AC coupling modules for bias ladders

What is claimed is: 1. A FET switch stack, including: (a) a plurality of series-coupled FETs defining a signal path and including one or more series-coupled positive-logic FETs requiring a relative negative V GS to effectively turn OFF but configured to not require a negative voltage source; (b) a first end-cap FET that turns OFF when the V GS of such first end-cap FET is essentially zero volts, series-coupled to a first end of the plurality of series-coupled FETs in the signal path and configured to selectably provide either a capacitive DC blocking function or a resistive signal path; (c) a gate bias resistor ladder including a plurality of resistors configured to be coupled to a gate bias voltage and to the gate of at least one corresponding series-coupled FET or the first end-cap FET; and (d) a body charge control resistor ladder including a plurality of resistors configured to be coupled to a body bias voltage and to the body of at least one corresponding series-coupled FET; wherein the resistors of the gate bias resistor ladder are series-connected and the resistors of the body charge control resistor ladder are parallel-connected. 2. The invention of claim 1 , further including a second end-cap FET that turns OFF when the V GS of such second end-cap FET is essentially zero volts, series-coupled to a second end of the plurality of series-coupled FETs in the signal path and configured to selectably provide either a capacitive DC blocking function or a resistive signal path. 3. The invention of claim 1 , further including an AC coupling gate module coupled to at least one end of the gate bias resistor ladder and configured to be coupled to a radio frequency voltage source. 4. The invention of claim 3 , wherein the AC coupling gate module includes one of a capacitor or a capacitor series coupled to a resistor. 5. The invention of claim 1 , further including an AC coupling body module coupled to at least one end of the body charge control resistor ladder and configured to be coupled to a radio frequency voltage source. 6. The invention of claim 5 , wherein the AC coupling body module includes one of a capacitor or a capacitor series coupled to a resistor. 7. The invention of claim 1 , further including a capacitor coupled between the gate bias resistor ladder and a reference potential. 8. The invention of claim 1 , further including a capacitor coupled between the body charge control resistor ladder and a reference potential. 9. The invention of claim 1 , further including a parallel-connected gate resistor ladder, including a plurality of resistors each coupled between the gate bias resistor ladder and the gate of a corresponding FET. 10. The invention of claim 1 , further including a drain-source resistor ladder including a plurality of series-coupled resistors configured to be coupled to a drain-source bias voltage, wherein each resistor is coupled to the respective drains and sources of at least one corresponding adjacent series-coupled FET. 11. A FET switch stack, including: (a) a plurality of series-coupled FETs defining a signal path and including one or more series-coupled positive-logic FETs requiring a relative negative V GS to effectively turn OFF but configured to not require a negative voltage source; (b) a first end-cap FET that turns OFF when the V GS of such first end-cap FET is essentially zero volts, series-coupled to a first end of the plurality of series-coupled FETs in the signal path and configured to selectably provide either a capacitive DC blocking function or a resistive signal path; (c) a gate bias resistor ladder including a plurality of resistors configured to be coupled to a gate bias voltage and to the gate of at least one corresponding series-coupled FET or the first end-cap FET; and (d) a body charge control resistor ladder including a plurality of resistors configured to be coupled to a body bias voltage and to the body of at least one corresponding series-coupled FET; wherein the resistors of the gate bias resistor ladder are parallel-connected and the resistors of the body charge control resistor ladder are series-connected. 12. The invention of claim 11 , further including a second end-cap FET that turns OFF when the V GS of such second end-cap FET is essentially zero volts, series-coupled to a second end of the plurality of series-coupled FETs in the signal path and configured to selectably provide either a capacitive DC blocking function or a resistive signal path. 13. The invention of claim 11 , further including an AC coupling gate module coupled to at least one end of the gate bias resistor ladder and configured to be coupled to a radio frequency voltage source. 14. The invention of claim 13 , wherein the AC coupling gate module includes one of a capacitor or a capacitor series coupled to a resistor. 15. The invention of claim 11 , further including an AC coupling body module coupled to at least one end of the body charge control resistor ladder and configured to be coupled to a radio frequency voltage source. 16. The invention of claim 15 , wherein the AC coupling body module includes one of a capacitor or a capacitor series coupled to a resistor. 17. The invention of claim 11 , further including a capacitor coupled between the gate bias resistor ladder and a reference potential. 18. The invention of claim 11 , further including a capacitor coupled between the body charge control resistor ladder and a reference potential. 19. The invention of claim 11 , further including a series-connected gate resistor ladder, including a plurality of resistors configured to be coupled to a gate bias voltage, each resistor configured to be coupled to a corresponding resistor of the gate bias resistor ladder. 20. The invention of claim 11 , further including a drain-source resistor ladder including a plurality of series-coupled resistors configured to be coupled to a drain-source bias voltage, wherein each resistor is coupled to the respective drains and sources of at least one corresponding adjacent series-coupled FET.