Fuel cell control system for vehicles

What is claimed is: 1. A vehicle comprising: a fuel cell including an air inlet port and an air outlet port; an air supply system including a compressor connected in fluid communication with the inlet port and a throttle valve connected in fluid communication with the outlet port; a mass air flow sensor in electric communication with the controller and located upstream of the compressor, wherein the mass air flow sensor is configured to output data indicative of the measured mass air flow; and a controller programmed to change a position of the throttle valve based on a target mass air flow, the measured mass air flow, a measured pressure, and the position of the throttle valve. 2. The vehicle of claim 1 , wherein the controller is further programmed to command a speed to the compressor based on a feedforward component derived from the measured mass air flow and a target pressure. 3. The vehicle of claim 2 , wherein commanding a speed to the compressor is further based on a feedback component derived from an error between the target pressure and the measured pressure. 4. The vehicle of claim 3 , wherein the speed commanded to the compressor is a summation of the feedforward component and the feedback component. 5. The vehicle of claim 1 further comprising a pressure sensor in electric communication with the controller and located at the inlet port, wherein the pressure sensor is configured to output data indicative of the measured pressure. 6. The vehicle of claim 1 , wherein the fuel cell further includes an anode side, a cathode side, and a membrane electrode assembly therebetween, wherein the cathode side has an internal air path in fluid communication with the inlet and outlet ports. 7. A vehicle comprising: a fuel cell including an air inlet port and an air outlet port; an air supply system including a compressor connected in fluid communication with the inlet port and a throttle valve connected in fluid communication with the outlet port; and a controller programmed to: command a speed to the compressor based on (i) a feedforward component derived from a measured mass air flow and a target pressure and (ii) a feedback component derived from an error between the target pressure and a measured pressure, and command a valve position to the throttle valve based on a dynamic feedforward component derived from a summation of (i) an error between a target mass air flow and a first estimated mass air flow and (ii) a second estimated mass air flow, wherein the first estimated mass air flow is based on the measured mass air flow, and the second estimated mass air flow is based on the measured pressure and the valve position. 8. The vehicle of claim 7 , wherein the measured mass air flow is at an inlet of the compressor. 9. The vehicle of claim 8 further comprising a mass air flow sensor in electric communication with the controller and configured to output data indicative of the measured mass air flow. 10. The vehicle of claim 7 , wherein the measured pressure is at the inlet port. 11. The vehicle of claim 10 further comprising a pressure sensor in electric communication with the controller and configured to output data indicative of the measured pressure. 12. The vehicle of claim 7 , wherein the measured mass air flow is at an inlet of the compressor, and the measured pressure is at the inlet port. 13. The vehicle of claim 7 , wherein the speed commanded to the compressor is a summation of the feedforward component and the feedback component. 14. The vehicle of claim 7 , wherein the controller is further programmed to adapt the second estimated mass air flow based on aging of the throttle valve. 15. The vehicle of claim 7 , wherein the controller is further programmed to adapt the valve position based on aging of the throttle valve. 16. The vehicle of claim 7 , wherein the fuel cell further includes an anode side, a cathode side, and a membrane electrode assembly therebetween, wherein the cathode side has an internal air path in fluid communication with the inlet and outlet ports. 17. A method of controlling air flow through a cathode side of a fuel cell, the method comprising: commanding a speed to a compressor that circulates air through the cathode, the speed being based on (i) a feedforward component derived from a measured mass air flow and a target pressure and (ii) a feedback component derived from an error between the target pressure and a measured pressure; and commanding a valve position to a throttle valve, that controls mass air flow through the cathode side, based on a dynamic feedforward component derived from a summation of (i) an error between a target mass air flow and a first estimated mass air flow and (ii) a second estimated mass air flow, wherein the first estimated mass air flow is based on the measured mass air flow, and the second estimated mass air flow is based on the measured pressure and the valve position. 18. The method of claim 17 , wherein the measured mass air flow is at an inlet of the compressor, and the measured pressure is at the inlet.