Space-to-time conversion technique using remotely sensed velocity fields

What is claimed is: 1. A method for determining wind field advection speed and direction comprising: disposing a first radar unit and a second radar unit in proximity to at least one wind turbine; collecting at least two wind volumes from an atmospheric boundary layer (ABL) wind field with the first radar unit and the second radar unit in proximity to the at least one wind turbine; defining portions of a measurement domain within said at least two wind volumes for analysis; using plan-position indicator scanning to direct the first radar unit and the second radar unit to scan along a fixed elevation angle while varying the azimuth of an antenna in order to document a horizontal structure of a flow of said at least two wind volumes; determining advection of an isolated wind field between said at least two wind volumes; iterating a process of correcting for intra-volume advection, objective analysis, and determining the inter-volume advective properties; wherein upon convergence of a measured advection profile, the advective properties of the ABL wind field are derived; and characterizing a wake of said at least one wind turbine according to the advection properties of the ABL wind field. 2. The method of claim 1 wherein said at least two wind volumes further comprise ABL wind measurements collected across at least two time periods. 3. The method of claim 2 wherein each of said first radar unit and said second radar unit comprise at least one of: a scanning radar; a scanning lidar; and a scanning remote sensing instrument providing like data coverage. 4. The method of claim 1 further comprising: transforming said ABL wind field measurements from a native coordinate system to another coordinate system. 5. The method of claim 1 wherein defining portions of the measurement domain within said at least two wind volumes for analysis further comprises: defining an advection analysis area in each of said at least two wind volumes; defining said isolated wind field in the first of said at least two wind volumes; and defining an initial location of said isolated wind field within the advection analysis area of the first of said at least two wind volumes. 6. The method of claim 5 wherein determining advection of said isolated wind field between said at least two wind volumes further comprises: determining a mean horizontal wind speed and wind direction of said first wind volume across said advection analysis area; determining a time elapsed between the first and latter of said at least two wind volumes; and defining a domain of feasible advection solutions in a latter of said at least two wind volumes. 7. The method of claim 6 further comprising: performing cross-correlation between said isolated wind field in said first wind volume and a domain of feasible advection solutions in the latter of said at least two wind volumes. 8. The method of claim 7 further comprising: using a displacement vector exhibiting a highest correlation coefficient to identify a most likely location of said isolated wind field in the latter of said at least two wind volumes. 9. The method of claim 8 further comprising: defining an advection speed and direction according to said displacement vector and said time elapsed between said first wind volume and latter of said at least two wind volumes. 10. A system for determining atmospheric boundary layer (ABL) wind field advection speed and direction comprising: at least one sensor; a first radar unit; a second radar unit; at least one wind turbine in proximity to the first radar unit and the second radar unit; at least one processor; and a storage device communicatively coupled to said at least one processor, said storage device storing instructions which, when executed by said at least one processor, cause said at least one processor to perform operations comprising: collecting at least two wind volumes from the ABL wind field with the first radar unit and the second radar unit in proximity to the at least one wind turbine; defining portions of the measurement domain within said at least two wind volumes for analysis; determining the advection of an isolated wind field between said at least two wind volumes; iterating a process of correcting for intra-volume advection, objective analysis, and determining the inter-volume advective properties; wherein upon convergence of the measured advection profile, the advective properties of the ABL wind field have been appropriately derived; using plan-position indicator scanning to direct the first radar unit and the second radar unit to scan along a fixed elevation angle while varying the azimuth of an antenna in order to document a horizontal structure of a flow said at least two wind volumes; and characterizing a wake of said at least one wind turbine according to the advection properties of the ABL wind field. 11. The system of claim 10 wherein each of said first radar unit and said second radar unit comprise at least one of: a scanning radar; a scanning lidar; and a scanning remote sensing instrument providing like data coverage. 12. The system of claim 10 wherein said at least two wind volumes further comprise ABL wind measurements collected across at least two times. 13. The system of claim 12 wherein each of said first radar unit and said second radar unit comprise at least one of: a scanning radar; a scanning lidar; and a scanning remote sensing instrument providing like data coverage. 14. The system of claim 10 wherein defining portions of the measurement domain within said at least two wind volumes for analysis further comprises: defining an advection analysis area in each of said at least two wind volumes; defining said isolated wind field in the first of said at least two wind volumes; and defining an initial location of said isolated wind field within the advection analysis area of the first of said at least two wind volumes. 15. The system of claim 14 wherein determining advection of said isolated wind field between said at least two wind volumes further comprises: determining a mean horizontal wind speed and wind direction of the first wind volume across said advection analysis area; determining a time elapsed between the first and latter of said at least two wind volumes; defining a domain of feasible advection solutions in the latter of said at least two wind volumes; performing cross-correlation between said isolated wind field in said first wind volume and a domain of feasible advection solutions in the latter of said at least two wind volumes; using a displacement vector exhibiting a highest correlation coefficient to identify a most likely location of said isolated wind field in the latter of said at least two wind volumes; and defining an advection speed and direction according to said displacement vector and said time elapsed between said first wind volume and latter of said at least two wind volumes. 16. A method for determining atmospheric boundary layer (ABL) wind field advection speed and direction comprising: collecting at least two wind volumes from the ABL wind field proximate to at least one wind turbine; transforming said ABL wind field measurements from a native coordinate system to another coordinate system; defining an advection analysis area in each of said at least two wind volumes; defining said isolated wind field in the first of said at least two wind volumes; defining an initial location of said isolated wind field within the advection analysis area of the first of said at least two wind volumes; determining