Resilient Cloud Control System: Dynamic Frequency Adaptation via Q-learning

Fatemeh Akbarian; William Tärneberg; Emma Fitzgerald; Maria Kihl

doi:10.1109/ICIN60470.2024.10494429

Resilient Cloud Control System: Dynamic Frequency Adaptation via Q-learning

Fatemeh Akbarian, William Tärneberg, Emma Fitzgerald, Maria Kihl

Research output: Chapter in Book/Report/Conference proceeding › Paper in conference proceeding › peer-review

54 Downloads (Pure)

Abstract

Traditional control systems face challenges in managing high data loads and computing power, prompting the evolution of Cloud Control Systems (CCS)-a fusion of Networked Control Systems (NCS) and cloud computing. Despite offering manifold advantages, CCS encounters hurdles in navigating the dynamic cloud environment characterized by fluctuating workloads, rendering static frequency settings inefficient. Moreover, the optimal utilization of cloud resources poses a pivotal challenge within CCS operations. To address these, the paper proposes a resilient CCS by adapting system frequency dynamically. Leveraging Q-learning, the approach measures Round Trip Time (RTT) and system output errors, dynamically adjusting the system's frequency to minimize control costs, optimize performance within the dynamic cloud environment, and achieve resource frugality, minimizing resource usage. Through real testbed experiments, this paper evaluates and analyzes the effectiveness of the proposed method, aiming to establish an adaptive and efficient control framework aligned with evolving cloud dynamics.

Original language	English
Title of host publication	27th Conference on Innovation in Clouds, Internet and Networks (ICIN)
Publisher	IEEE - Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	979-8-3503-9376-7
ISBN (Print)	979-8-3503-9377-4
DOIs	https://doi.org/10.1109/ICIN60470.2024.10494429
Publication status	Published - 2024
Event	27th Conference on Innovation in Clouds, Internet and Networks, ICIN - Paris, France Duration: 2024 Mar 11 → 2024 Mar 14

Conference

Conference	27th Conference on Innovation in Clouds, Internet and Networks, ICIN
Country/Territory	France
City	Paris
Period	2024/03/11 → 2024/03/14

Subject classification (UKÄ)

Computer Systems

Access to Document

10.1109/ICIN60470.2024.10494429

Resilient_Cloud_Control_System_Dynamic_Frequency_Adaptation_via_Q-learningFinal published version, 607 KB

Sec4Factory: Cyber Security for Next Generation Factory (SEC4FACTORY)
Gehrmann, C. (PI), Kihl, M. (CoPI), Hell, M. (CoI), Fitzgerald, E. (Researcher), Toorani, M. (Researcher), Fitzgerald, E. (Researcher), Tärneberg, W. (Researcher) & Akbarian, F. (Researcher)
Swedish Foundation for Strategic Research, SSF
2018/04/01 → 2024/12/31
Project: Research
(HI2OT) NordicIoT: Nordic University Hub on Internet of Things
Gruian, F. (PI), Larsson, E. (PI), Årzén, K.-E. (PI), Kihl, M. (PI), Fitzgerald, E. (Researcher), Tärneberg, W. (Researcher), Akbarian, F. (Researcher), Chamideh, S. (Researcher) & Peng, H. (Researcher)
2018/01/01 → 2023/12/31
Project: Network

Cite this

@inproceedings{bbc1f526ea4742b79f20c02bfceb106a,

title = "Resilient Cloud Control System: Dynamic Frequency Adaptation via Q-learning",

abstract = "Traditional control systems face challenges in managing high data loads and computing power, prompting the evolution of Cloud Control Systems (CCS)-a fusion of Networked Control Systems (NCS) and cloud computing. Despite offering manifold advantages, CCS encounters hurdles in navigating the dynamic cloud environment characterized by fluctuating workloads, rendering static frequency settings inefficient. Moreover, the optimal utilization of cloud resources poses a pivotal challenge within CCS operations. To address these, the paper proposes a resilient CCS by adapting system frequency dynamically. Leveraging Q-learning, the approach measures Round Trip Time (RTT) and system output errors, dynamically adjusting the system's frequency to minimize control costs, optimize performance within the dynamic cloud environment, and achieve resource frugality, minimizing resource usage. Through real testbed experiments, this paper evaluates and analyzes the effectiveness of the proposed method, aiming to establish an adaptive and efficient control framework aligned with evolving cloud dynamics.",

author = "Fatemeh Akbarian and William T{\"a}rneberg and Emma Fitzgerald and Maria Kihl",

year = "2024",

doi = "10.1109/ICIN60470.2024.10494429",

language = "English",

isbn = "979-8-3503-9377-4",

booktitle = "27th Conference on Innovation in Clouds, Internet and Networks (ICIN)",

publisher = "IEEE - Institute of Electrical and Electronics Engineers Inc.",

address = "United States",

note = "27th Conference on Innovation in Clouds, Internet and Networks, ICIN ; Conference date: 11-03-2024 Through 14-03-2024",

