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Neuromorphic computing for robotic vision: algorithms to hardware advances

Sayeed Shafayet Chowdhury, Deepika Sharma, Adarsh Kumar Kosta, Kaushik Roy

2025Communications Engineering20 citationsDOIOpen Access PDF

Abstract

Neuromorphic computing offers transformative potential for AI in resource-constrained environments by mimicking biological neural efficiency. This perspective article analyzes recent advances and future directions, advocating a system design approach that integrates specialized sensing (e.g., event-based cameras), brain-inspired algorithms (SNNs and SNN-ANN hybrids), and dedicated neuromorphic hardware. Using vision-based drone navigation (VDN) as an exemplar—drawing parallels with biological systems like Drosophila—we demonstrate how these components enable event-driven processing and overcome von Neumann architecture limitations through near-/in-memory computing. Key challenges include large-scale integration, benchmarking standardization, and algorithm-hardware co-design for emerging applications, which we discuss alongside current and future research directions. Neuromorphic computing promises energy-efficient AI at the edge by mimicking biological brains. Sayeed Chowdhury and colleagues review recent progress in sensing, algorithms, and hardware, and outline future research directions in this domain.

Topics & Concepts

Neuromorphic engineeringComputer scienceComputer architectureBenchmarkingRoboticsTransformative learningArtificial intelligenceVon Neumann architectureKey (lock)Event (particle physics)Benchmark (surveying)Unconventional computingArtificial neural networkAlgorithmRobotQuantum mechanicsGeographyGeodesyComputer securityPsychologyPedagogyBusinessPhysicsOperating systemMarketingAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance DevicesNeural dynamics and brain function
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