News — In an era where data privacy concerns loom large, a new approach in artificial intelligence (AI) could reshape how sensitive information is processed.

Researchers and , Ph.D students, and Assistant Professor of Electrical and Computer Engineering have introduced Orion, a novel framework that brings fully homomorphic encryption (FHE) to deep learning — allowing AI models to practically and efficiently operate directly on encrypted data without needing to decrypt it first.

The implications of this advancement, published and to be presented at the , are profound. FHE has long been considered the 'holy grail' of cryptography. Unlike traditional encryption, which protects data only when it is at rest or in transit, FHE allows computations to be performed on encrypted data without ever decrypting it. However, despite its promise, implementing deep learning models with FHE has been notoriously difficult due to the immense computational overhead and the technical hurdles in adapting neural networks to FHE’s bespoke programming model.

“Whenever you use online services, there are machine learning models operating in the background, collecting both your inputs and outputs,” says Garimella. “That compromises user privacy. Our goal is to bring FHE into the mainstream, and allow users to continue using the services they rely on everyday without releasing their personal, private data."

Orion tackles these challenges head-on with an automated framework that seamlessly converts deep learning models written in PyTorch into efficient FHE programs. It does so by introducing a novel method to optimize how encrypted data is structured, significantly reducing computational overhead. The framework also streamlines encryption-related processes, making it easier to manage accumulated noise and execute deep learning computations efficiently.

By employing these techniques, Orion achieves a 2.38x speedup over existing state-of-the-art methods on ResNet-20, a common benchmark model used in FHE deep learning research that is comparatively small. But perhaps most impressively, Orion enables computations on much larger networks than previously possible. The researchers demonstrated the first-ever high-resolution FHE object detection using YOLO-v1—a deep learning model with 139 million parameters, roughly 500 times larger than ResNet-20 — showcasing Orion’s ability to handle real-world AI workloads.

The code the team produced is lightweight and could be used by anyone with a basic understanding of computer science. Not only would this help in increasing the efficiency of the computations; it also makes it easily deployable across industries.

“There has been an incredible barrier to entry for people who don't want to spend months to years learning the ins and outs”, says Ebel. “With Orion, that barrier to entry is now almost non-existent.”

The development of Orion marks a critical milestone in bridging the gap between FHE and practical deep learning applications. With this framework, industries reliant on privacy — such as healthcare, finance, and cybersecurity — could leverage AI without exposing sensitive user data.

“Take online advertising,” says Reagen, who is also a member of the NYU Center for Cybersecurity. “If you want to process an individual's information in order to serve them targeted ads using neural networks, this allows service providers to analyze that data while keeping it totally confidential. For the marketers and the public, that’s a win-win scenario.”

While challenges remain in making FHE fully practical at scale, Orion brings the technology closer to widespread adoption. The research team has , making it accessible to developers and researchers worldwide.

As AI continues to integrate deeper into daily life, privacy-preserving techniques like Orion could redefine the balance between innovation and security — ensuring that smarter algorithms don’t come at the cost of user privacy.

About the New York University Tandon School of Engineering

The NYU Tandon School of Engineering is home to a community of renowned faculty, undergraduate and graduate students united in a mission to understand and create technology that powers cities, enables worldwide communication, fights climate change, and builds healthier, safer, and more equitable real and digital worlds. The school’s culture centers on encouraging rigorous, interdisciplinary collaboration and research; fostering inclusivity, entrepreneurial thinking, and diverse perspectives; and creating innovative and accessible pathways for lifelong learning in STEM.  NYU Tandon dates back to 1854, the founding year of both the New York University School of Civil Engineering and Architecture and the Brooklyn Collegiate and Polytechnic Institute. Located in the heart of Brooklyn, NYU Tandon is a vital part of New York University and its unparalleled global network. For more information, visit.