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Main Authors: Eames, Evan, Kannan, Priyadarshini, Sangouard, Ronan, Plank, Philipp, Hajizada, Elvin, Palinauskas, Gintautas, Amaya, Lana, Neumeier, Michael, Sharma, Sai Thejeshwar, Toth, Marcella, Sarkar, Prottush, von Arnim, Axel
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.13747
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author Eames, Evan
Kannan, Priyadarshini
Sangouard, Ronan
Plank, Philipp
Hajizada, Elvin
Palinauskas, Gintautas
Amaya, Lana
Neumeier, Michael
Sharma, Sai Thejeshwar
Toth, Marcella
Sarkar, Prottush
von Arnim, Axel
author_facet Eames, Evan
Kannan, Priyadarshini
Sangouard, Ronan
Plank, Philipp
Hajizada, Elvin
Palinauskas, Gintautas
Amaya, Lana
Neumeier, Michael
Sharma, Sai Thejeshwar
Toth, Marcella
Sarkar, Prottush
von Arnim, Axel
contents It has long been realized that neuromorphic hardware offers benefits for the domain of robotics such as low energy, low latency, as well as unique methods of learning. In aiming for more complex tasks, especially those incorporating multimodal data, one hurdle continuing to prevent their realization is an inability to orchestrate multiple networks on neuromorphic hardware without resorting to off-chip process management logic. To address this, we show a first example of a pipeline for vision-based robot control in which numerous complex networks can be run entirely on hardware via the use of a spiking neural state machine for process orchestration. The pipeline is validated on the Intel Loihi 2 research chip. We show that all components can run concurrently on-chip in the milli Watt regime at latencies competitive with the state-of-the-art. An equivalent network on simulated hardware is shown to accomplish robotic arm plug insertion in simulation, and the core elements of the pipeline are additionally tested on a real robotic arm.
format Preprint
id arxiv_https___arxiv_org_abs_2602_13747
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle The More the Merrier: Running Multiple Neuromorphic Components On-Chip for Robotic Control
Eames, Evan
Kannan, Priyadarshini
Sangouard, Ronan
Plank, Philipp
Hajizada, Elvin
Palinauskas, Gintautas
Amaya, Lana
Neumeier, Michael
Sharma, Sai Thejeshwar
Toth, Marcella
Sarkar, Prottush
von Arnim, Axel
Robotics
It has long been realized that neuromorphic hardware offers benefits for the domain of robotics such as low energy, low latency, as well as unique methods of learning. In aiming for more complex tasks, especially those incorporating multimodal data, one hurdle continuing to prevent their realization is an inability to orchestrate multiple networks on neuromorphic hardware without resorting to off-chip process management logic. To address this, we show a first example of a pipeline for vision-based robot control in which numerous complex networks can be run entirely on hardware via the use of a spiking neural state machine for process orchestration. The pipeline is validated on the Intel Loihi 2 research chip. We show that all components can run concurrently on-chip in the milli Watt regime at latencies competitive with the state-of-the-art. An equivalent network on simulated hardware is shown to accomplish robotic arm plug insertion in simulation, and the core elements of the pipeline are additionally tested on a real robotic arm.
title The More the Merrier: Running Multiple Neuromorphic Components On-Chip for Robotic Control
topic Robotics
url https://arxiv.org/abs/2602.13747