Amplification interface, and corresponding measurement system and method for calibrating an amplification interface

1 . An amplification interface, comprising: first and second differential input terminals, wherein the first differential input terminal is configured to receive a measurement sensor current and the second differential input terminal is configured to receive a reference sensor current; first and second differential output terminals, wherein the first differential output terminal is configured to provide a first output voltage, the second differential output terminal is configured to provide a second output voltage, and the first and second output voltages define a differential output signal; a first analog integrator coupled between the first differential input terminal and the first differential output terminal, the first analog integrator being resettable by a reset signal; a second analog integrator coupled between the second differential input terminal and the second differential output terminal, the second analog integrator being resettable by the reset signal; a control circuit configured to: generate the reset signal such that the first and second analog integrators are periodically reset during a reset interval and activated during a measurement interval; receive a control signal indicative of offsets in the measurement sensor current and the reference sensor current; and generate a drive signal as a function of the control signal; a first current generator configured to couple a first compensation current to the first differential input terminal as a function of a drive signal; and a second current generator configured to couple a second compensation current to the second differential input terminal as a function of the drive signal. 2 . The amplification interface of claim 1 : wherein the control circuit is further configured to: determine first and second durations as a function of the control signal, wherein a sum of the first and second durations corresponds to a duration of the measurement interval; and during the measurement interval, set the drive signal to a first logic value for the first duration and set the drive signal to a second logic value for the second duration; and wherein the first current generator is configured: when the drive signal has the first logic value, to generate the first compensation current as being positive and the second compensation current as being negative; and when the drive signal has the second logic value, to generate the first compensation circuit as being negative and the second compensation current as being positive. 3 . The amplification interface of claim 2 : wherein the first current generator comprises: a first current source selectively coupled to source current the first differential input terminal by a first switch controlled by the drive signal; and a second current source selectively coupled to sink current from the first differential input terminal by a second switch controlled by a complement of the drive signal; and wherein the second current generator comprises: a third current source selectively coupled to source current the second differential input terminal by a third switch controlled by the drive signal; and a fourth current source selectively coupled to sink current from the second differential input terminal by a fourth switch controlled by a complement of the drive signal. 4 . The amplification interface of claim 1 : wherein the first analog integrator comprises: a first operational amplifier having a non-inverting input coupled to a reference voltage, an inverting input coupled to the first differential input terminal, and an output coupled to the first differential output terminal; a first feedback capacitor coupled between the inverting input and the output of the first operational amplifier; and a first switch coupled between the inverting input and the output of the first operational amplifier, the first switch being controlled by the reset signal; and wherein the second analog integrator comprises: a second operational amplifier having an inverting input coupled to the reference voltage, a non-inverting input coupled to the second differential input terminal, and an output coupled to the second differential output terminal; a second feedback capacitor coupled between the non-inverting input and the output of the second operational amplifier; and a second switch coupled between the non-inverting input and the output of the second operational amplifier, the second switch being controlled by the reset signal. 5 . The amplification interface of claim 1 , wherein the control circuit comprises a counter circuit configured to generate the reset signal synchronously in response to a clock signal. 6 . The amplification interface of claim 5 , wherein the measurement interval corresponds to an even number of 2N sub-intervals, with a duration of each sub-interval corresponding to a multiple of a period of the clock signal. 7 . The amplification interface of claim 6 , wherein the control circuit is configured to determine said the first duration, T 4 , and the second duration, T 5 , as: T 4 = T 2 2 - COMP ⁢ T 2 2 ⁢ N T 5 = T 2 2 + COMP ⁢ T 2 2 ⁢ N where T 2 is the duration of the measurement interval, and COMP is an integer between −N and +N and corresponds to the control signal. 8 . The amplification interface of claim 1 , further comprising a sample-and-hold circuit controlled by a sampling control signal and configured to store the differential output signal. 9 . The amplification interface of claim 8 , wherein the sample-and-hold circuit is configured to store the differential output signal in response to the sampling control signal having a first logic value and to maintain storage of the differential output signal in response to the sampling control signal having a second logic value. 10 . The amplification interface of claim 1 , further comprising a caibration circuit comprising: a sensor connected to the first and second differential input terminals of said amplification interface; a first circuit configured to monitor, at an end of said measurement interval, the differential output signal; and a second circuit configured to vary said control signal such that said monitored differential output signal corresponds to a reference voltage. 11 . An amplification interface, comprising: first and second differential input terminals, where