Methods and system for controlling engine airflow with an auxiliary throttle arranged in series with a venturi and in parallel with a main intake throttle

The invention claimed is: 1. A method for an engine, comprising: actuating a canister purge valve (CPV) to supply airflow to the engine via a fuel vapor canister while holding closed a main throttle and an auxiliary throttle arranged in parallel with the main throttle and in series with a venturi; and as a desired intake manifold pressure increases, progressively opening the CPV, then the auxiliary throttle, and then the main throttle to achieve the desired intake manifold pressure, wherein the venturi is an ejector, wherein the auxiliary throttle is coupled upstream of a motive flow inlet of the elector and the CPV is coupled upstream of an entraining inlet of the elector, and wherein progressively opening the CPV, then the auxiliary throttle, and then the main throttle includes not opening the auxiliary throttle until the CPV is fully open and not opening the main throttle until both the CPV and the auxiliary throttle are fully open. 2. The method of claim 1 , wherein the actuating the CPV to supply airflow to the engine via the fuel vapor canister is responsive to an engine idle condition and wherein the desired intake manifold pressure is a desired intake manifold vacuum. 3. The method of claim 2 , further comprising, in response to an air-fuel ratio of effluent of the fuel vapor canister being rich, adjusting a duty cycle of the CPV based on fueling demand at engine cylinders and, upon the effluent becoming lean, adjusting the duty cycle of the CPV to increase an amount of opening of the CPV and achieve the desired intake manifold pressure. 4. The method of claim 1 , wherein actuating the CPV to supply airflow to the engine via the fuel vapor canister is responsive to an air-fuel ratio of effluent of the fuel vapor canister being lean while an engine power demand of the engine is greater than a threshold and wherein the desired intake manifold pressure is based on the engine power demand. 5. The method of claim 1 , further comprising determining an air mass flow rate into an intake manifold of the engine to achieve the desired intake manifold pressure based on engine speed, air temperature, and air pressure and progressively opening the CPV, then the auxiliary throttle, and then the main throttle to obtain the determined air mass flow rate. 6. The method of claim 5 , further comprising, in response to the determined air mass flow rate being less than a maximum possible CPV flow rate at the desired intake manifold pressure, adjusting an open and closed duty cycle of the CPV to obtain the determined air mass flow rate while holding the auxiliary throttle and the main throttle closed. 7. The method of claim 5 , further comprising, in response to the determined air mass flow rate being greater than a maximum possible CPV flow rate at the desired intake manifold pressure, fully opening the CPV, determining a first additional air mass flow rate needed to achieve the determined air mass flow rate, and adjusting an amount of opening of the auxiliary throttle to achieve the first additional air mass flow rate, while maintaining the main throttle closed. 8. The method of claim 7 , further comprising, in response to the additional air mass flow rate needed to achieve the determined air mass flow rate being greater than a maximum possible auxiliary throttle flow rate at the desired intake manifold pressure, fully opening the CPV and the auxiliary throttle, determining a second additional air mass flow rate needed to achieve the determined air mass flow rate, and adjusting an amount of opening of the main throttle to achieve the second additional air mass flow rate. 9. A method for an engine, comprising: adjusting an opening of a canister purge valve (CPV) to supply a determined airflow rate to an intake manifold via a fuel vapor canister while holding a main throttle and an auxiliary throttle closed, the auxiliary throttle arranged in parallel with the main throttle and in series with a venturi; responsive to a maximum flow rate of the CPV being below the determined airflow rate, fully opening the CPV and increasing an opening of the auxiliary throttle to achieve the determined airflow rate; and responsive to a combination of the maximum flow rate of the CPV and a maximum flow rate of the auxiliary throttle being below the determined airflow rate, fully opening each of the CPV and the auxiliary throttle and increasing an opening of the main throttle to achieve the determined airflow rate. 10. The method of claim 9 , wherein the adjusting the opening of the CPV to supply the determined airflow rate to the intake manifold is responsive to an engine idle condition and an air-fuel ratio of effluent of the fuel vapor canister being leaner than stoichiometry. 11. The method of claim 10 , wherein the determined airflow rate to the intake manifold is an airflow rate at which a desired intake manifold vacuum during the engine idle condition is achieved and wherein the determined airflow rate is further determined based on one or more of engine speed, air temperature, and air pressure. 12. The method of claim 10 , further comprising, in response to the air-fuel ratio of the effluent being richer than stoichiometry, first adjusting the opening of the CPV to purge vapors from the fuel vapor canister to the intake manifold based on a fueling demand at the engine and then, in response to the air-fuel ratio transitioning from rich to lean, increasing the opening of the CPV and adjusting the amount of opening based on the determined airflow rate. 13. The method of claim 9 , wherein the venturi is an ejector including a motive flow inlet, an outlet, and an entraining inlet and wherein the auxiliary throttle is coupled upstream of the motive flow inlet, the CPV is coupled upstream of the entraining inlet, and the outlet is fluidly coupled to the intake manifold, downstream of the main throttle. 14. A system for an engine, comprising: a main throttle disposed in an intake passage of the engine, upstream from an intake manifold; an auxiliary throttle arranged in parallel with the main throttle and in series with a first venturi positioned downstream from the auxiliary throttle in a first passage arranged parallel with the intake passage; an evaporative emissions system including: a fuel vapor canister coupled to a fuel tank; and a first canister purge valve (CPV) disposed in a second passage fluidly coupled to each of the fuel vapor canister, the first venturi, and the intake passage, downstream of the main throttle; and a controller with computer readable instructions stored in memory for: during engine idle operation and in response to an air-fuel ratio of effluent in the fuel vapor canister being lean, closing the main throttle and the auxiliary throttle and determining a desired intake manifold vacuum and corresponding desired air mass flow rate into the intake manifold; increasing an amount of opening of the first CPV while the main throttle and the auxiliary throttle remain closed responsive to the desired air mass flow rate being less than a first threshold flow rate; fully opening the first CPV and increasing an amount of opening of the auxiliary throttle while the main throttle remains closed responsive to the desired air mass flow rate being less than a second threshold flow rate, the second threshold greater than the first threshold; and fully opening the first CPV and the auxiliary throttle, and increasing an amount of opening of the main throttle responsive to the desired air mass flow rate being less than a third threshold flow rate, the third threshold greater than the second threshold. 15. The system of claim 14 , wherein th