Temperature control system and method thereof

What is claimed is: 1. A temperature control system for a device under test (DUT), comprising: a first channel, connected to a first valve to receive a first air from the first valve; a second channel, connected to a second valve to receive a second air from the second valve; a heating unit disposed downstream of the first channel and the second channel, wherein the heating unit comprises a heating element and a mixing chamber, the heating element is located in the mixing chamber, and the heating unit is adapted to heat a mixing of the first air and the second air with an input power to provide a mixing air with a temperature; a DUT chamber, disposed downstream of the heating element to receive the mixing air and configured to accommodate the DUT; a boost converter, configured to convert an alternating current (AC) power to a direct current (DC) power; a first proportional-integral-derivative (PID) controller, configured to provide a first input signal according to a difference between a first measurement signal of the heating element and a first set point, wherein the first measurement signal is indicative of an amount of power consumed by the heating element, and the first set point is indicative of a desired input power to be supplied to the heating element; at least one switching regulator, coupled to the boost converter to receive the DC power from the converter and coupled to the first PID controller to receive the first input signal, and configured to adjust the input power to the heating element; and an outlet temperature sensor and a second PID controller, wherein the outlet temperature sensor is configured to provide a second measurement signal indicative of a current outlet temperature of the mixing chamber, and the second PID controller is configured to provide a second input signal as the first set point according to a difference between the second measurement signal and a second set point indicative of a desired outlet temperature of the mixing chamber. 2. The system according to claim 1 , further comprising an electric current sensor and a voltage sensor, wherein the electric current sensor is configured to provide a current sensing signal indicative of a current supplied to the heating element, and the voltage sensor is configured to provide a voltage sensing signal indicative of a voltage applied to the heating element, and wherein the first measurement signal is generated in accordance with the current sensing signal and the voltage sensing signal. 3. The system according to claim 1 , further comprising a DUT temperature sensor and a third PID controller, wherein the DUT temperature sensor is configured to provide a third measurement signal indicative of a current temperature of the DUT, and the third PID controller is configured to provide a third input signal as the second set point according to a difference between the third measurement signal and a third set point indicative of a desired temperature of the DUT. 4. The system according to claim 1 , wherein the second air is an ambient air which is filtered, and the first air is treated by a compressor unit before flowing into the first channel. 5. The system according to claim 4 , further comprising: a main control unit, coupled to the first valve and the second valve, wherein the main control unit controls the first valve to regulate an amount of the first air flowing into the first channel, and controls the second valve to regulate an amount of the second air flowing into the second channel. 6. The system according to claim 5 , wherein the main control unit controls a temperature of the first air before the first air flows into the first channel and controls the temperature of the mixing air according to the input power, the amount of the second air, and the amount and the temperature of the first air. 7. A temperature control system for a device under test (DUT), comprising: a first channel, connected to a first valve to receive a first air from the first valve; a second channel, connected to a second valve to receive a second air from the second valve; a heating element, disposed downstream of the first channel and the second channel to heat a mixing of the first air and the second air with an input power to provide a mixing air with a temperature; a DUT chamber, disposed downstream of the heating element to receive the mixing air and configured to accommodate the DUT; a boost converter, configured to convert an alternating current (AC) power to a direct current (DC) power; a first proportional-integral-derivative (PID) controller, configured to provide a first input signal according to a difference between a first measurement signal of the heating element and a first set point, wherein the first measurement signal is indicative of an amount of power consumed by the heating element, and the first set point is indicative of a desired input power to be supplied to the heating element; at least one switching regulator, coupled to the boost converter to receive the DC power from the converter and coupled to the first PID controller to receive the first input signal, and configured to adjust the input power to the heating element; and a DUT temperature sensor and a third PID controller, wherein the DUT temperature sensor is configured to provide a third measurement signal indicative of a current temperature of the DUT, and the third PID controller is configured to provide a third input signal as the first set point according to a difference between the third measurement signal and a third set point indicative of a desired temperature of the DUT. 8. A temperature control system for a device under test (DUT), comprising: a first channel, connected to a first valve to receive a first air from the first valve; a second channel, connected to a second valve to receive a second air from the second valve; a heating element, disposed downstream of the first channel and the second channel to heat a mixing of the first air and the second air with an input power to provide a mixing air with a temperature; a DUT chamber, disposed downstream of the heating element to receive the mixing air and configured to accommodate the DUT; a boost converter, configured to convert an alternating current (AC) power to a direct current (DC) power; a first proportional-integral-derivative (PID) controller, configured to provide a first input signal according to a difference between a first measurement signal of the heating element and a first set point, wherein the first measurement signal is indicative of an amount of power consumed by the heating element, and the first set point is indicative of a desired input power to be supplied to the heating element; at least one switching regulator, coupled to the boost converter to receive the DC power from the converter and coupled to the first PID controller to receive the first input signal, and configured to adjust the input power to the heating element, wherein the at least one switching regulator is configured to adjust the input power according to the first input signal, and wherein the at least one switching regulator includes a plurality of switching regulators, each of the regulators has a different voltage step size and provides a corresponding different output power. 9. The system according to claim 8 , wherein a sum of output powers of the plurality of switching regulators is substantially equal to the desired input power to the heating element. 10. A temperature control system for a device under test (DUT), comprising: a first channel, connected to a first valve to receive a first air from the first valve; a second channel, connected to a second valve to receive a second air from the second va