Systems and methods for controlling a heat transfer system

What is claimed is: 1 . A flame sensing system comprising: a flame sense probe; a power regulating device electrically coupled to the flame sense probe and configured to: generate a regulated voltage from an input voltage received from a power source; and output the regulated voltage to the flame sense probe as a dynamic signal having a substantially square or sinusoidal wave form at a frequency higher than 60 Hz and up to approximately 500 Hz; a flame current detector electrically coupled to the power regulating device and the flame sense probe, the flame current detector configured to measure a flame current and generate an output voltage corresponding to the flame current; a first level detector electrically coupled to the flame current detector, the first level detector configured to generate a flame strength output signal based on the output voltage, wherein the flame strength output signal is indicative of a strength of a flame located proximate the flame sense probe; a second level detector electrically coupled to the flame current detector, the second level detector configured to generate a flame presence output signal based on comparison of the output voltage to a pre-determined presence threshold, wherein the flame presence output signal is indicative of a presence or an absence of the flame proximate the flame sense probe, and a processor electrically coupled to the first level detector and the second level detector and configured to concurrently receive the flame strength output signal from the first level detector and the flame presence output signal from the second level detector, wherein the second level detector has a different sensitivity characteristic than the first level detector so that the flame presence output signal is different from the flame strength output signal. 2 . The flame sensing system of claim 1 , wherein the power regulating device is configured to output the regulated voltage to the flame sense probe at a frequency higher than 400 Hz and up to approximately 500 Hz, and wherein the first level detector is configured to generate the flame strength output signal based on comparison of the output voltage to a pre-determined strength threshold. 3 . The flame sensing system of claim 1 , further comprising a third level detector configured to generate a diagnostic output signal based on comparison of the output voltage to a pre-determined diagnostic threshold level, wherein the diagnostic output signal is indicative of an operationality of the flame sensing system. 4 . The flame sensing system of claim 3 , wherein the processor is further electrically coupled to the third level detector, and wherein the processor is further configured to: receive the diagnostic output signal from the third level detector; monitor a change in the flame current, a change in the flame strength output signal, a change in the flame presence output signal, and/or a change in the diagnostic output signal; and generate a digital output indicative of working condition of the flame sensing device and/or a flame status indicative of the strength of the flame; and a display unit electrically coupled to the processor and configured to display the digital output. 5 . The flame sensing system of claim 1 , further comprising a peak detector configured to generate an analog secondary flame strength output signal based on the output voltage, wherein the analog secondary flame strength output signal provides an analog indication of the strength of the flame. 6 . The flame sensing system of claim 1 , wherein the power regulating device comprises a rectifier and a regulated inverter configured to generate the regulated voltage from the input voltage received from the power source and to output the flame current. 7 . The flame sensing system of claim 3 , wherein the third level detector has a different sensitivity characteristic than the first level detector and the second level detector so that the diagnostic output signal is different from the flame presence output signal and the flame strength output signal. 8 . A flame sensing unit comprising: a flame sense probe; a flame sensing device comprising: a power regulating device electrically coupled to the flame sense probe and configured to: generate a regulated voltage from an input voltage received from a power source; and output the regulated voltage to the flame sense probe as a dynamic signal having a substantially square or sinusoidal wave form at a frequency higher than 60 Hz and up to approximately 500 Hz; a flame current detector electrically coupled to the power regulating device and the flame sense probe, the flame current detector being configured to: detect a flame current from the flame sense probe; and generate an output voltage corresponding to the flame current; and a first level detector electrically coupled to the flame current detector and configured to generate a flame strength output signal based on the output voltage; a second level detector electrically coupled to the flame current detector and configured to generate a flame presence output signal based on a comparison of the output voltage to a pre-determined presence threshold; and a processor electrically coupled to the first level detector and the second level detector and configured to: concurrently receive the flame strength output signal and the flame presence output signal; and generate an output indicative of a strength and either a presence or an absence of a flame located proximate the flame sense probe, wherein the second level detector has a different sensitivity characteristic than the first level detector so that the flame presence output signal is different from the flame strength output signal. 9 . The flame sensing unit of claim 8 , wherein the first level detector is configured to generate the flame strength output signal based on comparison of the output voltage to a pre-determined strength threshold. 10 . The flame sensing unit of claim 8 further comprising a third level detector configured to generate a diagnostic output signal indicative of an operationality of the flame sensing unit. 11 . The flame sensing unit of claim 10 , wherein the third level detector has a different sensitivity characteristic than the first level detector and the second level detector so that the diagnostic output signal is different from the flame presence output signal and the flame strength output signal. 12 . The flame sensing unit of claim 10 , wherein the third level detector is configured to generate the diagnostic output signal based on comparison of the output voltage to a pre-determined diagnostic threshold. 13 . The flame sensing unit of claim 8 further comprising a peak detector to generate an analog secondary flame strength output signal, wherein the analog secondary flame strength output signal provides an analog indication of a strength of the flame. 14 . The flame sensing unit of claim 8 , wherein the power regulating device comprises a rectifier and a regulated inverter to generate the regulated voltage from the input voltage and to output the regulated voltage. 15 . A method of sensing a flame comprising: generating, by a power regulating device, a regulated voltage from an input voltage received from a power source, wherein the power regulating device is configured to output the regulated voltage as a dynamic signal having a substantially square or sinusoidal wave form at a frequency higher than 60 Hz and up to approximately 500 Hz; providing the regulated voltage to a flame current detector; providing the regulated voltag