Innovative Approaches to 3D GIS Modeling for Volumetric and Geoprocessing Applications in Subsurface Infrastructures in a Virtual Immersive Environment

As subsurface features remain largely ‘out of sight, out of mind’, this has led to challenges when dealing with underground space and infrastructures and especially so for those working in GIS. Since subsurface infrastructure plays a major role in supporting the needs of modern society, groups such as city planners and utility companies and decision makers are looking for an ‘holistic’ approach where the sustainable use of underground space is as important as above ground space. For such planning and management, it is crucial to examine subsurface data in a form that is amenable to 3D mapping and that can be used for increasingly sophisticated 3D modeling. The subsurface referred to in this study focuses particularly on examples of both shallow and deep underground infrastructures. In the case of shallow underground infrastructures mostly two-dimensional maps are used in the management and planning of these features. Depth is a very critical component of underground infrastructures that is difficult to represent in a 2D map and for this reason these are best studied in three-dimensional space. In this research, the capability of 3D GIS technology and immersive geography are explored for the storage, management, analysis, and visualization of shallow and deep subsurface features

Spatializing Coupled Human and Natural System (CHANS)

Human sustainability is one of the most pressing issues of the 21st century. Coupled Human and Natural Systems (CHANS) offers a useful framework to focus on understanding the complex process and pattern that characterizes the dynamical interactions between human and natural systems. This dissertation research integrates the geospatial analysis into the CHANS framework from three perspectives: temporal, spatial, and organizational coupling. Using the temporal coupling aspect, we monitor the risk of deforestation and biodiversity threats from energy investments in Southeast Asia. We assess the energy investment evaluate changes to forest morphology and the risk to biodiversity. In terms of land cover change, we find that hydroelectric power plants tend to have more extensive biodiversity impacts than coal-fired plants, which are usually built within proximity to major population centers. Next, we explore spatial coupling by examining the spatial heterogeneity and homogeneity in home prices across Massachusetts, using Geographically Weighted Regression models with natural and socio-demographic variables. We discovered models that utilized spatial heterogeneity perform better. However, statistical tests of significance are required to determine the model specification to avoid over-fitting. In the fourth chapter, we examined a critical refugium for endangered fish species in East Africa by mapping the organizational dynamics of aquatic vegetation on Lake Kyoga, Uganda. A CHANS organizational coupling involving the natural infrastructure of aquatic vegetation and fishes can adversely impact endangered species and the surrounding human communities. Floating aquatic vegetation can protect the native fishes from predation by Nile Perch by creating hypoxic barriers between water bodies. We developed an algorithm to locate and identify various types of aquatic vegetation. Profiles of lakes are created to examine the spatiotemporal dynamics of refugia. The results are valuable in shaping strategies to conserve both fish species and human livelihoods. The fifth chapter explores emerging technologies, Virtual Reality, in communicating the complex CHANS coupling of green (trees) and gray infrastructure (gas pipelines). This chapter demonstrates the building of 3D urban landscapes from remote sensing data and the emerging use of VR to communicate, educate and empower the stakeholders on sustainability issues related to aging natural gas infrastructure and resulting methane emissions. This dissertation research aims to build a set of methodologies based on extensive geospatial data, spatially explicit models, and tools essential for operationalizing and monitoring CHANS in studies ranging from local to regional scales. Each application builds or revises a new model or algorithm to address a real-world CHANS problem

Semantic location extraction from crowdsourced data

Crowdsourced Data (CSD) has recently received increased attention in many application areas including disaster management. Convenience of production and use, data currency and abundancy are some of the key reasons for attracting this high interest. Conversely, quality issues like incompleteness, credibility and relevancy prevent the direct use of such data in important applications like disaster management. Moreover, location information availability of CSD is problematic as it remains very low in many crowd sourced platforms such as Twitter. Also, this recorded location is mostly related to the mobile device or user location and often does not represent the event location. In CSD, event location is discussed descriptively in the comments in addition to the recorded location (which is generated by means of mobile device's GPS or mobile communication network). This study attempts to semantically extract the CSD location information with the help of an ontological Gazetteer and other available resources. 2011 Queensland flood tweets and Ushahidi Crowd Map data were semantically analysed to extract the location information with the support of Queensland Gazetteer which is converted to an ontological gazetteer and a global gazetteer. Some preliminary results show that the use of ontologies and semantics can improve the accuracy of place name identification of CSD and the process of location information extraction

