization unit. Moreover, a method for operating an electrical measurement device is described.

According to various embodiments, a multi-slope converter can have the following: an integrator circuit having a charge store; a clocked comparator; a sensor circuit having a capacitor arrangement and a charging circuit for pre-charging the capacitor arrangement, a discharging circuit; a switch arrangement and a controller circuit for actuating the switch arrangement based on a clock signal; wherein the controller circuit is set up to actuate the switch arrangement such that, alternately: in an integration cycle electrical charge is transferred from the capacitor arrangement of the sensor circuit to the charge store of the integrator circuit, and in a deintegration cycle the charge store of the integrator circuit is discharged by means of the discharging circuit, wherein after the integration cycle a residual charge remains stored in the charge store of the integrator circuit and is taken into consideration during a subsequent integration cycle.

A self-calibrating analog-to-digital converter includes a reference signal circuit configured to provide a reference signal, an analog-to-digital converter configured to generate a first digital representation of the reference signal, a dual-slope analog-to-digital converter configured to generate a second digital representation of the reference signal, and a digital engine configured to compare the first digital representation with the second digital representation to obtain a difference and output a calibration signal to the analog-to-digital converter in response to the difference. The reference signal circuit, the analog-to-digital converter, the dual-slop analog-to-digital converter, and digital engine are integrated in an integrated circuit.

An analog-to-digital convertor of an integration type, includes: a charging circuit having a capacitor configured to store electric charges based on an input current; a discharging circuit configured to discharge the electric charges stored in the capacitor; and a counting circuit configured to count a charge-discharge count of the capacitor in a first conversion period and in a second conversion period, in order to convert a current value of the input current into a digital value, wherein the first conversion period includes a first pre-charging period and a first counting period, the second conversion period includes a second pre-charging period and a second counting period, and the analog-to-digital convertor further comprises a phase changing circuit configured to change a first phase of an output signal of the charging circuit in the first counting period to a second phase in the second counting period.

An analog-to-digital convertor of an integration type, includes: a charging circuit having a capacitor configured to store electric charges based on an input current; a discharging circuit configured to discharge the electric charges stored in the capacitor; and a counting circuit configured to count a charge-discharge count of the capacitor in a first conversion period and in a second conversion period, in order to convert a current value of the input current into a digital value, wherein the first conversion period includes a first pre-charging period and a first counting period, the second conversion period includes a second pre-charging period and a second counting period, and the analog-to-digital convertor further comprises a phase changing circuit configured to change a first phase of an output signal of the charging circuit in the first counting period to a second phase in the second counting period.

An A/D converter is provided with: an integrator that includes an operational amplifier provided with a first input terminal and an output terminal, and an integration capacitor; a quantizer that outputs a quantization result obtained by quantizing an output signal from the operational amplifier; and a DAC that is connected to the first input terminal and determines DAC voltage. The integrator has a feedback switch between the integration capacitor and the output terminal of the operational amplifier. An analog signal as an input signal is inputted between the integration capacitor and the feedback switch. The integration capacitor samples the analog signal. The quantizer performs the quantization based on the output of the operational amplifier. The DAC sequentially subtracts electric charge accumulated in the integration capacitor to thereby change the analog signal to a digital value.

An A/D converter is provided with: an integrator that includes an operational amplifier provided with a first input terminal and an output terminal, and an integration capacitor; a quantizer that outputs a quantization result obtained by quantizing an output signal from the operational amplifier; and a DAC that is connected to the first input terminal and determines DAC voltage. The integrator has a feedback switch between the integration capacitor and the output terminal of the operational amplifier. An analog signal as an input signal is inputted between the integration capacitor and the feedback switch. The integration capacitor samples the analog signal. The quantizer performs the quantization based on the output of the operational amplifier. The DAC sequentially subtracts electric charge accumulated in the integration capacitor to thereby change the analog signal to a digital value.