This report summarizes a survey of the Taluka Sports Complex in Paithan using Google Earth and GPS. The sports complex was established in 2007 and contains facilities for tennis, football, gymnastics, boxing, squash, and cricket. The total land area is 1.48 acres. GPS was used to obtain latitude and longitude coordinates at 4 points around the complex. When compared to the Google Earth coordinates, small differences of up to 3 meters were found at some points, likely due to GPS or Google Earth inaccuracies. The report concludes that there can be slight differences between coordinates from online maps versus physical measurements.
This document provides an overview of geographic information systems (GIS) and their applications in civil engineering, the environment, and natural resource management. It discusses how GIS integrates data from various sources and disciplines to store, manipulate, analyze, and display spatial information. GIS has become an important tool for tasks like infrastructure and urban planning, natural resource management, and disaster mitigation by allowing users to query data, find optimal routes, and better understand spatial relationships. The document also covers GIS components like maps, coordinate systems, software, and how various fields contributed to the development of GIS technology.
Introduction to Digital Mapping for UG StudentsAbhijitZende3
Digital mapping involves converting traditional paper maps into digital formats. Etak was a pioneer in digital mapping and automotive navigation systems. It was founded in 1983 and created the first digital maps and navigation system for cars called the Etak Navigator in 1985. Over time, digital mapping has expanded and improved, allowing for applications like tracking diseases and monitoring natural disasters. Issues remain around data sharing and costs, but digital mapping provides important benefits for research, emergency response, and more. Google Earth further advanced digital mapping by providing satellite imagery and street views of locations around the world, though it also raised privacy and security concerns for some.
This document provides an overview of geographic information systems (GIS) and how GIS is used across many industries and fields. It begins with an introduction to GIS and how GIS links geographic data to other information. The document then describes how GIS is used in business, defense, government, natural resources, transportation, utilities and more. It provides examples of how GIS helps with tasks like facilities management, marketing, emergency response and more. The document aims to demonstrate how location matters to decision making and that GIS is a tool that can help organizations in many sectors.
Geographical Information System and Karnataka Forest cover digitizationKamlesh Kumar
This work is an effort to share GIS awareness, Digitization and map making of the forest cover of Karnataka between 2001 and 2011.
GIS
Introduction
Component
Application
About the state: Karnataka
Introduction
History
Geography
Economy
Administrative Division
Demography
Education
Transport
Tourism
Geo-referencing and Digitization
Data Joining & Map Making
Software used: QGIS 2.0.1
This document provides an overview of geographic information systems (GIS). It begins with a definition of GIS as a system that integrates hardware, software, and data to capture, store, analyze and display spatially referenced information. The document then outlines the historical background of GIS, the key components including hardware, software, data, procedures and personnel. It also describes the GIS process, common application areas, what makes GIS unique in its ability to handle spatial information, technologies used in GIS like digitization, and the two main data formats of raster and vector. Finally, it discusses the importance of GIS for urban planning by allowing layered maps and helping businesses target customers.
A Geographic Information System (GIS) is a computer-based tool used to represent and analyze geographic features and events on Earth. GIS integrates spatial data like maps with non-spatial data like databases to allow users to more easily visualize, question, interpret, and understand data for a variety of purposes such as planning, management, engineering, and analysis. Key advantages of GIS include enabling better planning of projects through spatial analysis and generation of thematic maps, improved decision-making through querying and analyzing spatial data, enhanced visualization of landscapes and calculations through tools like digital terrain modeling, and increased organizational integration and efficiency by facilitating information sharing across departments.
A geographic information system (GIS) allows users to capture, store, manipulate, analyze, manage and display spatial or geographical data. GIS integrates hardware, software and data to visualize relationships within mapped information. Key components include hardware, GIS software, data and people. There are two main data types - raster, which stores cell-based data like images, and vector, which represents discrete features using points, lines and polygons. GIS has evolved significantly since the 1960s and is now widely used across various fields and applications.
This document provides an overview of what Geographic Information Systems (GIS) are by explaining that GIS combines spatial data and tabular data to map and analyze real-world problems. It then discusses key components of GIS, including hardware, software, data, and trained personnel. GIS uses both vector and raster data layers to perform spatial analysis and create maps to help address issues across many fields.
This document provides an overview of geographic information systems (GIS) and their applications in civil engineering, the environment, and natural resource management. It discusses how GIS integrates data from various sources and disciplines to store, manipulate, analyze, and display spatial information. GIS has become an important tool for tasks like infrastructure and urban planning, natural resource management, and disaster mitigation by allowing users to query data, find optimal routes, and better understand spatial relationships. The document also covers GIS components like maps, coordinate systems, software, and how various fields contributed to the development of GIS technology.
