An integration of random forest regression model in tourism suitability evaluation index system

Abstract

Analyzing an IoT-enabled smart tourist environment backed by a real-time wireless sensor network is appropriate for the tourism industry. Wireless sensor network nodes are employed as relays, and mutual information accumulation is used in cooperative transmission. Rateless codes allow nodes to collect data in advance to extract the original code of the text. Mobile robot movement makes it possible for predetermined routing patterns to abruptly fail; as a result, a dynamic system for collaborative information gathering and transmission is proposed. Using the neighbor search and chance transmission, to dynamically acquire routing pathways covers both situations of data transfer from the robot to the cloud and from the cloud to the robot. Experimental findings demonstrate the decreased time complexity and latency of a collaborative, dynamic method for exchanging knowledge. Due to the broadcasting nature use, mutual information accumulates through the cooperative transmission strategy of wireless transmission, which enables all neighbor nodes to get a portion moment the transmitter first begins to transmit the data. It uses single-hop broadcasts using rateless codes to improve the possibility of successful transmissions. Using rateless codes is more efficient since waiting for the next neighbor to awaken during a transmission failure requires much time and energy in a low-duty cycle situation. The viability of underground space development is shown by the study area's extensive bearing capabilities and its significant subsurface resource base, which includes sensitive geological bodies, mineral resources, soil, and water environments.

Keywords

Rateless robotics model random forest IoT in tourism wireless sensor network suitability index

Get full access to this article

View all access options for this article.

References

Ivanov

Webster

. Perceived appropriateness and intention to use service robots in tourism. In: Information and communication technologies in tourism 2019: proceedings of the international conference in Nicosia, Cyprus, January 30–February 1, 2019. Springer International Publishing, 2019, pp.237–248.

Fan

Tang

. Labor costs and the adoption of robots in China. Journal of Economic Behavior & Organization 2021; 186: 608–631.

Lima

Kim

Ryu

, et al. Collecting the public perception of AI and robot rights. Proceedings of the ACM on Human-Computer Interaction 2020; 4: 1–24.

Pai

Shetty

Dinesh

, et al. Effectiveness of social robots as a tutoring and learning companion: a bibliometric analysis. Cogent Business & Management 2024; 11: 2299075.

Schlegel

Kraus

. Skills and competencies for digital transformation–a critical analysis in the context of robotic process automation. International Journal of Organizational Analysis 2023; 31: 804–822.

de Kervenoael

Hasan

Schwob

, et al. Leveraging human-robot interaction in hospitality services: incorporating the role of perceived value, empathy, and information sharing into visitors’ intentions to use social robots. Tourism Management 2020; 78: 104042.

Wang

Zheng

, et al. Multimodal human-robot interaction for human-centric smart manufacturing: a survey. Advanced Intelligent Systems 2024; 6: 2300359.

Chan

APH

Tung

VWS

. Examining the effects of robotic service on brand experience: the moderating role of hotel segment. Journal of Travel & Tourism Marketing 2019; 36: 458–468.

Graterol

Diaz-Amado

Cardinale

, et al. Emotion detection for social robots based on NLP transformers and an emotion ontology. Sensors 2021; 21: 1322.

10.

Gualtieri

Rauch

Vidoni

. Methodology for defining the optimal assembly cycle and calculating the optimized assembly cycle time in human-robot collaborative assembly. The International Journal of Advanced Manufacturing Technology 2021; 113: 2369–2384.

11.

Ngo

HQT

Thien

VDN

, et al. Develop the socially human-aware navigation system using a dynamic window approach and optimize cost function for autonomous medical robots. Advances in Mechanical Engineering 2020; 12: 1687814020979430.

12.

Wang

. A literature survey of the robotic technologies during the COVID-19 pandemic. Journal of Manufacturing Systems 2021; 60: 823–836.

13.

Santos

Pereira

Vasconcelos

. Toward robotic process automation implementation: an end-to-end perspective. Business Process Management Journal 2020; 26: 405–420.

14.

Bonn

. Hotel employee's artificial intelligence and robotics awareness and its impact on turnover intention: the moderating roles of perceived organizational support and competitive psychological climate. Tourism Management 2019; 73: 172–181.

15.

Kim

Yeom

, et al. Gait optimization of a quadruped robot using evolutionary computation. Journal of Bionic Engineering 2021; 18: 306–318.

16.

Touzani

Hadj-Abdelkader

Séguy

, et al. Multi-robot task sequencing & automatic path planning for cycle time optimization: application for the car production line. IEEE Robotics and Automation Letters 2021; 6: 1335–1342.

17.

Filippini

Perpetuini

Cardone

, et al. A review of thermal infrared imaging-based affective computing and its application to facilitate human-robot interaction. Applied Sciences 2020; 10: 2924.

18.

Sarker

Jamal

Ahmed

, et al. Robotics and artificial intelligence in healthcare during COVID-19 pandemic: a systematic review. Robotics and Autonomous Systems 2021; 146: 103902.

19.

Zhou

Zhang

, et al. Design, development, and field evaluation of a rubber-tapping robot. Journal of Field Robotics 2022; 39: 28–54.

20.

Papadakis

Raptopoulos

Koskinopoulou

, et al. On the use of vacuum technology for applied robotic systems. In 2020 6th International Conference on Mechatronics and Robotics Engineering (ICMRE) (pp. 73–77). IEEE. 2020, February.

21.

Malik

Brem

. Digital twins for collaborative robots: a case study in human-robot interaction. Robotics and Computer-Integrated Manufacturing 2021; 68: 102092.

22.

Stadnicka

Antonelli

. Human-robot collaborative work cell implementation through lean thinking. International Journal of Computer Integrated Manufacturing 2019; 32: 580–595.