Compressor recirculation valve control to reduce charge air cooler condensate

The invention claimed is: 1. An engine method, comprising: determining condensate forming conditions at a charge air cooler based on humidity; and in response to the determined condensate forming conditions, during driving conditions when an induction pressure of air measured between a compressor and a throttle is greater than required to produce a manifold pressure required for a torque demand, opening a compressor recirculation valve, where the torque demand is based on a pedal position that changes during engine operation. 2. The method of claim 1 , wherein determining condensate forming conditions based on humidity includes determining condensate forming conditions when humidity is greater than a first threshold and further comprising, further determining condensate forming conditions when an induction pressure is greater than atmospheric pressure, wherein the induction pressure is measured upstream of the throttle and downstream of the charge air cooler in an engine intake passage. 3. The method of claim 1 , further comprising maintaining the compressor recirculation valve closed and adjusting alternative engine operating parameters to decrease condensate formation in the charge air cooler in response to the determined condensate forming conditions when the induction pressure is not greater than required to produce the manifold pressure required for the torque demand. 4. The method of claim 2 , further comprising closing the compressor recirculation valve in response to a requested manifold pressure increasing above the induction pressure, where the requested manifold pressure is based on the torque demand. 5. The method of claim 2 , wherein the opening the compressor recirculation valve includes maintaining the compressor recirculation valve open until the induction pressure decreases to atmospheric pressure and further comprising, in response to the induction pressure decreasing to atmospheric pressure, closing the compressor recirculation valve. 6. The method of claim 2 , further comprising opening a wastegate in addition to opening the compressor recirculation valve in response to one or more of the induction pressure being greater than a threshold pressure, the threshold pressure a threshold amount greater than atmospheric pressure, the humidity being greater than a second threshold, the second threshold greater than the first threshold, and a compressor surge condition, during driving conditions when the induction pressure is greater than required to produce the manifold pressure required for the torque demand and an engine is at steady-state, where the engine being at steady-state includes when the engine is operating at a relatively constant pedal position that is greater than zero and that maintains a vehicle speed within a threshold speed of an average speed, and where the wastegate is disposed in a bypass around a turbine. 7. The method of claim 6 , further comprising closing the wastegate while maintaining the compressor recirculation valve open in response to one or more of an increase in torque demand due to an increase in pedal position and the induction pressure decreasing to atmospheric pressure. 8. The method of claim 7 , further comprising closing the compressor recirculation valve in response to a requested manifold pressure increasing above the induction pressure, where the requested manifold pressure is based on the torque demand. 9. The method of claim 2 , further comprising opening the compressor recirculation valve responsive to compressor surge conditions, wherein the humidity is one or more of a measured humidity and an inferred humidity of intake air, and wherein the first threshold is a humidity level at which condensate is likely to form in the charge air cooler. 10. An engine method, comprising: during a first condition, opening a compressor recirculation valve in response to each of an induction pressure being greater than a first threshold pressure and a humidity greater than a first threshold; and during a second condition, maintaining the compressor recirculation valve closed even if each of the induction pressure is greater than the first threshold pressure and the humidity is greater than the first threshold. 11. The method of claim 10 , wherein the first condition includes when the induction pressure is greater than a level required to produce a manifold pressure required for a torque demand, where the torque demand is based on a pedal position. 12. The method of claim 10 , wherein the second condition includes an engine being at steady-state, where torque demand is not increasing, and the induction pressure being greater than a level required to produce a manifold pressure required for a torque demand, where the torque demand is based on a pedal position, and further comprising, during the second condition, opening a wastegate in a bypass around a turbine in response to each of the induction pressure being greater than the first threshold pressure and the humidity being greater than the first threshold. 13. The method of claim 11 , wherein the second condition includes when the induction pressure is at or below the level required to produce the manifold pressure required for the torque demand. 14. The method of claim 13 , further comprising adjusting alternative engine operating parameters to decrease condensate formation in a charge air cooler, the alternative engine operating parameters including one or more of vehicle grille shutters, engine fan operation, and airflow to an intake manifold. 15. The method of claim 10 , further comprising, after opening the compressor recirculation valve, closing the compressor recirculation valve responsive to one or more of a requested manifold pressure being greater than the induction pressure and the induction pressure decreasing to the first threshold pressure, where the requested manifold pressure is based on a torque demand that is based on a pedal position that changed during engine operation. 16. The method of claim 10 , wherein the first threshold pressure is based on a pressure at which condensate forms in a charge air cooler and the first threshold is based on a humidity level at which condensate forms in the charge air cooler, where the first threshold pressure is atmospheric pressure. 17. The method of claim 16 , further comprising, during the first condition, opening a wastegate in addition to opening the compressor recirculation valve in response to an engine being at steady-state where torque demand is not increasing and one or more of the induction pressure being greater than a second threshold pressure, the second threshold pressure being greater than the first threshold pressure, the humidity being greater than a second threshold, and a compressor surge condition. 18. A system, comprising: an engine with an intake manifold; a throttle positioned upstream of the intake manifold; a turbocharger with a turbine operable to drive a compressor; a compressor recirculation valve operable to divert air around the compressor; a charge air cooler positioned upstream of the throttle and downstream of the compressor; a wastegate operable to divert exhaust gas around the turbine; a pedal position sensor configured to generate a pedal position signal; and a controller including a read-only memory programmed with computer readable instructions executable by a processor of the controller for opening the compressor recirculation valve responsive to each of a humidity greater than a first threshold and an induction pressure, measured downstream of the charge air cooler and upstream