System and method for improved gas exchange in cylinder deactivation applications

We claim: 1. A cylinder-deactivation system for an internal combustion engine used to disable an activation of an engine-valve, said system comprising: an intake cam-follower-assembly which opens an intake-engine-valve, said intake cam-follower-assembly switchable to operate in one of an active-state that opens the intake-engine-valve and defines an active-combustion-cycle, and a deactive-state that prevents the opening of the intake-engine-valve and defines a deactive-combustion-cycle; an exhaust cam-follower-assembly which opens an exhaust-engine-valve, said exhaust cam-follower-assembly switchable to operate in one of a primary-lift-state, and a secondary-lift-state; an exhaust-cam which includes a primary-lift cam-lobe and a secondary-lift cam-lobe in rotational contact with the exhaust cam-follower-assembly, said primary-lift cam-lobe positioned to actuate the exhaust cam-follower-assembly in the primary-lift-state, and said secondary-lift cam-lobe positioned to actuate the exhaust cam-follower-assembly in the secondary-lift-state; and a controller in communication with the intake cam-follower-assembly and the exhaust cam-follower-assembly, said controller programmed to select the deactive-state, said controller further programmed to select the secondary-lift-state such that the exhaust-engine-valve is opened with the secondary-lift cam-lobe during an exhaust-blow-down period of the deactive-combustion-cycle in advance of the opening of the intake-engine-valve that occurs during a subsequent active-combustion-cycle. 2. The system in accordance with claim 1 , wherein the exhaust-engine-valve and the intake-engine-valve are located in a same engine-cylinder. 3. The system in accordance with claim 2 , wherein the secondary-lift cam-lobe opens the exhaust-engine-valve within ten degrees of a crankshaft-revolution before the opening of the intake-engine-valve. 4. The system in accordance with claim 3 , wherein the exhaust-engine-valve is open for greater than sixty degrees of the crankshaft-revolution and open for less than one-hundred degrees of the crankshaft-revolution. 5. The system in accordance with claim 2 , wherein the secondary-lift cam-lobe opens the exhaust-engine-valve when a position of a cylinder-piston in an engine-cylinder is within 5° of a crankshaft-revolution before top-dead-center and within 5° of the crankshaft-revolution after top-dead-center. 6. The system in accordance with claim 5 , wherein the exhaust-engine-valve is open for greater than three-hundred-sixty degrees of the crankshaft-revolution. 7. The system in accordance with claim 2 , wherein the selection by the controller of the deactive-state and the selection of the secondary-lift-state occur simultaneously. 8. The system in accordance with claim 7 , wherein the secondary-lift cam-lobe opens the exhaust-engine-valve within ten degrees of a crankshaft-revolution before the opening of the intake-engine-valve. 9. The system in accordance with claim 8 , wherein the exhaust-engine-valve is open for greater than sixty degrees of the crankshaft-revolution and open for less than one-hundred degrees of the crankshaft-revolution. 10. The system in accordance with claim 7 , wherein the secondary-lift cam-lobe opens the exhaust-engine-valve when a position of a cylinder-piston in an engine-cylinder is within 5° of a crankshaft-revolution before top-dead-center and within 5° of the crankshaft-revolution after top-dead-center. 11. The system in accordance with claim 10 , wherein the exhaust-engine-valve is open for greater than three-hundred-sixty degrees of the crankshaft-revolution. 12. A method for controlling a cylinder-deactivation system including an intake cam-follower-assembly which opens an intake-engine-valve, said intake cam-follower-assembly switchable to operate in one of an active-state that opens the intake-engine-valve and defines an active-combustion-cycle, and a deactive-state that prevents the opening of the intake-engine-valve and defines a deactive-combustion-cycle, an exhaust cam-follower-assembly which opens an exhaust-engine-valve, said exhaust cam-follower-assembly switchable to operate in one of a primary-lift-state, and a secondary-lift-state, an exhaust-cam which includes a primary-lift cam-lobe and a secondary-lift cam-lobe in rotational contact with the exhaust cam-follower-assembly, said primary-lift cam-lobe positioned to actuate the exhaust cam-follower-assembly in the primary-lift-state, and said secondary-lift cam-lobe positioned to actuate the exhaust cam-follower-assembly in the secondary-lift-state, and a controller in communication with the intake cam-follower-assembly and the exhaust cam-follower-assembly, said controller programmed to select the deactive-state, said controller further programmed to select the secondary-lift-state, said method comprising; selecting the deactive-state; selecting the secondary-lift-state; and opening the exhaust-engine-valve with the secondary-lift cam-lobe during an exhaust-blow-down period of the deactive-combustion-cycle in advance of the opening of the intake-engine-valve that occurs during a subsequent active-combustion-cycle. 13. The method in accordance with claim 12 , wherein the exhaust-engine-valve and the intake-engine-valve are located in a same engine-cylinder. 14. The method in accordance with claim 13 , further comprising opening the exhaust-engine-valve with the secondary-lift cam-lobe within ten degrees of a crankshaft-revolution before the opening of the intake-engine-valve. 15. The method in accordance with claim 14 , further comprising opening the exhaust-engine-valve for greater than sixty degrees of the crankshaft-revolution and for less than one-hundred degrees of the crankshaft-revolution. 16. The method in accordance with claim 13 , further comprising opening the exhaust-engine-valve with the secondary-lift cam-lobe when a position of a cylinder-piston in an engine-cylinder is within 5° of a crankshaft-revolution before top-dead-center and within 5° of the crankshaft-revolution after top-dead-center. 17. The method in accordance with claim 16 , further comprising opening the exhaust-engine-valve for greater than three-hundred-sixty degrees of the crankshaft-revolution. 18. The method in accordance with claim 13 , further comprising selecting by the controller the deactive-state, and selecting by the controller the secondary-lift-state occur simultaneously. 19. The method in accordance with claim 18 , further comprising opening the exhaust-engine-valve with the secondary-lift cam-lobe within ten degrees of a crankshaft-revolution before the opening of the intake-engine-valve. 20. The method in accordance with claim 19 , further comprising opening the exhaust-engine-valve for greater than sixty degrees of the crankshaft-revolution and for less than one-hundred degrees of the crankshaft-revolution. 21. The method in accordance with claim 18 , further comprising opening the exhaust-engine-valve with the secondary-lift cam-lobe when a position of a cylinder-piston in an exhaust-cylinder is within 5° of a crankshaft-revolution before top-dead-center and within 5° of the crankshaft-revolution after top-dead-center. 22. The method in accordance with claim 21 , further comprising opening the exhaust-engine-valve for greater than three-hundred-sixty degrees of the crankshaft-revolution.