A new active thermography scheme is here introduced, referred as "'Multi -Frequency Thermography"', which uses an optimized multi -tone signal for simultaneously implementing lock -in analysis on a discrete and arbitrary set of linearly spaced frequencies. Such a signal, which modulates the intensity of the heating source here being a LED system in the visible range, results from the non -trivial summation of a desired number of odd and even harmonics of a fundamental tone, each of them having a specific initial phase value but equal amplitude, so as to deliver the same energy amount for all the chosen frequencies. In this way, a discrete set of thermal waves having different diffusion lengths are simultaneously excited within the inspected sample to probe different depths into it. With respect to standard lock -in thermography, it is demonstrated that the proposed approach can extract amplitude and phase features for all the excited frequencies from a single measurement, which lasts as long as a lock -in implemented at the fundamental tone. Both quantitative and qualitative comparisons with standard lock -in thermography are here reported, showing an excellent agreement. Hence, this new active thermography scheme can provide several advantages in practical implementations of thermography nondestructive evaluation.
Simultaneous Multi-frequency lock-in Thermography: A new flexible and effective Active Thermography scheme
Laureti, Stefano
;Zito, Rocco;Ricci, Marco
2024-01-01
Abstract
A new active thermography scheme is here introduced, referred as "'Multi -Frequency Thermography"', which uses an optimized multi -tone signal for simultaneously implementing lock -in analysis on a discrete and arbitrary set of linearly spaced frequencies. Such a signal, which modulates the intensity of the heating source here being a LED system in the visible range, results from the non -trivial summation of a desired number of odd and even harmonics of a fundamental tone, each of them having a specific initial phase value but equal amplitude, so as to deliver the same energy amount for all the chosen frequencies. In this way, a discrete set of thermal waves having different diffusion lengths are simultaneously excited within the inspected sample to probe different depths into it. With respect to standard lock -in thermography, it is demonstrated that the proposed approach can extract amplitude and phase features for all the excited frequencies from a single measurement, which lasts as long as a lock -in implemented at the fundamental tone. Both quantitative and qualitative comparisons with standard lock -in thermography are here reported, showing an excellent agreement. Hence, this new active thermography scheme can provide several advantages in practical implementations of thermography nondestructive evaluation.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.