Patent ID: 9634626
Date: 2017-04-25
CPC Classifications: H03F

Claim:
1. An instrumentation amplifier, comprising: a capacitive feedback closed-loop amplifier, an input capacitor charging module, a feedback capacitor discharging module, a noise separation module and a logic controller, wherein the capacitive feedback closed-loop amplifier comprises a fully differential operational amplifier, a first input capacitor arranged at a positive input terminal of the fully differential operational amplifier, a second input capacitor arranged at a negative input terminal of the fully differential operational amplifier, a first feedback capacitor connected between a negative output terminal and the positive input terminal of the fully differential operational amplifier, and a second feedback capacitor connected between a positive output terminal and the negative input terminal of the fully differential operational amplifier; the input capacitor charging module is connected to the first input capacitor and the second input capacitor to charge the first input capacitor and the second input capacitor periodically; the feedback capacitor discharging module is connected to the first feedback capacitor and the second feedback capacitor to discharge the first feedback capacitor and the second feedback capacitor periodically; the noise separation module is arranged on input and output sides of the capacitive feedback closed-loop amplifier to separate a noise from a signal using a chopping modulation technology; and the logic controller is connected to the input capacitor charging module, the feedback capacitor discharging module and the noise separation module to control the modules to operate; and wherein the input capacitor charging module comprises: a first switch connected between one plate of the first input capacitor and the first voltage source, wherein an output voltage of the first voltage source is the same as a common-mode voltage of a signal for the instrumentation amplifier; a second switch connected between the other plate of the first input capacitor and the second voltage source, wherein an output voltage of the second voltage source is the same as a common-mode input voltage of the fully differential operational amplifier; a third switch connected between one plate of the second input capacitor and the first voltage source; a fourth switch connected between the other plate of the second input capacitor and the second voltage source; a fifth switch, wherein one end of the fifth switch is connected to a connection point between the first switch and the first input capacitor, and the other end of the fifth switch is connected to a positive input terminal of the instrumentation amplifier; and a sixth switch, wherein one end of the sixth switch is connected to a connection point between the third switch and the second input capacitor, and the other end of the sixth switch is connected to a negative input terminal of the instrumentation amplifier; the feedback capacitor discharging module comprises: a seventh switch connected in parallel across the first feedback capacitor; an eighth switch connected in parallel across the second feedback capacitor; a ninth switch, wherein one end of the ninth switch is connected to a connection point between the second switch and the first input capacitor, and the other end of the ninth switch is connected to the positive input terminal of the fully differential operational amplifier; and a tenth switch, wherein one end of the tenth switch is connected to a connection point between the fourth switch and the second input capacitor, and the other end of the tenth switch is connected to the negative input terminal of the fully differential operational amplifier; the noise separation module comprises: an eleventh switch connected between the positive input terminal of the instrumentation amplifier and the fifth switch; a twelfth switch connected between the positive input terminal of the instrumentation amplifier and the sixth switch; a thirteenth switch connected between the negative input terminal of the instrumentation amplifier and the fifth switch; a fourteenth switch connected between the negative input terminal of the instrumentation amplifier and the sixth switch; a fifteenth switch connected between a negative output terminal of the instrumentation amplifier and the negative output terminal of the fully differential operational amplifier; a sixteenth switch connected between the negative output terminal of the instrumentation amplifier and the positive output terminal of the fully differential operational amplifier; a seventeenth switch connected between a positive output terminal of the instrumentation amplifier and the negative output terminal of the fully differential operational amplifier; and an eighteenth switch connected between the positive output terminal of the instrumentation amplifier and the positive output terminal of the fully differential operational amplifier; the logic controller comprises: a first clock, a second clock, a third clock and a fourth clock, wherein the first clock and the second clock are a pair of clocks which are inverted and are not overlapped; the third clock and the fourth clock are a pair of clocks which are inverted and are not overlapped; the first clock is configured to control the first switch, the second switch, the third switch, the fourth switch, the seventh switch and the eighth switch to be on or off simultaneously; the second clock is configured to control the fifth switch, the sixth switch, the ninth switch and the tenth switch to be on or off simultaneously; the third clock is configured to control the eleventh switch, the fourteenth switch, the fifteenth switch and the eighteenth switch to be on or off simultaneously; and the fourth clock is configured to control the twelfth switch, the thirteenth switch, the sixteenth switch and the seventeenth switch to be on or off simultaneously.