Modern logistics technology may be the key to breaking the deadlock. Utilizing modern logistics technology to build an efficient logistics platform is an effective way to capture opportunities in today's global competitive environment. However, modern logistics still encounter several challenges. Fortunately, the development of big data and smart technology has driven the development of smart logistics. Building a smart logistics platform is conducive to controlling costs, increasing efficiency, reducing energy consumption, etc. With advances in information technology, the existing modern logistics technology can be enhanced to produce maximum and measurable output. This paper aims to discuss findings about the extent to which artificial intelligence is applied in supporting logistical activities by targeting several previous studies. The following literature study aims to determine the level of usability that has been applied in the implementation stage. In order to obtain data or information, proposers conduct a review of previous studies. This literature study was carried out with the aim of seeing the level of satisfaction and usability of the use of Artificial Intelligence in the logistics sector from the stakeholder's point of view. The information obtained in the discussion section shows that use shows a significant impact on indicators of effectiveness, efficiency, and productivity levels.

Artificial Intelligence; Logistics; Mobile Agent

Abousaeidi, M., Fauzi, R., & Muhamad, R. (2016). Geographic Information System (GIS) modeling approach to determine the fastest delivery routes. Saudi journal of biological sciences, 23(5), 555-564.

Alicke, K., Rexhausen, D., & Seyfert, A. (2017). Supply Chain 4.0 in consumer goods. Mckinsey & Company, 1(11).

Amosa, B. M. G., JB, E., Oyetunji, O. O., Nwaekpe, C., & Ogunleye, T. Operability of Mobile Agent Applications in a Protected Environment. International Journal on Future Recolution in Computer Science & Communication Engineering, 3(12), 190-196.

Attaran, M. (2020). Digital technology enablers and their implications for supply chain management. In Supply Chain Forum: An International Journal, 21(3), 258-172.

Al-Kuwaiti, M., Kyriakopoulos, N., & Hussein, S. (2009). A comparative analysis of network dependability, fault-tolerance, reliability, security, and survivability. IEEE Communications Surveys & Tutorials, 11(2), 106-124.

Cichosz, M., Wallenburg, C. M., & Knemeyer, A. M. (2020). Digital transformation at logistics service providers: barriers, success factors and leading practices. The International Journal of Logistics Management, 31(2), 209-238.

Das, S., Dey, A., Pal, A., & Roy, N. (2015). Applications of artificial intelligence in machine learning: review and prospect. International Journal of Computer Applications, 115(9), 31-41.

Deichmann, U., Goyal, A., & Mishra, D. (2016). Will digital technologies transform agriculture in developing countries?. Agricultural Economics, 47(S1), 21-33.

Doelitzscher, F., Reich, C., Knahl, M., Passfall, A., & Clarke, N. (2012). An agent based business aware incident detection system for cloud environments. Journal of Cloud Computing: Advances, Systems and Applications, 1, 1-19.

Du‐Harpur, X., Watt, F. M., Luscombe, N. M., & Lynch, M. D. (2020). What is AI? Applications of artificial intelligence to dermatology. British Journal of Dermatology, 183(3), 423-430.

Gorodetsky, V. I., Laryukhin, V. B., & Skobelev, P. O. (2019). Conceptual Model of a Digital Platform for Cyber-Physical Management of a Modern Enterprises Part 1. Digital Platform and Digital Ecosystem. Mekhatronika, Avtomatizatsiya, Upravlenie, 20(6), 323-332.

Hassanat, A., Almohammadi, K., Alkafaween, E. A., Abunawas, E., Hammouri, A., & Prasath, V. S. (2019). Choosing mutation and crossover ratios for genetic algorithms—a review with a new dynamic approach. Information, 10(12), 390.

Kumar, S., Tiwari, P., & Zymbler, M. (2019). Internet of Things is a revolutionary approach for future technology enhancement: a review. Journal of Big data, 6(1), 1-21.

Mintsis, G., Basbas, S., Papaioannou, P., Taxiltaris, C., & Tziavos, I. N. (2004). Applications of GPS technology in the land transportation system. European journal of operational Research, 152(2), 399-409.

Navickas, V., & Gruzauskas, V. (2016). Big data concept in the food supply chain: Small markets case. Analele stiintifice ale Universitatii “Al. I. Cuza” din Iasi. Stiinte economice/Scientific Annals of the" Al. I. Cuza", 63 (1), 15-28.

Raza, E., & Komala, A. L. (2020). Manfaat dan Dampak Digitalisasi Logistik di Era Industri 4.0. Jurnal Logistik Indonesia, 4(1), 49-63.

Sarker, I. H. (2021). Machine learning: Algorithms, real-world applications and research directions. SN computer science, 2(3), 160.

Ulin Hernandez, E. J., Saucedo Martinez, J. A., & Marmolejo Saucedo, J. A. (2020). Optimization of the distribution network using an emerging technology. Applied sciences, 10(3), 857.

Peres, R. S., Rocha, A. D., Leitao, P., & Barata, J. (2018). IDARTS–Towards intelligent data analysis and real-time supervision for industry 4.0. Computers in industry, 101, 138-146.

Zhang, G., Li, G., & Peng, J. (2020). Risk assessment and monitoring of green logistics for fresh produce based on a support vector machine. Sustainability, 12(18), 7569.