초록 ▼

A display system employs an active image-generating screen (102) that presents a video image. The screen contains a plurality of block facets (112), each containing a plurality of light-emissive modules (114) preferably implemented with LEDs. Each light-emissive module is configured so that the maxi

A display system employs an active image-generating screen (102) that presents a video image. The screen contains a plurality of block facets (112), each containing a plurality of light-emissive modules (114) preferably implemented with LEDs. Each light-emissive module is configured so that the maximum intensity of that module's light emission occurs along a direction (138) materially non-perpendicular to the back surface (136) of the module's supporting body (130). The modules are arranged so that their maximum light-intensity directions are largely the same. The block facets are configured to approximate a convex curved surface. The maximum light-intensity directions (158) of the block facets are thereby materially slanted relative to one another. Arranging the display system in this manner enables the light-processing efficiency to be very high. A motion simulator, such as a flight simulator, is formed by combining the screen with a reflective collimator (104).

대표청구항 ▼

1. A structure comprising a plurality of light-emissive components connected together for generating an image, each light-emissive component having a light-providing surface and a further surface, referred to as the back surface, generally opposite the light-providing surface, light emitted from eac

1. A structure comprising a plurality of light-emissive components connected together for generating an image, each light-emissive component having a light-providing surface and a further surface, referred to as the back surface, generally opposite the light-providing surface, light emitted from each light-emissive component emanating from its light-providing surface with an intensity having a maximum that occurs in a maximum light-intensity direction materially non-perpendicular to that component's back surface, the components' back surfaces being materially slanted relative to one another so as to approximate a three-dimensional convex curved surface whereby the components' maximum light-intensity directions are materially slanted relative to one another. 2. A structure as in claim 1 wherein the light-emissive components are, as a group, shaped approximately like a thin shell. 3. A structure as in claim 1 wherein each light-emissive component comprises a plurality of modules each comprising: a supporting body having a mounting surface and a further surface, referred to as the back surface, generally opposite the mounting surface; anda light-providing device, mounted on the body's mounting surface, for providing light at an intensity having a maximum that occurs largely in that component's maximum light-intensity direction. 4. A structure as in claim 3 wherein each module has another surface, referred to as the front surface, situated generally opposite the back surface of that module, the mounting surface of each module situated between its front and back surfaces, the front surface of each module being of annular shape and generally flat. 5. A structure as in claim 3 wherein the back surfaces of the supporting bodies of the modules in each light-emissive component extend largely parallel to one another and materially non-perpendicular to that component's maximum light-intensity direction. 6. A structure as in claim 3 wherein: the modules of each light-emissive component are arranged in rows and columns; andthe mounting surfaces of the supporting bodies of the modules in each column of modules in that component extend generally in respective largely coplanar planes spaced apart from one another. 7. A structure as in claim 6 wherein the mounting surfaces of the supporting bodies of the modules in each row of modules in each light-emissive component are largely coplanar. 8. A structure as in claim 3 wherein the light-providing device of each module comprises at least one light-emissive element for emitting light of largely a selected color. 9. A structure as in claim 8 wherein each light-emissive element comprises a light-emitting diode. 10. A structure as in claim 3 wherein the light-providing device of each module comprises three light-emissive elements which respectively emit light of three selected colors capable of being combined to produce white light. 11. A display system comprising: an image-generating screen comprising a plurality of light-emissive components connected together for actively generating an image, each light-emissive component having a light-providing surface and a further surface, referred to as the back surface, generally opposite the light-providing surface, light emitted from each light-emissive component emanating from its light-providing surface with an intensity having a maximum that occurs in a maximum light-intensity direction materially non-perpendicular to that component's back surface, the components' back surfaces being materially slanted relative to one another so as to approximate a three-dimensional convex curved surface whereby the components' maximum light-intensity directions are materially slanted relative to one another; anda collimator for collimating light provided from the image-generating screen in order to substantially replicate the image. 12. A display system as in claim 11 wherein the light-emissive components are, as a group, shaped approximately like a thin shell. 13. A display system as in claim 11 wherein the curved surface approximated by the back surfaces of the light-emissive components is of spherical curvature. 14. A display system as in claim 11 wherein the collimator substantially replicates the image by reflectively collimating light emitted from the light-emissive components. 15. A display system as in claim 14 wherein the collimator has a curved surface of approximately spherical curvature for reflectively collimating light emitted from the light-emissive components. 16. A display system as in claim 11 wherein each light-emissive component comprises a plurality of modules each comprising: a supporting body having a mounting surface and a further surface, referred to as the back surface, generally opposite the mounting surface; anda light-providing device, mounted on the body's mounting surface, for providing light at an intensity having a maximum that occurs largely in that component's maximum light-intensity direction. 