Sustainable Development Using Geospatial Techniques (eBook)

eBook Download: EPUB
2024
685 Seiten
Wiley-Scrivener (Verlag)
978-1-394-21439-6 (ISBN)

Lese- und Medienproben

Sustainable Development Using Geospatial Techniques -
Systemvoraussetzungen
194,99 inkl. MwSt
  • Download sofort lieferbar
  • Zahlungsarten anzeigen

This book is a must-have for anyone interested in leveraging geospatial technology, as it covers a wide range of applications and offers valuable insights into the mapping, visualization, and analysis of natural resource planning using GIS, remote sensing, and GPS.

Geospatial technology (GT) is a combination of geographic information systems (GIS), remote sensing (RS), and the global position system (GPS) for the mapping, visualization, and analysis of natural resource planning. Nowadays, GIS is widely used throughout the globe for a wide range of applications. GIS is a system that combines locations, geography, hardware, software, statistics, planning, and digital mapping. GIS is a system in which one can store, manipulate, analyze, and visualize or display spatial data. The basic components of GIS are hardware, software, data, input, and manpower. One can develop spatial, temporal, and dynamic models using GIS, which may help in effective decision-making tools.

Geospatial information is a computer programme that collects, stores, verifies, and presents information on locations on the surface of the Earth. Geographical information systems play a key role in sustainable development. Geospatial technology combines traditional database operations like query and statistical analysis with the specific graphical and geographic analytical capabilities offered by maps.

Disha Thakur, PhD is an assistant professor in civil engineering at the University Institute of Technology (UIT), Shimla, India. She has published 13 research and conference papers and book chapters in reputed journals and national and international Conferences. Her research interests include geotechnical engineering and solid waste management.

Sanjay Kumar, PhD is working an assistant professor at the University Institute of Technology, Himachal Pradesh University, Shimla, India. He has research experience in various areas of electrical engineering. He has published 24 research papers in reputed national and international journals and 18 research papers in national and international conferences. He has 8 years of teaching and has delivered expert lectures at many colleges and universities in India.

Har Amrit Singh Sandhu, PhD is part of the faculty in the Civil Engineering Department at Punjab Engineering College, Chandigarh, India. He is also president of the American Society of Civil Engineers' Indian Chapter (North) and the coordinator at the Centre of Geospatial Technologies and a Digital India Land Records Modernization Programme cell. He has more than 20 years of experience in working, teaching, and researching in the geospatial field and has published various research papers in reputed national and international journals.

Chander Prakash, PhD is an assistant professor in the Civil Engineering Department at the National Institute of Technology (NIT), Hamirpur, India. He has published more than 25 research papers in reputed national and international journals and conferences and has completed a number of research and development projects.


This book is a must-have for anyone interested in leveraging geospatial technology, as it covers a wide range of applications and offers valuable insights into the mapping, visualization, and analysis of natural resource planning using GIS, remote sensing, and GPS. Geospatial technology (GT) is a combination of geographic information systems (GIS), remote sensing (RS), and the global position system (GPS) for the mapping, visualization, and analysis of natural resource planning. Nowadays, GIS is widely used throughout the globe for a wide range of applications. GIS is a system that combines locations, geography, hardware, software, statistics, planning, and digital mapping. GIS is a system in which one can store, manipulate, analyze, and visualize or display spatial data. The basic components of GIS are hardware, software, data, input, and manpower. One can develop spatial, temporal, and dynamic models using GIS, which may help in effective decision-making tools. Geospatial information is a computer programme that collects, stores, verifies, and presents information on locations on the surface of the Earth. Geographical information systems play a key role in sustainable development. Geospatial technology combines traditional database operations like query and statistical analysis with the specific graphical and geographic analytical capabilities offered by maps.

1
Development of a Two-Layer Meta-Classifier–Based Drought Stress Detection System for Wheat Crop Sustainability


Ankita Gupta1*, Lakhwinder Kaur2 and Gurmeet Kaur3

1Department of Computer Science and Engineering, CT Group of Institutions, Shahpur Campus, Jalandhar, Punjab, India

2Department of Computer Science and Engineering, Punjabi University, Patiala, Punjab, India

3Department of Electronics and Communication Engineering, Punjabi University, Patiala, Punjab, India

