Node positioning technology can help industrial Internet of Things systems control production processes more accurately, monitor product quality in real time, discover and handle problems timely, thereby improving product quality. It is significant for improving the efficiency and safety of industrial production. However, existing node localization technologies have low accuracy in node localization in complex environments, which cannot effectively ensure localization effectiveness and directly affect device monitoring in industrial Internet of Things. To address this issue, a node localization method is constructed based on the radial basis function neural network function. Then the cuckoo algorithm is applied to optimize it. From the results, the improved CS-RBF model had a smaller change in absolute error value, with a minimum absolute error value of -9.3 and an average absolute error value of 0.8. When the proportion of beacon nodes was 35%, the average positioning errors of DE, APTT, and DV Hop were 0.27, 0.23, and 0.22, respectively. The node positioning error of CS-RBF was 0.18. This indicates that the node positioning method designed in the industrial Internet of Things can effectively achieve accurate positioning of the required nodes, thereby effectively scheduling and managing equipment, reducing equipment waiting time, and improving production efficiency.

Chao Z, Xu W. A new general maximum intensity projection technology via the hybrid of U-Net and radial basis function neural network. Journal of Digital Imaging, 2021, 34(5):1264-1278.

Hou Z, Zhou M, Roberts C, Dong H R. Cuckoo search approach for automatic train regulation under capacity limitation. Science China Information Sciences, 2023, 66(4):295-296.

Pu R, Wang S, Chen X. A novel cuckoo search particle filtering strategy for the remaining useful life prediction of the lithium-ion batteries in hybrid electric vehicle. International Journal of Energy Research, 2022, 46(15):21703-21715.

Aluvala S, Rajasekhar K. Secure routing in MANETS using adaptive cuckoo search and entropy based signature authentication. Wireless personal communications: An International Journal, 2023, 128(3):1519-1541.

Lee G, Saad W, Bennis M. An online framework for ephemeral edge computing in the internet of things. IEEE transactions on wireless communications, 2023, 22(3):1992-2007.

Yang C, Wang Z, Oh S K, Pedrycz W, Yang B. Ensemble fuzzy radial basis function neural networks architecture driven with the aid of multi-optimization through clustering techniques and polynomial-based learning. Fuzzy Sets and Systems, 2022, 438(6):62-83.

Tian Y, He Y L, Zhu Q X. Soft sensor development using improved whale optimization and regularization-based functional link neural network. Industrial and Engineering Chemistry Research, 2020, 59(43):19361-19369.

Wang Y, Chen X. A joint optimization QSAR model of fathead minnow acute toxicity based on a radial basis function neural network and its consensus modeling. RSC Advances, 2020, 10(36):21292-21308.

Pazouki G, Golafshani E M, Behnood A. Predicting the compressive strength of self-compacting concrete containing Class F fly ash using metaheuristic radial basis function neural network. Structural Concrete: Journal of the FIB, 2022, 23(2):1191-1213.

Shadkam E, Bijari M. A novel improved cuckoo optimisation algorithm for engineering optimisation. International Journal of Artificial Intelligence and Soft Computing, 2020, 7(2):164-177.

Ma X, Mu Y, Zhang Y, Zang C, Li S R, Jiang X Y, Cui M. Multi-objective microgrid optimal dispatching based on improved bird swarm algorithm. Global Energy Interconnection, 2022, 5(2):514-167.

Zhang D, Zhou L, Huang L, Chen X, Zhang J F, Guo L. Study on improved cuckoo search algorithm applied in parameters estimation of multi-layer soil: 1D and 3D. IET Science, Measurement and Technology, 2020, 14(7):14.844-852.

Oruc R, Sahin O, Baklacioglu T. Fuel flow rate modeling for descent using cuckoo search algorithm: a case study for point merge system procedure at Istanbul airport. Aircraft Engineering and Aerospace Technology, 2022, 94(5):824-833.

Li Y. Privacy protection algorithm for source node location based on phantom routing in the internet of things environment. International Journal of Innovative Computing, Information and Control, 2021, 17(3):973-989.

Kassab R, Simeone O, Popovski P. Information-centric grant-free access for IoT Fog Networks: Edge vs. cloud detection and Learning. IEEE Transactions on Wireless Communications, 2020, 19(10):6347-6361.

Sah D K, Nguyen T N, Cengiz K, Dumba B, Kumar V. Load-balance scheduling for intelligent sensors deployment in industrial internet of things. Cluster Computing, 2022, 25(3):1415-1727.

Zhao J, Xu X, Zhu W P. Adaptive delay-constrained resource allocation in mobile edge computing for Internet of Things communications networks. Computer Communications, 2020, 160(7):607-613.

Galanopoulos A, Salonidis T, Iosifidis G. Cooperative edge computing of data analytics for the internet of things. IEEE Transactions on Cognitive Communications and Networking, 2020, 6(4):1166-1179.

Groumpos P P. A critical historic overview of artificial intelligence: Issues, challenges, opportunities, and threats. Artificial Intelligence and Applications. 2023, 1(4):197-213.

Yang S, He N, Li F, Trajanovski S, Chen X, Wang Y, Fu X M. Survivable task allocation in cloud radio access networks with mobile-edge computing. IEEE Internet of Things Journal, 2020, 8(2):1095-1108.