Blocking plate structure for improved acoustic transmission efficiency

The invention claimed is: 1. An acoustic matching structure for a transducer, the structure comprising: a cavity which, in use, contains a fluid, the cavity having a substantially flat cylindrical shape; two end walls bounding the substantially planar shape of the cavity; at least one side wall bounding the cavity; a side wall bounding the cavity and substantially perpendicular to the end walls; the structure defining an area A cavity given by the average cross-sectional area in the planar dimension in the cavity within the at least one side wall; wherein the cavity has an effective side wall radius r cavity defined as: r cavity =( A cavity /π) 1/2 ; and at least one aperture placed within the at least one side wall; wherein the cavity height h cavity is defined as the average separation of the end walls; wherein r cavity and h cavity , satisfy the inequality: r cavity is greater than h cavity ; wherein an area of one of the at least one aperture (A aperture ), and A cavity satisfy the inequality: A cavity /A aperture is greater than 2; wherein, in operation, a transducing element acting on one of the cavity end walls generates acoustic oscillations in the fluid in the cavity; and whereby, in use, the acoustic oscillations in the fluid in the cavity cause pressure waves to propagate into a surrounding acoustic medium. 2. The acoustic matching structure according to claim 1 , wherein, in operation, the cavity supports a resonant frequency of acoustic oscillation in the fluid; wherein the resonant frequency determines a wavelength defined by λ = c f , where c is the speed of sound in the fluid; where h cavity is substantially less than half of said wavelength and where r cavity is substantially equal to or greater than half of said wavelength; at least one aperture is placed in within the at least one side wall; and at least one acoustic transducing element is located within the at least one side wall; such that the resulting acoustic cavity constrains the surrounding acoustic medium in the cavity to induce a resonant mode that substantially improves the transfer of acoustic energy from the transducing element to the medium outside the aperture. 3. The acoustic matching structure according to claim 1 , wherein substantially flat cylindrical shape has an aspect ratio of less than 2. 4. The acoustic matching structure according to claim 1 , wherein r cavity |h cavity is greater than 5. 5. The acoustic matching structure according to claim 1 , wherein the fluid contained in the cavity is air and the speed of sound is between 300m/s and 400m/s. 6. The acoustic matching structure according to claim 1 , wherein h cavity 2 /r cavity is greater than 10-8 meters. 7. The acoustic matching structure according to claim 1 , wherein, in use, lowest resonant frequency of radial pressure oscillations in the cavity is in the range 200 Hz-2 MHz. 8. The acoustic matching structure according to claim 1 , wherein the transducing element is one of: a piezoelectric actuator, an electromagnetic actuator, an electrostatic actuator, a magnetostrictive actuator, a thermoacoustic transducing element. 9. An acoustic matching structure for a transducer, the acoustic matching structure comprising: 1) a cavity which, in use, contains a fluid, the cavity having a substantially flat cylindrical shape; two end walls bounding the substantially planar shape of the cavity; at least one side wall bounding the cavity; the structure defining an area A cavity given by the average cross-sectional area in the planar dimension in the cavity within the at least one side wall; wherein the cavity has an effective wall radius r cavity defined as: r cavity =( A cavity /π) 1/2 ; and at least one aperture placed within the at least one side wall; wherein the cavity height h cavity is defined as the average separation of the end walls; wherein r cavity and h cavity , satisfy the inequality: cavity is greater than h cavity , wherein an area of one of the at least one aperture (A aperture ), and A cavity satisfy the inequality: A cavity /A aperture is greater than 2 wherein, in operation, a transducing element acting on one of the cavity end walls generates acoustic oscillations in the fluid in the cavity; and whereby, in use, the acoustic oscillations in the fluid in the cavity cause pressure waves to propagate into a surrounding acoustic medium; 2) an actuator, wherein, in use, a frequency of oscillatory motion of the actuator is within 30% of a lowest resonant frequency of radial acoustic oscillations in the cavity. 10. The acoustic matching structure according to claim 9 , wherein the actuator causes motion of one of the end walls with a displacement profile approximating a Bessel function. 11. The acoustic matching structure according to claim 9 , wherein, in use, acoustic pressure oscillations in the cavity have a pressure antinode located within a distance of r cavity /4 of a center of the cavity. 12. The acoustic matching structure according to claim 9 , wherein displacement of the actuator follows a bending shape when actuated. 13. The acoustic matching structure according to claim 9 , wherein motion of an edge of the actuator is constrained by an actuator support. 14. The acoustic matching structure according to claim 9 , wherein motion of a center of the actuator is unconstrained. 15. The acoustic matching structure according to claim 9 , wherein the transducing element is one of: a piezoelectric actuator, an electromagnetic actuator, an electrostatic actuator, a magnetostrictive actuator, a thermoacoustic transducing element. 16. The acoustic matching structure according to claim 13 , wherein motion of the actuator support is constrained by a blocking plate. 17. The acoustic matching structure according to claim 16 , further comprising a thin film matching structure positioned between the transducing element and the blocking plate. 18. The acoustic matching structure according to claim 16 , further comprising a thin film matching structure positioned between the blocking plate and the surrounding acoustic medium. 19. The acoustic matching structure according to claim 16 , further comprising a perforated plate matching structure containing apertures of approximately λ/4 height positioned between the transducing element and the blocking plate. 20. The acoustic matching structure according to claim 16 , further comprising a perforated plate matching structure containing apertures of approximately λ/4 height positioned between the blocking plate and the surrounding acoustic medium.