Computational virtual measurement for trees

National forest inventory (NFI) is a systematic sampling method to collect forest information, including tree parameters, site conditions, and auxiliary data. The sample plot measurement is the key work in NFI. However, compared to the techniques 100 years ago, measuring methods and data-processing (modeling) approaches for NFI sample plots have been improved to a minor extent. The limit was that the newly-developed methods introduced additional validation workflows and would increase the workload in NFI. That was due to that these methods were usually developed based on species-specific and site-specific strategies. In order to overcome these obstacles, the integration of the novel measuring instruments is in urgent need, e.g., light detection and ranging (LiDAR) and the corresponding data processing methods with NFI. Given these situations, this thesis proposed a novel computational virtual measurement (CVM) method for the determination of tree parameters without the need for validation. Primarily, CVM is a physical simulation method and works as a virtual measuring instrument. CVM measures raw data, e.g., LiDAR point clouds and tree models, by the simulation of the physical mechanism of measuring instruments and natural phenomena. Based on the theory of CVM, this thesis is a systematic description of how to develop virtual measuring instruments. The first work is to introduce the CVM theory. CVM is a conceptual and general methodology, which is different from a specific measurement of tree parameters. Then, the feasibility of CVM was tested using a conceptual implementation, i.e., virtual ruler. The development of virtual ruler demonstrated the two key differences between CVM and conventional modeling methods. Firstly, the research focus of CVM is to build an appropriate physical scenario instead of finding a mathematical relationship between modeling results and true values. Secondly, the CVM outputs can approach true values, whereas the modeling results could not. Consequently, in a virtual space, tree parameters are determined by a measuring process without mathematical predictions. Accordingly, the result is free of validation and can be regarded as true values, at least in virtual spaces. With the knowledge from the virtual ruler development, two exceptional implementations are further developed. They are the virtual water displacement (VWD) method and sunlight analysis method. Both of them employ the same CVM workflow, which is firstly measured in reality and secondly measured in virtual space. The VWD aims to virtually measure the point clouds using the simulation of water displacement methods in reality. There are two stages in this method. The first stage is to apply the simulation of water displacement using massive virtual water molecules (VWMs). Some empirical regressions have to be employed in this stage, due to the limitation of computer performance. In the second stage, a single (or few) VWM (or VWMs) is developed to remove those empirical processes in VWD. Finally, VWD can function as a fully automatic method to measure point clouds.The sunlight analysis method aims to virtually measure the tree models using the simulation of solar illumination during daylight. There are also two stages in this method. The first stage is to develop sunlight analysis for a single tree. The second stage is to analyze the interference from neighboring trees. The results include default tree attributes, which can be collected in the future NFI. The successful developments of CVM, along with implementations of VWD and sunlight analysis methods, prove the initial assumptions in this thesis. It is the conversion of mathematical processing of data into virtual measurements. Accordingly, this is a different philosophy, i.e., the role of data is extended to the digital representative of trees. It opens an avenue of data processing using a more natural approach and is expected to be employed in the near future as a standard measuring instrument, such as a diameter tape, in NFI.Die Nationale Waldinventur (NFI) ist eine systematische Stichprobenmethode zur Erfassung von Waldinformationen, einschließlich Baumparameter, Standortbedingungen und Hilfsdaten. Die Messung von Stichprobenparzellen ist die Schlüsselarbeit der NFI. Im Vergleich zu den Techniken vor 100 