17. A display system as in claim 16 wherein the back surfaces of the supporting bodies of the modules in each light-emissive component extend largely parallel to one another and materially non-perpendicular to that component's maximum light-intensity direction. 18. A display system as in claim 16 wherein: the modules of each light-emissive component are arranged in rows and columns; andthe mounting surfaces of the supporting bodies of the modules in each column of modules in that component extend generally in respective largely coplanar planes spaced apart from one another. 19. A display system as in claim 18 wherein the mounting surfaces of the supporting bodies of the modules in each row of modules in each light-emissive component are largely coplanar. 20. A display system as in claim 16 wherein the light-providing device of each module comprises at least one light-emissive element for emitting light of largely a selected color. 21. A display system as in claim 20 wherein each light-emissive element comprises a light-emitting diode. 22. A display system as in claim 16 wherein the light-providing device of each module comprises three light-emissive elements which respectively emit light of three selected colors capable of being combined to produce white light. 23. A display system as in claim 16 wherein the three selected colors of light provided by each module's light-providing device are red, green, and blue. 24. A display system as in claim 16 wherein the supporting bodies contain electronic circuitry for controlling light provided from the light-providing devices. 25. A display system as in claim 16 wherein each module has another surface, referred to as the front surface, situated generally opposite the back surface of that module, the mounting surface of each module situated between its front and back surfaces, the front surface of each module being of annular shape and generally flat. 26. A display system comprising: a curved image-generating screen comprising a multiplicity of light-emitting diodes (“LEDs”) for generating an image, the LEDs being deployed among a plurality of light-emissive components connected together, each light-emissive component having a light-emissive surface and a further surface, referred to as the back surface, generally opposite the light-emissive surface, light emanating from the light-emissive surface of each light-emissive component with an intensity having a maximum that occurs in a maximum light-intensity direction materially non-perpendicular to that component's back surface, the components' back surfaces being materially slanted relative to one another so as to approximate a three-dimensional convex curved surface whereby the components' maximum light-intensity directions are materially slanted relative to one another; anda collimator for collimating light provided from the LEDs in order to substantially replicate the image. 27. A display system as in claim 26 wherein the collimator reflectively collimates light emitted from the LEDs. 28. A display system as in claim 26 wherein the light-emissive components are, as a group, shaped approximately like a thin shell. 29. A display system as in claim 26 wherein: the curved surface approximated by the back surfaces of the light-emissive components is of spherical curvature; andthe collimator has a curved surface of approximately spherical curvature for reflectively collimating light emitted from the light-emissive components. 30. A display system as in claim 26 wherein each light-emissive component comprises a plurality of modules each comprising: a supporting body having a mounting surface and a further surface, referred to as the back surface, generally opposite the mounting surface; anda light-emissive device, mounted on the body's mounting surface, for emitting light at an intensity having a maximum that occurs largely in that component's maximum light-intensity direction, each light-emissive device comprising a different one of the LEDs. 31. A display system as in claim 30 wherein the back surfaces of the supporting bodies of the modules in each light-emissive component extend largely parallel to one another and materially non-perpendicular to that component's maximum light-intensity direction. 32. A display system as in claim 30 wherein: the modules of each light-emissive component are arranged in rows and columns; andthe mounting surfaces of the supporting bodies of the modules in each column of modules in that component extend generally in respective largely coplanar planes spaced apart from one another. 33. A display system as in claim 32 wherein the mounting surfaces of the supporting bodies of the modules in each row of modules in each light-emissive component are largely coplanar. 34. A display system as in claim 30 wherein three of the LEDs are present in the light-emissive device of each module, those three LEDs respectively emitting light of three selected colors capable of being combined to produce white light. 35. A simulator as in claim 30 wherein each module has another surface, referred to as the front surface, situated generally opposite the back surface of that module, the mounting surface of each module situated between its front and back surfaces, the front surface of each module being of annular shape and generally flat. 36. A motion simulator comprising: a display system comprising (a) an image-generating screen comprising a plurality of light-emissive components connected together for actively generating an image, each light-emissive component having a light-providing surface and a further surface, referred to as the back surface, generally opposite the light-providing surface, light emitted from each light-emissive component emanating from its light-providing surface with an intensity having a maximum that occurs in a maximum light-intensity direction materially non-perpendicular to that component's back surface, the components' back surfaces being materially slanted relative to one another so as to approximate a three-dimensional convex curved surface whereby the components' maximum light-intensity directions are materially slanted relative to one another and (b) a collimator for collimating light provided from the image-generating screen in order to substantially replicate the image; anda station for receiving a person such that the person can see the replicated image by receiving light collimated by the collimator after being emitted from the light-emissive components. 