Image redirection and optical path folding

1. An x-ray apparatus for capturing an image from an imaging screen, comprising:

a source of x-rays disposed for directing x-rays through an object, wherein said object is positioned between said x-ray source and an imaging screen, and wherein said imaging screen is disposed at least partially in the path of said x-rays passing through said object;

a first subsystem for capturing an image from a first portion of said imaging screen, wherein said first subsystem comprises a first redirecting element and a second redirecting element for redirecting visible light from said first portion of said imaging screen onto a first imaging sensor, wherein said first portion of said imaging screen is positioned between said x-ray source and said first subsystem; and

a second subsystem for capturing an image from a second portion of said imaging screen, wherein said second subsystem comprises a third redirecting element for redirecting light from said second portion of said imaging screen onto a second imaging sensor.

2. The x-ray apparatus of claim 1, wherein said imaging screen is a fluorescent phosphor screen.

3. The x-ray apparatus of claim 1, wherein said first redirecting element is positioned at a 45 degree angle to a plane of said imaging screen.

4. The x-ray apparatus of claim 1, wherein said second redirecting element is adapted to encompass a field of view of said first imaging sensor when said second redirecting element is positioned at a 45 degree angle to an image plane of said first redirecting element.

5. The x-ray apparatus of claim 1, wherein said first and second portions of said imaging screen overlap.

6. The x-ray apparatus of claim 1, wherein said first and second portions of said imaging screen overlap by 20%.

7. The x-ray apparatus of claim 1, wherein said first redirecting element is a mirror adapted to redirect light from said first portion onto said second redirecting element.

8. The x-ray apparatus of claim 7, wherein said first redirecting element redirects only a predetermined portion of said light received from said first portion onto said second redirecting element.

9. The x-ray apparatus of claim 1, wherein said second redirecting element is a mirror adapted to redirect light from said first redirecting element onto said first imaging sensor.

10. The x-ray apparatus of claim 1, wherein said first imaging sensor comprises:

a lens assembly to focus said image received from said first portion of said imaging screen; and

a photosensitive plate for capturing said image.

11. The x-ray apparatus of claim 10, wherein said photosensitive plate is a CCD chip and said first imaging sensor is a CCD camera.

12. The x-ray apparatus of claim 1, wherein said third redirecting element is a mirror adapted to redirect light from said second portion of said imaging screen.

13. The x-ray apparatus of claim 12, wherein said second subsystem further comprises:

a fourth redirecting element for redirecting light from said third redirecting element onto said second imaging sensor.

14. The x-ray apparatus of claim 13, wherein said fourth redirecting element is a mirror adapted to redirect light from said third redirecting element onto said second imaging sensor.

15. The x-ray apparatus of claim 1, wherein said second imaging sensor comprises:

a CCD chip for capturing said image.

16. The x-ray apparatus of claim 10, wherein said multiple redirection of light by said first and second redirecting elements increases an optical path length of light from said first portion.

17. The x-ray apparatus of claim 16, wherein said increase in said optical path length facilitates a corresponding decrease in the length of said lens assembly.

18. The x-ray apparatus of claim 1, wherein utilization of multiple subsystems to capture an image of different portions of said imaging screen increases an optical path length of light from said imaging screen necessary to capture said image.

19. An x-ray apparatus, comprising:

an x-ray source capable of directing x-rays through an object;

an imaging screen wherein said object is positioned between said imaging screen and said x-ray source, and wherein said imaging screen is divided into at least two portions;

a first redirecting element for redirecting a visible portion of light received from a first portion of said imaging screen;

a second redirecting element for redirecting visible light received from said first redirecting element;

a first imaging sensor, comprising:

a lens assembly to focus said light received from said first portion of said imaging screen; and

a photosensitive plate for capturing a first image of said object;

a third redirecting element for redirecting a predetermined portion of light received from a second portion of said imaging screen; and

a second imaging sensor for receiving redirected visible light from said third redirecting element, wherein said second imaging sensor comprises a CCD chip for capturing a second image of said object, wherein said first and second captured images overlap.

20. The x-ray apparatus of claim 19, further comprising:

a fourth redirecting element for redirecting visible light received from said third redirecting element prior to providing it to said second imaging sensor.

21. The x-ray apparatus of claim 19, wherein said imaging screen is a fluorescent phosphor screen.

22. The x-ray apparatus of claim 19, wherein said first redirecting element is a mirror adapted to absorb x-ray radiation.

23. The x-ray apparatus of claim 19, wherein said second redirecting element is a trapezoidal mirror.

24. A method for capturing an image from an imaging screen, comprising:

receiving x-rays at an imaging screen;

converting said x-rays into radiation of at least one selected spectral component at said imaging screen;

capturing a first image from a first portion of said radiation at a first imaging subsystem; and

capturing a second image from a second portion of said radiation at a second imaging subsystem, wherein said first image and second image comprise image data associated with a common portion of said imaging screen.

25. The method of claim 24 wherein said at least one selected spectral component is visible light.

26. The method of claim 24 wherein said imaging screen comprises fluorescent phosphor material.

27. The method of claim 24 further comprising:

directing a portion of said radiation to said first imaging subsystem utilizing a trapezoidal mirror.

28. The method of claim 24 wherein said first imaging subsystem comprises a CCD chip.