Optical phantom for producing a time-resolved diffuse reflectance spectrum

What is claimed is: 1 . An optical phantom to produce a time-resolved diffuse reflectance spectrum, the optical phantom comprising: a light source that produces a first light; a spatial light modulator comprising a plurality of mirrors arranged in an array, the mirrors being independently controlled to reflect the first light in a plurality of light paths comprising a first light path and a second light path, such that the spatial light modulator: receives the first light over the plurality of mirrors; selectively reflects the first light as filtered light into the light paths such that the first light path includes a first photon flux and the second light path includes a second photon flux, the first photon flux being greater than the second photon flux; and an optical delay line comprising a plurality of optical fibers that comprises a first delay fiber and a second delay fiber, such that: a first optical entrance of the first delay fiber is disposed in the first light path and receives the first photon flux from the spatial light modulator; a second optical entrance of the second delay fiber is disposed in the second light path and receives the second photon flux from the spatial light modulator; the first delay fiber has a first length and produces a first time-of-flight distribution of the first photon flux after propagating through the first delay fiber; and the second delay fiber has a second length and produces a second time-of-flight distribution of the second photon flux after propagating in the second delay fiber; the first length being different than the second length so that the first time-of-flight distribution is different than the second time-of-flight distribution; and a combination of the first time-of-flight distribution and the second time-of-flight distribution are combined to produce phantom light having the time-resolved diffuse reflectance spectrum. 2 . The optical phantom of claim 1 , further comprising a telescope interposed between the light source and the spatial light modulator, such that telescope receives the first light from the light source and enlarges a cross-sectional area of the first light to cover a selected portion of the mirrors. 3 . The optical phantom of claim 1 , further comprising a polarizer interposed between the light source and the spatial light modulator, such that the polarizer receives the first light from the light source and selectively polarizes the first light to be received by the mirrors. 4 . The optical phantom of claim 1 , further comprising a polarizer interposed between the spatial light modulator and the optical delay line, such that the polarizer receives filtered light from the spatial light modulator and selectively polarizes the filtered light to be received by the optical fibers. 5 . The optical phantom of claim 1 , further comprising an optical density filter interposed between the spatial light modulator and the optical delay line, such that the optical density filter: receives the filtered light from the spatial light modulator; increases a contrast between the first photon flux and the second photon flux; and communicates the first photon flux and the second photon flux with increased contrast to the optical delay line. 6 . The optical phantom of claim 1 , further comprising a light detector in optical communication with the optical delay line to receive the phantom light communicated from the optical fibers and to produce a time-of-flight signal from the first photon flux and the second photon flux. 7 . The optical phantom of claim 6 , further comprising a time correlator in communication with the light detector and the light source and that: receives the time-of-flight signal from the light detector; receives a timing signal from the light source; and correlates the first time-of-flight distribution and the second time-of-flight distribution with the timing signal from the light source. 8 . An optical phantom for testing a measuring device for time-resolved diffuse optical spectroscopy, the optical phantom comprising: an input optic in optical communication with a light supply line; a filter device in optical communication with the light supply line and disposed in a direction of propagation of light from light supply line; and an optical delay line in optical communication with the filter device and comprising a plurality of optical delay fibers, the optical delay fibers being arranged relative to the filter device such that light received by each of optical delay fiber is individually filtered by the filter device, the optical delay fibers being joined to receive light leaving the filter device, such that the optical delay line produces phantom light with time-resolved diffuse reflectance spectrum in response to receiving first light with an initial time-of-flight distribution at input optic, wherein optical delay fibers comprise different optical path lengths (wi) for light such that output pulse lengths of photon time-of-flight distributions from the optical delay fibers are greater than an input pulse length of the first light, and a combination of the optical delay line and the filter device provide the time-resolved diffuse reflectance spectrum that mimics a photon time-of-flight distribution produced by biological tissue upon subjecting the biological tissue to a pulse of light from the measuring device. 9 . The optical phantom of claim 8 , wherein the filter device comprises a spatial light modulator. 10 . The optical phantom of claim 9 , wherein the spatial light modulator comprises a liquid crystal light modulator. 11 . The optical phantom of claim 8 , wherein the optical delay fibers independently comprise a graded-index glass fiber. 12 . The optical phantom of claim 8 , wherein the input optic comprises a plurality of light supply lines in optical communication with the filter device such that one light supply line exists for each optical delay fiber, and light exiting the light supply line is communicated to the filter device and subsequently enters an optical delay fiber. 13 . The optical phantom of claim 8 , wherein the filter device comprises: a wavelength-selective light filter; and an array of filter elements, wherein the filter elements are arranged such that filtering by the filter elements depends on a wavelength of light, and a plurality of different time-of-flight distributions are produced based on a difference in wavelength of light filtered by the filter device. 14 . The optical phantom of claim 13 , wherein the wavelength-selective light filter comprises a dispersive element. 15 . A method for producing phantom light having a time-resolved diffuse reflectance spectrum for testing a measuring device for time-resolved diffuse optical spectroscopy of biological tissue, the method comprising: illuminating a filter device with an input light pulse from an input optic, wherein each filter element of the filter device receives photons as a partial light pulse from the input light pulse incident on the filter device; filtering the partial light pulses by the filter device, a filter transmission varies for at least one of the partial light pulses; guiding of the partial light pulses along optical paths w i of varying lengths of an optical delay line; and merging the partial light pulses by a light collector arranged in optical communication with the filter device in a direction of light propagation, such that phantom light exits an output surface of the light collector, wherein the optical paths w i are selected and filtering is conducted such that a time-res