37. A simulator as in claim 36 wherein the collimator presents a moving picture as seen from the cockpit of an airplane. 38. A simulator as in claim 36 wherein the collimator has a curved surface for reflectively collimating light emitted from the light-emissive components so as to substantially replicate the image. 39. A simulator as in claim 36 wherein each light-emissive component comprises a plurality of modules each comprising: a supporting body having a mounting surface and a further surface, referred to as the back surface, generally opposite the mounting surface; anda light-providing device, mounted on the body's mounting surface, for providing light at an intensity having a maximum that occurs largely in that component's maximum light-intensity direction. 40. A simulator as in claim 39 wherein: the modules of each light-emissive component are arranged in rows and columns; andthe mounting surfaces of the supporting bodies of the modules in each column of modules in that component extend generally in respective largely coplanar planes spaced apart from one another. 41. A simulator as in claim 40 wherein the mounting surfaces of the supporting bodies of the modules in each row of modules in each light-emissive component are largely coplanar. 42. A simulator as in claim 39 wherein the light-providing device of each module comprises at least one light-emissive element for emitting light of largely a selected color. 43. A simulator as in claim 39 wherein each module has another surface, referred to as the front surface, situated generally opposite the back surface of that module, the mounting surface of each module situated between its front and back surfaces, the front surface of each module being of annular shape and generally flat. 44. A motion simulator comprising: a display system comprising (a) a three-dimensionally curved-image-generating screen comprising a multiplicity of light-emitting diodes (“LEDs”) for generating an image and (b) a collimator for collimating light provided from the image-generating screen in order to substantially replicate the image, the LEDs being deployed among a plurality of light-emissive components connected together, each light-emissive component having a light-emissive surface and a further surface, referred to as the back surface, generally opposite the light-emissive surface, light emanating from the light-emissive surface of each light-emissive component with an intensity having a maximum that occurs in a maximum light-intensity direction materially non-perpendicular to that component's back surface, the components' back surfaces being materially slanted relative to one another so as to approximate a three-dimensional convex curved surface whereby the components' maximum light-intensity directions are materially slanted relative to one another; anda station for receiving a person such that the person can see the replicated image by receiving light collimated by the collimator after being emitted from the light-emissive components. 45. A simulator as in claim 44 wherein the collimator presents a moving picture as seen from the cockpit of an airplane. 46. A simulator as in claim 44 wherein: the curved surface approximated by the back surfaces of the light-emissive components is of spherical curvature; andthe collimator has a curved surface of approximately spherical curvature for reflectively collimating light emitted from the light-emissive components. 47. A simulator as in claim 44 wherein each light-emissive component comprises a plurality of modules each comprising: a supporting body having a mounting surface and a further surface, referred to as the back surface, generally opposite the mounting surface; anda light-emissive device, mounted on the body's mounting surface, for emitting light at an intensity having a maximum that occurs largely in that component's maximum light-intensity direction, each light-emissive device comprising a different one of the LEDs. 48. A display system as in claim 47 wherein each module has another surface, referred to as the front surface, situated generally opposite the back surface of that module, the mounting surface of each module situated between its front and back surfaces, the front surface of each module being of annular shape and generally flat. 49. A simulator as in claim 47 wherein: the modules of each light-emissive component are arranged in rows and columns; andthe mounting surfaces of the supporting bodies of the modules in each column of modules in that component extend generally in respective largely coplanar planes spaced apart from one another. 50. A simulator as in claim 49 wherein the mounting surfaces of the supporting bodies of the modules in each row of modules in each light-emissive component are largely coplanar. 51. A structure as in claim 10 wherein the three selected colors of light provided by the three LEDs in each module's light-emissive device are red, green, and blue. 52. A display system as in claim 34 wherein the three selected colors of light provided by the three LEDs in each module's light-emissive device are red, green, and blue. 53. A simulator as in claim 38 wherein: the curved surface approximated by the back surfaces of the light-emissive components is of spherical curvature; andthe curved surface of the collimator is approximately spherical. 54. A simulator as in claim 39 wherein the light-providing device of each module comprises three light-emissive elements which respectively emit light of three selected colors capable of being combined to produce white light. 55. A simulator as in claim 54 wherein the three selected colors of light provided by each module's light-providing device are red, green, and blue. 56. A simulator as in claim 39 wherein the supporting bodies contain electronic circuitry for controlling light provided from the light-providing devices. 57. A simulator as in claim 47 wherein three of the LEDs are present in the light-emissive device of each module, those three LEDs respectively emitting light of three selected colors capable of being combined to produce white light. 58. A simulator as in claim 57 wherein the three selected colors of light provided by the three LEDs in each module's light-emissive device are red, green, and blue. 59. A simulator as in claim 47 wherein the supporting bodies contain electronic circuitry for controlling light provided from the light-emissive devices.