Top

Published in:

2024 | OriginalPaper | Chapter

Landslide Monitoring System Using an IoT Wireless Sensor Network

Authors : Gian Quoc Anh, Tran Binh Duong, Vijender Kumar Solanki, Duc-Tan Tran

Published in: Modern Approaches in IoT and Machine Learning for Cyber Security

Publisher: Springer International Publishing

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Landslides are a common phenomenon globally and also in Vietnam. The damage significantly affects people’s lives and property. However, its predictions and warnings are still sketchy. Continuous landslide warning monitoring systems were built to minimize the damage caused by such landslides. A landslide monitoring system using wireless sensor networks can detect soil movement, measure movement, and send an alert level and position landslide or in danger of landslides for the center. All causes and factors related to this dangerous phenomenon will be automatically recorded and archived and give accurate warnings. Wireless sensor network (WSN) is an energy-saving technology solution such as sensor selection, changing sampling frequency, and switching network configuration based on operating scenarios. Furthermore, micro electro-mechanical system (MEMS) sensors with low power consumption are used to receive ground displacement information instead of traditional measuring sensors. This chapter will focus on surveying and evaluating landslide monitoring systems using a wireless sensor network.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Wirtschaft"

Online-Abonnement

Mit Springer Professional "Wirtschaft" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 340 Zeitschriften

aus folgenden Fachgebieten:

Bauwesen + Immobilien
Business IT + Informatik
Finance + Banking
Management + Führung
Marketing + Vertrieb
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

previous chapter IOT for Healthcare

next chapter Precision Livestock Farming Systems Based on Accelerometer Technology and Machine Learning

S. Ahmed, S. Gupta, A. Suri, S. Sharma, Adaptive energy efficient fuzzy: An adaptive and energy efficient fuzzy clustering algorithm for wireless sensor network-based landslide detection system. IET Network 10(1), 1–12 (2021)CrossRef

G. Anastasi, M. Conti, M. Di Francesco, A. Passarella, Energy conservation in wireless sensor networks: A survey. Ad Hoc Netw. 7, 537–568 (2009)CrossRef

M.-G. Angeli, A. Pasuto, S. Silvano, A critical review of landslide monitoring experiences. Eng. Geol. 55, 133–147 (2000)CrossRef

G. Antonello, N. Casagli, P. Farina, D. Leva, G. Nico, A. Sieber, et al., Ground-based SAR interferometry for monitoring mass movements. Landslides 1, 21–28 (2004)CrossRef

C. Arnhardt, K. Asch, R. Azzam, R. Bill, T. Fernandez-Steeger, S. Homfeld, et al., Sensor based landslide early warning system-SLEWS. Development of a geoservice infrastructure as basis for early warning systems for landslides by integration of real-time sensors. Geotechnologien Sci. Rep. 10, 75–88 (2007)

S. Asano, H. Ochiai, H.D. Vinh, TXT-tool 4.081-8.1: landslide monitoring for early warning in the Hai Van Station landslide in Vietnam, in Landslide Dynamics: ISDR-ICL Landslide Interactive Teaching Tools, (Springer, 2018), pp. 785–792CrossRef

M. Barla, F. Antolini, An integrated methodology for landslides’ early warning systems. Landslides 13, 215–228 (2015)CrossRef

P. Baronti, P. Pillai, V.W. Chook, S. Chessa, A. Gotta, Y.F. Hu, Wireless sensor networks: A survey on the state of the art and the 802.15. 4 and ZigBee standards. Comput. Commun. 30, 1655–1695 (2007)CrossRef

R.L. Baum, J.W. Godt, Early warning of rainfall-induced shallow landslides and debris flows in the USA. Landslides 7, 259–272 (2010)CrossRef

10.

M. Berti, M. Martina, S. Franceschini, S. Pignone, A. Simoni, M. Pizziolo, Probabilistic rainfall thresholds for landslide occurrence using a Bayesian approach. J. Geophys. Res. Earth Surf. 117 (2012)

11.

C. Buratti, A. Conti, D. Dardari, R. Verdone, An overview on wireless sensor networks technology and evolution. Sensors 9, 6869–6896 (2009)CrossRef

12.