}

Akbarian, F , Tärneberg, W, Fitzgerald, E & Kihl, M 2024, Resilient Cloud Control System: Dynamic Frequency Adaptation via Q-learning. in 27th Conference on Innovation in Clouds, Internet and Networks (ICIN). IEEE - Institute of Electrical and Electronics Engineers Inc., 27th Conference on Innovation in Clouds, Internet and Networks, ICIN, Paris, France, 2024/03/11. https://doi.org/10.1109/ICIN60470.2024.10494429

Resilient Cloud Control System: Dynamic Frequency Adaptation via Q-learning. / Akbarian, Fatemeh ; Tärneberg, William; Fitzgerald, Emma et al.
27th Conference on Innovation in Clouds, Internet and Networks (ICIN). IEEE - Institute of Electrical and Electronics Engineers Inc., 2024.

Research output: Chapter in Book/Report/Conference proceeding › Paper in conference proceeding › peer-review

TY - GEN

T1 - Resilient Cloud Control System: Dynamic Frequency Adaptation via Q-learning

AU - Akbarian, Fatemeh

AU - Tärneberg, William

AU - Fitzgerald, Emma

AU - Kihl, Maria

PY - 2024

Y1 - 2024

N2 - Traditional control systems face challenges in managing high data loads and computing power, prompting the evolution of Cloud Control Systems (CCS)-a fusion of Networked Control Systems (NCS) and cloud computing. Despite offering manifold advantages, CCS encounters hurdles in navigating the dynamic cloud environment characterized by fluctuating workloads, rendering static frequency settings inefficient. Moreover, the optimal utilization of cloud resources poses a pivotal challenge within CCS operations. To address these, the paper proposes a resilient CCS by adapting system frequency dynamically. Leveraging Q-learning, the approach measures Round Trip Time (RTT) and system output errors, dynamically adjusting the system's frequency to minimize control costs, optimize performance within the dynamic cloud environment, and achieve resource frugality, minimizing resource usage. Through real testbed experiments, this paper evaluates and analyzes the effectiveness of the proposed method, aiming to establish an adaptive and efficient control framework aligned with evolving cloud dynamics.

AB - Traditional control systems face challenges in managing high data loads and computing power, prompting the evolution of Cloud Control Systems (CCS)-a fusion of Networked Control Systems (NCS) and cloud computing. Despite offering manifold advantages, CCS encounters hurdles in navigating the dynamic cloud environment characterized by fluctuating workloads, rendering static frequency settings inefficient. Moreover, the optimal utilization of cloud resources poses a pivotal challenge within CCS operations. To address these, the paper proposes a resilient CCS by adapting system frequency dynamically. Leveraging Q-learning, the approach measures Round Trip Time (RTT) and system output errors, dynamically adjusting the system's frequency to minimize control costs, optimize performance within the dynamic cloud environment, and achieve resource frugality, minimizing resource usage. Through real testbed experiments, this paper evaluates and analyzes the effectiveness of the proposed method, aiming to establish an adaptive and efficient control framework aligned with evolving cloud dynamics.

U2 - 10.1109/ICIN60470.2024.10494429

DO - 10.1109/ICIN60470.2024.10494429

M3 - Paper in conference proceeding

SN - 979-8-3503-9377-4

BT - 27th Conference on Innovation in Clouds, Internet and Networks (ICIN)

PB - IEEE - Institute of Electrical and Electronics Engineers Inc.

T2 - 27th Conference on Innovation in Clouds, Internet and Networks, ICIN

Y2 - 11 March 2024 through 14 March 2024

ER -

Resilient Cloud Control System: Dynamic Frequency Adaptation via Q-learning

Abstract

Conference

Subject classification (UKÄ)

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Projects

Sec4Factory: Cyber Security for Next Generation Factory (SEC4FACTORY)

(HI2OT) NordicIoT: Nordic University Hub on Internet of Things

Cite this