In-body wireless charging system

What is claimed is: 1. A far-field wireless charging system, comprising: a plurality of slave radios located about an area, each slave radio configured for transmitting a respective spread spectrum (SS) modulated radio wave within the area, and for adapting a time-offset of the radio wave in response to a control signal; and a leader radio, configured for receiving backscatter radio energy from a target device within the area, for receiving SS modulated radio waves from slave radios, and for generating slave radio control signals; the leader radio, in a time synchronization mode of operation, configured for determining changes in received power associated with radio wave transmissions of at least a portion of the plurality of slave radios and responsively interacting with the slave radios to modify respective radio wave transmission times such that slave radio wave transmissions are received at the leader radio in a substantially synchronized manner to thereby achieve beamforming at the leader radio; the leader radio, in a charging mode of operation, is configured for determining changes in received power associated with backscatter radio energy received from a target device and responsively interacting with the slave radios to modify respective radio wave transmission times such that slave radio wave transmissions are received at the target device in a substantially synchronized manner to thereby achieve beamforming at the target device. 2. The system of claim 1 , wherein the leader radio in the time synchronization mode of operation is configured for: broadcasting a synchronizing chirp preamble configured to enable each slave radio to determine an initial transmission time offset; and for each slave radio, iteratively transmitting thereto control signals indicative of changes in total received power at the leader radio associated with respective changes to slave radio transmission time until slave radio waves received at the leader radio are substantially phase aligned. 3. The system of claim 2 , wherein control signals indicative of changes in total received power at the leader radio comprise two-bit feedback signals. 4. The system of claim 1 , wherein the leader radio in the charging mode of operation is configured for: for each slave radio, iteratively transmitting thereto control signals indicative of changes in total received power at the target device associated with respective changes to slave radio transmission time until slave radio waves received at the target device are substantially phase aligned. 5. The system of claim 1 , wherein the system includes a plurality of radio transceivers capable of operating as either a leader radio or a slave radio, and the leader radio is selected as the transceiver closest to the target device. 6. The system of claim 1 , wherein the area comprises a sleep space or work space for use by an entity having a target device implanted therein. 7. The system of claim 6 , wherein the entity having a target device implanted therein comprises one of a human, an animal, and a mobile autonomous device. 8. The system of claim 1 , wherein the system includes a leader radio located proximate an expected location of the implanted target device and a plurality of slave radios disposed about the area and configured to provide sufficient energy to charge the implanted target device. 9. The system of claim 1 , wherein: the leader radio, in a cold start mode of operation, is configured for searching for a target device by sequentially interacting with the slave radios to modify respective radio wave transmission times such that slave radio wave transmissions are received at each of a corresponding sequence of locations proximate the leader radio in a substantially synchronized manner to thereby achieve and hold beamforming at each of the sequence of locations proximate the leader radio, wherein the cold start mode of operation is exited in response to the leader radio receiving a backscatter signal indicative of a proximate target device. 10. The system of claim 9 , wherein the leader radio, in the cold start mode of operation, is further configured to cause the selection of a new leader radio and slave radios in response to a determination that a backscatter signal indicative of a proximate target device is not received within a predefined time period. 11. The system of claim 1 , wherein the SS modulated waves comprise chirp spread spectrum (CSS) modulated waves. 12. The system of claim 1 , wherein the SS modulated waves comprise one or more of chirp spread spectrum (CSS) modulated waves, code-division multiple access (CDMA) modulated waves, and code-division multiplexing (CDM) modulated waves. 13. The system of claim 1 , wherein the portion of the plurality of slave radios is determined with respect to a number of slave radios determined to be able to provide at least sufficient power to a target device. 14. The system of claim 13 , wherein each slave radio modulates a respective identification code upon its transmitted radio signal, the leader radio being further configured to identify those slave radios insufficiently contributing to the delivery of power to the target device. 15. The system of claim 1 , wherein the leader radio is further configured to change the portion of slave radios used to charge a target device. 16. The system of claim 1 , further comprising: a second leader radio, configured for receiving backscatter radio energy from a target device within the area, for receiving SS modulated radio waves from slave radios, and for generating slave radio control signals; the second leader radio, in a time synchronization mode of operation, configured for determining changes in received power associated with radio wave transmissions of at least a second portion of the plurality of slave radios and responsively interacting with the second slave radios to modify respective radio wave transmission times such that second slave radio wave transmissions are received at the second leader radio in a substantially synchronized manner to thereby achieve beamforming at the second leader radio; the second leader radio, in a charging mode of operation, determining changes in received power associated with backscatter radio energy received from a second target device and responsively interacting with the second slave radios to modify respective radio wave transmission times such that second slave radio wave transmissions are received at the second target device in a substantially synchronized manner to thereby achieve beamforming at the second target device. 17. The system of claim 1 , wherein the target device comprises: a first antenna, for receiving said SS modulated waves; an energy harvesting module, coupled to the first antenna and converting energy derived from the received SS modulated waves to a charging signal suitable for use by an energy storage device; and a backscatter module, for reflecting a backscatter signal derived from the received SS modulated waves via a second antenna. 18. A far-field wireless charging method for use at a leader radio proximate a target device to be charged by spread spectrum (SS) modulated radio waves transmitted from each of a plurality of slave radios, the method comprising: determining, in a charging mode of operation, changes in total received power at the target device associated with radio wave transmissions of each of the plurality of slave radios using backscatter radio energy reflected from the target device; and transmitting control signals configured to cause the slave radios