Precision low noise continuous time sigma delta converter

What is claimed is: 1. A sigma delta analog-to-digital converter (ADC) comprising: a capacitive gain amplifier circuit having a first input to receive an input signal and a second input, wherein the capacitive gain amplifier circuit is configured to amplify the input signal; a first signal chopper circuit arranged at the first and second inputs of the capacitive gain amplifier circuit, and a second signal chopper circuit included in the loop filter circuit, wherein the loop filter circuit includes a resistor arranged between the first signal chopper circuit and the second signal chopper circuit: a sub-ADC circuit including an output and an input connected to an output of the loop filter circuit and configured to sample the amplified and filtered input signal and convert the amplified filtered input signal to a digital output; and a digital-to-analog (DAC) circuit including a DAC input connected to the output of the sub-ADC circuit, and a DAC output connected to the second input of the capacitive gain amplifier, wherein the capacitive gain amplifier circuit is configured to divide down a signal received at the second input by a gain of the capacitive gain amplifier circuit. 2. The sigma delta ADC of claim 1 , wherein the loop filter circuit is a continuous time filter circuit. 3. The sigma delta ADC of claim 1 , wherein the loop filter circuit includes a switching circuit, wherein the switching circuit and the DAC circuit are controllable by a switch clock signal, wherein the loop filter circuit is enabled to integrate an electrical signal received from the capacitive gain amplifier circuit during a first voltage level of the switch clock and the DAC circuit is enabled to convert the output of the sub-ADC circuit during a second voltage level of the switch clock signal. 4. The sigma delta ADC of claim 3 , wherein the loop filter circuit includes a first integrator stage, a second integrator stage, and a summing node connected to outputs of the first and second integrator stages, wherein the input of the sub-ADC circuit is connected to the summing node. 5. The sigma delta ADC of claim 1 , including a first signal chopper circuit arranged at the first and second inputs to the capacitive gain amplifier circuit, and a second signal chopper circuit included in the loop filter circuit, wherein the first and second signal chopper circuits are controlled by a chop clock signal, wherein the loop filter circuit includes a switching circuit controllable by a switch clock signal and the loop filter circuit is enabled to integrate an electrical signal received from the capacitive gain amplifier circuit according to the switch clock signal, and the DAC circuit is enabled to convert the output of the sub-ADC circuit according to the chop clock signal. 6. The sigma delta ADC of claim 5 , wherein a clock period of the chop clock signal is a multiple of a clock period of the switch clock signal. 7. The sigma delta ADC of claim 1 , including a first signal chopper circuit arranged at the first input to the capacitive gain stage, and a second signal chopper circuit arranged at the output of the sub-ADC circuit, wherein the first and second signal chopper circuits are controlled by a chop clock signal, wherein the loop filter circuit includes a switching circuit controlled by a switch clock signal and the loop filter circuit is enabled to integrate an electrical signal received from the capacitive gain amplifier using a specified phase of the switch clock signal, and the DAC circuit is enabled to convert the output of the sub-ADC circuit using a specified phase of the chop clock signal. 8. The sigma delta ADC of claim 1 , wherein the sub-ADC circuit includes a latched comparator circuit. 9. The sigma delta ADC of claim 1 , wherein the sub-ADC circuit includes a Flash ADC circuit. 10. The sigma delta ADC of claim 9 , wherein the Flash ADC circuit is an N bit Flash ADC circuit, wherein N is an integer greater than one. 11. A sigma delta analog-to-digital converter (ADC) comprising: a capacitive gain amplifier circuit having a first input to receive an input signal and a second input, wherein the capacitive gain amplifier circuit is configured to amplify the input signal; a loop filter circuit connected to an output of the capacitive gain amplifier circuit and configured to filter the amplified input signal; a sub-ADC circuit including an output and an input connected to an output of the loop filter circuit and configured to sample the amplified and filtered input signal and convert the amplified filtered input signal to a digital output; a digital-to-analog (DAC) circuit including a DAC input connected to the output of the sub-ADC circuit, and a DAC output connected to the second input of the capacitive gain amplifier, wherein the capacitive gain amplifier circuit is configured to divide down a signal received at the second input by a gain of the capacitive gain amplifier circuit; a second capacitive gain amplifier circuit having a first input to receive the input voltage, a second input, and an output connected to the loop filter circuit; and a second DAC circuit including a DAC input connected to the output of the sub-ADC circuit and a DAC output connected to the second input of the second capacitive gain amplifier. 12. The sigma delta ADC of claim 11 , including a first signal chopper circuit arranged at the first and second inputs to the first capacitive gain amplifier circuit, and a second signal chopper circuit arranged at the first and second inputs of the second capacitive gain amplifier circuit, wherein the first DAC circuit is enabled to convert the output of the sub-ADC circuit according to the first chop clock signal and the second DAC circuit is enabled to convert the output of the sub-ADC circuit according to the second chop clock signal. 13. A method of controlling operation of a sigma delta analog-to-digital converter (ADC), the method comprising: receiving an input signal using a gain stage that includes a capacitive gain amplifier of the sigma delta ADC, wherein the gain stage amplifies the input signal; filtering the amplified input signal from the capacitive gain amplifier, wherein the filtering the output signal from the capacitive gain amplifier includes applying the output signal from the capacitive gain amplifier to a resistor and chopping the input voltage received at the capacitive gain amplifier and the output signal from the resistor to reduce circuit noise; sampling the amplified and filtered input signal; converting the amplified and filtered input signal to a digital output; converting the digital output to an analog signal; and feeding back the analog signal to the capacitive gain amplifier and dividing the analog signal by a gain of the gain stage. 14. The method of claim 13 , wherein the filtering the output signal from the capacitive gain amplifier includes filtering the output signal during a first phase of a clock signal and wherein converting the digital input to an analog signal includes converting the digital input during a second phase of the clock signal. 15. The method of claim 13 , including: chopping input signals to the capacitive gain amplifier and the output signal from the capacitive gain amplifier using a chop clock signal; and wherein filtering the output signal from the capacitive gain amplifier includes filtering the output signal during a specified phase of a switch clock signal, wherein converting the digital output to an analog signal includes converting the digital output using a specified phase of the chopping clock signal, and wherein a clock period of the chop clock signal is