Gain calibration for ADC with external reference

What is claimed is: 1. An analog-to-digital converter (ADC) comprising: a passive sample and hold (SH) capacitance arranged to receive an analog input voltage; a digital-to-analog converter (DAC) capacitance coupled to the SH capacitance at a first node and switchably coupled to a reference voltage at another node; and a calibration capacitance coupled at the first node, the calibration capacitance adjustable to minimize a difference between a capacitance value of the SH capacitance and a capacitance value comprising a sum of the calibration capacitance and the DAC capacitance; a comparator coupled to the first node and configured to compare an injected voltage from the SH capacitance to an injected voltage from the DAC capacitance at the first node; and a calibration logic module configured to: control the comparator to set a trip point of the comparator when the injected voltage from the SH capacitance and the injected voltage from the DAC capacitance are equal; detect a sign of a voltage magnitude deviation between the injected voltage from the SH capacitance and the injected voltage from the DAC capacitance; and add or subtract a capacitance from the calibration capacitance based on the sign of the voltage magnitude deviation when the injected voltage from the SH capacitance and the injected voltage from the DAC capacitance are not equal. 2. The ADC of claim 1 , further comprising a successive approximation register (SAR) coupled to an output of the comparator, an output of the SAR comprising a digital output of the ADC. 3. The ADC of claim 2 , wherein the DAC capacitance comprises an array of multiple switched capacitances, wherein the calibration logic module is configured to receive the output of the SAR and to adjust the calibration capacitance based on how many of the multiple capacitances of the DAC capacitance are switched to the reference voltage. 4. The ADC of claim 1 , wherein the calibration capacitance is arranged to track the DAC capacitance and to reduce or eliminate a deviation between a capacitance value of the DAC capacitance and a capacitance value of the SH capacitance. 5. The ADC of claim 1 , wherein the ADC does not implement a buffer. 6. The ADC of claim 1 , wherein the calibration capacitance is arranged to reduce or eliminate a gain error and a linear error of the ADC. 7. The ADC of claim 1 , wherein the calibration capacitance comprises an array of multiple capacitances having a total capacitance value that is greater than a difference between a capacitance value of the SH capacitance and a capacitance value of the DAC capacitance. 8. The ADC of claim 1 , wherein a single capacitance array is used as the SH capacitance and the DAC capacitance. 9. An analog-to-digital converter (ADC) comprising: a passive sample and hold (SH) capacitance arranged to receive an analog input voltage; a digital-to-analog converter (DAC) capacitance comprising an array of multiple switched capacitances, coupled to the SH capacitance at a first node and switchably coupled to a reference voltage at another node; a comparator coupled at the first node at an input of the comparator and configured to compare an injected voltage from the SH capacitance to an injected voltage from the DAC capacitance at the first node; a successive approximation register (SAR) coupled to an output of the comparator, an output of the SAR comprising a digital output of the ADC; a calibration capacitance coupled at the first node, the calibration capacitance adjustable to minimize a difference between a capacitance value of the SH capacitance and a capacitance value comprising a sum of the calibration capacitance and the DAC capacitance; and a calibration logic module configured to: control the comparator to set a trip point of the comparator when the injected voltage from the SH capacitance and the injected voltage from the DAC capacitance are equal; detect a sign of a voltage magnitude deviation between the injected voltage from the SH capacitance and the injected voltage from the DAC capacitance; and add or subtract a capacitance from the calibration capacitance based on the sign of the voltage magnitude deviation when the injected voltage from the SH capacitance and the injected voltage from the DAC capacitance are not equal; receive the output of the SAR; and adjust the calibration capacitance based on how many of the multiple capacitances of the DAC capacitance are switched to the reference voltage. 10. The ADC of claim 9 , further comprising an up-down counter arranged to derive a gain calibration value used by the calibration logic module to adjust the calibration capacitance. 11. The ADC of claim 10 , wherein the up-down counter is increased or decreased after a calibration step, tracking a gain error of the ADC based on a difference in capacitance values of the SH capacitance and the DAC capacitance. 12. The ADC of claim 10 , wherein the calibration capacitance comprises an array of multiple switched capacitances, and wherein an output of the up-down counter triggers a switching of one or more capacitances of the calibration capacitance to or from the reference voltage, based on a switching of one or more capacitances of the DAC capacitance to or from the reference voltage. 13. The ADC of claim 10 , further comprising an arithmetic unit arranged to calculate a final calibration value used by the calibration logic module to adjust the calibration capacitance, the final calibration value comprising the gain calibration value and a derived linearity calibration value. 14. The ADC of claim 13 , wherein the linearity calibration value is derived by comparing a capacitance value of an identified capacitance representing an associated bit position with a sum of capacitance values of capacitances representing all lesser bit positions from the associated bit position. 15. The ADC of claim 9 , further comprising a coupling capacitor coupled between the calibration capacitance and the first node and arranged to scale the calibration capacitance down with respect to the DAC capacitance. 16. A method comprising: forming an analog-to-digital converter (ADC), including: coupling a passive sample and hold (SH) capacitance to a digital-to-analog converter (DAC) capacitance at a first node; coupling the SH capacitance to an input voltage of the ADC at another node of the SH capacitance; and coupling the DAC capacitance to a reference voltage at another node of the DAC capacitance; coupling a calibration capacitance at the first node; coupling a comparator to the first node to compare an injected voltage from the SH capacitance to an injected voltage from the DAC capacitance at the first node; adjusting the calibration capacitance such that a sum of the DAC capacitance and the calibration capacitance is equal to the SH capacitance at least in part by: controlling the comparator to set a trip point of the comparator when the injected voltage from the SH capacitance and the injected voltage from the DAC capacitance are equal; detecting a sign of a voltage magnitude deviation between the injected voltage from the SH capacitance and the injected voltage from the DAC capacitance; and adding or subtracting a capacitance from the calibration capacitance based on the sign of the voltage magnitude deviation when the injected voltage from the SH capacitance and the injected voltage from the DAC capacitance are not equal. 17. The method of claim 16 , further comprising reducing or eliminating a gain error of the ADC via the adjusting. 18. The method of claim 16