Ultra high entropy material-based non-reversible spectral signature generation via quantum dots

12166,866

18/363857

August 02, 2023

A physically unclonable function (PUF) device is provided, comprising an excitation source providing light for exciting quantum dots (QDs); a first layer of a material having contained therein a first random distribution of first QDs of a first type that are configured to generate a first color in response to being excited by the excitation source; a second layer of a second material having contained therein a second random distribution of second QDs of a second type that are configured to generate a second color, different from the first color, in response to being excited by the first excitation source, and a detector fixedly attached to one of the first and second layers and configured for detecting a pattern of light emitted by at least one of the first QDs and the second QDs and for providing an output indicative of the detected pattern.

Raytheon Company (Waltham, MA, US)

Raytheon Company (Tewksbury, MA, US)

1. A method of verifying an article of manufacture, the method comprising: coupling to an article of manufacture a physically unclonable function (PUF) device that comprises: a first excitation source configured to be externally controllable to provide light at a frequency suitable for exciting quantum dots (QDs); a first layer of a first material having contained therein a first random distribution of first quantum dots (first QDs) of a first type, disposed at a first plurality of random locations, wherein the first type of the first QDs are configured to generate a first color in response to being excited by light from the first excitation source; a second layer of a second material having contained therein a second random distribution of second QDs of a second type, disposed at a second plurality of random locations, wherein the second type of the second QDs are configured to generate a second color in response to being excited by light from the first excitation source, wherein the second color is different from the first color; and a detector fixedly attached to one of the first and second layers, the detector configured for detecting a first pattern of light emitted by at least one of the first QDs and the second QDs in response to the first excitation source providing light, wherein the detector is configured for providing an output indicative of the detected first pattern of light; causing the first excitation source providing light to excite at least a portion of the first random distribution of first QDs and at least a portion of the second random distribution of second QDs; causing the detector, in response to the first excitation source providing light, to detect the first pattern of light and to provide the output indicative of the detected first pattern of light; receiving from the PUF device, in response to the first excitation source providing light and the detector detecting the first pattern of light, the output indicative of the detected first pattern of light; and verifying the article of manufacture if the output indicative of the detected first pattern of light satisfies a first predetermined condition.

2. The method of claim 1 wherein the output indicative of the detected first pattern of light comprises a spectral signature.

3. The method of claim 1 further comprising configuring the PUF device to convert the detected first pattern of light into a digital fingerprint.

4. The method of claim 3 , wherein the digital fingerprint is configured to be unique to the PUF device.

5. The method of claim 1 , wherein the output indicative of the detected first pattern of light has a first appearance if the detector is fixedly attached to the first layer and a second appearance if the detector is fixedly attached to the second layer, wherein the first appearance is different from the second appearance.

6. The method of claim 1 , wherein the first excitation source is disposed at a first location and is configured to emit light at a first angle and wherein the method further comprises: coupling a second excitation source to the PUF device, the second excitation source externally controllable to provide second light at the frequency suitable for exciting QDs, wherein the second excitation source is disposed at a second location different than the first location, so that the second excitation source is configured to emit light at a second angle different than the first angle; causing the second excitation source providing light to excite at least a portion of the first random distribution of first QDs and at least a portion of the second random distribution of second QDs; causing the detector, in response to the second excitation source providing light, to detect a second pattern of light and to provide an output indicative of the detected second pattern of light; receiving from the PUF device, in response to the second excitation source providing light and the detector detecting the second pattern of light, the output indicative of the detected second pattern of light; and verifying that the output indicative of the detected second pattern of light satisfies a second predetermined condition.

7. The method of claim 1 , wherein the detected first pattern of light is unique to the PUF.

8. The method of claim 1 , further comprising: configuring the detector to determine a hash of the detected first pattern of light; and communicating the hash of the first pattern of light to an external system that is configured to determine if the hash of the first pattern of light matches a stored hash associated with at least one of the article of manufacture and the PUF device.

