Air turbine start system

The invention claimed is: 1. An air turbine starter device comprising: a rotor arranged in a rotor cavity of a housing; the housing comprising a first manifold having a first manifold cavity with a first manifold port operative to direct a first portion of compressed air to the rotor for rotation in a first direction; the housing comprising a second manifold having a second manifold cavity with a second manifold port operative to direct a second portion of compressed air to the rotor for rotation in the first direction, wherein the first manifold is larger than the second manifold, wherein the air turbine starter is communicatively connected to a compressed air source providing the first portion of compressed air and the second portion of compressed air, wherein the first manifold is connected in parallel with the second manifold between the rotor and the compressed air source, and wherein the rotor is mechanically linked through a gear assembly to a core of a gas turbine engine such that rotation of the rotor rotates a compressor and a turbine of the gas turbine engine. 2. The device of claim 1 , wherein the first manifold port is one of a plurality of first manifold ports, wherein the second manifold port is one of a plurality of second manifold ports, and wherein the first manifold includes a greater number of the first manifold ports than a number of the second manifold ports in the second manifold. 3. The device of claim 1 , wherein the first manifold cavity of the first manifold defines a first manifold compressed air flow path for the first portion of compressed air that flows through the first manifold cavity of the first manifold, through the first manifold port of the first manifold, and through a nozzle that is communicative with the rotor cavity of the housing. 4. The device of claim 1 , wherein the second manifold cavity of the second manifold defines a second manifold compressed air flow path for the second portion of compressed air that flows through the second manifold cavity of the second manifold, through the second manifold port of the second manifold, and through a nozzle that is communicative with the rotor cavity of the housing. 5. The device of claim 1 , wherein the rotor is operative to rotate when either the first portion of compressed air, the second portion of compressed air, or both impinge on the rotor. 6. An air turbine starter system, the system comprising: an air turbine starter device comprising: a rotor arranged in a rotor cavity of a housing; the housing comprising a first manifold having a first manifold cavity with a first manifold port operative to direct a flow of first manifold compressed air to the rotor for rotation in a first direction; and the housing comprising a second manifold having a second manifold cavity with a second manifold port operative to direct a flow of second manifold compressed air to the rotor for rotation in the first direction, wherein the first manifold is larger than the second manifold; a first control valve operative to control the flow of first manifold compressed air to the first manifold; and a second control valve operative to control the flow of second manifold compressed air to the second manifold, wherein the air turbine starter is communicatively connected to a compressed air source supplying the first manifold compressed air and the second manifold compressed air, wherein the first manifold is connected in parallel with the second manifold between the rotor and the compressed air source, and wherein the rotor is mechanically linked through a gear assembly to a core of a gas turbine engine such that rotation of the rotor rotates a compressor and a turbine of the gas turbine engine. 7. The system of claim 6 , wherein the first manifold port is one of a plurality of first manifold ports, wherein the second manifold port is one of a plurality of second manifold ports, wherein the first manifold includes a greater number of the first manifold ports than a number of the second manifold ports in the second manifold. 8. The system of claim 6 , wherein the first manifold cavity of the first manifold defines a first manifold compressed air flow path through the first manifold cavity of the first manifold, through the first manifold port of the first manifold, and through a nozzle that is communicative with the rotor cavity of the housing. 9. The system of claim 6 , wherein the second manifold cavity of the second manifold defines a second manifold compressed air flow path through the second manifold cavity of the second manifold, through the second manifold port of the second manifold, and through a nozzle that is communicative with the rotor cavity of the housing. 10. The system of claim 6 , wherein the rotor is operative to rotate when either the first manifold compressed air, the second manifold compressed air, or both impinge on the rotor. 11. The system of claim 6 , wherein the system is operative to drive the air turbine starter at a first speed when the first valve is in a closed position and the second valve is in an open position, and the system is operative to drive the air turbine starter at a second speed when the first valve is in an open position. 12. The system of claim 11 , wherein the first speed is lower than the second speed. 13. The system of claim 6 , wherein the air turbine starter device is controlled by a controller. 14. A method for controlling an air turbine starter system having an air turbine starter device comprising: a rotor arranged in a rotor cavity of a housing, the housing comprising a first manifold having a first manifold cavity with a first manifold port operative to direct a flow of first manifold compressed air to the rotor for rotation in a first direction, the housing comprising a second manifold having a second manifold cavity with a second manifold port operative to direct a flow of second manifold compressed air to the rotor for rotation in the first direction, wherein the first manifold is larger than the second manifold, wherein the first manifold is connected in parallel with the second manifold between the rotor and a compressed air source supplying the first manifold compressed air and the second manifold compressed air, and the rotor being mechanically linked through a gear assembly to a core of a gas turbine engine such that rotation of the rotor rotates a compressor and a turbine of the gas turbine engine, the method comprising: closing a first valve that is operative to control the flow of first manifold compressed air to the first manifold of the air turbine starter device; and opening a second valve that is operative to control the flow of second manifold compressed air to the second manifold of the air turbine starter device, such that the flow of second manifold compressed air to the second manifold is operative to drive the rotor of the air turbine starter system to a first speed. 15. The method of claim 14 , further comprising: opening the first valve that is operative to control the flow of first manifold compressed air to the first manifold of the air turbine starter device, such that the flow of first manifold compressed air to the first manifold is operative to drive the rotor of the air turbine starter system to a second speed. 16. The method of claim 15 , wherein the second speed is greater than the first speed.