A number of biometric systems and methods are disclosed. A system according to one embodiment includes an illumination subsystem, an imaging subsystem, and an analyzer. The illumination subsystem is disposed to illuminate a target space. The imaging subsystem is configured to image the target space
A number of biometric systems and methods are disclosed. A system according to one embodiment includes an illumination subsystem, an imaging subsystem, and an analyzer. The illumination subsystem is disposed to illuminate a target space. The imaging subsystem is configured to image the target space under distinct optical conditions. The analyzer is provided in communication with the illumination subsystem, the imaging subsystem, and the three-dimensional subsystem. The analyzer also has instructions to operate the subsystems to collect substantially simultaneously a plurality of images of the object disposed at the predetermined spatial location under multispectral conditions.
대표청구항▼
1. A contactless biometric system comprising: an illumination source configured to illuminate a target space with polarized light of a first polarization condition;a first imager configured to receive light scattered from a purported skin site of an individual within at least a portion of the target
1. A contactless biometric system comprising: an illumination source configured to illuminate a target space with polarized light of a first polarization condition;a first imager configured to receive light scattered from a purported skin site of an individual within at least a portion of the target space under the first polarization condition;a second imager configured to simultaneously receive light scattered from the purported skin site within at least a portion of the target space under a second polarization condition, wherein the second imager is distinct from the first imager, wherein the first polarization condition is distinct from the second polarization condition; andan analyzer communicatively coupled with the illumination source, the first imager, and the second imager, wherein the analyzer is configured to control the operation of the illumination source, the first imager, and the second imager in order to perform a biometric function based on the light received at the first imager and the second imager. 2. The contactless biometric system according to claim 1, wherein the analyzer is further configured to produce a multispectral image of the skin site. 3. The contactless biometric system according to claim 1, wherein the skin site is not in physical contact with the biometric system. 4. The contactless biometric system according to claim 1, wherein the illumination source comprises a polarizer. 5. The contactless biometric system according to claim 1, wherein the illumination source comprises a linear polarizer. 6. The contactless biometric system according to claim 1, wherein the illumination source comprises a circular polarizer. 7. The contactless biometric system according to claim 1, wherein the first polarization condition is parallel with the polarized light from the illumination source. 8. The contactless biometric system according to claim 1, wherein the first polarization condition is orthogonal with the polarized light from the illumination source. 9. The contactless biometric system according to claim 1, wherein the illumination source comprises a plurality of illumination sources that are configured to illuminate the target space with polarized light. 10. The contactless biometric system according to claim 9, wherein two of the plurality of illumination sources illuminate the target space with cross-polarized light. 11. The contactless biometric system according to claim 10, wherein the first imager comprises a first polarizer that filters light according to the first polarization condition and the second imager comprises a second polarizer that filters light according to the second polarization condition. 12. The contactless biometric system according to claim 1 further comprising a housing, wherein the illumination source, the first imager, and the second imager are coupled together with the housing, and wherein the target space is distinct from the housing. 13. The contactless biometric system according to claim 1, wherein the skin site comprises a human hand. 14. A contactless biometric method comprising: illuminating a skin site with polarized light of a first polarization condition;collecting light with the first polarization condition from the skin site;simultaneously collecting light with a second polarization condition from the skin site, wherein the second polarization condition is distinct from the first polarization condition; andperforming a biometric function with the light collected with the first polarization condition and the second polarization condition. 15. The contactless biometric method according to claim 14, wherein the skin site is not in contact with a platen. 16. The contactless biometric method according to claim 14 further comprising producing an image of the skin site from the light collected with the first polarization condition and the light collected with the second polarization condition. 17. The contactless biometric method according to claim 14, wherein the light with the first polarization condition is cross-polarized with the polarized light used to illuminate the skin site. 18. The contactless biometric method according to claim 14, wherein the light with the first polarization condition is parallel with polarized light used to illuminate the skin site. 19. The contactless biometric method according to claim 14, wherein the biometric function comprises determining the identity of the individual. 20. A contactless biometric system comprising: an illumination subsystem configured to illuminate a target space with polarized light of a first polarization condition;a first imager configured to receive light scattered from a purported skin site of an individual within at least a portion of the target space under the first polarization condition, wherein the skin site is not in physical contact with the biometric system;a second imager configured to simultaneously receive light scattered from the purported skin site within at least a portion of the target space under a second polarization condition, wherein the second imager is separate from the first imager, wherein the first polarization condition is distinct from the second polarization condition; andan analyzer communicatively coupled with the illumination source, the first imager, and the second imager, wherein the analyzer is configured to control the operation of the illumination source, the first imager, and the second imager in order to perform a biometric function based on the light received at the first imager and the second imager.
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