Method and apparatus of plasma flow control for drag reduction

We claim: 1. A plasma actuator array comprising: a plurality of plasma actuators positioned on a surface, each plasma actuator comprising: a dielectric; a first electrode exposed to a fluid flow, the fluid flow having a boundary layer with a boundary layer mean flow direction; a second electrode separated from the fluid flow by the dielectric; a pulsed direct current power supply providing a first voltage to the first electrode and a second voltage to the second electrode; and a bus operably connected to distribute power to the plasma actuators, positioned to minimize flow disturbances; wherein the plasma actuators are arranged into a series of linear rows, each of the linear rows aligned parallel to the boundary layer mean flow direction, such that a velocity component perpendicular to the boundary layer mean flow direction is imparted to the fluid flow close to the surface, and wherein the exposed first electrode is adapted to produce opposing spanwise blowing with a stagnation line in the space between neighboring covered second electrodes. 2. The plasma actuator array of claim 1 wherein the plasma actuators are arranged to produce a reduction in the viscous drag of the fluid flow across the surface. 3. The plasma actuator array of claim 2 wherein the reduction in the viscous drag is accomplished by smoothing a mean flow distortion produced by turbulent boundary layer low-speed streaks to prevent streak transient growth instability that results in streak lift-up and the generation of higher viscous drag. 4. The plasma actuator array of claim 1 wherein the exposed electrode is adapted to produce uniform spanwise blowing. 5. The plasma actuator array of claim 4 wherein the exposed electrode is located on the edge of the covered electrode. 6. The plasma actuator array of claim 1 wherein each plasma actuator further comprises: a switch electrically coupled to the first and second electrode and to the direct current power supply such that energization of the direct current power supply by action of the switch causes the fluid to generate a plasma on the surface; the plasma, having an electric field vector produced by the first and second electrodes resulting in a body force vector field that induces a velocity component in the fluid in a direction parallel to the surface and perpendicular to a mean flow direction of the boundary layer fluid flow; wherein the energization caused by the switch creates a repetitive pulse having a length of time by momentarily connecting one of the first or second electrodes to a ground, such that, for the majority of the pulse, the voltages of the first and second electrodes are at the same DC potential and no power is consumed by the plasma actuator array. 7. The plasma actuator array of claim 1 wherein the fluid flow along the surface is an attached turbulent boundary layer. 8. The plasma actuator array of claim 1 wherein the plasma actuators are arranged to lower the viscous drag in the turbulent boundary layer that passes over the surface covered by the actuator array. 9. The plasma actuator array of claim 8 wherein the plasma actuator array is positioned on the surface in areas over which attached turbulent boundary layers exist. 10. The plasma actuator array of claim 1 wherein plasma actuators are arranged in a rectangular pattern to cover a portion of the surface over which an attached turbulent boundary layer flows. 11. The plasma actuator array of claim 10 is located at anywhere the turbulent boundary layer along the surface is fully attached. 12. The plasma actuator array of claim 1 wherein the difference between the first voltage and the second voltage is sufficient to form a plasma and to generate a body force that imparts momentum to the air. 13. A method of reducing viscous drag due to attached turbulent boundary layer fluid flow on a surface comprising arranging an ordered series of plasma actuators, each plasma actuator with an exposed first electrode and a covered second electrode, to cover a surface under the turbulent boundary layer fluid flow to produce opposing spanwise blowing with a stagnation line in the space between neighboring covered second electrodes; energizing the ordered series of plasma actuators with a pulsed direct current power flow; imparting a velocity component to the fluid flow that is parallel to the surface and perpendicular to a mean flow direction of the fluid flow; and smoothing a distortion in the fluid flow produced by low-speed streaks to prevent streak transient growth instability and lift-up of the low-speed streaks from the surface and thereby to reduce viscous drag of the fluid flow across the surface. 14. A plasma actuator array comprising: a plurality of plasma actuators positioned on a surface, each plasma actuator comprising: a dielectric; a first electrode exposed to a fluid flow, the fluid flow having a boundary layer with a boundary layer mean flow direction; a second electrode separated from the fluid flow by the dielectric; a pulsed direct current power supply providing a first voltage to the first electrode and a second voltage to the second electrode; a bus operably connected to distribute power to the plasma actuators, positioned to minimize flow disturbances; and wherein the plasma actuators are arranged into a series of linear rows, each of the linear rows aligned parallel to the boundary layer mean flow direction, such that a velocity component perpendicular to the boundary layer mean flow direction is imparted to the fluid flow close to the surface, wherein the exposed first electrode is adapted to produce opposing spanwise blowing with a stagnation line in the space between neighboring covered second electrodes. 15. The plasma actuator array of claim 14 wherein the exposed first electrode is located in the spanwise center of the covered second electrodes.