Jahren wurden die Messmethoden und Datenverarbeitungsansätze (Modellierung) für NFI-Stichprobenparzellen jedoch in geringem Umfang verbessert. Die Grenze lag darin, dass die neu entwickelten Methoden zusätzliche Validierungsabläufe einführten und den Arbeitsaufwand in der NFI erhöhen würden. Dies war darauf zurückzuführen, dass diese Methoden in der Regel auf der Grundlage art- und standortspezifischer Strategien entwickelt wurden. Um diese Hindernisse zu überwinden, ist die Integration der neuartigen Messinstrumente dringend erforderlich, z.B. Light Detection and Ranging (LiDAR) und die entsprechenden Datenverarbeitungsmethoden mit NFI. Vor diesem Hintergrund wird in dieser Arbeit ein neuartiges rechnergestütztes virtuelles Messverfahren (CVM) zur Bestimmung von Baumparametern ohne Validierungsbedarf vorgeschlagen. CVM ist in erster Linie eine physikalische Simulationsmethode und arbeitet als virtuelles Messinstrument. CVM misst Rohdaten, z.B. LiDAR-Punktwolken und Baummodelle, durch die Simulation des physikalischen Mechanismus von Messinstrumenten und Naturphänomenen. Basierend auf der Theorie des CVM ist diese Arbeit eine systematische Beschreibung, wie virtuelle Messinstrumente entwickelt werden können. Die erste Arbeit dient der Einführung in die Theorie des CVM. CVM ist eine konzeptuelle und allgemeine Methodik, die sich von einer spezifischen Messung von Baumparametern unterscheidet. Anschliessend wird die Durchführbarkeit des CVM anhand einer konzeptuellen Implementierung, d.h. eines virtuellen Lineals, getestet. Die Entwicklung des virtuellen Lineals zeigte die beiden Hauptunterschiede zwischen CVM und konventionellen Modellierungsmethoden auf. Erstens besteht der Forschungsschwerpunkt von CVM darin, ein geeignetes physisches Szenario zu erstellen, anstatt eine mathematische Beziehung zwischen Modellierungsergebnissen und wahren Werten zu finden. Zweitens können sich die Ergebnisse des CVM den wahren Werten annähern, während die Modellierungsergebnisse dies nicht konnten. Folglich werden in einem virtuellen Raum die Baumparameter durch einen Messprozess ohne mathematische Vorhersagen bestimmt. Dementsprechend ist das Ergebnis frei von Validierung und kann, zumindest in virtuellen Räumen, als wahre Werte betrachtet werden. Mit dem Wissen aus der Entwicklung des virtuellen Lineals werden zwei aussergewöhnliche Implementierungen weiterentwickelt. Es handelt sich um die Methode der virtuellen Wasserverdrängung (VWD) und die Methode der Sonnenlichtanalyse. Beide verwenden den gleichen CVM-Workflow, der erstens in der Realität und zweitens im virtuellen Raum gemessen wird. Das VWD zielt darauf ab, die Punktwolken virtuell zu messen, wobei die Simulation von Wasserverdrängungsmethoden in der Realität verwendet wird. Diese Methode besteht aus zwei Stufen. Die erste Stufe besteht in der Anwendung der Simulation der Wasserverdrängung unter Verwendung massiver virtueller Wassermoleküle (VWMs). Aufgrund der begrenzten Computerleistung müssen in dieser Phase einige empirische Regressionen angewandt werden. In der zweiten Stufe wird ein einzelnes (oder wenige) VWM (oder VWMs) entwickelt, um diese empirischen Prozesse im VWD zu entfernen. Schließlich kann VWD als vollautomatische Methode zur Messung von Punktwolken fungieren. Die Methode der Sonnenlichtanalyse zielt darauf ab, die Baummodelle virtuell zu messen, indem die Simulation der Sonneneinstrahlung bei Tageslicht verwendet wird. Auch bei dieser Methode gibt es zwei Stufen. In der ersten Stufe wird die Sonnenlichtanalyse für einen einzelnen Baum entwickelt. Die zweite Stufe ist die Analyse der Interferenz von benachbarten Bäumen. Die Ergebnisse umfassen Standard-Baumattribute, die in der zukünftigen NFI gesammelt werden können. Die erfolgreichen Entwicklungen von CVM, zusammen mit Implementierungen von VWD- und Sonnenlichtanalysemethoden, beweisen die anfänglichen Annahmen in dieser Arbeit. Es handelt sich um die Umsetzung der mathematischen Verarbeitung von Daten in virtuelle Messungen. Dementsprechend handelt es sich um eine andere Philosophie, d.h. die Rolle der Daten wird auf die digitale Darstellung von Bäumen ausgedehnt. Sie eröffnet einen Weg der Datenverarbeitung unter Verwendung eines natürlicheren Ansatzes und wird voraussichtlich in naher Zukunft als Standard-Messinstrument, wie z.B. ein Durchmesser-Band, in der NFI eingesetzt werden

