System and method for zone cooking according to spectromodal theory in an electromagnetic cooking device

What is claimed is: 1. A method for controlling a heating distribution of an electromagnetic cooking device comprising: scanning a resonant cavity of the cooking device in which a food load has been placed with a plurality of radio frequency (RF) feeds that are coupled to a plurality of respective high power amplifiers; based on the scanning, identifying a plurality of resonant frequencies and corresponding phases of the RF feeds; creating and storing a resonance map in the frequency phase domain; classifying symmetries in the resonant map; determining paths defining stirring routes between poles of different symmetries; determining midpoints in the paths with a maximum unbalance between reflected powers of the plurality of respective high power amplifiers; classifying the unbalance in terms of power steered to a first side of the food load with respect to power steered to a second side of the food load; synthesizing a heating strategy for zone cooking using the classified unbalance; and implementing the heating strategy by causing the plurality of high power amplifiers and RF feeds to introduce electromagnetic radiation at specific frequencies and phases into the cavity, wherein the specific frequencies and phases are selected in accordance with the heating strategy. 2. The method according to claim 1 , wherein information used for classifying the unbalance may be pre-stored in a look-up table (LUT) and recalled using at least one of: a recipe; a computational electromagnetic engine; and an IR sensor testing of at least one of two asymmetric paths. 3. The method according to claim 1 , wherein the electromagnetic radiation introduced into the cavity is incrementally changed according to the stirring routes. 4. The method according to claim 3 , wherein the incremental change of the electromagnetic radiation achieves a smooth change in the plurality of RF feeds thereby smoothly changing a heating pattern of the resonant chamber over time. 5. The method according to claim 1 , wherein a rate of change of the electromagnetic radiation introduced into the cavity along the stirring routes is controlled. 6. The method according to claim 1 , wherein the first side of the food load is the right side and the second side of the food load is the left side. 7. The method according to claim 1 , further comprising providing a measurement device in configured to measure a plurality of reflected signals from the RF feeds. 8. The method according to claim 7 , further comprising: measuring an efficiency of the plurality of reflected signals with the measurement device. 9. The method according to claim 1 , wherein the resonant modes identify the frequency and phase of coordinates of end points wherein the stirring route includes coordinate points between the end points. 10. The method according claim 9 , wherein the coordinates correspond to points of the resonant modes in the frequency and phase domain. 11. An electromagnetic cooking device comprising: an enclosed cavity configured to receive a food load; a plurality of high power amplifiers configured to amplify a first radio frequency (RF) signal and a second RF signal thereby supplying the RF signals to the enclosed cavity; a plurality of RF feeds for receiving the RF signals from the plurality of high power amplifiers to introduce electromagnetic radiation corresponding to the RF signals into the enclosed cavity; and a controller in communication with the plurality of amplifiers, the controller configured to: scan the enclosed cavity with using the plurality of RF feeds; based on the scan, identify a plurality of resonant frequencies and corresponding phases of the RF feeds; create and store a resonance map in the frequency phase domain; classify symmetries in the resonant map; determine paths defining stirring routes between poles of different symmetries; determine midpoints in the paths with a maximum unbalance between reflected powers of the plurality of respective high power amplifiers; classify the unbalance in terms of power steered to a first side of the food load with respect to power steered to a second side of the food load; synthesize a heating strategy for zone cooking using the classified unbalance; and implement the heating strategy by causing the plurality of high power amplifiers and RF feeds to introduce the electromagnetic radiation at specific frequencies and phases into the cavity, wherein the specific frequencies and phases are selected in accordance with the heating strategy. 12. The electromagnetic cooking device according to claim 11 , wherein information used by the controller for classifying the unbalance may be pre-stored in a look-up table (LUT) and recalled using at least one of: a recipe; a computational electromagnetic engine; and an IR sensor testing of at least one of two asymmetric paths. 13. The electromagnetic cooking device according to claim 11 , further comprising: a measurement device in communication with the controller, wherein the measurement device is configured to measure a plurality of reflected signals from the RF feeds. 14. The electromagnetic cooking device according to claim 13 , wherein the controller is further configured to: measure an efficiency of the plurality of reflected signals with the measurement device. 15. The electromagnetic cooking device according to claim 14 , wherein based on the efficiency, the controller is further configured to identify a plurality of resonance frequencies. 16. The electromagnetic cooking device according to claim 15 , wherein the controller is further configured to select the resonant modes based on the plurality of resonance frequencies. 17. The electromagnetic cooking device according to claim 11 , wherein the resonant modes identify the frequency and phase of coordinates of the stirring route. 18. The electromagnetic cooking device according to claim 17 , wherein the coordinates correspond to points of the resonant modes in the frequency and phase domain. 19. An electromagnetic cooking device comprising: an enclosed cavity configured to receive a food load; a plurality of high power amplifiers configured to amplify a first RF signal and a second radio frequency (RF) signal thereby supplying the RF signals to the enclosed cavity; a plurality of RF feeds for receiving the RF signals from the plurality of high power amplifiers to introduce electromagnetic radiation corresponding to the RF signals into the enclosed cavity; and a controller in communication with the plurality of amplifiers, the controller configured to: scan the enclosed cavity using the plurality of RF feeds; based on the scan, identify a plurality of resonant frequencies and corresponding phases of the RF feeds; create and store a resonance map in the frequency phase domain; classify symmetries in the resonant map; determine paths defining stirring routes between poles of different symmetries; determine midpoints in the paths with a maximum unbalance between reflected powers of the plurality of respective high power amplifiers; classify the unbalance in terms of power steered to a first side of the food load with respect to power steered to a second side of the food load, wherein information used for classifying the unbalance may be pre-stored in a look-up table and recalled using at least one of: a recipe; a computational electromagnetic engine; and an IR sensor testing of at least one of two asymmetric paths; synthesize a heating strategy for zone cooking using the classified unbalance; and implem