9. The method of claim 1 , wherein the PUF device is configured so that the light and the first pattern of light are externally unrevealed.

10. The method of claim 1 , wherein the PUF further comprises a reflector fixedly attached to one of the first and second layers, the reflector configured to re-direct unabsorbed light back into the PUF device.

11. The method of claim 10 , wherein the reflector is configured to provide at least one of mechanical and electrical protection for the PUF device.

12. The method of claim 10 , wherein the reflector is configured to conceal at least one of the light from the first excitation source and the first pattern of light.

13. The method of claim 10 , wherein the reflector is configured to conceal the light from the first excitation source and the first pattern of light.

14. The method of claim 1 , further comprising enclosing at least a portion of the PUF device within a tamper evident structure, wherein an arrangement of the PUF device and the tamper evident structure is configured so that an attempt to view the PUF device causes damage to at least one of the first random distribution of first QDs and the second random distribution of second QDs, wherein the damage changes the first pattern of light.

15. A method of authenticating, the method comprising: providing a layered structure comprising: a first layer of a first material having contained therein a first random distribution of first quantum dots (QDs) of a first type, disposed at a first plurality of random locations, wherein the first type of QDs are configured to generate a first color in response to being excited by light; and a second layer of a second material having contained therein a second random distribution of second QDs of a second type, disposed at a second plurality of random locations, wherein the second type of QDs are configured to generate a second color in response to being excited by light, wherein the second color is different from the first color; coupling to the layered structure an excitation source configured to be externally controllable to provide light at a frequency suitable for exciting quantum dots (QDs); coupling a detector to at least one of the first and second layers, the detector configured for detecting a pattern of light emitted by at least one of the first QDs and the second QDs in response to the excitation source providing light, wherein the detector is configured for providing an output indicative of the detected pattern of light; causing the excitation source providing light to excite at least a portion of the first random distribution of first QDs and at least a portion of the second random distribution of second QDs; causing the detector, in response to the excitation source providing light, to detect the pattern of light and to provide the output indicative of the detected pattern of light; receiving from the layered structure, in response to the excitation source providing light and the detector detecting the pattern of light, the output indicative of the detected pattern of light; and basing an authentication decision on whether the output indicative of the detected pattern of light satisfies a predetermined condition.

16. The method of claim 15 wherein the pattern of light has a first appearance if the detector is coupled to the first layer and a second appearance if the detector is coupled to the second layer, wherein the first appearance is different from the second appearance.

17. The method of claim 15 , wherein the layered structure is configured so that the light from the excitation source and the pattern of light are externally unrevealed.

18. An authentication method, comprising: providing a layered structure comprising: a first layer of a first material having contained therein a first random distribution of first quantum dots (QDs) of a first type, disposed at a first plurality of random locations, wherein the first type of QDs are configured to generate a first color in response to being excited by light; a second layer of a second material having contained therein a second random distribution of second QDs of a second type, disposed at a second plurality of random locations, wherein the second type of QDs are configured to generate a second color in response to being excited by light, wherein the second color is different from the first color; an excitation source controllable to provide light at a frequency suitable for exciting QDs; and a detector configured for detecting a pattern of light emitted by at least one of the first QDs and the second QDs in response to the excitation source providing light, wherein the detector is configured for providing an output indicative of the detected pattern of light; causing the excitation source providing light to excite at least a portion of the first random distribution of first QDs and at least a portion of the second random distribution of second QDs; causing the detector, in response to the excitation source providing light, to detect the pattern of light and to provide the output indicative of the detected pattern of light; and making an authentication decision based on whether the detected pattern of light satisfies a predetermined condition.

19. The method of claim 18 , further comprising: determining a first hash of the detected pattern of light; and communicating the first hash to an external system configured to determine if the first hash matches a second hash, wherein the second hash comprises a stored hash associated with the layered structure; and making the authentication decision based on whether the first hash matches the second hash.

20. The method of claim 18 , further comprising using the output indicative of the detected pattern of light as an access code to access another entity.

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