Method and system for vacuum generation using a throttle

The invention claimed is: 1. A method for an engine, comprising: responsive to an increase in vacuum demand, adjusting a hollow throttle plate with a perforated edge to a more closed position and, responsive to the adjusting the hollow throttle plate to the more closed position, adjusting an engine operating parameter; and generating vacuum via intake airflow past the perforated edge of the hollow throttle plate. 2. The method of claim 1 , wherein adjusting the hollow throttle plate to the more closed position includes creating a constricted passage between an inside edge of an intake conduit of the engine in which the hollow throttle plate is positioned and the perforated edge of the hollow throttle plate, wherein generating vacuum via intake airflow past the perforated edge includes generating vacuum via intake airflow through the constricted passage, and further comprising applying the generated vacuum to a vacuum consumption device fluidly coupled to the hollow throttle plate via a hollow shaft, the vacuum consumption device including a brake booster. 3. The method of claim 2 , further comprising, during the applying of generated vacuum, flowing air from the vacuum consumption device through perforations of the perforated edge of the hollow throttle plate into the intake airflow past the perforated edge. 4. The method of claim 3 , wherein the hollow throttle plate is moved towards the more closed position as the vacuum demand of the vacuum consumption device increases; and wherein adjusting the hollow throttle plate to the more closed position is further responsive to determining that engine conditions permit a more closed throttle position, where if it is determined that engine conditions do not permit the more closed throttle position, the hollow throttle plate is not moved to the more closed position. 5. The method of claim 4 , wherein adjusting the engine operating parameter is performed to maintain engine torque output as the hollow throttle plate is moved toward the more closed position; and wherein determining that engine conditions permit the more closed throttle position is based on one or more of an engine speed and an acceleration. 6. The method of claim 5 , wherein the engine is a turbocharged engine including a turbocharger and a boost chamber arranged downstream of a compressor of the turbocharger, where the hollow throttle plate controls intake airflow from the boost chamber to an intake manifold of the engine, wherein the engine operating parameter includes boost pressure of the boost chamber, the boost pressure supplied by the turbocharger, and wherein the adjusting includes increasing boost pressure as the hollow throttle plate is moved towards the more closed position. 7. The method of claim 6 , wherein increasing boost pressure includes reducing an opening of a wastegate coupled across an exhaust turbine of the turbocharger. 8. The method of claim 5 , wherein the engine operating parameter includes exhaust gas recirculation (EGR), and wherein the adjusting includes decreasing a rate of EGR as the hollow throttle plate is moved towards the more closed position. 9. The method of claim 5 , wherein the engine operating parameter comprises intake valve timing, and wherein the adjusting includes increasing a duration of intake valve opening as the hollow throttle plate is moved towards the more closed position. 10. The method of claim 3 , further comprising adjusting one or more of a fuel injection amount and fuel injection timing based on each of the intake airflow past the perforated edge and the air flowing from the vacuum consumption device through the hollow throttle plate into the intake airflow to maintain engine combustion at or around stoichiometry. 11. A system comprising: an engine including an intake conduit; a hollow throttle plate mounted on a hollow shaft positioned in the intake conduit, the hollow throttle plate having a plurality of perforations along its circumference, the perforations being located on both a top edge and a bottom edge of the hollow throttle plate, where the top edge and the bottom edge are arranged on opposite sides of a rotational axis of the hollow throttle plate; and a controller with computer-readable instructions stored in non-transitory memory for: in response to an increase in vacuum demand, adjusting a position of the hollow throttle plate to a more closed position to generate vacuum at the hollow throttle plate as intake air flows past the perforated top and bottom edges of the hollow throttle plate and through a constricted passage created between each of the perforated top and bottom edges and an inside surface of the intake conduit. 12. The system of claim 11 , further comprising a vacuum consumption device, wherein the hollow shaft of the hollow throttle plate is fluidly coupled to the vacuum consumption device, and wherein the controller includes further instructions for applying the generated vacuum to the vacuum consumption device; and wherein the perforations located on the top edge of the hollow throttle plate are diametrically opposed to the perforations located on the bottom edge of the hollow throttle plate and wherein, when the position of the hollow throttle plate is adjusted to the more closed position, a first constricted passage is formed between the top edge and a top edge of the inside surface of the intake conduit and a second constricted passage is formed between the bottom edge and a bottom edge of the inside surface of the intake conduit. 13. A system comprising: an engine including an intake; a hollow throttle plate mounted on a hollow shaft positioned in the intake, the hollow throttle plate having a plurality of perforations along its circumference, the perforations being located on both a top edge and a bottom edge of the hollow throttle plate, where the perforations located on the top edge of the hollow throttle plate are diametrically opposed to the perforations located on the bottom edge of the hollow throttle plate; a vacuum consumption device, wherein the hollow shaft of the hollow throttle plate is fluidly coupled to the vacuum consumption device; and a controller with computer-readable instructions stored in non-transitory memory for: in response to vacuum demand, adjusting a position of the hollow throttle plate to generate vacuum at the hollow throttle plate as intake air flows past the perforated edges, wherein the adjusting is in response to a vacuum demand of the vacuum consumption device, the controller configured to move the hollow throttle plate towards a more closed position to increase vacuum generation at the hollow throttle plate as the vacuum demand of the vacuum consumption device increases; and applying the generated vacuum to the vacuum consumption device. 14. The system of claim 13 , wherein applying the vacuum to the vacuum consumption device includes flowing air from the vacuum consumption device, through the hollow shaft into the hollow throttle plate, and then into the intake via the perforations of the perforated edges; and wherein the controller is further configured to, in response to the hollow throttle plate moving to the more closed position, adjust an operating parameter to maintain an engine torque output. 15. A method for an engine, comprising: connecting a vacuum consumption device via a hollow shaft to a hollow throttle plate positioned in an intake passage, a periphery of the hollow throttle plate, along a circumference of the hollow throttle plate, configured with multiple perforations; responsive to the vacuum consumption device demanding increased vacuum, determining whet