About us
We are a theoretical research group at the School of Electrical and Electronic Engineering and the Institute for Digital Molecular Analytics and Science at Nanyang Technological University, Singapore. The group is lead by Assistant Professor Matthew R. Foreman.
Our research focuses on optical and plasmonic sensing, polarisation sensitive imaging, disordered media and electromagnetic theory. More information on some of our past and present projects can be found by visiting our Research pages.
Recent news
Joint A*STAR - DST grant awarded!
15 Jun 2026: We are happy to announce that we have been awarded a new joint grant by A*STAR (Singapore) and the Department of Science and Technology (India) for our project "Physics Informed AI Powered Polarisation Sensitive Mobile Based Cancer Diagnosis". Working alongside collaborators at the Manipal School of Life Sciences, the project aims to build an affordable, smartphone-based polarization imaging platform for telepathology. The Optical Theory Group will be leading the physical modeling efforts, embedding rigorous electromagnetic models directly into novel AI architectures to ensure physical plausibility and robustness.
Congratulations Dr Feng!
13 May 2026: Huge congratulations to Zhonghe Feng, who successfully defended his PhD thesis today at Imperial College London. His work, "Polarisation Microscopy and Its Application to Optical Data Storage: Design, Informational Analysis, and ML-Based Decoding", was co-supervised with Prof. Mark Neil and James Clegg from Microsoft Research Cambridge. The project, which involved developing systems for 3D birefringence measurement and data readout, was generously funded by Microsoft Research. It’s been a pleasure to see this work through to a successful defense, and we will be posting the final thesis here very soon. Well done, Zhonghe!
New arXiv preprint posted!
6 May 2026: We have just posted a new preprint to arXiv, "Anisotropic memory effects in single scattering disordered media", by Niall Byrnes. In this work, we investigate anisotropy in Fourier-domain speckle correlations and show that correlation strength depends non-trivially on axial wavevector components, a factor often neglected in scattered field correlations. The study includes both theoretical derivations and 3D numerical simulations, demonstrating that analogous anisotropic behavior also arises in the conjugate memory effect. These results offer a more complete picture of how axial disorder influences optical memory effects in disordered media. Read the full paper here.
ICMVA 26 and accompanying arXiv preprint
27 Apr 2026: This week Ganesh is in Nanjing, China, for the 9th International Conference on Machine Vision and Applications (ICMVA 2026). He gave an invited talk on our recent breakthroughs in single-shot lensless imaging. This work, a collaboration between Ganesh, Radhika, and Xiao-Liu Chu, introduces a genetically programmed algorithm that eliminates the need for multiple measurements or object-specific training. By coupling wave-propagation models with adaptive meta-optimisation, we’ve demonstrated high-fidelity recovery of both amplitude and phase-dominant samples, including U2OS cells and β-amyloid-based digital assays. You can read the full details in our latest preprint, "Single-Shot Lensless Imaging with Physics Guided Genetic Programming" now available on arXiv.
Recent publications
Abstract : Exceptional points (EPs) have long promised enhanced sensing of physical signals, but have practically been limited by simultaneous enhancement of noise. Aligning an EP's non-analytic response with target perturbations while suppressing noise has, however, remained challenging. Here we show that fully passive, phase-tuned multi-port scattering networks enable scattering EPs with tailored anisotropic response to perturbations. We leverage projection-induced non-unitarity to realize effective non-Hermitian behavior when measuring only a subset of system ports. By formulating EP design in terms of the discriminant of the projected scattering sub-block and its directional derivatives, we give control-counting rules relating the number of programmable link phases to achievable Riemann surface topologies. We demonstrate our framework in a four-port photonic network by designing both an anisotropic EP and a Dirac-type EP with linear splitting along two parametric directions. We further suppress the global thermal drift response of a network-based sensor to a 3/2 power-law scaling while retaining square-root sensitivity to localized signals. Since the effective non-Hermiticity arises purely from port projection, our approach transfers to integrated photonic and microwave meshes, acoustic circuits, and projected metasurfaces, offering a phase-only route to reconfigurable non-Hermitian response and noise-robust EP sensing.
Abstract : We investigate anisotropy in Fourier-domain speckle correlations associated with the optical memory effect in disordered scattering media. Within a single scattering framework, we show that while the conventional memory effect constrains transverse wavevector shifts, the correlation strength also depends non-trivially on differences in the axial wavevector components. Our theory is supported by numerical simulations of a three-dimensional, single scattering medium, which show excellent agreement with theory. We extend the analysis to pseudo-correlations, demonstrating that analogous anisotropic behavior arises in the conjugate memory effect. Our results highlight the often neglected role of axial disorder in scattered field correlations.
Abstract : Lensless optical imaging eliminates the need for refractive optics, enabling compact and low-cost cameras with a large field-of-view, supporting point-of-care diagnostics and industrial monitoring. Practical deployments, however, remain constrained by ill-posed image reconstruction pipelines that require multiple measurements, careful calibration or object-specific training, thus limiting robustness and scalability. In this work, we introduce a single-shot lensless imaging framework that reconstructs complex objects from only a single recorded intensity pattern using a genetically programmed iterative algorithm. Our method couples a wave-propagation model with an adaptive meta-optimisation strategy to jointly estimate the object amplitude, object phase, and effective object-detector distance. Experiments demonstrate high-fidelity recovery of amplitude objects, including a USAF target and 2 μm silicon beads on a glass slide, as well as a phase-dominant biological sample consisting of U2OS cells on a glass slide. Across multiple object types, wavelengths, and propagation distances, the same learned policy maintains high reconstruction quality with minimal retuning, indicating strong out-of-distribution generalisation. As a practical demonstration, the framework is integrated with a β-amyloid-based optical digital bead assay under wide field-of-view acquisition. The resulting platform combines single-shot capture, compact hardware, and accurate reconstruction of complex fields, enabling rapid, portable assays in which throughput, alignment tolerance, and cost are critical.
Funding
Our research is supported by generous funding from: