Analytical Assessment of the Suitability of Multicast Communications for the SpiNNaker Neuromimetic System

Navaridas, Javier; Luj'n, Mikel; Plana, Luis A.; Miguel-Alonso, José; Furber, Steve

doi:10.1109/hpcc.2012.11

Cited by 6 publications

(13 citation statements)

References 27 publications

(19 reference statements)

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“…For instance the SpiNNaker chip [Jin et al 2010] is likely to be powerful in recurrent connectivity, given the good performance of their event-address mapping network (in Navaridas et al [2012], the chip is able to simulate a spiking neural networks of 2000 spiking neurons with all-to-all connections in the worst case scenario).…”

Section: Discussionmentioning

confidence: 99%

Randomly Spiking Dynamic Neural Fields

Vangel

Torres-Huitzil

Girau

2015

J. Emerg. Technol. Comput. Syst.

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Bio-inspired neural computation attracts a lot of attention as a possible solution for the future challenges in designing computational resources. Dynamic neural fields (DNF) provide cortically inspired models of neural populations to which computation can be applied for a wide variety of tasks, such as perception and sensorimotor control. DNFs are often derived from continuous neural field theory (CNFT). In spite of the parallel structure and regularity of CNFT models, few studies of hardware implementations have been carried out targeting embedded real-time processing. In this article, a hardware-friendly model adapted from the CNFT is introduced, namely the RSDNF model (randomly spiking dynamic neural fields). Thanks to their simplified 2D structure, RSDNFs achieve scalable parallel implementations on digital hardware while maintaining the behavioral properties of CNFT models. Spike-based computations within neurons in the field are introduced to reduce interneuron connection bandwidth. Additionally, local stochastic spike propagation ensures inhibition and excitation broadcast without a fully connected network. The behavioral soundness and robustness of the model in the presence of noise and distracters is fully validated through software and hardware. A field programmable gate array (FPGA) implementation shows how the RSDNF model ensures a level of density and scalability out of reach for previous hardware implementations of dynamic neural field models.

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Section: Discussionmentioning

confidence: 99%

Randomly Spiking Dynamic Neural Fields

Vangel

Torres-Huitzil

Girau

2015

J. Emerg. Technol. Comput. Syst.

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“…This can be directly attributed to the fact that network latency introduces a performance overhead that increases linearly with the number of distributed ranks. Thus we conclude that large-scale simulations are dominated by the latency of the collective communication, and that investigating spike communication strategies such as neighbourhood collectives (Jordan et al 2018), nonblocking point-to-point schemes (Ananthanarayanan and Modha 2007), asynchronous execution (Magalhaes et al 2019b) or custom hardware (Navaridas et al 2012) will be essential to reach brain-scale simulations.…”

Section: Network Latency and Memory Bandwidth Are The Main Bottleneckmentioning

confidence: 91%

“…In distributed simulations we identified the network latency, and not the network bandwidth, as the major bottleneck for scaling to very large networks or very large cluster sizes. This provides a new motivation and justification for the extensive efforts described in Navaridas et al (2012) in designing a specific communication infrastructure for the SpiNNaker neuromorphic system.…”

Section: Memory Bandwidth and Network Latency Severely Limit Maximum mentioning

confidence: 97%

“…An analysis showed that, in the context of real-time simulations, SpiNNaker is inherently limited in its scope to a restricted subset of synaptic formalism, because the single node's memory bandwidth puts a hard limit on the number of synaptic parameters that can be streamed at every timestep (Painkras et al 2013). In designing the network for SpiNNaker, a performance model was used to determine the ideal topology and network connectivity (Navaridas et al 2012), proving that performance modeling can be an extremely valuable tool in optimization and co-design for brain tissue simulations.…”

Section: Related Workmentioning

confidence: 99%

“…The level of diversity means that design tradeoffs will inevitably require very restrictive decisions about the scale, model and configuration of the target simulation, such as e.g. (Navaridas et al 2012;Knight and Nowotny 2018). For example, in the context of accelerating small networks of neurons up to real-time, we predict that I-based models would benefit from architectures with high memory level parallelism and a simple cache hierarchy, while for G-based models the cache bandwidth as well as the throughput of CPU arithmetic operations must be improved concurrently in order observe the desired speedup.…”

Section: Performance Modeling Is Required To Enable Next-generation Hmentioning

confidence: 99%

See 2 more Smart Citations

Understanding Computational Costs of Cellular-Level Brain Tissue Simulations Through Analytical Performance Models

Cremonesi

Schürmann

2020

Neuroinform

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Computational modeling and simulation have become essential tools in the quest to better understand the brain's makeup and to decipher the causal interrelations of its components. The breadth of biochemical and biophysical processes and structures in the brain has led to the development of a large variety of model abstractions and specialized tools, often times requiring high performance computing resources for their timely execution. What has been missing so far was an in-depth analysis of the complexity of the computational kernels, hindering a systematic approach to identifying bottlenecks of algorithms and hardware. If whole brain models are to be achieved on emerging computer generations, models and simulation engines will have to be carefully co-designed for the intrinsic hardware tradeoffs. For the first time, we present a systematic exploration based on analytic performance modeling. We base our analysis on three in silico models, chosen as representative examples of the most widely employed modeling abstractions: current-based point neurons, conductance-based point neurons and conductance-based detailed neurons. We identify that the synaptic modeling formalism, i.e. current or conductance-based representation, and not the level of morphological detail, is the most significant factor in determining the properties of memory bandwidth saturation and shared-memory scaling of in silico models. Even though general purpose computing has, until now, largely been able to deliver high performance, we find that for all types of abstractions, network latency and memory bandwidth will become severe bottlenecks as the number of neurons to be simulated grows. By adapting and extending a performance modeling approach, we deliver a first characterization of the performance landscape of brain tissue simulations, allowing us to pinpoint current bottlenecks for state-of-the-art in silico models, and make projections for future hardware and software requirements. Keywords Computational models of neurons • Brain tissue simulations • Performance modeling • High performance computing This study was supported by funding to the Blue Brain Project, a research center of theÉcole polytechnique fédérale de Lausanne (EPFL), from the Swiss governments ETH Board of the Swiss Federal Institutes of Technology Electronic supplementary material The online version of this article (

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