Temperature measurement arrangement

1 - 4 . (canceled) 5 . A system for processing objects by radio frequency (RF) energy in a cavity, the system comprising: a cavity; an RF feeding module that comprises: a plurality of radiating elements configured to feed RF radiation into the cavity, and a plurality of dummy loads for receiving RF energy coupled from the cavity into the radiating elements; and a processor configured to: estimate an effect operating the system at each of a plurality of sets of operating parameters will have on the temperature of each of the dummy loads; choosing among the plurality of sets of operating parameters at least one set based on the estimation; and controlling the system to operate at the chosen at least one set of operating parameters. 6 . A system according to claim 5 , wherein the processor is configured to estimate the effect by estimating amounts of power that each will be returned from the cavity through one of the radiating elements. 7 . A system according to claim 5 , wherein the processor is configured to estimate field distributions, each of which will be excited in the cavity by operating the system at a corresponding one of the plurality of sets of operating parameters, and choose the at least one set based on the estimation of the field distribution associated with the at least one set and the estimation of the effect of the at least one set on the temperature of each dummy load. 8 . A system according to claim 5 , further comprising at least one temperature sensing arrangement configured to measure the temperatures of each of the dummy loads. 9 . A system according to claim 8 , wherein the processor is configured to choose the at least one set of operating parameters based on the measured temperature of each dummy load. 10 . A system for dielectrically processing a product in a radio frequency (RF) cavity, the system comprising: an RF feeding module that is operative to feed RF energy into the cavity at various frequencies for processing the product; a dummy load, in an electromagnetically noisy space, configured to receive RF energy returning from the cavity; and a temperature sensing arrangement configured to measure the temperature of the dummy load, wherein the temperature sensing arrangement comprises: an RF filter configured to allow propagation of infrared (IR) radiation through the filter and configured so that propagation of the various frequencies through the filter is decreased by at least 10 dB; and a temperature sensor operative to measure the temperature of an object based on the amount of IR radiation that propagates through the filter and arranged with respect to the RF filter to be substantially unaffected by the electromagnetic noise in the electromagnetically noisy space. 11 . A system according to claim 10 , comprising: a processor that is operatively coupled with the RF feeding module and the temperature sensing arrangement to enable operating the RF feeding module based on the measured temperature of the dummy load. 12 . A system according to claim 11 , wherein the processor is programmed to operate the RF feeding module based on the temperature of the dummy load as measured by the temperature sensing arrangement. 13 . A system according to claim 10 , wherein the RF filter comprises electrically conductive walls defining an electrically non-conductive core, wherein the dimensions of the non-conductive core are such that propagation of frequencies of electromagnetic noise through the core is not supported while the propagation of IR radiation through the core is allowed. 14 . A system according to claim 10 , wherein the temperature sensor is arranged in an EMI-free space that is created by an electromagnetic shielding; and wherein the EMI-free space and the electromagnetically noisy space are in IR radiation communication with each other via the RF filter. 15 . A system according to claim 14 , wherein the electromagnetic shielding is configured for creating the EMI-free space. 16 . A system according to claim 14 , wherein the RF filter is in communication with the electromagnetically noisy space via an opening in the electromagnetic shielding. 17 . A system according to claim 16 , wherein the RF filter and the electromagnetic shielding are integrally formed. 18 . A system according to claim 10 , wherein the RF filter comprises an RF waveguide having a cutoff frequency above any one of the various frequencies, and length sufficient to attenuate any one of the various frequencies by at least 10 dB. 19 - 23 . (canceled) 24 . A temperature sensing arrangement for measuring the temperature of an object positioned in an electromagnetically noisy space with respect to RF frequencies, the arrangement comprising: a radiofrequency (RF) filter, wherein the RF filter is configured to allow propagation of infrared (IR) radiation through the filter and configured so that propagation of RF frequencies through the filter is substantially unsupported; and a temperature sensor operative to measure the temperature of an object based on the amount of the IR radiation that propagates through the filter and arranged with respect to the RF filter such to be substantially unaffected by the RF frequencies. 25 . The temperature sensing arrangement according to claim 24 , wherein the RF filter comprises electrically conductive walls defining an electrically non-conductive core, wherein the dimensions of the non-conductive core are such that propagation of frequencies of electromagnetic noise through the core is not supported while the propagation of IR radiation through the core is allowed. 26 . The temperature sensing arrangement of claim 24 , wherein the temperature sensor is arranged in an EMI-free space that is created by an electromagnetic shielding; and wherein the EMI-free space and the EM noisy space are in IR radiation communication with each other via the RF filter. 27 . The temperature sensing arrangement of claim 26 , wherein the electromagnetic shielding is configured for creating the EMI-free space. 28 . The temperature sensing arrangement of claim 26 , wherein the RF filter is in communication with the electromagnetically noisy space via an opening in the electromagnetic shielding. 29 . A temperature sensing arrangement according to claim 24 , wherein the RF filter comprises an RF waveguide having a cutoff frequency above any one of the various frequencies, and length sufficient to attenuate any one of the various frequencies by at least 10 dB. 30 . The temperature sensing arrangement of claim 28 , wherein the RF filter and the electromagnetic shielding are integrally formed. 31 . (canceled) 32 . A system according to claim 8 , wherein the temperature sensing arrangement measures the temperature of an object positioned in an electromagnetically noisy space with respect to radiofrequency (RF) frequencies, the arrangement comprising: an RF filter, wherein the RF filter is configured to allow propagation of infrared (IR) radiation through the filter and configured so that propagation of RF frequencies through the filter is substantially unsupported; and a temperature sensor operative to measure the temperature of an object based on the amount of the IR radiation that propagates through the filter and arranged with respect to the RF filter such to be substantially unaffected by the RF frequencies; wherein the RF filter comprises electrica