Autochromes were produced by adding a single layer of dyed, finely sieved potato starch to a glass plate. These particles were applied in a single layer to a glass plate lightly covered in pitch (tree sap). In the spaces between the particles, lamp black was applies. The plate would then be pressed, flattening the particles in order to maximize translucency and minimize space between the particles. The plate would then be baked in order to fix the particles to the plate. The plate would then be covered in panchromatic emulsion.
Because the original autochrome patent covers any color photographic process which similarly uses a stochastic screen of such microfilters, we figured we could use colored gelatin in place of starch, the gelatin could be swollen such that it bumps up against neighboring particles, avoiding the need of the lampblack and requiring less pressure. The only issue we could not resolve was getting the filters to be applied to the plate in a single layer. If this could be resolved, it may be possible to sensitize the colored filters themselves, avoiding the shooting "through the glass" drawback of traditional autochromes.
One person suggested we could use inkjet printers, and instead of using a glass plate we could use transparency films. One problem exists in that inkjets inks not wholly waterproof, however this could be solved by using fixative. The printed inkjet screen would then be coated in a panchromatic emulsion.
At the time, panchromatic dyes were not well understood to the laymen. However today resources from the holography community are available which describe how to dye silver-based emulsions to provide greater red and green sensitivity, this should not be as much an issue
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