English

Terahertz Pulse Shaping Using Diffractive Surfaces

Optics 2021-01-05 v2 Neural and Evolutionary Computing

Abstract

Recent advances in deep learning have been providing non-intuitive solutions to various inverse problems in optics. At the intersection of machine learning and optics, diffractive networks merge wave-optics with deep learning to design task-specific elements to all-optically perform various tasks such as object classification and machine vision. Here, we present a diffractive network, which is used to shape an arbitrary broadband pulse into a desired optical waveform, forming a compact pulse engineering system. We experimentally demonstrate the synthesis of square pulses with different temporal-widths by manufacturing passive diffractive layers that collectively control both the spectral amplitude and the phase of an input terahertz pulse. Our results constitute the first demonstration of direct pulse shaping in terahertz spectrum, where a complex-valued spectral modulation function directly acts on terahertz frequencies. Furthermore, a Lego-like physical transfer learning approach is presented to illustrate pulse-width tunability by replacing part of an existing network with newly trained diffractive layers, demonstrating its modularity. This learning-based diffractive pulse engineering framework can find broad applications in e.g., communications, ultra-fast imaging and spectroscopy.

Keywords

Cite

@article{arxiv.2006.16599,
  title  = {Terahertz Pulse Shaping Using Diffractive Surfaces},
  author = {Muhammed Veli and Deniz Mengu and Nezih T. Yardimci and Yi Luo and Jingxi Li and Yair Rivenson and Mona Jarrahi and Aydogan Ozcan},
  journal= {arXiv preprint arXiv:2006.16599},
  year   = {2021}
}

Comments

27 pages, 6 figures

R2 v1 2026-06-23T16:43:37.672Z