Defrosting apparatus with mass estimation and methods of operation thereof

What is claimed is: 1. A thermal increase system comprising: a radio frequency (RF) signal source configured to supply an RF signal; an electrode coupled to the RF signal source; at least one variable impedance network that includes at least one variable passive component having at least one current variable component value, wherein the at least one variable impedance network is coupled between the RF signal source and the electrode; and a controller configured to determine an estimated mass of a load that is proximate to the electrode by comparing the at least one current variable component value of the at least one variable impedance network with stored component values in a look-up table (LUT) to determine a correlated entry of the LUT that most closely correlates with the at least one current variable component value, wherein the correlated entry of the LUT includes a stored mass value that corresponds to the estimated mass of the load, and wherein the controller is further configured to determine one or more desired signal parameters for the RF signal based on at least the estimated mass of the load, and to control the RF signal source to supply a mass-estimate-based RF signal with the one or more desired signal parameters. 2. The thermal increase system of claim 1 , wherein the controller is configured to estimate an amount of energy sufficient to defrost the load based on the estimated mass of the load. 3. The thermal increase system of claim 2 , wherein the controller is configured to determine the one or more desired signal parameters for the RF signal based on the estimated amount of energy sufficient to defrost the load. 4. A thermal increase system comprising: a radio frequency (RF) signal source configured to supply an RF signal; an electrode coupled to the RF signal source; at least one variable impedance network that includes at least one variable passive component having at least one current variable component value, wherein the at least one variable impedance network is coupled between the RF signal source and the electrode; a controller configured to determine an estimated mass of a load that is proximate to the electrode based at least on the at least one current variable component value of the at least one variable impedance network, to determine one or more desired signal parameters for the RF signal based on at least the estimated mass of the load, to control the RF signal source to supply a mass-estimate-based RF signal with the one or more desired signal parameters, and to estimate an amount of energy sufficient to defrost the load based on the estimated mass of the load; and a memory configured to store a look-up table (LUT) that includes multiple entries, wherein each entry of the multiple entries includes a different set of stored component values corresponding to the at least one variable passive component of the at least one variable impedance network, and the LUT further includes multiple stored mass values, each corresponding to a respectively different set of stored component values in the multiple entries. 5. The thermal increase system of claim 4 , wherein the controller is configured to determine the estimated mass of the load by comparing the at least one component value to the sets of stored component values of the LUT to identify a correlated entry of the multiple entries, wherein the correlated entry includes a set of stored component values that correlates with the at least one current variable component value, and by identifying a stored mass value of the stored mass values that corresponds to the correlated entry, wherein the identified stored mass value is determined by the controller to be the estimated mass of the load. 6. The thermal increase system of claim 5 , wherein the at least one variable impedance matching network includes a double-ended variable impedance matching network that comprises: first and second inputs; first and second outputs; a first variable passive component that is connected between the first input and the first output and that has a first component value; a second variable passive component connected between the second input and the second output and that has a second component value; and a third variable passive component that is connected between the first input and the second input and that has a third component value, wherein the at least one component value comprises the first, second, and third impedance values. 7. The thermal increase system of claim 1 , wherein the at least one variable impedance matching network includes a single-ended variable impedance matching network that comprises: an input; an output; a set of passive components coupled between the input and the output; and one or more variable passive components that are connected between the input and a ground reference node and that have one or more component values, wherein the at least one component value comprises the one or more component values. 8. The thermal increase system of claim 1 , wherein the one or more desired signal parameters include at least one signal parameter selected from a group that includes a frequency of the RF signal, an amplitude of the RF signal, and a power level of the RF signal. 9. A thermal increase system coupled to a cavity for containing a load, the thermal increase system comprising: a radio frequency (RF) signal source configured to supply an RF signal; a transmission path electrically coupled between the RF signal source and first and second electrodes that are positioned across the cavity; an impedance matching network electrically coupled along the transmission path, wherein the impedance matching network comprises one or more variable passive components, wherein each of the one or more variable passive components has a current variable component value at an evaluation time, and a current variable component value set includes the current variable component value of each of the one or more variable passive components; and a controller configured to determine an estimated mass of the load based on at least the current variable component value set by comparing the current variable component value set with stored component values in a look-up table (LUT) to determine a correlated entry of the LUT that most closely correlates with the current variable component value set, wherein the correlated entry of the LUT includes a stored mass value that corresponds to the estimated mass of the load, and wherein the controller is further configured to determine one or more desired signal parameters for the RF signal based on at least the estimated mass of the load, and to modify the RF signal source to supply a mass-estimate-based RF signal with the one or more desired signal parameters. 10. The thermal increase system of claim 9 , wherein the controller is configured to determine an estimated amount of energy sufficient to defrost the load based on at least the estimated mass of the load. 11. The thermal increase system of claim 10 , wherein the controller is configured to determine the one or more desired signal parameters for the RF signal based on the estimated amount of energy sufficient to defrost the load. 12. A thermal increase system coupled to a cavity for containing a load, the thermal increase system comprising: a radio frequency (RF) signal source configured to supply an RF signal; a transmission path electrically coupled between the RF signal source and first and second electrodes that are positioned across the cavity; an impedance matching network electrically coupled along the transmission path, wherein the impedance matching network comprises one or more variable passive compone