Abstract


Focusing on the Raj 3765 wheat variety’s chlorophyll fluorescence–based canopy level images, this research aims to formulate an ultraprecise, bilayered meta-classifier to curtail economic adversity within wheat farming. Preprocessing of images, utilizing the total variation - L1 (TV-L1) with a primal-dual algorithm, succeeded by contrast stretching (Min-Max), emerged as paramount. This pipeline’s choice hinged on mean squared error (MSE), peak signal-to-noise ratio (PSNR), and structural similarity index measure (SSIM) average values. Regarding feature selection and optimization, 23 gray-level co-occurrence matrix (GLCM) features, 9*255 color band features, 10 landmarks, and 20 wheat canopy geometric features proved significant. These features substantially enhanced machine learning algorithms’ efficacy. Most prominent classifiers are included in this research, viz, random forests (RF), naive Bayes (NB), K-nearest neighbors (KNN), and support vector machines (SVM), with RF achieving an accuracy of 93.06%, followed by NB and KNN. A blend of these classifiers showed RF and NB flourishing in the initial layer and KNN in the succeeding layer, exhibiting numerical constancy relative to the difference between training and testing accuracy. Our custom meta-classifier accomplished an apex accuracy of 95.8%. The research concludes with a case study showcasing the potential of such advancements in mitigating farmers’ losses.

Keywords: Wheat, water-stress, machine learning, phenotyping, chlorophyll fluorescence, image processing, meta-learning, sustainability

1.1 Introduction


Wheat and barley are two main crops on which consistent research has been done since the independence of India [1]. Wheat is a nutrient-rich, inexpensive source of energy that is highly consumed by all sections of society throughout the world [2]. Due to an accelerated increase in the population, the country (India) will not be able to feed its population due to lower yields in these crops [3]. The Indian government has been making sincere efforts to overcome this challenge by introducing new high-yielding and stress-tolerant wheat varieties [4]. This can be accomplished by increasing the area under irrigation and technological regimes and developing sustainable agriculture practices [5].

Techniques proved to be most fruitful in differentiating stress-tolerant and stress-susceptible genotypes utilizing physiological tools like canopy morphological analysis [6]. Most of the authors are using the crop water stress index (CWI) as a key metric for the identification of water stress by measuring canopy temperature [5, 7]. But still, there is a need to develop a technique that is purely nonintrusive in a cost-effective manner. It has been observed that an aggregate of 60% of global agriculture uses rain-fed farming practices, which are under threat due to unprecedented rains [8]. This underlines the need for the development of an affordable phenotyping platform for wheat crops under drought and controlled conditions for stress identification. The authors can identify the most dominant factors that are influenced by drought stress nonintrusively by analyzing color spectrum, texture, and statistical features [911]. The yield losses can be significantly affected by the water stress caused by the deficiency in soil moisture levels. This leads to an urge to analyze the soil and its characteristics for the development of efficient drought control systems.

There are standard protocols (gravimetric method) for conducting soil sampling, and the analysis of the water content in the soils is done in the laboratory using instrumentation [12, 13]. The method requires a lot of fieldwork and does not exactly give the status of plant conditions in a noninvasive manner. Another approach is the analysis of the subsurface of the soil using multiple instruments and sensors. This method requires field work and the installation of moisture probes along with other peripheral equipment that can be connected to computer networks [14, 15]. The neutron probes use radioactive material to analyze the water content in the soil. Multiple instruments with similar capacity and functionality use principles of resistance, dielectric permittivity, thermal conductivity, and thermalized neutrons [1618]. Through the soil-water retention or soil-water characteristic curve [19], tensiometers relate the relationship between pressure potential and soil water tension to soil water content [20]. This relationship is unique to each soil or porous medium.

Furthermore, indicators known as “organ level stress indicators” can also be used to identify water stress in wheat [21]. In this study, various parts of the wheat plant, including the canopy, roots, pollens, grains, development stages, hormonal regulation, and leaves, have been analyzed to gain insights into the signals emitted by these components in response to water stress. The objective was to understand how each part of the plant indicates the presence of water stress. This objective can be accomplished by employing high-throughput imaging technologies, such as hyperspectral imaging, thermal imaging, and chlorophyll fluorescence (CHF) imaging. These advanced imaging techniques enable the computation of spectral vegetation indices and xanthophyll indices using satellite imagery and cameras, which capture and quantify the “photosynthetic activity” within a given frame. The utilization of these imaging technologies proves to be highly valuable in assessing and monitoring the impact of water stress on different parts of the wheat plant [22].

1.2 Literature Review


Water stress in plants is a complex phenomenon that has significant implications for their growth and development. As researchers have explored this subject, they have observed a range of changes in plants exposed to dehydration stress, including reductions in the number of leaves, leaf size, leaf area, and leaf longevity [15, 2326]. These alterations ultimately lead to a decrease in the overall canopy size and shape of the plants. Furthermore, water stress also affects the root-to-shoot ratio and the biomass of the plants, as they struggle to absorb water in different parts of their body under drought conditions [27].

