Common shut-off valve for actuator vacuum at low engine power and fuel vapor purge vacuum at boost

The invention claimed is: 1. A vehicle system, comprising: an ejector in a compressor recirculation passage and an aspirator in a throttle bypass passage; and a canister purge valve having first and second outlets, a single flow restriction arranged in a first passage coupling a solenoid with the first outlet leading to an intake manifold, and a second passage having no flow restriction coupling the solenoid with the second outlet which leads to a suction port of the ejector. 2. The system of claim 1 , further comprising a common passage having a first end coupled with an intake passage downstream of a compressor and upstream of a throttle and a second end coupled with the compressor recirculation passage and the throttle bypass passage at a juncture of the compressor recirculation passage and the throttle bypass passage. 3. The system of claim 2 , further comprising a common shut-off valve for the aspirator and ejector arranged in the common passage, a first check valve arranged in the compressor recirculation passage between a motive inlet of the ejector and the juncture of the compressor recirculation passage and the throttle bypass passage, and a second check valve arranged in the throttle bypass passage between a motive inlet of the aspirator and the juncture of the compressor recirculation passage and the throttle bypass passage. 4. The system of claim 3 , further comprising a vacuum reservoir coupled with a suction port of the aspirator via a third passage, and a fourth passage coupling the third passage with the intake manifold, wherein the fourth passage forms part of the throttle bypass passage and communicates with a mixed flow outlet of the aspirator. 5. The system of claim 4 , further comprising a fifth passage coupling the second outlet of the canister purge valve with the third passage upstream of the suction port of the aspirator. 6. An engine method, comprising: opening a solenoid arranged in a canister purge valve which has only one flow restriction, the flow restriction arranged in a first passage coupling the solenoid with a first outlet of the canister purge valve which leads to an intake manifold; enabling motive flow through an ejector arranged in a compressor recirculation passage, the ejector having a suction port receiving flow from a second outlet of the canister purge valve, the solenoid coupled with the second outlet via a second passage which does not include a flow restriction; and enabling motive flow through an aspirator arranged in a throttle bypass passage, the aspirator having a suction port coupled with a vacuum reservoir. 7. The method of claim 6 , wherein enabling motive flow through the ejector comprises enabling motive flow through the ejector after turbocharger spin-up is completed. 8. The method of claim 7 , wherein enabling motive flow through the ejector further comprises disabling motive flow through the ejector while a turbocharger is spinning up. 9. The method of claim 6 , wherein enabling motive flow through the aspirator comprises enabling motive flow through the aspirator if a level of stored vacuum in the vacuum reservoir is less than a desired level of stored vacuum. 10. The method of claim 9 , wherein enabling motive flow through the aspirator further comprises disabling motive flow through the aspirator if the level of stored vacuum in the vacuum reservoir is not less than the desired level of stored vacuum and an estimated mass air flow into an engine which would result from enabling motive flow through the aspirator is greater than a desired mass air flow into the engine. 11. The method of claim 10 , wherein if the level of stored vacuum in the vacuum reservoir is not less than the desired level of stored vacuum and the estimated mass air flow into the engine which would result from enabling motive flow through the aspirator is not greater than the desired mass air flow into the engine, enabling and disabling motive flow through the aspirator based on engine operating conditions. 12. An engine method, comprising: enabling vacuum generation at a suction port of an ejector arranged in a compressor recirculation flow path if spin-up of a turbocharger compressor is completed, the suction port of the ejector coupled with a canister purge valve having a first outlet and a second outlet, the suction port of the ejector coupled with the second outlet, wherein flow from a fuel vapor purge system to the ejector suction port via the second outlet does not undergo any restriction upstream of the suction port of the ejector, and wherein flow from the fuel vapor purge system is restricted intermediate a solenoid of the canister purge valve and the first outlet; and enabling vacuum generation at a suction port of an aspirator arranged in a throttle bypass flow path if a level of stored vacuum is below a threshold. 13. The method of claim 12 , further comprising opening the solenoid when vacuum generation at the suction port of the ejector is enabled. 14. The method of claim 12 , wherein enabling vacuum generation at the suction port of the ejector comprises opening a first two-way shut-off valve arranged upstream of a motive inlet of the ejector in the compressor recirculation flow path. 15. The method of claim 14 , wherein enabling vacuum generation at the suction port of the aspirator comprises opening a second two-way shut-off valve arranged upstream of a motive inlet of the aspirator in the throttle bypass flow path. 16. The method of claim 15 , wherein the first and second shut-off valves are controlled by a common actuator, and wherein the common actuator controls both the first and second shut-off valves to a same state such that the first and second shut-off valves are either both open or both closed. 17. The method of claim 15 , wherein the first and second shut-off valves are controlled by a common actuator, and wherein the common actuator controls the first and second shut-off valves to opposite states, such that the first shut-off valve is open when the second shut-off valve is closed and the second shut-off valve is open when the first shut-off valve is closed. 18. The method of claim 14 , wherein the first and second shut-off valves are each controlled by a dedicated actuator, such that the vacuum generation may be enabled at none, one, or both of the ejector and aspirator via control of the first and second shut-off valves by their respective dedicated actuators. 19. The method of claim 12 , wherein enabling vacuum generation at the suction port of the ejector comprises controlling an actuator to adjust a three-way shut-off valve arranged at a juncture of the compressor recirculation flow path and the throttle bypass flow path to open a flow path from downstream of the compressor to a motive inlet of the ejector, wherein enabling vacuum generation at the suction port of the aspirator comprises controlling the actuator to adjust the three-way shut-off valve to open a flow path from downstream of the compressor to a motive inlet of the aspirator, and wherein vacuum generation cannot be enabled at both suction ports concurrently. 20. The method of claim 12 , wherein enabling vacuum generation at the suction port of the ejector comprises controlling an actuator to adjust a two-way shut-off valve arranged upstream of the suction port of the ejector and the suction port of the aspirator, wherein vacuum generation at the suction port of the aspirator is also enabled whenever vacuum generation at the suction port of the ejector is enabled, and wherein a first check valve is arrang