G. Capparelli, P. Versace, FLaIR and SUSHI: Two mathematical models for early warning of landslides induced by rainfall. Landslides 8, 67–79 (2010)CrossRef

13.

N. Casagli, S. Morelli, W. Frodella, E. Intrieri, V. Tofani, TXT-tool 2.039-3.2 ground-based remote sensing techniques for landslides mapping, monitoring and early warning, in Landslide Dynamics: ISDR-ICL Landslide Interactive Teaching Tools, (Springer, 2018), pp. 255–274CrossRef

14.

M. Castillo-Effer, D.H. Quintela, W. Moreno, R. Jordan, W. Westhoff, Wireless sensor networks for flash-flood alerting, in Devices, Circuits and Systems, (Proceedings of the Fifth IEEE International Caracas Conference on, 2004, 2004), pp. 142–146

15.

B.-G. Chae, M.-I. Kim, Suggestion of a method for landslide early warning using the change in the volumetric water content gradient due to rainfall infiltration. Environ. Earth Sci. 66, 1973–1986 (2011)CrossRef

16.

K. Chintalapudi, T. Fu, J. Paek, N. Kothari, S. Rangwala, J. Caffrey, et al., Monitoring civil structures with a wireless sensor network. IEEE Internet Comput. 10, 26–34 (2006)CrossRef

17.

G.M. Dias, B. Bellalta, S. Oechsner, A survey about prediction-based data reduction in wireless sensor networks. ACM Comput. Surv. (CSUR) 49, 58 (2016)

18.

M.J. Dong, K.G. Yung, W.J. Kaiser, Low Power Signal Processing Architectures for Network Microsensors (Proceedings of the 1997 International Symposium on Low Power Electronics and Design, 1997), pp. 173–177

19.

C. Fosalau, C. Zet, D. Petrisor, Implementation of a Landslide Monitoring System as a Wireless Sensor Network, in Ubiquitous Computing, Electronics & Mobile Communication Conference (UEMCON), (IEEE Annual, 2016), pp. 1–6

20.

A. Gian Quoc, C. Nguyen Dinh, N. Tran Duc, T. Tran Duc, S. Kumbesan, Wireless technology for monitoring site-specific landslide in Vietnam. Int. J. Electr. Comput. Eng. 8(6), 4448–4455 (2018)

21.

Q.A. Gian, D.C. Nguyen, D.N. Tran, D.T. Tran, Monitoring of landslides in mountainous regions based on FEM modelling and rain gauge measurements. Int. J. Electric. Comput. Eng. 6(5), 2106 (2016)

22.

Q.A. Gian, D.T. Tran, D.C. Nguyen, V.H. Nhu, D. Tien Bui, Design and implementation of site-specific rainfall-induced landslide early warning and monitoring system: A case study at Nam Dan landslide (Vietnam). Geomatic. Nat. Hazards Risk 8(2), 1978–1996 (2017)CrossRef

23.

J.A. Gili, J. Corominas, J. Rius, Using global positioning system techniques in landslide monitoring. Eng. Geol. 55, 167–192 (2000)CrossRef

24.

P. Giri, K. Ng, W. Phillips, Wireless Sensor Network System for Landslide Monitoring and Warning (IEEE Transactions on Instrumentation and Measurement, 2018), pp. 1–11

25.

J. Goswami, A. Saha, IoT sensor network based implementation for rainfall induced landslide monitoring, in International Conference on Computational Intelligence, Security and Internet of Things, (Springer, Cham, 2020), pp. 304–316

26.

R. Greco, A. Guida, E. Damiano, L. Olivares, Soil water content and suction monitoring in model slopes for shallow flowslides early warning applications. Phys. Chem. Earth, Parts A/B/C 35, 127–136 (2010)CrossRef

27.

J.A. Gutierrez, M. Naeve, E. Callaway, M. Bourgeois, V. Mitter, B. Heile, IEEE 802.15. 4: A developing standard for low-power low-cost wireless personal area networks. IEEE Netw. 15, 12–19 (2001)CrossRef

28.

M. Hons, R. Stewart, D. Lawton, M. Bertram, G. Hauer, Field data comparisons of MEMS accelerometers and analog geophones. Lead. Edge 27, 896–903 (2008)CrossRef

29.

http://www.safeland-fp7.eu

30.

