Regulated switch banks for driving transmit power amplifiers of a MIMO wireless transceiver

What is claimed is: 1. A wireless multiple-input multiple-output (MIMO) transceiver apparatus for wireless communication on a wireless local area network (WLAN), and the wireless transceiver apparatus comprising: a plurality of antennas; a plurality of components coupled to one another to form transmit and receive chains coupled to the plurality of antenna for MIMO wireless communications on the WLAN; and the plurality of components forming the transmit chains including; power amplifiers (PA)s each coupled at a signal input to a corresponding one of the transmit chains for amplifying radio frequency (RF) signals of a MIMO communication link and each power amplifier having a supply voltage input for powering the power amplifier; voltage sources having distinct voltage levels; PA supply voltage detectors each coupled at an input to an associated one of the transmit chains to detect changes in an amplitude of the signal on each transmit chain and to identify required changes in the supply voltage level of the corresponding PA for transmission of said signal the PA supply voltage detectors each further responsive to the corresponding signal to normalize said signal to a link specific maximum supply voltage level prior to identifying the required changes in the supply voltage level of the corresponding PA; and regulated switches coupled between the voltage sources and the PAs, and responsive to each PA's supply voltage detector to switchably couple the supply voltage input of each PA to the voltage sources providing the identified voltage levels during transmission of the RF signal. 2. The wireless MIMO transceiver apparatus of claim 1 , wherein the switches further comprise: low dropout voltage regulators (LDO)s each coupling each voltage sources to the supply voltage input of each PA and switchably operative in an ‘On’ switch state to regulate the identified supply voltage level to the PA from a corresponding one of the voltage sources independent of the load on the PA, and in an ‘Off’ switch state to disconnect the corresponding voltage source from the PA. 3. The wireless MIMO transceiver apparatus of claim 1 , wherein the switches further comprise: low dropout voltage regulators (LDO)s each coupling each voltage source to the supply voltage input of each PA and switchably operative in an ‘On’ switch state to regulate the identified supply voltage level to the PA from a corresponding one of the voltage sources and in an ‘Off’ switch state to disconnect the corresponding voltage source from the PA, and each LDO having an adjustable dropout range to vary the amount of isolation between the corresponding voltage source and the regulated output voltage provided by the LDO. 4. The wireless MIMO transceiver apparatus of claim 1 , wherein the switches further comprise: current mirrors (CM)s each coupling each voltage source to the supply voltage input of each PA and switchably operative in an ‘On’ switch state to regulate current to the PA from the corresponding one of the voltage sources supplying the identified supply voltage level and in an ‘Off’ state to disconnect the corresponding voltage source from the PA. 5. The wireless MIMO transceiver apparatus of claim 1 , wherein the switches further comprise: current mirrors (CM)s each coupling each voltage source to the supply voltage input of each PA and switchably operative in an ‘Oncm’ switch state to regulate current to the PA from the corresponding one of the voltage sources supplying the identified supply voltage level, and in an ‘On’ state to avoid regulation of the current to the PA from the corresponding one of the voltage sources, and in an ‘Off’ state to disconnect the corresponding voltage source from the PA. 6. The wireless MIMO transceiver apparatus of claim 1 , further comprising: a link power regulator circuit to determine a maximum supply voltage level for each MIMO communication link between the wireless MIMO transceiver apparatus and other wireless transceivers on the WLAN, based on distinct communication parameters of each link. 7. The wireless MIMO transceiver apparatus of claim 1 , further comprising: the voltage sources having distinct programmable voltage levels determined based on operational characteristics of the PAs. 8. The wireless MIMO transceiver apparatus of claim 1 , operative as one of: a Wireless Access Point (WAP) transceiver or a station transceiver. 9. A method for operating a multiple-input multiple-output (MIMO) wireless transceiver having multiple transmit chains each including a corresponding power amplifier (PA) for amplifying radio frequency (RF) signals of a MIMO communication link, and the method comprising the acts of: providing voltage sources having distinct voltage levels; detecting changes in an amplitude of the signal on each transmit chain; normalizing the signal on each transmit chain to a maximum supply voltage level identified for the MIMO communication link; identifying required changes in the supply voltage level of the corresponding PA for transmission of said signal responsive to the detected changes in each chain's signal; and switchably coupling the supply voltage input of each PA to the voltage sources providing the voltage levels identified in the identifying act during transmission of the signal on each chain. 10. The method for operating the MIMO wireless transceiver of claim 9 , wherein the switchable coupling act further comprises: regulating the identified supply voltage level to the PA from a corresponding one of the voltage sources independent of the load on the PA in an ‘On’ switch state; and disconnecting the corresponding voltage source from the PA in an ‘Off’ switch state. 11. The method for operating the MIMO wireless transceiver of claim 9 , wherein the switchable coupling act further comprises: regulating the identified supply voltage level to the PA from a corresponding one of the voltage sources in an ‘On’ switch state, including; adjusting a dropout voltage range to vary the amount of isolation between the corresponding voltage source and the regulated output voltage provided by the LDO; and disconnecting the corresponding voltage source from the PA in an ‘Off’ switch state. 12. The method for operating the MIMO wireless transceiver of claim 9 , wherein the switchable coupling act further comprises: regulating current to the PA from the corresponding one of the voltage sources supplying the identified supply voltage level in an ‘On’ switch state; and disconnecting the corresponding voltage source from the PA in an ‘Off’ switch state. 13. The method for operating the MIMO wireless transceiver of claim 9 , wherein the switchable coupling act further comprises: regulating current to the PA from the corresponding one of the voltage sources supplying the identified supply voltage level in an in an ‘Oncm’ switch state; avoiding regulation of the current to the PA from the corresponding one of the voltage sources in an ‘On’ switch state; and disconnecting the corresponding voltage source from the PA in an ‘Off’ switch state. 14. The method for operating the MIMO wireless transceiver of claim 9 , wherein the identifying act further comprises: determining a maximum supply voltage level for each MIMO communication link between the wireless MIMO transceiver and other wireless transceivers on the WLAN, based on distinct communication parameters of each link. 15. The method for operating the MIMO wireless transceiver of claim 9 , wherein the providing act further comprises: determining the distinct voltage levels for the provided voltage sources based on operational chara