Generation of a pulsed jet by jet vectoring through a nozzle with multiple outlets

What is claimed is: 1. A method for vectored jet thrust of a vehicle, the vehicle defining three mutually perpendicular axes, the method comprising: generating a jet of substantially constant flow within the vehicle from an engine, wherein a downstream trajectory of the jet is vectored at one or more angles with respect to an axis of an upstream portion of the jet; connecting the jet to at least two fluid conduits in fluid communication with the jet, the at least two fluid conduits being within the vehicle, wherein the at least two fluid conduits are in alignment with the jet; and positioning at least one respective outlet in fluid communication with each of the at least two fluid conduits, each respective outlet positioned on an outer surface of the vehicle and configured to exhaust at the outer surface of the vehicle, wherein fluid flow through each of the at least two fluid conduits is transiently variable by alternately vectoring the jet to each of the at least two fluid conduits, wherein exhaust at each of the respective outlets is transient while the jet is substantially constant, thereby providing vectored jet thrust, wherein the jet is alternately vectored to the at least two fluid conduits fluidically by secondary control jets, and wherein the respective outlets are positioned such that the vectored jet thrust can be directed parallel to each of the three mutually perpendicular axes. 2. The method of claim 1 , wherein the secondary control jets alternately vector the jet by: (a) Coanda-assisted jet vectoring, (b) using a momentum conservation effect, (c) synthetic-jet actuator jet vectoring, or (d) counter-flow jet vectoring. 3. The method of claim 1 , wherein the exhaust from each outlet comprises short pulses, generated by the alternate vectoring of the jet between the at least two fluid conduits, which generate compact vortex rings, wherein a frequency and a duration of the short pulses are independently controlled by varying a flow rate of the jet and a frequency of vectoring between the at least two fluid conduits. 4. The method of claim 1 , wherein each outlet is capable of being oriented at different angles relative to the axis of the upstream portion of the jet to provide thrust vectoring, directional control, or propulsion. 5. The method of claim 1 , wherein the engine is a ducted fan/propeller, a turbojet engine, a jet engine, a turboprop, a ramjet, a rocket, or a scramj et. 6. The method of claim 1 , wherein the one or more angles with respect to the axis of the upstream portion of the jet comprise a multiplicity or a continuum of angles.