Abstract: An engine assembly may include an engine structure, a first intake valve, a first valve lift mechanism, a second intake valve, a second valve lift mechanism, and a boost mechanism. The first intake valve may be located in a first intake port and the first valve lift mechanism may be engaged with the first intake valve. The second intake valve may be located in a second intake port and the second valve lift mechanism may be engaged with the second intake valve and operable in first and second modes. The second intake valve may be displaced to an open position during the first mode and may be maintained in a closed position during the second mode. The boost mechanism may be in communication with an air source and the first intake port and isolated from the second intake port.

Abstract: An engine assembly includes an engine block defining a cylinder, an exhaust system, and an exhaust gas recirculation system. A first exhaust valve is configured to control the flow of fluid from the cylinder to the exhaust system. A second exhaust valve configured to control the flow of fluid from the cylinder to the exhaust gas recirculation system. The second valve is deactivatable independently of the first valve, thereby enabling EGR flow.

Abstract: An engine assembly includes an engine block defining a cylinder, an exhaust system, and an exhaust gas recirculation system. A first cam-actuated exhaust valve is configured to control the flow of fluid from the cylinder to the exhaust system. A second cam-actuated exhaust valve configured to control the flow of fluid from the cylinder to the exhaust gas recirculation system. The timing of the second valve is adjustable independently of the timing of the first valve, thereby enabling control of EGR flow through manipulation of exhaust valve timing.

Abstract: An engine assembly may include an engine structure and a crankshaft. The engine structure may include an engine block defining a first bank of cylinders defining two cylinders and a second bank of cylinders defining two cylinders forming a V4 arrangement. The crankshaft may include a first crank pin, a second crank pin, a third crank pin and a fourth crank. The fourth crank pin may be rotationally offset from the first crank pin by a first angle of less than two hundred and seventy degrees in the rotational direction of the crankshaft. The second and third crank pins may be located rotationally between the first crank pin and the fourth crank pin in the rotational direction.

Abstract: A crankshaft for a V8 engine includes first, second, third, fourth, fifth, sixth, seventh and eighth crank pins defined on the crankshaft. The second crank pin is rotationally offset from the first crank pin, the third crank pin is rotationally offset from the first and second crank pins, the fourth crank pin is rotationally offset from the first, second and third crank pins, the fifth crank pin is rotationally offset from the first, second, third and fourth crank pins, and the sixth pin is rotationally offset from the first, second, third, fourth and fifth crank pins. The seventh crank pin is rotationally aligned with the first crank pin and the eighth crank pin is rotationally aligned with the second crank pin.

Abstract: An engine assembly may include an engine structure, a first intake valve located in a first intake port, a first valve lift mechanism, a second intake valve located in a second intake port, a second valve lift mechanism, a first throttle valve, and a second throttle valve. The second intake valve may be displaced to an open position by the second valve lift mechanism during a first mode and the second intake valve may be maintained in a closed position by the second valve lift mechanism during a second mode. The first throttle valve may be in communication with an air source and the first intake port and control air flow from the air source to the first intake port. The second throttle valve may be in communication with the air source and the second intake port and control air flow from the air source to the second intake port.

Abstract: An engine assembly may include an engine structure, a first intake valve, a first valve lift mechanism, a second intake valve, a second valve lift mechanism, and a boost mechanism. The first intake valve may be located in a first intake port and the first valve lift mechanism may be engaged with the first intake valve. The second intake valve may be located in a second intake port and the second valve lift mechanism may be engaged with the second intake valve and operable in first and second modes. The second intake valve may be displaced to an open position during the first mode and may be maintained in a closed position during the second mode. The boost mechanism may be in communication with an air source and the first intake port and isolated from the second intake port.

Abstract: An engine assembly may include a rotary engine and a reciprocating engine. The rotary engine may include a first engine structure defining a rotor housing, a rotor located within the rotor housing and cooperating with the first engine structure to define a first combustion chamber and a first exhaust port defined by the first engine structure and in communication with the first combustion chamber. The reciprocating engine may include a second engine structure defining a cylinder bore and a piston disposed within the cylinder bore and cooperating with the second engine structure to define a second combustion chamber in communication with the first exhaust port.

Abstract: A method, information processing system, and wireless device are disclosed for managing network scanning intervals. The method includes detecting a new wireless network coverage area (130). At least one local dynamic scanning profile (110) is analyzed in response to the determining. The at least one local dynamic scanning profile (110) is determined to include identification information (306) associated with the new wireless network coverage area (130). A network scanning interval for identifying wireless sub-networks (112) within the new wireless network coverage area is dynamically adjusted in response to the determining that the at least one local dynamic scanning profile 110 includes the identification information (306). The adjustment is based on a scanning interval (312) indicated by the at least one local dynamic scanning profile 110 for the new wireless network coverage area (130).

Abstract: A method, equipment, and environment for dynamically controlling a wireless group call and group call participants in a manner that provides and enables accurate billing of each call participant. The methodology involves selecting a group of mobile stations to participate in the wireless group call (30) and causing an invitation message to be transmitted to the group of mobile stations (34). The methodology then includes setting up a dynamic group of mobile stations based on replies received from the group of mobile stations (36), preferably by editing the dynamic group of mobile stations, and then validating the mobile stations in the dynamic group as members of the wireless group call (38).

Abstract: A high efficiency high ratio dual swirl combustion chamber of a spark ignition internal combustion engine includes in preferred embodiment opposing closely conforming squish surfaces with an eight (8) shaped subchamber recess formed of adjoining subcylinders with concave sides joining to provide opposed diametrically located projections that generate dual swirling turbulent mixture flow for ignition and combustion in the subchamber.