TY - GEN
T1 - Evaluating Edge and Cloud Computing for Automation in Agriculture
AU - Najera, Alberto
AU - Singh, Harkirat
AU - Pandey, Chandra Shekhar
AU - Sarpkaya, Fatih Berkay
AU - Fund, Fraida
AU - Panwar, Shivendra
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - Thanks to advancements in wireless networks, robotics, and artificial intelligence, future manufacturing and agriculture processes may be capable of producing more output with lower costs through automation. With ultra fast 5G mmWave wireless networks, data can be transferred to and from servers within a few milliseconds for real-time control loops, while robotics and artificial intelligence can allow robots to work alongside humans in factory and agriculture environments. One important consideration for these applications is whether the 'intelligence' that processes data from the environment and decides how to react should be located directly on the robotic device that interacts with the environment - a scenario called 'edge computing' - or whether it should be located on more powerful centralized servers that communicate with the robotic device over a network - 'cloud computing.' For applications that require a fast response time, such as a robot that is moving and reacting to an agricultural environment in real time, there are two important tradeoffs to consider. On the one hand, the processor on the edge device is likely not as powerful as the cloud server, and may take longer to generate the result. On the other hand, cloud computing requires both the input data and the response to traverse a network, which adds some delay that may cancel out the faster processing time of the cloud server. Even with ultra-fast 5G mmWave wireless links, the frequent blockages that are characteristic of this band can still add delay. To explore this issue, we run a series of experiments on the Chameleon testbed emulating both the edge and cloud scenarios under various conditions, including different types of hardware acceleration at the edge and the cloud, and different types of network configurations between the edge device and the cloud. These experiments will inform future use of these technologies and serve as a jumping off point for further research.
AB - Thanks to advancements in wireless networks, robotics, and artificial intelligence, future manufacturing and agriculture processes may be capable of producing more output with lower costs through automation. With ultra fast 5G mmWave wireless networks, data can be transferred to and from servers within a few milliseconds for real-time control loops, while robotics and artificial intelligence can allow robots to work alongside humans in factory and agriculture environments. One important consideration for these applications is whether the 'intelligence' that processes data from the environment and decides how to react should be located directly on the robotic device that interacts with the environment - a scenario called 'edge computing' - or whether it should be located on more powerful centralized servers that communicate with the robotic device over a network - 'cloud computing.' For applications that require a fast response time, such as a robot that is moving and reacting to an agricultural environment in real time, there are two important tradeoffs to consider. On the one hand, the processor on the edge device is likely not as powerful as the cloud server, and may take longer to generate the result. On the other hand, cloud computing requires both the input data and the response to traverse a network, which adds some delay that may cancel out the faster processing time of the cloud server. Even with ultra-fast 5G mmWave wireless links, the frequent blockages that are characteristic of this band can still add delay. To explore this issue, we run a series of experiments on the Chameleon testbed emulating both the edge and cloud scenarios under various conditions, including different types of hardware acceleration at the edge and the cloud, and different types of network configurations between the edge device and the cloud. These experiments will inform future use of these technologies and serve as a jumping off point for further research.
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U2 - 10.1109/ISEC61299.2024.10664737
DO - 10.1109/ISEC61299.2024.10664737
M3 - Conference contribution
AN - SCOPUS:85205595036
T3 - 2024 IEEE Integrated STEM Education Conference, ISEC 2024
BT - 2024 IEEE Integrated STEM Education Conference, ISEC 2024
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 14th IEEE Integrated STEM Education Conference, ISEC 2024
Y2 - 9 March 2024
ER -