Differential output PGIA architecture

What is claimed is: 1. A front-end circuit for an analog-to-digital converter (ADC), the front-end circuit comprising: first and second JFET input amplifiers configured to receive an input signal; and a gain selection circuit coupled to the first JFET input amplifier and the second JFET input amplifier; the gain selection circuit comprising a plurality resistor strings, each resistor string including a plurality of resistors coupled in series, and wherein each string includes a first end node coupled to an output of the first JFET input amplifier and a second end node coupled to an output of the second JFET input amplifier; and a differential amplifier configured to receive an output of the first JFET input amplifier at a first differential input, to receive an output of the second JFET input amplifier at a second differential input, and to provide a differential output signal to the ADC, the differential amplifier including a pair of matched resistors to set a gain of the differential amplifier. 2. The front-end circuit of claim 1 , wherein each resistor string is integrated within an integrated circuit separate from the first and second JFET amplifiers, and separate from other resistor string integrated circuits of the plurality of resistor strings. 3. The front-end circuit of claim 1 , wherein the gain selection circuit includes a multiplexer, the multiplexer configured to couple a plurality of intermediate nodes of a selected resistor string. 4. The front-end circuit of claim 3 , wherein the multiplexer is configured to selectively bypass the resistor strings. 5. The front-end circuit of claim 4 , wherein the multiplexer is configured to bypass the resistor strings, and to couple the output of the first JFET input amplifier to an input of the first JFET input amplifier and coupling the output of the second JFET input amplifier to an input of the second JFET input amplifier. 6. The front-end circuit of claim 3 , wherein the multiplexer is configured to couple a first intermediate node of the selected resistor string to a first input of the first JFET input amplifier; wherein the first input of the first JFET input amplifier is an inverting input of the first JFET input amplifier; and wherein the multiplexer is configured to couple a second intermediate node of the selected resistor string to a first input of the second JFET input amplifier. 7. The front-end circuit of claim 6 , wherein the first input of the second JFET input amplifier is an inverting input of the second JFET input amplifier. 8. The front-end circuit of claim 6 , wherein a second input of the first JFET input amplifier is configured to receive a first portion of the input signal. 9. The front-end circuit of claim 8 , wherein a second input of the second JFET input amplifier is configured to receive a second portion of the input signal. 10. The front-end circuit of claim 1 , wherein the representation of the input signal includes a signal-to-noise ratio (SNR) on the order of 98 dB, and gain error and offset error drift of about +/−6 ppm/° C. over a temperature range of 0° C. to 70° C. 11. The front-end circuit of claim 1 , wherein the representation of the input signal includes total harmonic distortion on the order of −115 dB. 12. The front-end circuit of claim 1 , wherein the representation of the input signal includes a common mode rejection ratio on the order of at least 90 dB. 13. The front-end circuit of claim 1 , wherein the differential amplifier includes an active, anti-aliasing filter to remove out-of-band noise; and wherein the active, anti-aliasing filter include passive components to remove the out-of-band noise at a bandwidth of interest. 14. The front-end circuit of claim 1 , wherein the differential amplifier includes a over-ranging resistor coupled in parallel with a feedback resistor of the pair of matched resistors. 15. A method for providing a scaled representation of an input signal to an analog-to-digital converter, the method comprising: receiving an input signal at a first JFET input amplifier and at a second JFET input amplifier; and selecting a gain of each of the first and second JFET input amplifiers, wherein selecting the gain of each of the first and second JFET input amplifiers includes, in a first selection state, selectively coupling a first intermediate node of a resistor string of a plurality of resistor strings with a first input of the first JFET input amplifier, and selectively coupling a second intermediate node of the resistor string of the plurality of resistor strings with a first input of the second JFET input amplifier; receiving an output of the first JFET input amplifier at a first differential input of a differential amplifier; receiving an output of the second JFET input amplifier at a second differential input of the differential amplifier; and providing a differential output signal to the analog-to-digital converter, wherein a matched set of resistors determine a gain of the differential amplifier; wherein a first end node of the resistor string is coupled to an output of the first JFET input amplifier, and a second end node of the resistor string is coupled to an output of the second JFET input amplifier; wherein each resistor string of the plurality of resistor strings includes a plurality of resistors coupled in series, and wherein each resistor string of the plurality of resistor strings includes a first end node coupled to an output of the first JFET input amplifier and a second end node coupled to an output of the second JFET input amplifier; providing an output signal representative of the input signal scaled by the gain; and wherein the plurality of resistor strings includes a plurality of individual integrated circuits, each individual integrated circuit of the plurality of individual integrated circuits including one resistor string of the plurality of resistor strings. 16. The method of claim 15 , wherein selecting a gain of each of the first JFET input amplifier and the second JFET input amplifier includes: in a second selection state, selectively coupling an output of the first JFET input amplifier directly with the first input of the first JFET input amplifier via a multiplexer, and selectively coupling an output of the second JFET input amplifier directly with the first input of the second JFET input amplifier via the multiplexer. 17. The method of claim 16 , wherein the providing the output signal includes providing the output signal with an integral nonlinearity error (INL) of +/−2.5 parts per million (ppm) over a temperature range of 0° C. to 70° C. 18. An analog-to-digital converter (ADC) system comprising: a front-end circuit configured to receive an input signal and to provide a scaled, differential representation of the input signal; and an analog-to-digital converter (ADC) configured to receive the scaled, differential representation and to provide a digital representation of the input signal; wherein the front-end circuit includes: first and second input JFET amplifiers configured to receive an input signal; a gain selection circuit coupled to the first JFET input amplifier and the second JFET input amplifier; and a differential amplifier configured to receive an output of the first JFET input amplifier at a first differential input, to receive an output of the second JFET input amplifier at a second differential input, and to provide a differential output signal to the ADC as the scaled, differential representation of the input signal, the differential amplifier including a pair of matched resist