Fuel pump with quiet rotating suction valve

The invention claimed is: 1. A fuel system for an engine, comprising: a cam-driven fuel pump including a plunger and a pump chamber surrounded by a pump housing, the pump housing including an inlet and an outlet; a cam driving the cam-driven fuel pump; a fuel injector in fluidic communication with the outlet; a motor-driven metering valve positioned at the inlet of the pump housing, the motor-driven metering valve including a metering valve chamber, a shaft, an orifice extending through the shaft, and a valve body arranged entirely within the metering valve chamber, the valve body having a passage passing through its length which is perpendicular to an axis of rotation of the shaft, the shaft extending through the passage, and the orifice positioned perpendicular to the passage when the motor-driven metering valve is closed, wherein an outlet of the passage is in communication with the inlet of the pump housing even when the motor-driven metering valve is closed; a motor in mechanical communication with the motor-driven metering valve; and a controller including instructions stored in a non-transitory medium to: rotate the motor synchronously with the cam; adjust a phase of rotation of the motor relative to a phase of rotation of the cam; during a pumping phase of the cam-driven fuel pump in which the plunger moves in a direction to decrease volume in the pump chamber, open and close the motor-driven metering valve by rotating the orifice via rotation of the motor; and for the entirety of a suction phase of the cam-driven fuel pump in which the plunger moves in a direction to increase volume in the pump chamber, maintain the motor-driven metering valve open, wherein the controller includes further instructions to open and close the motor-driven metering valve a plurality of times during the pumping phase of the cam-driven fuel pump. 2. The fuel system of claim 1 , wherein the valve body includes a plurality of seals in communication with the shaft. 3. The fuel system of claim 1 , where the motor is a stepper motor. 4. The fuel system of claim 1 , wherein opening and closing the motor-driven metering valve by rotating the orifice via rotation of the motor comprises selectively opening and closing the passage via rotation of the shaft. 5. The fuel system of claim 4 , wherein opening the passage comprises rotating the shaft 90 degrees. 6. The fuel system of claim 1 , wherein the pumping phase comprises a spill phase followed by an output phase, wherein the controller includes further instructions to maintain the motor-driven metering valve open during the entirety of the suction phase and close the motor-driven metering valve during the entirety of the output phase, and wherein during the spill phase, fuel in the pump chamber is pushed into the metering valve chamber. 7. A method for a fuel system of an engine, comprising: rotating a motor synchronously with a cam of a cam-driven fuel pump, wherein the motor is in mechanical communication with a motor-driven metering valve, wherein the cam-driven fuel pump includes the cam, a plunger, and a pump chamber surrounded by a pump housing, the pump housing including an inlet and an outlet, wherein the motor-driven metering valve is positioned at the inlet of the pump housing and includes a metering valve chamber, a shaft, an orifice extending through the shaft, and a valve body arranged entirely within the metering valve chamber, wherein the valve body has a passage passing through its length, wherein the shaft extends through the passage, wherein the orifice is positioned perpendicular to the passage when the motor-driven metering valve is closed, wherein an outlet of the passage is in communication with the inlet of the pump housing even when the motor-driven metering valve is closed, and wherein a fuel injector is in fluid communication with the outlet of the pump housing; adjusting a phase of rotation of the motor relative to a phase of rotation of the cam; rotating the orifice via rotation of the motor to control fuel flow to the cam-driven fuel pump; and adjusting an opening timing and a closing timing of the motor-driven metering valve relative to a position of the plunger, including opening and closing the motor-driven metering valve a plurality of times while the plunger moves in a direction to decrease volume in the pump chamber, and maintaining the motor-driven metering valve open for the entire time that the plunger moves in a direction to increase volume in the pump chamber. 8. The method of claim 7 , wherein the cam-driven fuel pump is in mechanical communication with an engine camshaft. 9. The method of claim 7 , further comprising adjusting the closing timing of the motor-driven metering valve in response to operating conditions of the engine. 10. The method of claim 7 , further comprising adjusting the opening timing of the motor-driven metering valve to when the plunger is substantially at a maximum lift amount. 11. The method of claim 7 , further comprising varying the closing timing of the motor-driven metering valve while the plunger moves in the direction to decrease volume in the pump chamber. 12. The method of claim 7 , further comprising maintaining the motor-driven metering valve open during part of the movement of the plunger in the direction to decrease volume in the pump chamber, such that fuel in the pump chamber is pushed into the metering valve chamber. 13. A fuel system for an engine, comprising: a cam-driven fuel pump including a cam, a plunger, and a pump chamber surrounded by a pump housing, the pump housing including an inlet and an outlet; a fuel injector in fluidic communication with the outlet; a motor-driven metering valve positioned at the inlet of the pump housing, the motor-driven metering valve including a metering valve chamber, a shaft, an orifice extending through the shaft, and a valve body arranged entirely within the metering valve chamber, the valve body having a passage passing through its length which is perpendicular to an axis of rotation of the shaft, the shaft extending through the passage, and the orifice positioned perpendicular to the passage when the motor-driven metering valve is closed, wherein an outlet of the passage is in communication with the inlet of the pump housing even when the motor-driven metering valve is closed; a motor coupled to the motor-driven metering valve; and a controller including instructions stored in a non-transitory medium to: rotate the motor synchronously with the cam; operate the motor in response to a fuel pressure, including adjusting a phase of rotation of the motor relative to a phase of rotation of the cam in response to the fuel pressure; and rotate the orifice via rotation of the motor to control fuel flow to the cam-driven fuel pump, including maintaining the orifice in a position in which the motor-driven metering valve is open during the entirety of a suction phase of the cam-driven fuel pump in which the plunger moves in a direction to increase volume in the pump chamber, wherein the controller includes further instructions to open and close the motor-driven metering valve at least twice during a pumping phase of the cam-driven fuel pump in which the plunger moves in a direction to decrease volume in the pump chamber. 14. The fuel system of claim 13 , where the controller includes further instructions to advance a closing timing of the motor-driven metering valve in response to the fuel pressure being lower than a desired fuel pressure. 15. The fuel system of claim 14 , where the controller includes further instructions to retard the closing timing of th