Analog optical computer for AI inference and combinatorial optimization.
Authors
Affiliations (7)
Affiliations (7)
- Microsoft Research, Cambridge, UK. [email protected].
- Microsoft Research, Cambridge, UK.
- Microsoft, Redmond, WA, USA.
- Chief Technology Office, Barclays, London, UK.
- Department of Applied Mathematics and Theoretical Physics, University of Cambridge, Cambridge, UK.
- Microsoft Research, Cambridge, UK. [email protected].
- Microsoft Research, Cambridge, UK. [email protected].
Abstract
Artificial intelligence (AI) and combinatorial optimization drive applications across science and industry, but their increasing energy demands challenge the sustainability of digital computing. Most unconventional computing systems<sup>1-7</sup> target either AI or optimization workloads and rely on frequent, energy-intensive digital conversions, limiting efficiency. These systems also face application-hardware mismatches, whether handling memory-bottlenecked neural models, mapping real-world optimization problems or contending with inherent analog noise. Here we introduce an analog optical computer (AOC) that combines analog electronics and three-dimensional optics to accelerate AI inference and combinatorial optimization in a single platform. This dual-domain capability is enabled by a rapid fixed-point search, which avoids digital conversions and enhances noise robustness. With this fixed-point abstraction, the AOC implements emerging compute-bound neural models with recursive reasoning potential and realizes an advanced gradient-descent approach for expressive optimization. We demonstrate the benefits of co-designing the hardware and abstraction, echoing the co-evolution of digital accelerators and deep learning models, through four case studies: image classification, nonlinear regression, medical image reconstruction and financial transaction settlement. Built with scalable, consumer-grade technologies, the AOC paves a promising path for faster and sustainable computing. Its native support for iterative, compute-intensive models offers a scalable analog platform for fostering future innovation in AI and optimization.