TMMax: High-performance modeling of multilayer thin-film structures using transfer matrix method with JAX

Abstract: Optical multilayer thin-films are fundamental components that enable the precise control of reflectance, transmittance, and phase shift in the design of photonic systems. Rapid and accessible simulation of these structures holds critical importance for designing and analyzing complex coatings, such as distributed Bragg reflectors, anti-reflection layers, and spectral filters. While researchers commonly use the traditional transfer matrix method for designing these structures, its scalar approach to wavelength and angle of incidence causes redundant recalculations and inefficiencies in large-scale simulations. Furthermore, traditional method implementations do not support automatic differentiation, which limits their applicability in gradient-based inverse design approaches. Here, we present TMMax, a Python library that fully vectorizes and accelerates transfer matrix method using the high-performance machine learning library JAX. TMMax supports CPU, GPU, and TPU hardware, includes a publicly available material database, and offers comprehensive multilayer optical thin-film analysis tools. Our approach, demonstrated through benchmarking, allows us to model thin-film stacks with hundreds of layers within seconds. This illustrates that our method achieves a simulation speedup of x100s over a baseline NumPy implementation, providing a significant advantage in computational efficiency. Our method enables rapid and scalable simulations of large and complex multilayer thin-film structures, significantly accelerating the design process.