Training of Crisis Mappers and Map Production from Multi-sensor Data: Vernazza Case Study (Cinque Terre National Park, Italy)

This aim of paper is to presents the development of a multidisciplinary project carried out by the cooperation between Politecnico di Torino and ITHACA (Information Technology for Humanitarian Assistance, Cooperation and Action). The goal of the project was the training in geospatial data acquiring and processing for students attending Architecture and Engineering Courses, in order to start up a team of "volunteer mappers". Indeed, the project is aimed to document the environmental and built heritage subject to disaster; the purpose is to improve the capabilities of the actors involved in the activities connected in geospatial data collection, integration and sharing. The proposed area for testing the training activities is the Cinque Terre National Park, registered in the World Heritage List since 1997. The area was affected by flood on the 25th of October 2011. According to other international experiences, the group is expected to be active after emergencies in order to upgrade maps, using data acquired by typical geomatic methods and techniques such as terrestrial and aerial Lidar, close-range and aerial photogrammetry, topographic and GNSS instruments etc.; or by non conventional systems and instruments such us UAV, mobile mapping etc. The ultimate goal is to implement a WebGIS platform to share all the data collected with local authorities and the Civil Protectio

Geographic Information Systems and Science

Geographic information science (GISc) has established itself as a collaborative information-processing scheme that is increasing in popularity. Yet, this interdisciplinary and/or transdisciplinary system is still somewhat misunderstood. This book talks about some of the GISc domains encompassing students, researchers, and common users. Chapters focus on important aspects of GISc, keeping in mind the processing capability of GIS along with the mathematics and formulae involved in getting each solution. The book has one introductory and eight main chapters divided into five sections. The first section is more general and focuses on what GISc is and its relation to GIS and Geography, the second is about location analytics and modeling, the third on remote sensing data analysis, the fourth on big data and augmented reality, and, finally, the fifth looks over volunteered geographic information.info:eu-repo/semantics/publishedVersio

Cognitive Buildings

Cognitive building is a pioneering topic envisioning the future of our built environment. The concept of "cognitive" provides a paradigm shift that steps from the static concept of the building as a container of human activities towards the modernist vision of "machine à habiter" of Le Corbusier, where the technological content adds the capability of learning from users' behavior and environmental variables to adapt itself to achieve major goals such as user comfort, energy-saving, flexible functionality, high durability, and good maintainability. The concept is based on digital frameworks and IoT networks towards the concept of a smart city

Mobility Design

Climate change and the scarcity of resources, but also the steadily increasing amount of traffic, make it indispensable to develop new solutions for environmentally friendly and people-friendly mobility. With the expansion of digital information systems, we will in future be able to easily combine different modes of transport according to our needs. These developments are a great challenge for the design of different mobility spaces. While the focus in Volume 1 was on practice, Volume 2 now brings together research from the fields of design, architecture, urban planning, geography, social science, transport planning, psychology and communication technology. The current discussion about the traffic turnaround is expanded to include the perspective of user-centred mobility design