To gain a deeper understanding of water stress in wheat, researchers have conducted experiments using field setups to impose water stress at various stages of crop growth and development [28, 29]. They have focused on parameters such as canopy biomass and root-shoot size to study drought tolerance in wheat crops [30, 31]. It has been observed that during extended dry periods, crops extend their roots deeper into the soil, altering their root-shoot ratio and canopy morphology [3133].

In addition to the noninvasive techniques mentioned earlier, other technical methods have proven valuable in detecting water stress in plants. Thermal imaging has been widely used to assess changes in plant temperature distribution, providing insights into their water status and stress levels [6, 34]. Hyperspectral imaging, on the other hand, analyzes the interaction of plants with different wavelengths of light, allowing researchers to identify specific spectral signatures associated with water stress [3538]. These techniques, along with advancements in digital imaging instrumentation and high-throughput phenotyping capabilities of cameras, have transformed precision agriculture. Moreover, the use of 3D imaging and LiDAR has gained prominence, enabling detailed analysis of plant architecture and structure, as well as precise measurement of plant height, canopy structure, and biomass [39].

Traditional plant phenotyping methods, involving manual processing of agricultural samples, are time-consuming and inefficient. However, the advent of data collection tools like cameras and unmanned aerial vehicles (UAVs) has revolutionized this field [10, 15, 40]. CHF imaging using remote sensing is a valuable tool for detecting and assessing drought and water stress conditions in vegetation. It measures the light emitted by chlorophyll during photosynthesis and provides indicators of stress and changes in photosynthetic efficiency. By quantifying fluorescence signals, remote sensing enables the early detection of water stress, estimation of water use efficiency, and large-scale monitoring of vegetation health. This information aids in timely intervention and resource allocation, supporting effective drought management and sustainable agricultural practices.

Machine learning approaches have significantly improved the accuracy of CHF-based systems by leveraging time series data for trend analysis. By automating the process of feature extraction, machine learning pipelines facilitate the development...

Erscheint lt. Verlag 26.9.2024
Sprache englisch
Themenwelt Naturwissenschaften Biologie
Naturwissenschaften Geowissenschaften Geologie
Schlagworte Artificial Intelligence (AI) • Convolution Neural Network • Deep Learning, Fuzzy System • Digital Elevation Model • Digital Image Processing • Digital Mapping • drone mapping • Emerging technology • geographical information system (GIS) • Geospatial Technology • Machine Learning (ML) • Maps • Remote Sensing (RS) • Smart City • Zonation
ISBN-10 1-394-21439-1 / 1394214391
ISBN-13 978-1-394-21439-6 / 9781394214396
Haben Sie eine Frage zum Produkt?
EPUBEPUB (Adobe DRM)
Größe: 26,1 MB

Kopierschutz: Adobe-DRM
Adobe-DRM ist ein Kopierschutz, der das eBook vor Mißbrauch schützen soll. Dabei wird das eBook bereits beim Download auf Ihre persönliche Adobe-ID autorisiert. Lesen können Sie das eBook dann nur auf den Geräten, welche ebenfalls auf Ihre Adobe-ID registriert sind.
Details zum Adobe-DRM

Dateiformat: EPUB (Electronic Publication)
EPUB ist ein offener Standard für eBooks und eignet sich besonders zur Darstellung von Belle­tristik und Sach­büchern. Der Fließ­text wird dynamisch an die Display- und Schrift­größe ange­passt. Auch für mobile Lese­geräte ist EPUB daher gut geeignet.

Systemvoraussetzungen:
PC/Mac: Mit einem PC oder Mac können Sie dieses eBook lesen. Sie benötigen eine Adobe-ID und die Software Adobe Digital Editions (kostenlos). Von der Benutzung der OverDrive Media Console raten wir Ihnen ab. Erfahrungsgemäß treten hier gehäuft Probleme mit dem Adobe DRM auf.
eReader: Dieses eBook kann mit (fast) allen eBook-Readern gelesen werden. Mit dem amazon-Kindle ist es aber nicht kompatibel.
Smartphone/Tablet: Egal ob Apple oder Android, dieses eBook können Sie lesen. Sie benötigen eine Adobe-ID sowie eine kostenlose App.
Geräteliste und zusätzliche Hinweise

Buying eBooks from abroad
For tax law reasons we can sell eBooks just within Germany and Switzerland. Regrettably we cannot fulfill eBook-orders from other countries.

Mehr entdecken
aus dem Bereich