Amplifier sharing technique for power reduction in analog-to-digital converter

1 . A dual delta-sigma analog-to-digital converter (ADC), comprising: a dual delta-sigma modulator configured to receive an analog input signal, the dual delta-sigma modulator including: a first modulator including a first integrator configured to integrate a difference between the analog input signal and a current modulator output signal of the first modulator during a first period of time, hold a first integrator output value by a first low power amplifier during a second period of time, and generate a first modulator output signal; a second modulator including a second integrator configured to hold a second integrator output value during the first period of time, integrate a difference between the analog input signal and a current modulator output signal of the second modulator during the second period of time, and generate a second modulator output signal; and a shared operational amplifier configured to assist the first modulator during the first period of time and to assist the second modulator during the second period of time; an interleaver configured to interleave the first modulator output signal and the second modulator output signal to generate an interleaved output signal; and a decimation filter configured to filter and decimate the interleaved output signal to generate a digital output signal. 2 . The dual delta-sigma ADC of claim 1 , wherein the decimation filter is configured to filter and decimate the interleaved output signal utilizing an over-sampling ratio (OSR). 3 . The dual delta-sigma ADC of claim 1 , wherein the first modulator includes a first low power operational amplifier configured to: integrate the difference between the analog input signal and the current modulator output signal of the first modulator during the first period of time with assistance of the shared operational amplifier; and hold the first integrator output value without assistance of the shared operational amplifier during the second period of time. 4 . The dual delta-sigma ADC of claim 3 , wherein the second modulator includes a second low power operational amplifier configured to: integrate the difference between the analog input signal and the current modulator output signal of the second modulator during the second period of time with assistance of the shared operational amplifier; and hold the second integrator output value without assistance of the shared operational amplifier during the second period of time. 5 . The dual delta-sigma ADC of claim 4 , wherein approximately 85% of total integrator power of the first and second integrators of dual delta-sigma modulator is consumed by the shared operational amplifier and the first low power operational amplifier and approximately 15% of total integrator power of the first and second integrators of the delta-sigma modulator is consumed by the second low power operational amplifier during the first period of time. 6 . The dual delta-sigma ADC of claim 1 , wherein the decimation filter is further configured to attenuate high frequency out of band noise in the interleaved output signal prior to decimating the interleaved output signal. 7 . The dual delta-sigma ADC of claim 1 , wherein the first period of time corresponds with a first sampling clock signal being HIGH, the first sampling clock signal configured to provide a sampling clock to the first modulator. 8 . The dual delta-sigma ADC of claim 7 , wherein the second period of time corresponds with a second sampling clock signal being HIGH and the first sampling clock signal being LOW, the second sampling clock signal configured to provide a sampling clock to the second modulator. 9 . The dual delta-sigma ADC of claim 1 , wherein the dual delta-sigma modulator is a single channel ADC. 10 . A dual delta-sigma modulator, comprising: a first modulator configured to generate a first modulator output signal; a second modulator configured to generate a second modulator output signal; and a shared operational amplifier coupled to the first modulator and the second modulator, the shared operational amplifier configured to assist a first integrator of the first modulator integrating a difference between a first analog input signal and a first modulator output signal from the first modulator during a first period of time and to assist a second integrator of the second modulator integrate a difference between a second analog input signal and a second modulator output signal from the second modulator during a second period of time. 11 . The dual delta-sigma modulator of claim 10 , wherein: the first integrator is configured to receive the first analog input signal, integrate the difference between the first analog input signal and the first modulator output signal during the first period of time, and hold a first integrator output value during a second period of time; and the second integrator is configured to receive the second analog input signal, integrate the difference between the second analog input signal and the second modulator output signal during the second period of time, and hold a second integrator output value during the first period of time. 12 . The dual delta-sigma modulator of claim 11 , wherein the dual delta-sigma modulator is a multiple channel dual delta-sigma modulator. 13 . The dual delta-sigma modulator of claim 10 , wherein the first modulator includes a first low power operational amplifier configured to: integrate the difference between the first analog input signal and a current modulator output signal of the first modulator during the first period of time with assistance of the shared operational amplifier; and hold the first integrator output value without assistance of the shared operational amplifier during the second period of time. 14 . The dual delta-sigma modulator of claim 13 , wherein the second modulator includes a second low power operational amplifier configured to: integrate the difference between the second analog input signal and a current modulator output signal of the second modulator during the second period of time with assistance of the shared operational amplifier; and hold the second integrator output value without assistance of the shared operational amplifier during the second period of time. 15 . The dual delta-sigma modulator of claim 14 , wherein approximately 85% of total integrator power of the first and second integrators of the dual delta-sigma modulator is consumed by the shared operational amplifier and the first low power operational amplifier and approximately 15% of total amplifier power of the first and second integrators of the delta-sigma modulator is consumed by the second low power operational amplifier during the first period of time. 16 . The dual delta-sigma modulator of claim 10 , wherein: the first period of time corresponds with a first sampling clock signal being HIGH and a second sampling clock signal being LOW, the first sampling clock signal configured to provide a sampling clock to the first modulator and the second sampling clock signal configured to provide a sampling clock to the second modulator; and the second period of time corresponds with the first sampling clock signal being LOW and the second sampling clock signal being HIGH. 17 . A method of converting an analog signal to a digital signal, comprising: receiving, by a first modulator and a second modulator, an analog input signal; during a first period of time: integrating, by a first integrator of the first modulator, a difference between the analog input signal and a first modulator output signal utilizing