TY - JOUR
T1 - Artificial Intelligence-Driven Mechanism for Edge Computing-Based Industrial Applications
AU - Sodhro, Ali Hassan
AU - Pirbhulal, Sandeep
AU - De Albuquerque, Victor Hugo C.
N1 - Funding Information:
Manuscript received December 3, 2018; revised February 13, 2019; accepted February 14, 2019. Date of publication March 4, 2019; date of current version July 3, 2019. This work was supported by CENIIT project 17.01 which is led by Professor Andrei Gurtov at Linkoping University, Linkoping-58183, Sweden. There is no conflict of interest between all authors. Paper no. TII-18-3268. (Corresponding author: Sandeep Pirbhulal.) A. H. Sodhro is with the IDA-Computer and Information Science Department, Linkoping University, Linkoping SE-58183, Sweden (e-mail:, [email protected]).
Publisher Copyright:
© 2005-2012 IEEE.
PY - 2019/7
Y1 - 2019/7
N2 - Due to various challenging issues such as, computational complexity and more delay in cloud computing, edge computing has overtaken the conventional process by efficiently and fairly allocating the resources i.e., power and battery lifetime in Internet of things (IoT)-based industrial applications. In the meantime, intelligent and accurate resource management by artificial intelligence (AI) has become the center of attention especially in industrial applications. With the coordination of AI at the edge will remarkably enhance the range and computational speed of IoT-based devices in industries. But the challenging issue in these power hungry, short battery lifetime, and delay-intolerant portable devices is inappropriate and inefficient classical trends of fair resource allotment. Also, it is interpreted through extensive industrial datasets that dynamic wireless channel could not be supported by the typical power saving and battery lifetime techniques, for example, predictive transmission power control (TPC) and baseline. Thus, this paper proposes 1) a forward central dynamic and available approach (FCDAA) by adapting the running time of sensing and transmission processes in IoT-based portable devices; 2) a system-level battery model by evaluating the energy dissipation in IoT devices; and 3) a data reliability model for edge AI-based IoT devices over hybrid TPC and duty-cycle network. Two important cases, for instance, static (i.e., product processing) and dynamic (i.e., vibration and fault diagnosis) are introduced for proper monitoring of industrial platform. Experimental testbed reveals that the proposed FCDAA enhances energy efficiency and battery lifetime at acceptable reliability (∼0.95) by appropriately tuning duty cycle and TPC unlike conventional methods.
AB - Due to various challenging issues such as, computational complexity and more delay in cloud computing, edge computing has overtaken the conventional process by efficiently and fairly allocating the resources i.e., power and battery lifetime in Internet of things (IoT)-based industrial applications. In the meantime, intelligent and accurate resource management by artificial intelligence (AI) has become the center of attention especially in industrial applications. With the coordination of AI at the edge will remarkably enhance the range and computational speed of IoT-based devices in industries. But the challenging issue in these power hungry, short battery lifetime, and delay-intolerant portable devices is inappropriate and inefficient classical trends of fair resource allotment. Also, it is interpreted through extensive industrial datasets that dynamic wireless channel could not be supported by the typical power saving and battery lifetime techniques, for example, predictive transmission power control (TPC) and baseline. Thus, this paper proposes 1) a forward central dynamic and available approach (FCDAA) by adapting the running time of sensing and transmission processes in IoT-based portable devices; 2) a system-level battery model by evaluating the energy dissipation in IoT devices; and 3) a data reliability model for edge AI-based IoT devices over hybrid TPC and duty-cycle network. Two important cases, for instance, static (i.e., product processing) and dynamic (i.e., vibration and fault diagnosis) are introduced for proper monitoring of industrial platform. Experimental testbed reveals that the proposed FCDAA enhances energy efficiency and battery lifetime at acceptable reliability (∼0.95) by appropriately tuning duty cycle and TPC unlike conventional methods.
KW - Artificial intelligence (AI)
KW - battery model
KW - duty cycle
KW - edge computing
KW - forward central dynamic and available approach (FCDAA)
KW - industrial Internet of things (IIoT)
KW - mobile devices
KW - predictive transmission power control (PTPC)
U2 - 10.1109/TII.2019.2902878
DO - 10.1109/TII.2019.2902878
M3 - Article
AN - SCOPUS:85068611053
SN - 1551-3203
VL - 15
SP - 4235
EP - 4243
JO - IEEE Transactions on Industrial Informatics
JF - IEEE Transactions on Industrial Informatics
IS - 7
M1 - 8658105
ER -