Auto-zero technique for opamps with a source-follower output stage based on replica referencing

The invention claimed is: 1. An electronic circuit comprising: an input stage; a gain stage operatively coupled to the input stage; a primary output stage operatively coupled to the gain stage wherein the primary output stage is a source-follower output stage; a replica output stage operatively coupled to the gain stage in parallel to the primary output stage, wherein the replica output stage is a replica source-follower stage; and a clock circuit configured to operate the electronic circuit in multiple phases including: a sampling phase to disconnect the primary output stage and the replica output stage from the gain stage to obtain an offset voltage; an active phase to reconnect the primary output stage to apply the offset voltage to reduce an offset at the primary output stage; and an intermediate phase to first reconnect the replica output stage to the gain stage prior to the active phase. 2. The electronic circuit of claim 1 , including: a first switch circuit coupled to an output of the gain stage and a source or drain of an output transistor of the replica source-follower stage; a second switch circuit coupled to the output of the gain stage, a gate of the output transistor of the replica source-follower stage and a gate of an output transistor of the source follower output stage; and wherein the clock circuit is configured to produce a clock signal that deactivates the first switch circuit and the second switch circuit during the sample phase, activates the first switch and deactivates the second switch circuit during the intermediate phase, and deactivates the first switch circuit and activates the second switch circuit during the active phase. 3. The electronic circuit of claim 2 , including: an impedance modifier circuit element; a third switch circuit connected between the impedance modifier circuit element and an output of the gain stage; and wherein the clock signal activates the third switch circuit during the sampling phase and deactivates the third switch circuit during the intermediate phase and active phase. 4. The electronic circuit of claim 3 , wherein the impedance modifier circuit element includes a diode connected transistor. 5. The electronic circuit of claim 3 , including: a first input transistor and a second input transistor included in the input stage and coupled as a differential transistor pair, wherein the gate of the first transistor is an input circuit node; a fourth switch circuit coupled between the gates of the first and second input transistors; a feedback circuit coupled to the source-follower output stage; a feedback circuit path including a fifth switch circuit connected between the feedback circuit and a gate of the second transistor of the differential input stage; and wherein the clock signal activates the fourth switch circuit and deactivates the fifth switch circuit during the sampling phase, and deactivates the fourth switch circuit and activates the fifth switch circuit during the intermediate phase and active phase. 6. The electronic circuit of claim 1 , including: a first sample-and-hold capacitor connected to a gate of an output transistor of the source-follower output stage; and a second sample-and-hold capacitor connected to an output of the gain stage. 7. The electronic circuit of claim 6 , including: a first input transistor and a second input transistor included in the input stage and coupled as a differential transistor pair, wherein the gate of the first transistor is an input circuit node; wherein the gain stage comprises multiple intermediate gain stages between an input of the gain stage and the output of the gain stage; and wherein offset voltages of the differential transistor pair and the multiple intermediate gain stages are sampled onto the second sample-and-hold capacitor during the sampling phase. 8. The electronic circuit of claim 1 , wherein the source-follower output stage and the replica source-follower stage each include an output transistor, and a gate-to-source voltage (V GS ) of the output transistor of the replica source-follower stage is greater than the gate-to-source voltage of the output transistor of the source-follower output stage. 9. A method of operating an operational amplifier (opamp) circuit, the method comprising: disconnecting a source-follower output stage of the opamp circuit and a replica source-follower stage of the opamp circuit from a gain stage of the opamp circuit; applying voltage of a first sample-and-hold capacitor to the source-follower output stage, and sampling an offset voltage of the gain stage and an input stage of the opamp circuit onto a second sample-and-hold capacitor; connecting a source or drain of an output transistor of the replica output stage to the gain stage; disconnecting the source or drain of the output transistor of the replica output stage from the gain stage; and reconnecting a gate of an output transistor of the source-follower output stage and applying the offset voltage to the gate of the output transistor of the source-follower output stage. 10. The method of claim 9 , including reconnecting a gate of an output transistor of the replica source-follower stage when reconnecting the gate of the output transistor of the source-follower output stage. 11. The method of claim 9 , including: disconnecting a feedback circuit path of the opamp circuit when disconnecting the source-follower output stage and replica source-follower output stage; and reconnecting the feedback circuit path when reconnecting the gate of the output transistor of the source-follower output stage. 12. The method of claim 9 , including: connecting gates of transistors of an input differential transistor pair of the opamp circuit together when disconnecting the source-follower output stage and the replica source-follower stage from the gain stage; and disconnecting the gates of the transistors of the input differential transistor pair when reconnecting the gate of the output transistor of the replica output stage and the gate of an output transistor of the source-follower output stage. 13. The method of claim 12 , wherein sampling the offset voltage includes sampling offset voltages of the input stage and multiple intermediate gain stages of the gain stage onto the second sample-and-hold capacitor. 14. An electronic system comprising an operational amplifier (opamp) circuit including: an input stage; a gain stage; and a source-follower output stage; and an auto-zeroing circuit including; a replica source-follower stage operatively coupled to the gain stage in parallel the source follower output stage; and a clock circuit configured to operate the auto-zeroing circuit in multiple phases including: a sampling phase to disconnect the source-follower output stage and the replica source-follower stage from the gain stage to obtain an offset voltage; an active phase to reconnect the source-follower output stage to apply the offset voltage to reduce an offset at, the source-follower output stage; and an intermediate phase to first reconnect the replica source-follower stage to the gain stage prior to the active phase. 15. The electronic system of claim 14 , wherein the auto-zeroing circuit includes: a first switch circuit coupled to an output of the gain stage and a source or drain of an output transistor of the replica source-follower stage; a second switch circuit coupled to the output of the gain stage, a gate of the output transistor of the replica source-follower stage, and a gate of an output transistor of the source follower output stage; and wherein the