Published Date
, Volume 27, Issue 6, pp 1407–1414
Original Paper
Cite this article as:
Wang, C., Qiao, Y., Wu, H. et al. J. For. Res. (2016) 27: 1407. doi:10.1007/s11676-016-0230-5
Author
Recent advances in information and communication technologies, such as mobile Internet and smartphones, have created new paradigms for participatory environment monitoring. The ubiquitous mobile phones with capabilities such as a global positioning system, camera, and network access, offer opportunities to establish distributed monitoring networks that can perform a wide range of measurements for a landscape. This study examined the potential of mobile phone-based community monitoring of fall webworm (Hyphantria cuneaDrury). We built a prototype of a participatory fall webworm monitoring system based on mobile devices that streamlined data collection, transmission, and visualization. We also assessed the accuracy and reliability of the data collected by the local community. The system performance was evaluated at the Ziya commune of Tianjin municipality in northern China, where fall webworm infestation has occurred. The local community provided data with accuracy comparable to expert measurements (Willmott’s index of agreement >0.85). Measurements by the local community effectively complemented remote sensing images in both temporal and spatial resolution.
References
For further details log on website :
http://link.springer.com/article/10.1007/s11676-016-0270-x
, Volume 27, Issue 6, pp 1407–1414
Original Paper
- First Online:
- 13 May 2016
DOI: 10.1007/s11676-016-0230-5
Author
Recent advances in information and communication technologies, such as mobile Internet and smartphones, have created new paradigms for participatory environment monitoring. The ubiquitous mobile phones with capabilities such as a global positioning system, camera, and network access, offer opportunities to establish distributed monitoring networks that can perform a wide range of measurements for a landscape. This study examined the potential of mobile phone-based community monitoring of fall webworm (Hyphantria cuneaDrury). We built a prototype of a participatory fall webworm monitoring system based on mobile devices that streamlined data collection, transmission, and visualization. We also assessed the accuracy and reliability of the data collected by the local community. The system performance was evaluated at the Ziya commune of Tianjin municipality in northern China, where fall webworm infestation has occurred. The local community provided data with accuracy comparable to expert measurements (Willmott’s index of agreement >0.85). Measurements by the local community effectively complemented remote sensing images in both temporal and spatial resolution.
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For further details log on website :
http://link.springer.com/article/10.1007/s11676-016-0270-x
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