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Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices
NSF
About This Grant
Despite the advances in deep neural networks (DNNs) and edge computing, there exist substantial challenges to enabling end-to-end DNN inference on a full spectrum of edge devices, such as tiny wearables and low-cost Internet-of-things (IoT) devices. This problem has spurred the recent studies of brain-inspired vector symbolic representation (VSA) classifiers as an alternative framework for ubiquitous on-device inference. At a high level, VSA classifiers mimic the brain cognition process by representing each object as a vector (typically in a very high-dimensional space). While VSA classifiers offer advantages over DNNs in terms of inference efficiency due to parallel processing, the hyper-dimensionality in their design can still easily result in a prohibitively large VSA model size beyond the limit of many tiny devices with stringent resource constraints. If successful, this project will make it possible for more everyday devices to run advanced artificial intelligence (AI) on their own, without needing to send data to remote servers. This could improve privacy, save energy, and open the door to smarter wearables, medical devices, and home gadgets. Finally, the project will bring the latest discoveries into college courses to help train the next generation of engineers and computer scientists. To address the hyper-dimensionality challenge, this project moves away from hypervector-oriented VSA and proposes TinyVSA, which uses much smaller, compact vector representations. Specifically, this project focuses on three key directions: first, redesigning TinyVSA’s vectors to improve accuracy while the VSA dimensionality by orders of magnitude; second, making TinyVSA run continuously and efficiently on tiny, low-power chips; and third, developing an efficient, hardware-aware method to automatically find the best TinyVSA architecture for target devices. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
Grant Summary
Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices is a NSF grant providing up to $280K for university, nonprofit, small business. Applications are due 2028-09-30 (open). Check eligibility and apply with FindGrants.
Focus Areas
Eligibility
How to Apply
Up to $280K
2028-09-30
- 1Confirm your organization is eligible for Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices from NSF, checking organization type, location, and any population or project requirements.
- 2Gather the required documents and information, including your organization details, project plan, and budget figures.
- 3Draft your application narrative and budget addressing the funder's priorities and review criteria. FindGrants can draft each section for you to review and edit.
- 4Review every section against the requirements checklist, then export a submission-ready application pack and submit it to NSF before the deadline.
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Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices: Frequently Asked Questions
Who is eligible for the Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices?
Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices is offered by NSF and is generally open to university, nonprofit, small business. It is open to organizations nationwide unless the funder specifies otherwise. Review the specific eligibility terms before applying, since funders set their own requirements around organization type, location, and the population or project being served.
How much funding does the Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices provide?
Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices provides up to $280K per award from NSF. Actual award sizes depend on the scope of your project, available program funds, and the number of applicants, so build a budget that reflects realistic, allowable costs rather than the maximum figure.
When is the Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices deadline?
Applications for Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices are due 2028-09-30 (open). Because deadlines can change, verify the date with the funder, NSF, and give yourself enough time to prepare a complete, competitive application before the close date.
How do you apply for the Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices?
To apply for Collaborative Research: SHF: Small: Designing and Optimizing Tiny Vector Symbolic Architectures for Ultra-Efficient Inference on Tiny Devices, confirm your eligibility, gather the required documents, and prepare a narrative and budget that address the funder's priorities. FindGrants guides you step by step and can draft each section, then exports a submission-ready application pack for this grant from NSF.