Methods and systems for starting an engine

The invention claimed is: 1. A method for a hybrid vehicle, comprising: during a first engine restart, cranking an engine via a motor with a disconnect clutch between the engine and the motor at least partially disengaged while delaying fueling of the engine until only after an engine speed is above a threshold speed and a direction of engine rotation is positive from a first time to a second, later time of the cranking, with no intermediate engine reversals, the engine fueling resumed while maintaining the disconnect clutch partially disengaged via clutch slippage; and during a second engine restart, cranking the engine via the motor with the disconnect clutch between the engine and the motor at least partially disengaged and with an intermediate engine reversal, while delaying fueling of the engine until only after the engine speed is above the threshold speed and the direction of engine rotation is positive from a third time to a fourth, later time of the cranking and after a threshold duration after the intermediate engine reversal, the engine fueling resumed while maintaining the disconnect clutch partially disengaged via clutch slippage. 2. The method of claim 1 , wherein the direction of engine rotation being positive is based on engine restart crankshaft acceleration or a derivative of the engine speed once the engine starts rotating. 3. The method of claim 1 , wherein the direction of engine rotation being positive is based on a series of engine speed readings from the first time to the second, later time having a progressively larger speed value. 4. The method of claim 1 , wherein the disconnect clutch being at least partially disengaged includes the disconnect clutch being slipped, the method further comprising, in response to the engine speed being below the threshold speed, increasing motor torque supplied from the motor to crank the engine, and decreasing clutch slippage. 5. The method of claim 4 , wherein the disconnect clutch being slipped includes a degree of slippage of the disconnect clutch being adjusted based on engine acceleration and a difference between engine speed and motor speed across the disconnect clutch to provide a desired engine speed profile, the method further comprising learning the degree of slippage during the engine restart as a function of one or more of engine age, ambient temperature, ambient humidity, and hydraulic fluid temperature. 6. The method of claim 1 , further comprising, in response to an indication of engine reversal during the cranking, further delaying the fueling; and after the engine speed is above the threshold speed and the direction of engine rotation is positive from the first time to the second, later time, fueling the engine. 7. The method of claim 6 , further comprising, after resuming fueling of the engine, fully engaging the disconnect clutch when the engine speed is at or within a threshold of an expected motor speed. 8. The method of claim 7 , wherein the expected motor speed is predicted based on an expected transmission gear selection during the engine restart. 9. The method of claim 7 , wherein the expected motor speed is predicted based on a derivative of actual motor speed after resuming fueling of the engine. 10. The method of claim 9 , further comprising adjusting fueling and/or spark to the engine based on a difference between the engine speed and the expected motor speed, and further based on a derivative of the engine speed and a derivative of the expected motor speed after resuming the fueling. 11. The method of claim 10 , wherein the adjusting includes increasing fueling and/or retarding spark timing to increase engine acceleration and reduce the difference between the engine speed and the expected motor speed when the engine speed is predicted to be lower than the expected motor speed at a time of clutch engagement; and decreasing fueling and/or advancing spark timing to decrease engine acceleration when the engine speed is predicted to be higher than the expected motor speed at the time of clutch engagement. 12. A method for a hybrid vehicle, comprising: during an engine restart, slipping a disconnect clutch between an engine and a motor while cranking the engine unfueled via the motor; when an engine speed during the cranking is above a threshold speed and engine acceleration during the cranking is indicative of positive engine rotation with no intermediate negative engine rotation, resuming fueling of the engine at a first time of the cranking, while maintaining clutch slippage; when an engine speed during the cranking is above the threshold speed and engine acceleration during the cranking is indicative of intermediate negative engine rotation, resuming the engine fueling at a second, later time of the cranking, after a duration since the negative engine rotation while the engine speed remains above the threshold speed and after the engine acceleration is indicative of positive engine rotation with no intermediate negative engine rotation, the engine fueling resumed while maintaining the clutch slippage; and adjusting engine torque responsive to a predicted motor synchronous speed. 13. The method of claim 12 , wherein the adjusting engine torque is further based on a derivative of the engine speed, and wherein the adjusting engine torque includes adjusting one or more of engine fuel, air, and spark to increase engine acceleration if the predicted motor synchronous speed is higher than a current motor speed, and decrease engine acceleration if the predicted motor synchronous speed is lower than the current motor speed. 14. The method of claim 13 , further comprising fully engaging the disconnect clutch only after the engine speed of the fueled engine matches the predicted motor synchronous speed, wherein the predicted motor synchronous speed is predicted based on an expected transmission gear selection at a time of clutch engagement, the expected transmission gear selection predicted based on vehicle speed. 15. The method of claim 12 , wherein a degree of slipping of the disconnect clutch is adjusted based on a difference between the engine speed and a motor speed during the cranking, and further based on a compression torque of the engine, the method further comprising learning disconnect clutch modulation including the degree of slipping as a function of the engine restart. 16. The method of claim 13 , wherein the engine acceleration indicative of positive engine rotation includes the engine acceleration being higher than a threshold acceleration for more than a threshold duration of the cranking. 17. The method of claim 12 , further comprising learning the slipping of the disconnect clutch at the engine restart as a function of one or more of engine age, ambient temperature, ambient humidity, and hydraulic fluid temperature. 18. A vehicle system, comprising: an electric motor; an engine; a disconnect clutch coupled in a driveline between the engine and the electric motor; vehicle wheels configured to receive propulsion power from one or more of the electric motor and the engine via the driveline; and a controller including non-transitory executable instructions for: receiving an engine restart request; and in response to the restart request, cranking the engine via the electric motor with the disconnect clutch at least partially disengaged; and when there is no intermediate engine reversal during the engine cranking, delaying fueling of the engine to a first duration since initiating the engine cranking when each of an engine speed is above a first threshold spe