Flow control actuator with an adjustable frequency

The invention claimed is: 1. A fluidic oscillator comprising: a first structure including a first planar member having a first side and a second side opposite the first side, a first chamber formed on the first side of the first planar member and extending along a flow axis from an input port to an output port, the output port having a divergent section, the first chamber having a first section connected to a second section via a rectangular section, the first section extending from the input port to the rectangular section, and the second section extending from the rectangular section to the output port; a second structure having a second chamber in fluid communication with the first chamber via a first opening extending through the first planar member between the rectangular section of the first chamber and the second side of the first planar member and via a second opening extending through the first planar member between the second section of the first chamber and the second side of the first planar member; a third structure having a third chamber in fluid communication with the first chamber via a third opening extending through the first planar member between the rectangular section of the first chamber and the second side of the first planar member and via a fourth opening extending through the first planar member between the second section of the first chamber and the second side of the first planar member, the first opening and the third opening in fluid communication with the rectangular section of the first chamber on opposite sides of the flow axis; and a configuration changer for changing volumes of the second and third chambers. 2. The fluidic oscillator of claim 1 , wherein the first chamber has a throat between the rectangular section and the second section. 3. The fluidic oscillator of claim 1 , wherein the second and third structures are coupled to and extend from the second side of the first planar member. 4. The fluidic oscillator of claim 1 , wherein the configuration changer is configured to change the volumes of the second and third chambers to change a frequency of a side-to-side motion of fluid exiting the output port, the motion sweeping back and forth across the flow axis. 5. The fluidic oscillator of claim 4 , wherein the configuration changer includes first and second members movable within the second and third chambers, respectively. 6. The fluidic oscillator of claim 4 , wherein the second and third structures include shape memory material that changes the volumes of the respective second and third chambers in response to external excitation; and wherein the configuration changer is configured to apply the external excitation independently to each of the second and third structures. 7. The fluidic oscillator of claim 1 , wherein the input port extends in a direction that is orthogonal to the flow axis. 8. The fluidic oscillator of claim 1 , wherein the first structure includes a second planar member coupled to the first side of the first planar member. 9. An aircraft comprising: a source of pressurized air; and the fluidic oscillator of claim 1 , wherein the input port is coupled to the source. 10. The aircraft of claim 9 , wherein the first chamber has a throat between the rectangular section and the second section. 11. The aircraft of claim 9 , wherein the second and third structures are coupled to and extend from the second side of the first planar member. 12. The aircraft of clam 9 , wherein the configuration changer is configured to change the volumes of the second and third chambers to change a frequency of a side-to-side motion of fluid exiting the output port, the motion sweeping back and forth across the flow axis. 13. The aircraft of claim 12 , wherein the configuration changer includes first and second members movable within the second and third chambers, respectively. 14. The aircraft of claim 12 , wherein the second and third structures include shape memory material that changes the volumes of the respective second and third chambers in response to external excitation; and wherein the configuration changer is configured to apply the external excitation independently to each of the second and third structures. 15. A method of using the fluidic oscillator of claim 1 , comprising: supplying pressurized fluid to the input port of the fluidic oscillator; and changing a frequency of a sweeping jet at the output port by changing relative volumes of the second and third chambers. 16. The method of claim 15 , wherein the frequency is based on relative size of the volumes of the second and third chambers. 17. The method of claim 16 , wherein the sweeping jet stays on a side of the flow axis corresponding to the second or third chamber having a larger volume for a longer period of time. 18. The fluidic oscillator of claim 1 , wherein the second and fourth openings are in fluid communication with the second section of the first chamber on opposite sides of the flow axis. 19. The fluidic oscillator of claim 8 , wherein at least a portion of the first chamber is formed on a side of the second planar member facing the first side of the first planar member.