An Edge Computing System with AMD Xilinx FPGA AI Customer Platform for Advanced Driver Assistance System

An Edge Computing System with AMD Xilinx FPGA AI Customer Platform for Advanced Driver Assistance System

The convergence of edge computing systems with Field-Programmable Gate Array (FPGA) technology has shown considerable promise in enhancing real-time applications across various domains. This paper presents an innovative edge computing system design specifically tailored for pavement defect detection...

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Main Authors: Chi, Tsun Kuang, Chen, Tsung Yi, Lin, Yu Chen, Lin, Ting Lan, Zhang, Jun Ting, Lu, Cheng Lin, Chen, Shih Lun, Li, Kuo Chen, Abu, Patricia Angela R
Format: text
Published: Archīum Ateneo 2024
Subjects:
advanced driver-assistance systems
deep learning processing unit
edge computing system
FPGA
Computer Engineering
Computer Sciences
Electrical and Computer Engineering
Engineering
Physical Sciences and Mathematics
Online Access:https://archium.ateneo.edu/discs-faculty-pubs/423
https://archium.ateneo.edu/context/discs-faculty-pubs/article/1425/viewcontent/sensors_24_03098_v2.pdf
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Institution: Ateneo De Manila University
id ph-ateneo-arc.discs-faculty-pubs-1425
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spelling ph-ateneo-arc.discs-faculty-pubs-14252025-01-30T06:25:35Z An Edge Computing System with AMD Xilinx FPGA AI Customer Platform for Advanced Driver Assistance System Chi, Tsun Kuang Chen, Tsung Yi Lin, Yu Chen Lin, Ting Lan Zhang, Jun Ting Lu, Cheng Lin Chen, Shih Lun Li, Kuo Chen Abu, Patricia Angela R The convergence of edge computing systems with Field-Programmable Gate Array (FPGA) technology has shown considerable promise in enhancing real-time applications across various domains. This paper presents an innovative edge computing system design specifically tailored for pavement defect detection within the Advanced Driver-Assistance Systems (ADASs) domain. The system seamlessly integrates the AMD Xilinx AI platform into a customized circuit configuration, capitalizing on its capabilities. Utilizing cameras as input sensors to capture road scenes, the system employs a Deep Learning Processing Unit (DPU) to execute the YOLOv3 model, enabling the identification of three distinct types of pavement defects with high accuracy and efficiency. Following defect detection, the system efficiently transmits detailed information about the type and location of detected defects via the Controller Area Network (CAN) interface. This integration of FPGA-based edge computing not only enhances the speed and accuracy of defect detection, but also facilitates real-time communication between the vehicle’s onboard controller and external systems. Moreover, the successful integration of the proposed system transforms ADAS into a sophisticated edge computing device, empowering the vehicle’s onboard controller to make informed decisions in real time. These decisions are aimed at enhancing the overall driving experience by improving safety and performance metrics. The synergy between edge computing and FPGA technology not only advances ADAS capabilities, but also paves the way for future innovations in automotive safety and assistance systems. 2024-05-01T07:00:00Z text application/pdf https://archium.ateneo.edu/discs-faculty-pubs/423 https://archium.ateneo.edu/context/discs-faculty-pubs/article/1425/viewcontent/sensors_24_03098_v2.pdf Department of Information Systems & Computer Science Faculty Publications Archīum Ateneo advanced driver-assistance systems deep learning processing unit edge computing system FPGA Computer Engineering Computer Sciences Electrical and Computer Engineering Engineering Physical Sciences and Mathematics
institution Ateneo De Manila University
building Ateneo De Manila University Library
continent Asia
country Philippines
Philippines
content_provider Ateneo De Manila University Library
collection archium.Ateneo Institutional Repository
topic advanced driver-assistance systems
deep learning processing unit
edge computing system
FPGA
Computer Engineering
Computer Sciences
Electrical and Computer Engineering
Engineering
Physical Sciences and Mathematics
spellingShingle advanced driver-assistance systems
deep learning processing unit
edge computing system
FPGA
Computer Engineering
Computer Sciences
Electrical and Computer Engineering
Engineering
Physical Sciences and Mathematics
Chi, Tsun Kuang
Chen, Tsung Yi
Lin, Yu Chen
Lin, Ting Lan
Zhang, Jun Ting
Lu, Cheng Lin
Chen, Shih Lun
Li, Kuo Chen
Abu, Patricia Angela R
An Edge Computing System with AMD Xilinx FPGA AI Customer Platform for Advanced Driver Assistance System
description The convergence of edge computing systems with Field-Programmable Gate Array (FPGA) technology has shown considerable promise in enhancing real-time applications across various domains. This paper presents an innovative edge computing system design specifically tailored for pavement defect detection within the Advanced Driver-Assistance Systems (ADASs) domain. The system seamlessly integrates the AMD Xilinx AI platform into a customized circuit configuration, capitalizing on its capabilities. Utilizing cameras as input sensors to capture road scenes, the system employs a Deep Learning Processing Unit (DPU) to execute the YOLOv3 model, enabling the identification of three distinct types of pavement defects with high accuracy and efficiency. Following defect detection, the system efficiently transmits detailed information about the type and location of detected defects via the Controller Area Network (CAN) interface. This integration of FPGA-based edge computing not only enhances the speed and accuracy of defect detection, but also facilitates real-time communication between the vehicle’s onboard controller and external systems. Moreover, the successful integration of the proposed system transforms ADAS into a sophisticated edge computing device, empowering the vehicle’s onboard controller to make informed decisions in real time. These decisions are aimed at enhancing the overall driving experience by improving safety and performance metrics. The synergy between edge computing and FPGA technology not only advances ADAS capabilities, but also paves the way for future innovations in automotive safety and assistance systems.
format text
author Chi, Tsun Kuang
Chen, Tsung Yi
Lin, Yu Chen
Lin, Ting Lan
Zhang, Jun Ting
Lu, Cheng Lin
Chen, Shih Lun
Li, Kuo Chen
Abu, Patricia Angela R
author_facet Chi, Tsun Kuang
Chen, Tsung Yi
Lin, Yu Chen
Lin, Ting Lan
Zhang, Jun Ting
Lu, Cheng Lin
Chen, Shih Lun
Li, Kuo Chen
Abu, Patricia Angela R
author_sort Chi, Tsun Kuang
title An Edge Computing System with AMD Xilinx FPGA AI Customer Platform for Advanced Driver Assistance System
title_short An Edge Computing System with AMD Xilinx FPGA AI Customer Platform for Advanced Driver Assistance System
title_full An Edge Computing System with AMD Xilinx FPGA AI Customer Platform for Advanced Driver Assistance System
title_fullStr An Edge Computing System with AMD Xilinx FPGA AI Customer Platform for Advanced Driver Assistance System
title_full_unstemmed An Edge Computing System with AMD Xilinx FPGA AI Customer Platform for Advanced Driver Assistance System
title_sort edge computing system with amd xilinx fpga ai customer platform for advanced driver assistance system
publisher Archīum Ateneo
publishDate 2024
url https://archium.ateneo.edu/discs-faculty-pubs/423
https://archium.ateneo.edu/context/discs-faculty-pubs/article/1425/viewcontent/sensors_24_03098_v2.pdf
_version_ 1823107933759602688

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