Imaging fluorescence or luminescence lifetime

What is claimed is: 1. A device for use in fluorescence or luminescence lifetime imaging, the device comprising: a chip comprising: an imaging region comprising a photodetector for receiving a first optical signal corresponding to excitation light from a light source, and a second optical signal corresponding to emitted fluorescence or luminescence from a sample; and a time-to-digital converter for providing digital phase output based on the first and second optical signals, wherein the digital phase output corresponds to a temporal offset between waveforms corresponding to the excitation light and the emitted fluorescence or luminescence from the sample. 2. The device of claim 1 , wherein the imaging region comprises an array of photodetectors. 3. The device of claim 1 , wherein the chip comprises an integrated complementary metal-oxide semiconductor (CMOS) chip, and wherein the CMOS chip further comprises a phase extraction circuit that extracts a phase shift from the first and second optical signals and delivers the extracted phase shift to the time-to-digital converter. 4. The device of claim 1 , wherein the time-to-digital converter is configured to provide a localized digital phase output. 5. The device of claim 4 , wherein the time-to-digital converter comprises one or more delay cells and an encoder that scans the delay cells to locate the localized digital phase output. 6. The device of claim 1 , wherein the chip has a surface area of about 4 mm by 4 mm. 7. A microscope comprising: a lens; and an integrated complementary metal-oxide semiconductor (CMOS) chip comprising: an imaging region comprising a photodetector for receiving a first optical signal corresponding to excitation light from a light source, and a second optical signal corresponding to emitted fluorescence or luminescence from a sample that passes through the lens; and a time-to-digital converter for providing digital phase output based on the first and second optical signals, wherein the digital phase output corresponds to a temporal offset between waveforms corresponding to the excitation light and the emitted fluorescence or luminescence from the sample. 8. The microscope of claim 7 , wherein the microscope is an oxygen sensing microscope that further comprises an arbitrary function generator. 9. The microscope of claim 7 , wherein the imaging region comprises an array of photodetectors. 10. The microscope of claim 7 , wherein the integrated CMOS chip further comprises a phase extraction circuit that extracts a phase shift from the first and second optical signals and delivers the extracted phase shift to the time-to-digital converter. 11. The microscope of claim 7 , wherein the time-to-digital converter is configured to provide a localized digital phase output. 12. The microscope of claim 11 , wherein the time-to-digital converter comprises delay cells and an encoder that scans the delay cells to locate the localized digital phase output. 13. The microscope of claim 7 , wherein the CMOS chip has a surface area of about 4 mm by 4 mm. 14. A scanner for use in detecting skin cancer, the scanner comprising: an integrated complementary metal-oxide semiconductor (CMOS) chip comprising: an imaging region comprising a photodetector for receiving a first optical signal corresponding to excitation light from a light source, and a second optical signal corresponding to emitted fluorescence or luminescence from a sample; and a time-to-digital converter for providing digital phase output based on the first and second optical signals, wherein the digital phase output corresponds to a temporal offset between waveforms corresponding to the excitation light and the emitted fluorescence or luminescence from the sample; and a display for displaying the digital phase output from the integrated CMOS chip. 15. The scanner of claim 14 , wherein the scanner is portable. 16. The scanner of claim 15 , wherein the scanner is sized and configured to be hand-held. 17. The scanner of claim 14 , wherein the imaging region comprises an array of photodetectors. 18. The scanner of claim 14 , wherein the integrated CMOS chip further comprises a phase extraction circuit that extracts a phase shift from the first and second optical signals and delivers the extracted phase shift to the time-to-digital converter. 19. The scanner of claim 14 , wherein the time-to-digital converter is configured to provide a localized digital phase output. 20. The scanner of claim 19 , wherein the time-to-digital converter comprises delay cells and an encoder that scans the delay cells to locate the localized digital phase output. 21. The scanner of claim 14 , wherein the CMOS chip has a surface area of about 4 mm by 4 mm.