Method and apparatus for controlling fuel pressure

The invention claimed is: 1. A fuel system for an internal combustion engine, comprising: a fuel delivery system including a first fuel pump that is fluidly coupled to a pressure relief valve that is fluidly disposed in parallel with a second fuel pump; wherein the first fuel pump is disposed to deliver pressurized fuel to the second fuel pump in parallel with the pressure relief valve, and wherein the second fuel pump is disposed to deliver pressurized fuel to a fuel rail; and a controller, operatively connected to the first fuel pump and in communication with the internal combustion engine, the controller including an instruction set, the instruction set being executable to: characterize the first fuel pump to determine a relationship between a fuel pump speed and a fuel pump current at a setpoint pressure for the pressure relief valve; determine a target fuel pressure and a fuel flowrate for the first fuel pump; determine a feed-forward pump speed command for operating the first fuel pump based upon the target fuel pressure and the fuel flowrate; determine a closed-loop pump speed command for operating the first fuel pump based upon the target fuel pressure, the fuel flowrate and the relationship between fuel pump speed and fuel pump current of the first fuel pump at the setpoint pressure for the pressure relief valve; and control operation of the first fuel pump to deliver fuel to the second fuel pump based upon the feed-forward pump speed command and the closed-loop pump speed command. 2. The fuel system of claim 1 , wherein the fuel delivery system is configured to operate absent a fuel pressure sensor. 3. The fuel system of claim 1 , wherein the first fuel pump includes a positive-displacement fuel pumping element rotatably coupled to a multi-phase electric motor, and wherein the controller includes a fuel pump controller disposed to control the multi-phase electric motor in response to the feed-forward pump speed command and disposed to determine the closed-loop pump speed command for operating the first fuel pump. 4. The fuel system of claim 3 , wherein the fuel pump controller is disposed to determine a magnitude of electric current that is delivered to the electric motor and the fuel pump speed. 5. The fuel system of claim 1 , wherein the second fuel pump comprises a high-pressure fuel pump that is fluidly arranged in parallel with the pressure relief valve. 6. The fuel system of claim 1 , wherein the instruction set executable to control operation of the first fuel pump to deliver fuel to the high-pressure fuel pump based upon the feed-forward pump speed command and the closed-loop pump speed command comprises the instruction set executable to control the electric motor of the first fuel pump to cause the positive-displacement pumping element to operate at a final pump speed command to controllably deliver fuel to the second fuel pump at the desired pressure. 7. The fuel system of claim 1 , further comprising the instruction set being executable to intrusively characterize the first fuel pump to determine a relationship between the fuel pump speed and the fuel pump current at the setpoint pressure of the fuel system pressure relief valve. 8. The fuel system of claim 7 , wherein the instruction set being executable to characterize, via the controller, the first fuel pump to determine a relationship between a fuel pump speed and a fuel pump current at the setpoint pressure of the fuel system pressure relief valve comprises the instruction set being executable to: command an increase in the fuel pump speed and monitor the fuel pump current; and determine a point of inflection in the fuel pump current and an associated fuel pump speed. 9. The fuel system of claim 8 , wherein the instruction set being executable to determine a point of inflection in the fuel pump current comprises the instruction set being executable to subject the fuel pump current to dual low pass filtering to detect the point of inflection of the fuel pump current. 10. A fuel system for an internal combustion engine, comprising: an electrically-powered positive-displacement fuel pump; a fuel delivery system including the positive-displacement fuel pump fluidly coupled to a pressure relief valve that is arranged in parallel with a high-pressure fuel pump, wherein the high-pressure fuel pump is fluidly coupled to a fuel rail of the internal combustion engine; the fuel delivery system configured to operate absent a fuel pressure sensor; and a controller, operatively connected to the positive-displacement fuel pump and the internal combustion engine, the controller including an instruction set, the instruction set executable to: determine a relationship between a fuel pump speed and a fuel pump current for the positive-displacement fuel pump when operating the positive-displacement fuel pump at an operating point associated with a setpoint pressure for the pressure relief valve; determine a target fuel pressure and a fuel flowrate for the positive-displacement fuel pump; determine a feed-forward pump speed command for the positive-displacement fuel pump based upon the target fuel pressure and the fuel flowrate; determine a closed-loop pump speed command based upon the target fuel pressure, the fuel flowrate and the relationship between the fuel pump speed and the fuel pump current; and control operation of the positive-displacement fuel pump to deliver fuel to the second fuel pump based upon the feed-forward pump speed command and the closed-loop pump speed command. 11. The fuel system of claim 10 , wherein the positive-displacement fuel pump includes a positive-displacement fuel pumping element rotatably coupled to a multi-phase electric motor, and wherein the controller includes a fuel pump controller disposed to control the multi-phase electric motor in response to the feed-forward pump speed command and the closed-loop pump speed command. 12. The fuel system of claim 11 , wherein the fuel pump controller is disposed to determine a magnitude of electric current that is delivered to the multi-phase electric motor and determine the fuel pump speed. 13. The fuel system of claim 11 , wherein the instruction set executable to control operation of the positive-displacement fuel pump to deliver fuel to the high-pressure fuel pump based upon the feed-forward pump speed command and the closed-loop pump speed command comprises the instruction set executable to control the positive-displacement fuel pump to cause the positive-displacement pumping element to operate at a final pump speed command to controllably deliver fuel to the high-pressure fuel pump at the desired pressure. 14. The fuel system of claim 10 , further comprising the instruction set being executable to intrusively characterize the fuel pump to determine a relationship between the fuel pump speed and the fuel pump current at the setpoint pressure of the fuel system pressure relief valve. 15. The fuel system of claim 14 , wherein the instruction set being executable to characterize, via the controller, the positive-displacement fuel pump to determine a relationship between a fuel pump speed and a fuel pump current at the setpoint pressure of the fuel system pressure relief valve comprises the instruction set being executable to: command an increase in the fuel pump speed and monitor the fuel pump current; and determine a point of inflection in the fuel pump current and an associated fuel pump speed. 16. A method for controlling a fuel delivery system including a first fuel pump that is disposed to supply fuel to a second fuel pump of an internal combust