Rf switch having reduced signal distortion

What is claimed is: 1 . An RF switch having a common mode (CM) node, a first end node, and a second end node comprising: an M number of FETs that are stacked in series and coupled between the first end node and the second end node wherein M is a finite number greater than one and each of the M number of FETs has a gate; a resistive network coupled between the CM node and the gate for each of the M number of FETs such that a resistance between the CM node and each gate of the M number of FETs is substantially equal; and biasing circuitry coupled to the CM node and configured to sense a breakdown current flowing through the CM node, and in response to the breakdown current, generate a compensation signal that counters deviations of drain to source voltage across individual ones of the M number of FETs due to an applied RF voltage across the M number of FETs while the RF switch is in an OFF state. 2 . The RF switch of claim 1 wherein the M number of FETs comprise: a first end FET coupled to the first end node and having a first gate; an M th end FET coupled to the second end node and having a second gate; and M−2 FETs stacked in series with and in between the first end FET and the M th end FET; M−1 bias resistors coupled in series between the first gate and the CM node, wherein each of the M−1 bias resistors have a resistance of substantially R; a first gate resistor coupled between the second gate and the CM node and having a resistance of substantially (M−1)·R; and M−2 gate resistors wherein each of the M-2 gate resistors is coupled between a gate of one of the M−2 FETs and a connection node between adjacent ones of the M−1 bias resistors, wherein when progressing from the first end node to the second end node successive ones of the M−2 gate resistors has a resistance that increases by R. 3 . The RF switch of claim 2 further including a CM mode resistor coupled between the CM node and a control node. 4 . The RF switch of claim 3 wherein the biasing circuitry comprises: a current mirror having a mirror output, a drive input, and a drive output coupled to the control node; an operational amplifier (op-amp) having a non-inverting input coupled to the control node, an inverting input coupled to the mirror output, and an op-amp output coupled to the drive input; and a compensation resistor coupled between the inverting input and a first fixed voltage node. 5 . The RF switch of claim 4 wherein the current mirror comprises: a drive FET having the drive input, the drive output, and a drive source coupled to a second fixed voltage node; a mirror FET having the mirror output, a mirror gate coupled to the op-amp output, and a mirror source coupled to the second fixed voltage node. 6 . The RF switch of claim 5 wherein the drive FET and the mirror FET are both n-channel FETs. 7 . The RF switch of claim 5 wherein the first fixed voltage node and the second fixed voltage node are at a negative potential with respect to a ground node. 8 . The RF switch of claim 3 wherein the biasing circuitry comprises: a drive FET having a drive drain coupled to the CM node, a drive source coupled to a first fixed voltage node, and a drive gate; an operational amplifier (op-amp) having a non-inverting input coupled to the control node, an inverting input, and an op-amp output coupled to the drive gate; and a low-pass filter coupled between the drive drain and the inverting input. 9 . The RF switch of claim 8 wherein the drive FET is an n-channel FET. 10 . The RF switch of claim 9 wherein the first fixed voltage node is at a negative potential with respect to a ground node. 11 . The RF switch of claim 2 further including a speed-up device comprising an M number of p-FETS that are stacked in series and coupled between the first gate and the second gate, and wherein each of the M number of p-FETs is coupled between adjacent gates of the M number of FETs. 12 . The RF switch of claim 1 wherein the M number of FETs comprise: a first end FET coupled to the first end node and having a first gate; M/2−1 first FETs stacked in series with and in between the first end FET and a middle node; M/2 first bias resistors coupled in series between the first gate and the CM node, wherein each of the M/2 first bias resistors have a resistance of substantially R; and M/2−1 first gate resistors wherein each of the M/2−1 first gate resistors is coupled between a gate of one of the M/2−1 first FETs and a connection node between adjacent ones of the M/2 first bias resistors, wherein when progressing from the first end node to the middle node successive ones the M/2−1 first gate resistors has a resistance that increases by R. 13 . The RF switch of claim 12 further comprising: a second end FET coupled to the second end node and having a second gate; M/2−1 second FETs stacked in series with and in between the second end FET and the middle node; M/2 second bias resistors coupled in series between the second gate and the CM node, wherein each of the M/2 second bias resistors have a resistance of substantially R; and M/2−1 second gate resistors wherein each of the M/2−1 second gate resistors is coupled between a gate of one of the M/2−1 second FETs and a connection node between adjacent ones of the M/2 second bias resistors, wherein when progressing from the second end node to the middle node successive ones of the M/2−1 second FETs each one of the M/2−1 second gate resistors has a resistance that increases by R. 14 . The RF switch of claim 13 further including a CM mode resistor coupled between the CM node and a control node. 15 . The RF switch of claim 14 wherein the biasing circuitry comprises: a current mirror having a mirror output, a drive input, and a drive output coupled to the control node; an operational amplifier (op-amp) having a non-inverting input coupled to the control node, an inverting input coupled to the mirror output, and an op-amp output coupled to the drive input; and a compensation resistor coupled between the inverting input and a first fixed voltage node. 16 . The RF switch of claim 15 wherein the current mirror comprises: a drive FET having the drive input, the drive output, and a drive source coupled to a second fixed voltage node; a mirror FET having the mirror output, a mirror gate coupled to the op-amp output, and a mirror source coupled to the second fixed voltage node. 17 . The RF switch of claim 16 wherein the drive FET and the mirror FET are both n-channel FETs. 18 . The RF switch of claim 16 wherein the first fixed voltage node and the second fixed voltage node are at a negative potential with respect to a ground node. 19 . The RF switch of claim 14 wherein the biasing circuitry comprises: a drive FET having a drive drain coupled to the CM node, a drive source coupled to a first fixed voltage node, and a drive gate; an operational amplifier (op-amp) having a non-inverting input coupled to the control node, an inverting input, and an op-amp output coupled to the drive gate; and a low-pass filter coupled between the drive drain and the inverting input. 20 . The RF switch of claim 19 wherein the drive FET is an n-channel FET. 21 . The RF switch of claim 20 wherein the first fixed voltage node is at a negative potential with respect to a ground node.