Neuromorphic sequence learning with an event camera on routes through vegetation

Zhu, Le; Mangan, Michael; Webb, Barbara

doi:10.1126/scirobotics.adg3679

Cited by 4 publications

(2 citation statements)

References 110 publications

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“…Some earlier MB-inspired models suggested that such connectivity could allow dynamic recurrent patterns to emerge in KC firing (Payne et al 2010;Arena et al 2013), followed by adaptive linear readout by the MBONs, resembling a reservoir network (Schrauwen et al 2007). A more recent model has explored if adaptive connections between KCs could contribute to learning sequences of sensory patterns in a visual navigation context (Zhu et al 2023).…”

Section: What Lies Beyond?mentioning

confidence: 99%

Beyond prediction error: 25 years of modeling the associations formed in the insect mushroom body

Webb

2024

Learn. Mem.

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The insect mushroom body has gained increasing attention as a system in which the computational basis of neural learning circuits can be unraveled. We now understand in detail the key locations in this circuit where synaptic associations are formed between sensory patterns and values leading to actions. However, the actual learning rule (or rules) implemented by neural activity and leading to synaptic change is still an open question. Here, I survey the diversity of answers that have been offered in computational models of this system over the past decades, including the recurring assumption—in line with top-down theories of associative learning—that the core function is to reduce prediction error. However, I will argue, a more bottom-up approach may ultimately reveal a richer algorithmic capacity in this still enigmatic brain neuropil.

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Section: What Lies Beyond?mentioning

confidence: 99%

Beyond prediction error: 25 years of modeling the associations formed in the insect mushroom body

Webb

2024

Learn. Mem.

Self Cite

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“…In addition to addressing two distinct grand challenges [25,26], BRAID sought to advance the application of a new class of brain-inspired engineering learning system based on novel or existing neuroscience theories [27][28][29][30][31] in the domain of autonomous systems, including neuromorphic sensors [32][33][34], brain-inspired robots [35][36][37], metacontrollers for multi-agent robots [38][39][40], neuromorphic medical technologies [41,42], and other applications with global economic and health benefits. BRAID especially focused on improving performance metrics beyond energy-and data-efficient learning algorithms [20,43] and learning hardware, including the development of neuromorphic systems [10,[44][45][46], the designs of which were based on insights from recent neuroscience advances [27,31,[47][48][49][50][51][52].…”

Section: Introductionmentioning

confidence: 99%

Special Issue—Biosensors and Neuroscience: Is Biosensors Engineering Ready to Embrace Design Principles from Neuroscience?

Hwang,

Simonian

2024

Biosensors

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In partnership with the Air Force Office of Scientific Research (AFOSR), the National Science Foundation’s (NSF) Emerging Frontiers and Multidisciplinary Activities (EFMA) office of the Directorate for Engineering (ENG) launched an Emerging Frontiers in Research and Innovation (EFRI) topic for the fiscal years FY22 and FY23 entitled “Brain-inspired Dynamics for Engineering Energy-Efficient Circuits and Artificial Intelligence” (BRAID) [...]

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Fully neuromorphic vision and control for autonomous drone flight

Paredes-Vallés,

Hagenaars,

Dupeyroux

et al. 2024

Sci. Robot.

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Biological sensing and processing is asynchronous and sparse, leading to low-latency and energy-efficient perception and action. In robotics, neuromorphic hardware for event-based vision and spiking neural networks promises to exhibit similar characteristics. However, robotic implementations have been limited to basic tasks with low-dimensional sensory inputs and motor actions because of the restricted network size in current embedded neuromorphic processors and the difficulties of training spiking neural networks. Here, we present a fully neuromorphic vision-to-control pipeline for controlling a flying drone. Specifically, we trained a spiking neural network that accepts raw event-based camera data and outputs low-level control actions for performing autonomous vision-based flight. The vision part of the network, consisting of five layers and 28,800 neurons, maps incoming raw events to ego-motion estimates and was trained with self-supervised learning on real event data. The control part consists of a single decoding layer and was learned with an evolutionary algorithm in a drone simulator. Robotic experiments show a successful sim-to-real transfer of the fully learned neuromorphic pipeline. The drone could accurately control its ego-motion, allowing for hovering, landing, and maneuvering sideways—even while yawing at the same time. The neuromorphic pipeline runs on board on Intel’s Loihi neuromorphic processor with an execution frequency of 200 hertz, consuming 0.94 watt of idle power and a mere additional 7 to 12 milliwatts when running the network. These results illustrate the potential of neuromorphic sensing and processing for enabling insect-sized intelligent robots.

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Neuromorphic sequence learning with an event camera on routes through vegetation

Cited by 4 publications

References 110 publications

Beyond prediction error: 25 years of modeling the associations formed in the insect mushroom body

Beyond prediction error: 25 years of modeling the associations formed in the insect mushroom body

Special Issue—Biosensors and Neuroscience: Is Biosensors Engineering Ready to Embrace Design Principles from Neuroscience?

Fully neuromorphic vision and control for autonomous drone flight

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