C. Huggel, N. Khabarov, M. Obersteiner, J.M. Ramírez, Implementation and integrated numerical modeling of a landslide early warning system: A pilot study in Colombia. Nat. Hazards 52, 501–518 (2010)CrossRef

31.

E. Intrieri, G. Gigli, F. Mugnai, R. Fanti, N. Casagli, Design and implementation of a landslide early warning system. Eng. Geol. 147–148, 124–136 (2012)CrossRef

32.

B. Kerkez, S.D. Glaser, R.C. Bales, M.W. Meadows, Design and performance of a wireless sensor network for catchment-scale snow and soil moisture measurements. Water Resour. Res. 48 (2012)

33.

S. Kumar, S. Duttagupta, V.P. Rangan, M.V. Ramesh, Reliable network connectivity in wireless sensor networks for remote monitoring of landslides. Wirel. Netw 26(3), 2137–2152 (2020)CrossRef

34.

D. Lagomarsino, S. Segoni, R. Fanti, F. Catani, Updating and tuning a regional-scale landslide early warning system. Landslides 10, 91–97 (2013)CrossRef

35.

J. Landes, J. Begley, G. Clarke, American society for testing and materials. STP 590, 128–148 (1976)

36.

M. Li, Y. Liu, Underground Structure Monitoring with Wireless Sensor Networks (Proceedings of the 6th International Conference on Information Processing in Sensor Networks, 2007), pp. 69–78

37.

Li, Y. Liu, Underground coal mine monitoring with wireless sensor networks. ACM Trans. Sensor Network (TOSN) 5, 10 (2009)CrossRef

38.

Z. Liao, Y. Hong, J. Wang, H. Fukuoka, K. Sassa, D. Karnawati, et al., Prototyping an experimental early warning system for rainfall-induced landslides in Indonesia using satellite remote sensing and geospatial datasets. Landslides 7, 317–324 (2010)CrossRef

39.

R. Macciotta, C.D. Martin, N.R. Morgenstern, D.M. Cruden, Quantitative risk assessment of slope hazards along a section of railway in the Canadian Cordillera—A methodology considering the uncertainty in the results. Landslides 13, 115–127 (2016)CrossRef

40.

A. Manconi, D. Giordan, Landslide early warning based on failure forecast models: The example of the Mt. de La Saxe rockslide, northern Italy. Nat. Hazards Earth Syst. Sci. 15, 1639–1644 (2015)CrossRef

41.

J. Mathew, D.G. Babu, S. Kundu, K.V. Kumar, C. Pant, Integrating intensity–duration-based rainfall threshold and antecedent rainfall-based probability estimate towards generating early warning for rainfall-induced landslides in parts of the Garhwal Himalaya, India. Landslides 11, 575–588 (2014)CrossRef

42.

A. Menció, M. Galán, D. Boix, J. Mas-Pla, Analysis of stream–aquifer relationships: A comparison between mass balance and Darcy’s law approaches. J. Hydrol. 517, 157–172 (2014)CrossRef

43.

D.C. Nguyen, D.N. Tran, N.H. Le, D.T. Ta, A.T. Pham, D.T. Tran, Multi-sensors integration for landslide monitoring application. VNU J. Sci. 30(6S-B), 202–210 (2014)

44.

C.D. Nguyen, T.D. Tran, N.D. Tran, T.H. Huynh, D.T. Nguyen, Flexible and efficient wireless sensor networks for detecting rainfall-induced landslides. Int. J. Distrib. Sens. Netw. 2015, 235954 (2015a)CrossRef

45.

D.C. Nguyen, T. Duc-Tan, D.N. Tran, Application of compressed sensing in effective power consumption of WSN for landslide scenario, in Asia Pacific Conference on Multimedia and Broadcasting, (IEEE, 2015b), pp. 1–5

46.

M. Papa, V. Medina, F. Ciervo, A. Bateman, Derivation of critical rainfall thresholds for shallow landslides as a tool for debris flow early warning systems. Hydrol. Earth Syst. Sci. 17, 4095–4107 (2013)CrossRef

47.

