Fuel cell stack temperature control

What is claimed is: 1 . A method of operating a fuel cell system, the method comprising: measuring, by a first temperature sensor, a first temperature of an oxidant upstream of a cathode ejector and downstream of a fuel cell stack; measuring, by a second temperature sensor, a second temperature of combustion byproducts downstream of a combustor; determining, by a controller, a difference between a first temperature set point and the sensed first temperature; determining, by the controller, a second temperature set point based on the difference between the first temperature set point and the sensed first temperature; determining, by the controller, a difference between the second temperature set point and the sensed second temperature; and controlling, by the controller, a mass flow rate of the oxidant through the fuel cell system to reduce the differences between: (1) the first temperature set point and the sensed first temperature; and (2) the second temperature set point and the sensed second temperature. 2 . The method of claim 1 , wherein controlling the mass flow rate of oxidant into the fuel cell system comprises controlling an output of an oxidant flow control device. 3 . The method of claim 2 , wherein the oxidant flow control device comprises a turbo generator, and wherein controlling the output of the oxidant flow control device comprises controlling a rotational speed of the turbo generator. 4 . The method of claim 3 , further comprising determining, by the controller, an oxidant flow control device set point based on the difference between the second temperature set point and the sensed second temperature and controlling the output of the oxidant flow control device using the oxidant flow control device set point. 5 . The method of claim 1 , wherein determining the difference between the first temperature set point and the sensed first temperature comprises determining, by a first proportional-integral-derivative (PID) module of the controller, the difference between the first temperature set point and the sensed first temperature. 6 . The method of claim 1 , wherein determining the second temperature set point based on the difference between the first temperature set point and the sensed first temperature comprises determining, by the first PID module of the controller, the second temperature set point based on the difference between the first temperature set point and the sensed first temperature. 7 . The method of claim 6 , wherein determining the difference between the second temperature set point and the sensed second temperature comprises determining, by a second PID module of the controller, the difference between the second temperature set point and the sensed second temperature. 8 . The method of claim 7 , further comprising determining, by the second PID module of the controller, an oxidant flow control device set point based on the difference between the second temperature set point and the sensed second temperature. 9 . The method of claim 8 , wherein controlling the mass flow rate of the oxidant through the fuel cell system comprises controlling an output of an oxidant flow control device using the oxidant flow control device set point. 10 . A fuel cell system comprising: a fuel cell stack comprising multiple fuel cells each comprising an anode and a cathode and including an oxidant inlet and an oxidant outlet; a cathode ejector comprising a motive fluid inlet, a suction fluid inlet in fluid communication with the oxidant outlet of the fuel cell stack, and a fluid outlet in fluid communication with the oxidant inlet of the fuel cell stack; a combustor including a combustion product inlet and a combustion byproduct outlet, the combustion product inlet in fluid communication with the oxidant outlet of the fuel cell stack; a first temperature sensor configured to sense a first temperature between the oxidant outlet of the fuel cell stack and the suction fluid inlet of the cathode ejector; a second temperature sensor configured to sense a second temperature downstream of the combustion byproduct outlet of the combustor; and a controller communicatively connected to the first temperature sensor and the second temperature sensor and configured to: determine a difference between a first temperature set point and the sensed first temperature; determine a second temperature set point based on the difference between the first temperature set point and the sensed first temperature; determine a difference between the second temperature set point and the sensed second temperature; and control a mass flow rate of the oxidant through the fuel cell stack, the ejector, and the combustor to reduce the differences between: (1) the first temperature set point and the sensed first temperature; and (2) the second temperature set point and the sensed second temperature. 11 . The fuel cell system of claim 10 , further comprising an oxidant flow control device in fluid communication with the cathode ejector and operable to control the mass flow rate of the oxidant through the fuel cell stack, the ejector, and the combustor. 12 . The fuel cell system of claim 11 , wherein the controller is operably connected to the oxidant flow control device and configured to control the mass flow rate of the oxidant through the fuel cell stack, the ejector, and the combustor by controlling an output of the oxidant flow control device. 13 . The fuel cell system of claim 12 , wherein the oxidant flow control device comprises a turbo generator, and wherein the controller is configured to control the output of the oxidant flow control device by controlling a rotational speed of the turbo generator. 14 . The fuel cell system of claim 12 , wherein the controller is configured to determine an oxidant flow control device set point based on the difference between the second temperature set point and the sensed second temperature and to control the output of the oxidant flow control device using the oxidant flow control device set point. 15 . The fuel cell system of claim 10 , wherein the controller comprises a first proportional-integral-derivative (PID) module configured to determine the difference between the first temperature set point and the sensed first temperature. 16 . The fuel cell system of claim 15 , wherein the first PID module is configured to determine the second temperature set point based on the difference between the first temperature set point and the sensed first temperature. 17 . The fuel cell system of claim 16 , wherein the controller comprises a second PID module configured to determine the difference between the second temperature set point and the sensed second temperature. 18 . The fuel cell system of claim 17 , wherein the second PID module is configured to determine an oxidant flow control device set point based on the difference between the second temperature set point and the sensed second temperature. 19 . The fuel cell system of claim 18 , wherein the controller is configured to control the mass flow rate of the oxidant through the fuel cell system by controlling an output of an oxidant flow control device using the oxidant flow control device set point. 20 . The fuel cell system of claim 10 , further comprising a heat exchanger having a cold side in fluid communication with the motive fluid inlet of the cathode ejector and a hot side in fluid communication with the combustion byproduct outlet of the combustor, wherein the second temperature sensor is configured t