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Symbologies for encoding data, as well as methods of encoding and decoding thereof are described. The symbologies may have a plurality of pixels arranged in a plurality of patterns on or in a substrate. Furthermore, each of the plurality of pixels may have one or more optical properties that each pr

Symbologies for encoding data, as well as methods of encoding and decoding thereof are described. The symbologies may have a plurality of pixels arranged in a plurality of patterns on or in a substrate. Furthermore, each of the plurality of pixels may have one or more optical properties that each provides one or more types of non-interacting data.

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1. A symbology to encode data, wherein the symbology comprises a plurality of pixels arranged in a plurality of patterns on a substrate, wherein each of the plurality of pixels comprises a plurality of portions, each portion comprising one or more of a plurality of luminescent colorants, wherein eac

1. A symbology to encode data, wherein the symbology comprises a plurality of pixels arranged in a plurality of patterns on a substrate, wherein each of the plurality of pixels comprises a plurality of portions, each portion comprising one or more of a plurality of luminescent colorants, wherein each of the plurality of luminescent colorants has a corresponding luminance that decays, in response to an excitation event, according to a decay rate such that, as the corresponding luminance decays, optical properties associated with each of the plurality of portions comprising the corresponding luminance are changed, which alters encoded data contained within at least one portion of the symbology, thereby providing one or more types of non-interacting data encoded within the symbology. 2. The symbology of claim 1, wherein each portion further comprises a plurality of optical properties selected from a group comprising a color property, a shape property, a dimensional property, a relational property, an intensity property, a photobleaching property, a fluorescence property, a fluorescence resonance energy transfer property, and a gradient property. 3. The symbology of claim 2, wherein each of the plurality of optical properties provides one or more additional types of non-interacting data. 4. The symbology of claim 1, wherein each portion further comprises a shape that provides a first type of non-interacting data and a plurality of dimensions that provides a second type of non-interacting data. 5. The symbology of claim 1, wherein an intersection of a first luminescent colorant with a second luminescent colorant provides one or more types of non-interacting data. 6. The symbology of claim 5, wherein the intersection comprises one or more of a gradient and a shape. 7. The symbology of claim 1, wherein each of the one or more luminescent colorants comprises one or more of a fluorescent colorant and a phosphorescent colorant. 8. The symbology of claim 1, wherein at least one of the one or more luminescent colorants is a phosphorescent colorant having a phosphorescence that diminishes over a period of time. 9. The symbology of claim 8, wherein the phosphorescence provides at least one additional type of non-interacting data. 10. The symbology of claim 1, wherein at least one of the one or more luminescent colorants is a phosphorescent colorant having a phosphorescence that diminishes after repeated illumination. 11. The symbology of claim 10, wherein the phosphorescence provides at least one additional type of non-interacting data. 12. The symbology of claim 1, wherein the one or more types of non-interacting data each provide positioning information for the symbology. 13. A method to encode a symbology, the method comprising arranging a plurality of pixels on a substrate in a plurality of patterns to form a machine-readable code, wherein each of the plurality of pixels comprises a plurality of portions, each portion comprising one or more of a plurality of luminescent colorants, wherein each of the plurality of luminescent colorants has a corresponding luminance that decays, in response to an excitation event, according to a decay rate such that, as the corresponding luminance decays, optical properties associated with each of the plurality of portions comprising the corresponding luminance are changed, which alters encoded data contained within at least one portion of the symbology, thereby providing one or more types of non-interacting data encoded within the symbology. 14. The method of claim 13, wherein arranging the plurality of pixels comprises arranging the plurality of pixels such that each portion further comprises a shape that provides a first type of non-interacting data and a plurality of dimensions that provides a second type of non-interacting data. 15. The method of claim 13, wherein arranging the plurality of pixels comprises arranging the plurality of pixels such that an intersection of a first luminescent colorant with a second luminescent colorant provides one or more types of non-interacting data. 16. The method of claim 15, wherein arranging the plurality of pixels comprises arranging the plurality of pixels such that the intersection comprises one or more of a gradient and a shape. 17. The method of claim 13, wherein arranging the plurality of pixels comprises arranging the plurality of pixels such that each of the one or more luminescent colorants comprises one or more of a fluorescent colorant and a phosphorescent colorant. 18. The method of claim 13, wherein arranging the plurality of pixels comprises arranging the plurality of pixels such that at least one of the one or more luminescent colorants is a phosphorescent colorant having a phosphorescence that diminishes over a period of time. 19. The method of claim 13, wherein arranging the plurality of pixels comprises arranging the plurality of pixels such that at least one of the one or more luminescent colorants is a phosphorescent colorant having a phosphorescence that diminishes after repeated illumination. 20. The method of claim 13, wherein arranging the plurality of pixels comprises arranging the plurality of pixels such that the one or more types of non-interacting data each provide positioning information for the symbology. 21. A method to decode a symbology comprising a plurality of pixels having a plurality of portions, the method comprising: reading a shape of each portion of the plurality of pixels by an optical reading apparatus to obtain one or more first types of non-interacting data;reading a size of each portion of the plurality of pixels by the optical reading apparatus to obtain one or more second types of non-interacting data;reading one or more optical properties of each portion of the plurality of pixels by the optical reading apparatus to obtain one or more third types of non-interacting data;determining a luminance of each portion of the plurality of pixels by the optical reading apparatus to obtain one or more fourth types of non-interacting data, wherein the luminance decays, in response to an excitation event, over a period of time, such that, as the luminance decays, optical properties associated with each of the plurality of portions comprising the luminance are changed, which alters encoded data contained within at least one portion of the symbology, thereby providing non-interacting data encoded within the symbology;combining the first types of non-interacting data, the second types of non-interacting data, the third types of non-interacting data, and the fourth types of non-interacting data by a processing device; anddecoding the combination by the processing device. 22. A method to decode a symbology comprising a plurality of pixels having a plurality of portions, the method comprising: reading a shape and a size of each portion of the plurality of pixels by an optical reading apparatus to obtain one or more first types of non-interacting data;reading one or more optical properties of each portion of the plurality of pixels by the optical reading apparatus to obtain one or more second types of non-interacting data;determining a luminance of each portion of the plurality of pixels by the optical reading apparatus to obtain one or more third types of non-interacting data, wherein the luminance decays, in response to an excitation event, over a period of time such that, as the luminance decays, optical properties associated with each of the plurality of portions comprising the luminance are changed, which alters encoded data contained within at least one portion of the symbology, thereby providing non-interacting data encoded within the symbology;combining the first types of non-interacting data, the second types of non-interacting data, and the third types of non-interacting data by a processing device; anddecoding the combination by the processing device. 23. An article of manufacture comprising a symbology to encode data, wherein the symbology comprises a plurality of pixels arranged in a plurality of patterns on a substrate, wherein each of the plurality of pixels comprises a plurality of portions, each portion comprising one or more of a plurality of luminescent colorants, wherein each of the plurality of luminescent colorants has a corresponding luminance that decays, in response to an excitation event, according to a decay rate such that, as the corresponding luminance decays, optical properties associated with each of the plurality of portions comprising the corresponding luminance are changed, which alters encoded data contained within at least one portion of the symbology, thereby providing one or more types of non-interacting data encoded within the symbology. 24. The article of manufacture of claim 23, wherein the article of manufacture is selected from a group comprising apparel, computer components, storage devices, sanitation components, automobiles, chemicals, foods, beverages and paper products.