Akihiro Suzuki scite author profile

Akihiro Suzuki

5Publications

19Citation Statements Received

18Citation Statements Given

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Kyushu Institute of Technology, Kanazawa University

Publications

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A shared synapse architecture for efficient FPGA implementation of autoencoders

2018

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This paper proposes a shared synapse architecture for autoencoders (AEs), and implements an AE with the proposed architecture as a digital circuit on a field-programmable gate array (FPGA). In the proposed architecture, the values of the synapse weights are shared between the synapses of an input and a hidden layer, and between the synapses of a hidden and an output layer. This architecture utilizes less of the limited resources of an FPGA than an architecture which does not share the synapse weights, and reduces the amount of synapse modules used by half. For the proposed circuit to be implemented into various types of AEs, it utilizes three kinds of parameters; one to change the number of layers’ units, one to change the bit width of an internal value, and a learning rate. By altering a network configuration using these parameters, the proposed architecture can be used to construct a stacked AE. The proposed circuits are logically synthesized, and the number of their resources is determined. Our experimental results show that single and stacked AE circuits utilizing the proposed shared synapse architecture operate as regular AEs and as regular stacked AEs. The scalability of the proposed circuit and the relationship between the bit widths and the learning results are also determined. The clock cycles of the proposed circuits are formulated, and this formula is used to estimate the theoretical performance of the circuit when the circuit is used to construct arbitrary networks.

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An Effective Method for Minimizing Domain Gap in Sim2Real Object Recognition Using Domain Randomization

Ono

Suzuki

Tamukoh

2023

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Manual annotation is common, but problems occur, such as oversight and mislabeling via human error. These problems are known to affect the quality of datasets significantly. To resolve these problems, we propose a method to automatically generate high-quality and large datasets in a short time using a simulator. Our proposed method uses domain randomization to minimize domain gaps without faithfully reproducing real scenes. The generated dataset achieved more than 80% recognition accuracy against the real image dataset.

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Multi-Valued Quantization Neural Networks toward Hardware Implementation

Aratani

Jye

Suzuki

et al. 2017

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Evaluation of Hardware Oriented MRCoHOG using Logic Simulation

Yamasaki¹,

Ooe²,

Suzuki

et al. 2017

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FPGA Implementation of Autoencoders Having Shared Synapse Architecture

Suzuki

Matsukawa

Tamukoh

2016

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Akihiro Suzuki

A shared synapse architecture for efficient FPGA implementation of autoencoders

An Effective Method for Minimizing Domain Gap in Sim2Real Object Recognition Using Domain Randomization

Multi-Valued Quantization Neural Networks toward Hardware Implementation

Evaluation of Hardware Oriented MRCoHOG using Logic Simulation

FPGA Implementation of Autoencoders Having Shared Synapse Architecture

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