System, method and apparatus for wavelength-coded multi-focal microscopy

What is claimed: 1. A microscope comprising: an objective lens for receiving and collimating optical electromagnetic radiation from an illuminated source object of interest; a multiplexed volume hologram with a first wavelength-coded holographic grating and a second wavelength-coded holographic grating to receive and diffract collimated optical electromagnetic radiation from the objective lens, the first wavelength-coded holographic grating configured to diffract light at a first wavelength emitted or scattered from a selected first depth of the source object into a beam diffracted at a first angle with respect to the multiplexed volume hologram, the second wavelength-coded holographic grating configured to diffract light at a second wavelength emitted or scattered from a selected second depth of the source object into a beam diffracted at a second angle with respect to the multiplexed volume hologram with the first wavelength being different from the second wavelength and the first angle being different from the second angle, wherein the selected first depth of the source object corresponds to a first focal plane determined by a first location of a point source generated from a single light source during recordation of the first holographic grating; wherein the selected second depth of the source object corresponds to a second focal plane determined by a second location of the point source generated from the single light source during recordation of the second holographic grating; wherein the first holographic grating corresponding to the first focal plane is coded for reconstruction by the first wavelength of light and the second holographic grating corresponding to the second focal plane is coded for reconstruction by the second wavelength of light; wherein an angle of a signal beam with respect to a reference beam was different during recordation of the second holographic grating than during recordation of the first holographic grating and an angle of the volume hologram with respect to the reference beam was different during recordation of the second holographic grating than during recordation of the first holographic grating; and a focusing element configured to focus the diffracted beams from the first and the second grating onto an imaging plane forming corresponding images of two-dimensional slices of the object taken at the first object depth corresponding to the first focal plane and the second object depth corresponding to the second focal plane with the images occupying different positions on the imaging plane. 2. The microscope of claim 1 , wherein the volume hologram is transmissive. 3. The microscope of claim 1 , wherein the microscope is configured to project an image diffracted from each wavelength-coded holographic grating onto the imaging plane simultaneously. 4. The microscope of claim 1 , wherein the volume hologram is recorded in phenanthrenquinone doped poly methyl methacrylate. 5. The microscope of claim 1 , further comprising a source of optical electromagnetic radiation for illumination of the source object. 6. The microscope of claim 1 , wherein diffraction by the volume hologram is based on one or more Bragg matching properties. 7. The microscope of claim 1 , wherein the first holographic grating corresponding to the first focal plane is specifically coded for reconstruction by the first wavelength of light and the second holographic grating corresponding to the second focal plane is specifically coded for reconstruction by the second wavelength of light. 8. A multiplexed volume hologram comprising a first wavelength-coded holographic grating and a second wavelength-coded holographic grating, the first wavelength-coded holographic grating configured to diffract light at a first wavelength emitted or scattered from a selected first depth of a source object into a beam diffracted at a first angle with respect to the multiplexed volume hologram, the second wavelength-coded holographic grating configured to diffract light at a second wavelength emitted or scattered from a selected second depth of the source object into a beam diffracted at a second angle with respect to the multiplexed volume hologram with the first wavelength being different from the second wavelength and the first angle being different from the second angle, wherein the selected first depth of the source object corresponds to a first focal plane determined by a first location of a point source generated from a single light source during recordation of the first holographic grating, wherein the selected second depth of the source object corresponds to a second focal plane determined by a second location of the point source generated from the single light source during recordation of the second holographic grating, wherein the first holographic grating corresponding to the first focal plane is coded for reconstruction by the first wavelength of light and the second holographic grating corresponding to the second focal plane is coded for reconstruction by the second wavelength of light, and wherein an angle of a signal beam with respect to a reference beam was different during recordation of the second holographic grating than during recordation of the first holographic grating and an angle of the volume hologram with respect to the reference beam was different during recordation of the second holographic grating than during recordation of the first holographic grating. 9. The volume hologram of claim 8 , wherein the hologram is recorded in phenanthrenquinone doped poly methyl methacrylate. 10. A volume imaging system for imaging an object of interest, the system comprising: a multiplexed volume holographic element with a first wavelength-coded holographic grating and a second wavelength-coded holographic grating, the first wavelength-coded holographic grating configured to diffract light at a first wavelength emitted or scattered from a selected first depth of the object of interest into a beam diffracted at a first angle with respect to the multiplexed volume holographic element, the second wavelength-coded holographic grating configured to diffract light at a second wavelength emitted or scattered from a selected second depth of the object of interest into a beam diffracted at a second angle with respect to the multiplexed volume holographic element with the first wavelength being different from the second wavelength and the first angle being different from the second angle, wherein the selected first depth of the object of interest corresponds to a first focal plane determined by a first location of a point source generated from a single light source during recordation of the first holographic grating, wherein the selected second depth of the object of interest corresponds to a second focal plane determined by a second location of the point source generated from the single light source during recordation of the second holographic grating, wherein the first holographic grating corresponding to the first focal plane is coded for reconstruction by the first wavelength of light and the second holographic grating corresponding to the second focal plane is coded for reconstruction by the second wavelength of light, and wherein an angle of a signal beam with respect to a reference beam was different during recordation of the second holographic grating than during recordation of the first holographic grating, and an angle of the volume holographic element with respect to the reference beam was different during recordation of the second holographic grating than during recordation of the first holographic grating; collector optics configured to: focus the diffracted beams from the first and the second grating to form corresponding