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NEUROWARE (PGC2018-097339)

Efficient and Robust Hardware for Brain-Inspired Computing (Neuroware)

Summary

NEUROWARE deals with one of the topics with most intensive activity for these and coming years: big data processing, and in particular the area of efficient brain-inspired computing. Many applications require deep learning algorithms to be computed near to the source of information, what imposes strict restrictions in terms of memory, computational costs and energy consumption along with adaptability to
the source environment. However, there is a growing gap between the needs of algorithms designed by data scientist and the capabilities of the hardware available to accommodate them. These efficiency and energy gaps are not bridged by the technology reduction imposed by Moores Law, there is a need for novel circuital and architectural paradigms.
 
In NEUROWARE we propose hardware architectures for brain-inspired computing that contribute to increase the efficiency of current solutions to provide better performance and reduced energy consumption. The challenge is to implement reliable intelligence in edge devices and platforms in a way that is efficient in terms of performance and power.
 
The general objectives of this project address some of these issues from the device, circuit and architectural levels. Neuroware plans to explore the architectural limits of circuits implementing the basic processing element in deep neural network (DNN), the artificial neuron. First it proposes digital implementations at circuit and architectural level targeting novel designs for DNN. Furthermore, since reliability is a key issue in current nanometer technologies, it will also be studied the adaptability of DNN hardware to process, temperature, VDD, radiation and aging variations.
 
A second objective of NEUROWARE is the exploration of circuits and architectures for the robust design of memristive-based braininspired computing. There is a clear potential of ReRAM for DNN implementations, because it provides efficient implementation of interconnections and computation in memory for brain-inspired circuits. This results in a reduction in data management and a significant improvement in performance and energy savings. However, the immaturity of ReRAM technology makes designers face serious issues like device non-uniformity, conductance level instability, sneak path currents, and wire resistance. This directly affects the reliability of the implementation and has serious impact on the array size and system performance.
 
A last goal of NEUROWARE is the design of configurable hardware for the implementation of DNNs. This configurability will be studied both for the design of digital artificial neurons and memristive architectures. Finally, the project proposes the combination of both digital and analog memristor-based circuitries to conform efficient mixed-signal architectures.

Researchers

  • María Luisa López-Vallejo (Investigador principal)
  • Pablo Ituero Herrero  (Investigador principal)
  • Carlos A. López Barrio
  • Andrés Rodríguez
  • Mario Garrido Gálvez
  • Amadeo de Gracia Herranz
  • Samuel López Asunción
  • Asghar Bahramali
  • Javier de Mena Pacheco

Publications

Master Thesis
  1. Miguel Molina, “Design and Implementation of a Configurable Multilayer Perceptron (MLP) in FPGA”, July 2020.
  2. Amadeo de Gracia Herranz, “Design of a Multi-Level Driver for Memristors to be Used in Neuromorphic Applications”, Jan 2019.
Journal papers
  1. “Time-domain writing architecture for multilevel RRAM cells resilient to temperature and process variations”. A. de Gracia Herranz, M Lopez-Vallejo Integration the VLSI Journal 75, 141-149. 2020.
  2. “A Survey of Analog-to-Digital Converters for Operation under Radiation Environments” E Pun-García, M López-Vallejo. Electronics 9 (10), 1694. 2020. 
  3. “Opportunities and Challenges of Ambient Radio-Frequency Energy Harvesting”. X. Zhang, J. Grajal, M. López-Vallejo, E McVay, T. Palacios, Joule 4 (6), 1148-1152, 2020.
  4. “A 900 μm2 BiCMOS Temperature Sensor for Dynamic Thermal Management”. Hernán Aparicio; Pablo Ituero. Sensors July 2020, 20(13), 3725.
  5. “A low power RFID based energy harvesting temperature resilient CMOS-only reference voltage” A. Bahramali, M Lopez-Vallejo, Integration the VLSI Journal 67, 155-161, 2019.
Conference papers
  1. “Temperature-Aware Writing Architecture for Multilevel Memristive Cells”, A. de Gracia and M. Lopez-Vallejo. International Symposium on Power and Timing Modeling, Optimization and Simulation (PATMOS), Rhodes, Greece, July 2019. July 2019.
  2. “Time-Domain Coding for Resource-Efficient Deep Neural Networks”. Sergio Ávalos; Pablo Ituero. Conference on Design of Circuits and Integrated Systems 2019 (DCIS 2019). November 20-22. Bilbao, Spain.
  3. “A 365mV, 13nW CMOS-only energy harvested reference voltage in 40nm technology”. A Bahramali, M Lopez-Vallejo, CL Barrio, 2019 XXXIV Conference on Design of Circuits and Integrated Systems (DCIS), Nov. 2019.
  4. “An Ultra-Parallel Architecture for FPGA-Based Deep Neural Network Inference”. Sergio Ávalos; Pablo Ituero.  Conference on Design of Circuits and Integrated Systems 2020 (DCIS 2020). November 20-22. Online.
  5. “STDP Design Trade-offs for FPGA-Based Spiking Neural Networks”. Rafael Medina Morillas; Pablo Ituero. Conference on Design of Circuits and Integrated Systems 2020 (DCIS 2020). November 20-22. Online 
  6. “Algorithm-Architecture Optimization for Linear and Quadratic Regression on Reconfigurable Platforms”. S López Asunción, M Lopez-Vallejo, J Grajal. 2020 XXXV Conference on Design of Circuits and Integrated Systems (DCIS), Nov. 2020
  7. “An ultra-low power deep sub-micron fast start-up circuit with added line regulation”. A Bahramali, M Lopez-Vallejo, C. López Barrio 2020 XXXV Conference on Design of Circuits and Integrated Systems (DCIS), 1-5, 2020
  8. “A 65nm ultra low-power, -area and –frequency CMOS voltage-controlled oscillator”. J. de Mena Pacheco, M Lopez-Vallejo, M. Hempel y T. Palacios 2020 XXXV Conference on Design of Circuits and Integrated Systems (DCIS), 2020