Abstract
Pulsed photothermal radiometry (PPTR) is a non-contact method for determining the temperature increase in subsurface chromophore layers immediately following pulsed laser irradiation. In this paper the inherent limitations of PPTR are identified. A time record of infrared emission from a test material due to laser heating of a subsurface chromophore layer is calculated and used as input data for a non-negatively constrained conjugate gradient algorithm. Position and magnitude of temperature increase in a model chromophore layer immediately following pulsed laser irradiation are computed. Differences between simulated and computed temperature increase are reported as a function of thickness, depth and signal-to-noise ratio (SNR). The average depth of the chromophore layer and integral of temperature increase in the test material are accurately predicted by the algorithm. When the thickness/depth ratio is less than 25%, the computed peak temperature increase is always significantly less than the true value. Moreover, the computed thickness of the chromophore layer is much larger than the true value. The accuracy of the computed subsurface temperature distribution is investigated with the singular value decomposition of the kernel matrix. The relatively small number of right singular vectors that may be used (8% of the rank of the kernel matrix) to represent the simulated temperature increase in the test material limits the accuracy of PPTR. We show that relative error between simulated and computed temperature increase is essentially constant for a particular thickness/depth ratio.
Highlights
Pulsed photothermal radiometry (PPTR) is a non-contact method for obtaining information on subsurface chromophores in a test material
Our results indicate the circumstances when PPTR may be used to accurately predict the thickness, depth and magnitude of temperature increase in the chromophore layer contained in a test material
The mean of the deduced temperature distribution and Tcg(z) dz were predicted accurately (±10%), except for cases of (i) thickness/depth ratio less than 10%, (ii) signal-to-noise ratio (SNR) below 10, or (iii) T0 less than 5 ◦C
Summary
Pulsed photothermal radiometry (PPTR) is a non-contact method for obtaining information on subsurface chromophores in a test material. A fast infrared detector is used to measure increase in infrared emission at the test material surface following pulsed laser irradiation (Milner et al 1995a, b). From the time record of infrared emission increase, estimates of thickness and depth of subsurface chromophores can be computed. Analysis of the performance of PPTR to accurately compute the size and position of blood vessels in a port wine stain (PWS) is of particular interest. Efficacy of the pulsed laser treatment of PWS can be improved if the size and position of blood vessels is known (Kimel et al 1994)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
