Method and system for active casing treatment control

The invention claimed is: 1. A method for a boosted engine, comprising: actuating a sleeve of a variable geometry compressor casing to a selected position via a controller based on each of a compressor pressure ratio and a mass flow through the compressor as determined via the controller; and adjusting each of an EGR actuator and a boost actuator via the controller based on the selected position to maintain the compressor pressure ratio during the actuating. 2. The method of claim 1 , wherein the actuating includes: predicting a change in each of a compressor surge margin relative to a surge limit and a compressor choke margin relative to a choke limit via the controller based on the compressor pressure ratio and mass flow; responsive to a predicted decrease in compressor surge margin as determined via the controller, actuating the sleeve to a first position via the controller; and responsive to a predicted decrease in the compressor choke margin as determined via the controller, actuating the sleeve to a second position via the controller. 3. The method of claim 2 , further comprising: opening a surge slot of the compressor while a choke slot of the compressor is closed and compressed air is recirculated from compressor impeller blades to a compressor inlet via the surge slot when the sleeve is in the first position; and closing the surge slot while the choke slot is open and compressed air is recirculated from the compressor inlet to the compressor impeller blades via the choke slot when the sleeve is in the second position. 4. The method of claim 3 , further comprising, responsive to no predicted decrease in the compressor surge margin or the compressor choke margin as determined via the controller, maintaining the sleeve in a default position via the controller, wherein both the surge slot and the choke slot are closed. 5. The method of claim 3 , further comprising driving the compressor by an exhaust turbine, recirculating exhaust from an exhaust passage downstream of the turbine to upstream of the compressor via the EGR actuator which includes an EGR valve coupled in an EGR passage, and wherein the boost actuator includes one of a variable geometry turbine and a waste-gate valve, the waste-gate valve coupled in a waste-gate bypassing the exhaust turbine. 6. The method of claim 5 , wherein the adjusting includes: responsive to the sleeve being actuated to the first position, increasing an opening of the EGR valve and increasing an opening of the waste-gate valve via the controller, the increasing based on a predicted drop in boost pressure due to the actuating of the sleeve to the first position; and responsive to the sleeve being actuated to the second position, decreasing the opening of the EGR valve and decreasing the opening of the waste-gate valve via the controller, the decreasing based on a predicted rise in boost pressure due to the actuating of the sleeve to the second position. 7. The method of claim 5 , wherein the adjusting includes: responsive to the sleeve being actuated to the first position, increasing a nozzle opening of the variable geometry turbine via the controller, the increasing based on a predicted change in boost pressure due to the actuating of the sleeve to the first position; and responsive to the sleeve being actuated to the second position, decreasing the nozzle opening of the variable geometry turbine via the controller, the decreasing based on the predicted change in boost pressure due to the actuating of the sleeve to the second position. 8. The method of claim 2 , further comprising: actuating the sleeve to the first position prior to the compressor pressure ratio reaching the surge limit; and actuating the sleeve to the second position prior to the compressor pressure ratio reaching the choke limit. 9. The method of claim 2 , further comprising predicting the change in compressor surge margin or the compressor choke margin based on driver behavior including an estimated energy density of a driver pedal demand. 10. The method of claim 9 , wherein the predicting is further based on an input from a navigational system, the input including altitude and road gradient. 11. The method of claim 9 , further comprising selecting the position based on a prior frequency of sleeve actuation relative to a threshold, the threshold determined as a function of the estimated energy density of the driver pedal demand, the threshold lowered as the estimated energy density increases, wherein the sleeve is maintained in a current position responsive to the prior frequency of sleeve actuation being higher than the threshold even as the compressor surge margin or the compressor choke margin decreases. 12. A method for a boosted engine, comprising: dynamically adjusting each of a choke margin to a choke limit and a surge margin to a surge limit of a compressor based on driver behavior including energy density of driver pedal demand via a controller; actuating a sleeve of an active casing of the compressor to a choke slot responsive to compressor operation in the choke margin via the controller; and actuating the sleeve to a surge slot responsive to compressor operation in the surge margin via the controller. 13. The method of claim 12 , wherein the actuating is responsive to a change in driver pedal demand as determined via the controller, the method further comprising estimating the energy density of the driver pedal demand based on each of a rate, a magnitude, and a frequency of driver pedal application over a drive cycle via the controller. 14. The method of claim 12 , further comprising, adjusting each of an EGR actuator and a boost actuator based on the actuating to operate the compressor out of the choke margin or the surge margin via the controller. 15. The method of claim 14 , wherein the EGR actuator includes one or more of a high pressure EGR valve recirculating exhaust gas from upstream of an exhaust turbine to downstream of the compressor, and a low pressure EGR valve recirculating exhaust gas from downstream of the exhaust turbine to upstream of the compressor, and wherein the boost actuator includes one of a waste-gate valve for flowing exhaust gas to a tailpipe while bypassing the turbine, and a variable geometry turbine actuator for adjusting a nozzle opening of the turbine. 16. The method of claim 15 , wherein the adjusting includes: responsive to the sleeve being actuated to the choke slot, decreasing an opening of the low pressure EGR valve, increasing an opening of the high pressure EGR valve, decreasing an opening of the waste-gate valve, and decreasing the nozzle opening via the controller; and responsive to the sleeve being actuated to the surge slot, increasing the opening of the low pressure EGR valve, decreasing the opening of the high pressure EGR valve, increasing the opening of the waste-gate valve, and increasing nozzle opening via the controller. 17. The method of claim 12 , wherein each of the choke margin and the surge margin is further adjusted, dynamically, based on a measured frequency of sleeve actuation of the drive cycle via the controller, the surge margin increased and the choke margin increased as the measured frequency exceeds a threshold frequency. 18. A boosted engine system, comprising: an engine; an intake compressor having an impeller, a choke slot, a surge slot, an actuatable annular casing housing the impeller, the casing comprising a sleeve slot, and an actuator coupled to a sleeve of the casing; an exhaust turbine; an EGR valve coupled in an EGR passage for recirculating e