Y. Peng, Z. Li, W. Zhang, D. Qiao, Prolonging Sensor Network Lifetime Through Wireless Charging (IEEE Real-Time Systems Symposium, 2010), pp. 129–139

48.

L. Piciullo, S.L. Gariano, M. Melillo, M.T. Brunetti, S. Peruccacci, F. Guzzetti, et al., Definition and performance of a threshold-based regional early warning model for rainfall-induced landslides. Landslides 14, 995–1008 (2016)CrossRef

49.

M.V. Ramesh, Design, development, and deployment of a wireless sensor network for detection of landslides. Ad Hoc Netw. 13, 2–18 (2014)CrossRef

50.

P. Rawat, K.D. Singh, H. Chaouchi, J.M. Bonnin, Wireless sensor networks: A survey on recent developments and potential synergies. J. Supercomput. 68, 1–48 (2014)CrossRef

51.

S. Segoni, L. Piciullo, S.L. Gariano, A review of the recent literature on rainfall thresholds for landslide occurrence. Landslides 15, 1–19 (2018)CrossRef

52.

A. Sheth, K. Tejaswi, P. Mehta, C. Parekh, R. Bansal, S. Merchant, et al., Senslide: A Sensor Network Based Landslide Prediction System (Proceedings of the 3rd International Conference on Embedded Networked Sensor Systems, 2005), pp. 280–281

53.

A. Terzis, A. Anandarajah, K. Moore, I. Wang, Slip Surface Localization in Wireless Sensor Networks for Landslide Prediction (Proceedings of the 5th International Conference on Information Processing in Sensor Networks, 2006), pp. 109–116

54.

B. Thiebes, R. Bell, T. Glade, S. Jäger, J. Mayer, M. Anderson, et al., Integration of a limit-equilibrium model into a landslide early warning system. Landslides 11, 859–875 (2013)CrossRef

55.

H. Thirugnanam, M.V. Ramesh, V.P. Rangan, Enhancing the reliability of landslide early warning systems by machine learning. Landslides 17, 2231–2246 (2020)CrossRef

56.

I. Towhata, T. Uchimura, C. Gallage, On early detection and warning against rainfall-induced landslides (m129), in Landslides, (Springer, 2005), pp. 133–139CrossRef

57.

D.T. Tran, D.C. Nguyen, D.N. Tran, D.T. Ta, Development of a rainfall-triggered landslide system using wireless accelerometer network. Int. J. Adv. Comput. Technol. 7(5), 14 (2015)

58.

UN-ISDR, Developing Early Warning Systems: A Checklist (Third International Conference on Early Warning (EWC III), Bonn, 2006)

59.

L. Xiang, J. Luo, C. Rosenberg, Compressed data aggregation: Energy-efficient and high-fidelity data collection. IEEE/ACM Trans. Network (TON) 21, 1722–1735 (2013)CrossRef

60.

Y. Yin, H. Wang, Y. Gao, X. Li, Real-time monitoring and early warning of landslides at relocated Wushan town, the three Gorges reservoir, China. Landslides 7, 339–349 (2010)CrossRef

61.

X. Yu, P. Wu, W. Han, Z. Zhang, A survey on wireless sensor network infrastructure for agriculture. Comput. Stand. Interfaces 35, 59–64 (2013)CrossRef

62.

X. Zhu, Q. Xu, M. Tang, W. Nie, S. Ma, Z. Xu, Comparison of two optimized machine learning models for predicting displacement of rainfall-induced landslide: A case study in Sichuan Province, China. Eng. Geol. 218, 213–222 (2017)CrossRef

Title: Landslide Monitoring System Using an IoT Wireless Sensor Network
Authors: Gian Quoc Anh
Tran Binh Duong
Vijender Kumar Solanki
Duc-Tan Tran
Publisher: Springer International Publishing
Book: Modern Approaches in IoT and Machine Learning for Cyber Security
Print ISBN: 978-3-031-09954-0

Electronic ISBN: 978-3-031-09955-7

Copyright Year: 2024
DOI: https://doi.org/10.1007/978-3-031-09955-7_13

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Springer Professional "Wirtschaft"

Premium Partner