Systems and methods for controlling a fuel pump in start/stop and hybrid electric vehicles

The invention claimed is: 1. A method, comprising: propelling a vehicle at least in part by an engine that combusts fuel provided to the engine via a fuel pump; controlling fuel injection to one or more engine cylinders via one or more fuel injectors; monitoring the engine for a potential stall condition while the engine is combusting fuel; and controlling the fuel pump at a fuel shut-off event based on whether the potential stall condition is indicated, where controlling the fuel pump includes stopping the fuel pump responsive to a pressure in a fuel rail above a predetermined fuel rail pressure threshold and further responsive to the potential stall condition not being indicated, the pressure in the fuel rail monitored responsive to the fuel shut-off event and where the fuel pump is configured to provide pressurized fuel to the fuel rail prior to the fuel being delivered to the one or more fuel injectors. 2. The method of claim 1 , further comprising: monitoring acceleration of a crankshaft coupled to one or more pistons of the engine via a crankshaft sensor; and wherein the potential stall condition includes one of at least multiple misfire events, and loss of engine torque, where misfire events and loss of engine torque are indicated via the crankshaft sensor. 3. The method of claim 1 , further comprising; routing exhaust gas generated by the engine combusting fuel to an exhaust manifold; indicating an exhaust gas air/fuel ratio via an exhaust gas oxygen sensor; and wherein the potential stall condition includes an indication of a disturbance to the exhaust gas air/fuel ratio. 4. The method of claim 1 , wherein the potential stall condition further comprises: indicating one of at least a barometric pressure change rate greater than a predetermined barometric pressure change rate threshold, or indicating that the vehicle has been operating above a predetermined altitude for a predetermined amount of time; wherein barometric pressure or altitude is indicated via one of at least a pressure sensor positioned in an air intake manifold of the engine, an onboard navigation system, and wireless communication via the internet. 5. The method of claim 1 , wherein the potential stall condition further comprises: indicating whether temperature of the fuel provided to the engine is above a predetermined fuel temperature threshold; wherein fuel temperature is indicated via one of at least a fuel tank temperature sensor positioned in a fuel tank, and an indication of air mass consumed by the engine during a drive cycle. 6. The method of claim 1 , wherein the fuel shut-off event further comprises: stopping fuel injection to the one or more engine cylinders by commanding the one or more fuel injectors to stop injection of fuel. 7. The method of claim 1 , wherein controlling the fuel pump at the fuel shut-off event based on whether the potential stall condition is indicated further comprises: maintaining power to the fuel pump responsive to the pressure in the fuel rail below the predetermined fuel rail pressure threshold, and further responsive to the potential stall condition not being indicated. 8. The method of claim 7 , wherein maintaining power to the fuel pump includes controlling a fuel pump speed; wherein the fuel pump speed is controlled as a function of indicated pressure in the fuel rail; and wherein the fuel pump is stopped responsive to the pressure in the fuel rail reaching the predetermined fuel rail pressure threshold during the fuel shut-off event. 9. The method of claim 1 , wherein controlling the fuel pump at the fuel shut-off event based on whether the potential stall condition is indicated includes: maintaining power to the fuel pump responsive to the potential stall condition being indicated, and independent of the pressure in the fuel rail. 10. The method of claim 9 , wherein maintaining power to the fuel pump includes controlling fuel pump speed to a minimum speed, where the minimum speed comprises a lowest amount of power provided to the fuel pump that maintains fuel flowing across the fuel pump. 11. The method of claim 1 , wherein the fuel shut-off event comprises an idle stop event, or a deceleration fuel shut off (DFSO) event; wherein the idle stop event includes at least depression of a brake pedal by a vehicle operator to bring the vehicle to a stop; wherein the DFSO event includes at least release of an accelerator pedal; and wherein the engine is spun down to rest during the idle stop event, but wherein the engine continues to operate without fueling during the DFSO event. 12. A system for a vehicle, comprising: a fuel tank; a fuel rail; an electric fuel pump, configured to supply pressurized fuel from the fuel tank to the fuel rail; an onboard power supply, removably electrically coupled to the electric fuel pump; a combustion engine, with one or more cylinders, an intake manifold, and an exhaust manifold; one or more fuel injectors, configured to receive pressurized fuel from the fuel rail and supply fuel to the one or more cylinders; a fuel rail pressure sensor; and a controller storing instructions in non-transitory memory, that when executed, cause the controller to: responsive to a deceleration fuel shut off (DFSO) event, while the engine continues to spin without fuel injection to the one or more cylinders, maintain power to the fuel pump responsive to fuel rail pressure below a fuel rail pressure threshold at a time when fuel injection is stopped; and responsive to an engine idle stop, where the engine spins down to rest, maintain power to the electric fuel pump responsive to an indication of combustion instability before the engine idle stop, even if the fuel rail pressure is above the fuel rail pressure threshold. 13. The system of claim 12 , further comprising: a crankshaft coupled to one or more pistons; a crankshaft sensor; an exhaust gas oxygen sensor positioned in the exhaust manifold; a mass air flow sensor positioned in the intake manifold; a manifold air pressure sensor positioned in the intake manifold; wherein the controller further stores instructions in non-transitory memory, that when executed, cause the controller to: prior to commencing the DFSO event or the engine idle stop; monitor acceleration of the crankshaft via the crankshaft sensor; indicate an exhaust gas air/fuel ratio via the exhaust gas oxygen sensor; indicate barometric pressure via the manifold air pressure sensor; indicate a fuel temperature of fuel in the fuel tank as a function of total air mass consumed by the engine during a drive cycle via the mass air flow sensor; and wherein indicating combustion instability comprises one or more of at least: multiple misfire events and loss of engine torque, where misfire events and loss of engine torque are indicated via the crankshaft sensor; a barometric pressure change rate greater than a predetermined barometric pressure change rate threshold, or an indication that the vehicle has been operating above a predetermined altitude for a predetermined amount of time; and the fuel temperature of the fuel provided to the engine above a predetermined fuel temperature threshold. 14. The system of claim 12 , wherein the controller further stores instructions in non-transitory memory, that when executed, cause the controller to: indicate an absence of combustion instability in a drive cycle before the DFSO event, where the indicated absence of combustion instability and the DFSO event occur in the same drive cycle; control a fuel pump duty cycle to increase the fuel rail pressure in the fuel rail to above the predeterm