Power converter for a thermal system

What is claimed is: 1. A control system for controlling an output voltage provided to a heater, the control system comprising: a controller configured to: determine an input parameter based on an electrical characteristic of the heater, wherein the heater includes a resistive heating element that is operable to emit heat and operable as a sensor, wherein the input parameter includes data indicative of a temperature of the resistive heating element that is determined based on the electrical characteristic, wherein the heater is configured to operate in a plurality of operational states comprising a start-up mode, a soft-start mode, a rate mode, and a hold mode, determine an operational state of the heater to be at least one of the start-up mode, the soft-start mode, the rate mode, and the hold mode based on the input parameter, wherein each of the start-up mode, the soft-start mode, the rate mode, and the hold mode has one or more unique settings to create a programmable state machine, wherein the start-up mode is a mode in which power is being supplied to measure voltage and current, the soft-start mode is a mode in which the power is increased at a ramp rate until a specific resistance setpoint is passed, the rate mode is a mode in which the temperature is increased at a ramp rate selected based on a material of the heater, and the hold mode is a mode in which the temperature of the heater is controlled to a specific setpoint, determine the output voltage for the heater based on the input parameter and a desired setpoint using the programmable state machine, wherein the desired setpoint is based on the operational state of the heater, transmit a signal to a power converter to generate the output voltage, and control the heater based on the signal to the power converter. 2. The control system of claim 1 further comprising the power converter including a power switch and operable to generate the output voltage. 3. The control system of claim 2 , wherein the power converter includes: the power switch configured to generate the output voltage; and a driver circuit configured to operate the power switch to generate the output voltage. 4. The control system of claim 1 further comprising a sensor circuit configured to measure the electrical characteristic of the heater. 5. The control system of claim 1 , wherein the electrical characteristic includes at least one of a voltage and an electric current of the heater. 6. The control system of claim 1 further comprising: the power converter electrically coupled to the heater by way of temperature sensing power pins that define a first junction and a second junction; and a sensor circuit configured to electrically couple to the first junction and the second junction, wherein the controller is configured to measure a change in voltage at the first junction and the second junction, as the electrical characteristic, via the sensor circuit and determine the temperature of the resistive heating element, as the input parameter, based on the change in voltage. 7. The control system according to claim 1 , wherein the desired setpoint includes at least one of a desired power level, a desired temperature, a rate of change in temperature, and a rate in change of power. 8. The control system of claim 1 , wherein the controller is configured to select the operational state from among the plurality of defined operational states, and wherein each operational state defines a next state that is entered in response to an input condition being met. 9. The control system of claim 8 , wherein the controller is configured to independently control a plurality of heating elements of the heater based on the operational state, and wherein a model-based control uses the programmable state machine to match process ID (PID) proportional-integral-derivative states to system states. 10. The control system of claim 8 , wherein the controller is configured to perform a model-based control routine to match a proportional-integral derivative state of the heater to the operational state. 11. The control system of claim 1 , wherein: a sensor circuit is configured to measure a voltage and an electric current of the heater, as the electrical characteristic, and the controller is configured to: calculate a resistance of the resistive heating element, as the input parameter, based on the voltage and the electric current, determine the temperature of the resistive heating element based on the resistance, and set the output voltage based on the temperature, the resistance, the voltage, the electric current or a combination thereof, wherein the input parameter includes data indicative of at least one of the resistance, the voltage, and the electric current of the resistive heating element. 12. The control system of claim 1 , wherein the input parameter includes data indicative of at least one of a resistance, an electric current, and a voltage of the resistive heating element. 13. The control system of claim 1 , wherein the controller is configured to: calculate a resistance of the resistive heating element, as the input parameter, based on a voltage and an electric current of the resistive heating element, as the electrical characteristic, determine the temperature of the resistive heating element based on the resistance, and set the output voltage based on the temperature, the resistance, the voltage, the electric current, or a combination thereof. 14. The control system of claim 1 , wherein the controller is configured to continuously vary an amplitude of the output voltage based on a desired power of the heater. 15. The control system of claim 1 further comprising: the power converter including a power switch and operable to generate an adjustable output voltage; and a sensor circuit configured to measure the electrical characteristics of the heater, wherein the electrical characteristics includes at least one of a voltage and an electric current, and wherein the controller is configured to operate the power switch of the power converter to generate the output voltage. 16. A method for controlling a heater, the method comprising: measuring, by a processor, at least one of a voltage and an electric current of the heater, wherein the heater includes a resistive heating element that is operable to emit heat and operable as a sensor; determining, by the processor, an input parameter based on the at least one of the voltage and the electric current, wherein the input parameter includes data indicative of a temperature of the resistive heating element; wherein the heater is configured to operate in a plurality of operational states comprising a start-up mode, a soft-start mode, a rate mode, and a hold mode, determining, by the processor, an operational state of the heater to be at least one of the start-up mode, the soft-start mode, the rate mode, and the hold mode based on the input parameter, wherein each of the start-up mode, the soft-start mode, the rate mode, and the hold mode has one or more unique settings to create a programmable state machine; wherein the start-up mode is a mode in which power is being supplied to measure voltage and current, the soft-start mode is a mode in which the power is increased at a ramp rate until a specific resistance setpoint is passed, the rate mode is a mode in which the temperature is increased at a ramp rate selected based on a material of the heater, and the hold mode is a mode in which the temperature of the heater is controlled to a specific setpoint, setting, by the processor, an output voltage for the heater based on the input paramete