Adjustable color correction for automated high intensity stage lights

What is claimed is: 1. A color correction filter comprising: an optical substrate; said optical substrate having a first surface, and a first coating on only a portion of said first surface, said first coating first attenuating by a first amount both first and second spectral peaks in an optical beam passing through said optical substrate, said first coating having a density gradient between a first area of the substrate that has said coating and a second area of the first surface that does not have said coating, the density gradient effective to prevent an edge of the coating from being visible in a beam that passes through the edge, said optical substrate also having a second surface opposite said first surface, said second surface having at least first, second and third separate areas, said first area defining a first filter deposited on the optical substrate and lowering a color temperature of the light to a first level, said second area defining a second filter deposited on the optical substrate and raising the color temperature of the light to a second level greater than said first level, and said third area defining a third filter deposited on the optical substrate and changing the color temperature of the light to a third level different than either of said first or second levels. 2. The filter as in claim 1 , wherein said optical substrate is in the shape of a wheel having different areas of coating on different areas of said wheel. 3. A filter as in claim 1 , wherein said first and second spectral peaks comprise areas of two mid-band mercury peaks for spectral emission. 4. A filter as in claim 3 , wherein said first coating reduces an energy in the areas of said two mid-band Mercury peaks, without removing all of the energy in said areas. 5. A filter as in claim 4 , wherein said first and second peaks include area centered around 546 nm and 578 nm. 6. The filter as in claim 1 , wherein said first coating is on a side of said filter that faces to a light source, and said second surface faces to a lens. 7. The filter as in claim 6 , wherein said filters each include a density gradient across an area of said filter. 8. The filter as in claim 7 , wherein said filters each also include an area of constant density gradient. 9. The filter as in claim 1 , wherein said second surface includes said first area that lowers the color temperature to 3000 K, said second area that raises the color temperature to 7500 K, and the third area that raises the color temperature to 6500 K. 10. A color correction filter comprising: an optical substrate, having first and second coatings on opposite surfaces thereof, said first coating on a first surface of the substrate and said second coating on a second surface of the substrate, said first coating including a dual peak suppression filter over an area of the first surface of the substrate; said second coating including a color temperature modifying filter, having different modifying characteristics at different locations thereof, and having at least a first color temperature increasing part at a first location thereof which is opposite to said area of said first coating, and a second color temperature decreasing part at a second location thereof which is opposite to said area of said first coating, so that light passing through both said first color temperature increasing part and said second color temperature decreasing part also pass through said area of said first coating having said dual peak suppression filter, said second coating including a density gradient along at least a portion of an axis of the filter, wherein both said first surface and said second surface includes an area where there is no coating on opposite side thereof, and an edge of first coating has a density gradient effective to prevent said edge from being visible in a beam that passes through the edge. 11. The filter as in claim 10 , wherein said first coating attenuating by a first amount both first and second mid-band mercury-created spectral peaks in an optical beam passing through said optical substrate, said first amount being greater than a second amount by which spectral ranges outside a range including said spectral peaks are attenuated, and where said attenuating by the first amount reduces an energy in areas of said first and second mid-band mercury peaks, without removing all of the energy. 12. The filter as in claim 11 wherein said second coating includes at least one color correction filter that corrects color for said attenuating of said first and second mid-band mercury-created spectral peaks. 13. A filter as in claim 12 , wherein said attenuating of said first and second mid-band mercury-created spectral peaks by said first coating is by an amount less than 55%, and said first coating second attenuating of spectral ranges outside a range including said spectral peaks by said second amount, the attenuating by said second amount being an attenuating which is less than 20%. 14. The filter as in claim 12 , wherein said first color temperature increasing part increases the color temperature to 7500K, and said second color temperature decreasing part lowers the color temperature of the light beam to 3000K. 15. The filter as in claim 14 , wherein said first and second color temperature parts each include a density gradient across an area of said color correction filter. 16. The filter as in claim 15 , wherein said color filter is circular, and said density gradient is along a circumferential direction of the filter. 17. The filter as in claim 16 , wherein said color correction filters each also include an area of constant density gradient. 18. A filter as in claim 11 , wherein said first and second peaks include area centered around 546 nm and 578 nm. 19. A color correction filter comprising: an optical substrate, having first and second coatings coated on said optical substrate, said first coating attenuating by a first amount both first and second spectral peaks in an optical beam passing through said optical substrate over a first area of said substrate, said first amount being greater than a second amount by which spectral ranges outside a range including said spectral peaks are attenuated, and where said attenuating by the first amount reduces an energy of said first and second peaks, without removing all of the energy in said first and second peaks, and said second coating carries out a first color correction filtering on a second area of the substrate which raises a color temperature of the light beam and a second color correction filtering on a third area of the substrate which lowers the color temperature of the light beam, where both said first and second color correction filtering correct color of an optical beam also passing through said first coating, wherein both said first and second coatings cover only a portion of the substrate, leaving an open area of the substrate which does not have the first coating thereon and which does not filter light in said area, and where edges of both said first coating and said second coating that are adjacent to said open area, have a density gradient effective to prevent a filter edge from being visible in a beam that passes through the edges, wherein said first second coatings are coated on opposite surfaces of the optical substrate, wherein said second coating has a first color correction filter property on said second area thereof, said first color correction filter property which raises a color temperature of the light beam and wherein said second coating has a se