Introduction to Digital Mapping for UG StudentsAbhijitZende3
Digital mapping involves converting traditional paper maps into digital formats. Etak was a pioneer in digital mapping and automotive navigation systems. It was founded in 1983 and created the first digital maps and navigation system for cars called the Etak Navigator in 1985. Over time, digital mapping has expanded and improved, allowing for applications like tracking diseases and monitoring natural disasters. Issues remain around data sharing and costs, but digital mapping provides important benefits for research, emergency response, and more. Google Earth further advanced digital mapping by providing satellite imagery and street views of locations around the world, though it also raised privacy and security concerns for some.
This document provides an overview of geographic information systems (GIS) and how GIS is used across many industries and fields. It begins with an introduction to GIS and how GIS links geographic data to other information. The document then describes how GIS is used in business, defense, government, natural resources, transportation, utilities and more. It provides examples of how GIS helps with tasks like facilities management, marketing, emergency response and more. The document aims to demonstrate how location matters to decision making and that GIS is a tool that can help organizations in many sectors.
Geographical Information System and Karnataka Forest cover digitizationKamlesh Kumar
This work is an effort to share GIS awareness, Digitization and map making of the forest cover of Karnataka between 2001 and 2011.
GIS
Introduction
Component
Application
About the state: Karnataka
Introduction
History
Geography
Economy
Administrative Division
Demography
Education
Transport
Tourism
Geo-referencing and Digitization
Data Joining & Map Making
Software used: QGIS 2.0.1
This document provides an overview of geographic information systems (GIS). It begins with a definition of GIS as a system that integrates hardware, software, and data to capture, store, analyze and display spatially referenced information. The document then outlines the historical background of GIS, the key components including hardware, software, data, procedures and personnel. It also describes the GIS process, common application areas, what makes GIS unique in its ability to handle spatial information, technologies used in GIS like digitization, and the two main data formats of raster and vector. Finally, it discusses the importance of GIS for urban planning by allowing layered maps and helping businesses target customers.
A Geographic Information System (GIS) is a computer-based tool used to represent and analyze geographic features and events on Earth. GIS integrates spatial data like maps with non-spatial data like databases to allow users to more easily visualize, question, interpret, and understand data for a variety of purposes such as planning, management, engineering, and analysis. Key advantages of GIS include enabling better planning of projects through spatial analysis and generation of thematic maps, improved decision-making through querying and analyzing spatial data, enhanced visualization of landscapes and calculations through tools like digital terrain modeling, and increased organizational integration and efficiency by facilitating information sharing across departments.
A geographic information system (GIS) allows users to capture, store, manipulate, analyze, manage and display spatial or geographical data. GIS integrates hardware, software and data to visualize relationships within mapped information. Key components include hardware, GIS software, data and people. There are two main data types - raster, which stores cell-based data like images, and vector, which represents discrete features using points, lines and polygons. GIS has evolved significantly since the 1960s and is now widely used across various fields and applications.
This document provides an overview of what Geographic Information Systems (GIS) are by explaining that GIS combines spatial data and tabular data to map and analyze real-world problems. It then discusses key components of GIS, including hardware, software, data, and trained personnel. GIS uses both vector and raster data layers to perform spatial analysis and create maps to help address issues across many fields.
This document provides an overview of geographic information systems (GIS). It defines GIS as a tool that integrates hardware, software and data to capture, manage, analyze and display spatially referenced information. The document outlines the typical components and functional parts of a GIS, including spatial data, computer tools, and specific applications. It also discusses how GIS can be used to make better decisions, improve communication, increase efficiency and manage information geographically.
TYBSC IT PGIS Unit I Chapter I- Introduction to Geographic Information SystemsArti Parab Academics
A Gentle Introduction to GIS The nature of GIS: Some fundamental observations, Defining GIS, GISystems, GIScience and GIApplications, Spatial data and Geoinformation. The real world and representations of it: Models and modelling, Maps, Databases, Spatial databases and spatial analysis
This document summarizes a study that used remote sensing and GIS techniques to produce a digital land use map of the Technical Institute of Anbar in Iraq. Satellite imagery and attribute data were collected and digitized in ArcGIS to create vector data layers representing land use classes. The final digital map identified destroyed buildings, service buildings, green areas, sports facilities, and unused land. It found that 20% of the institute's area contained structures while 80% was unused land. The digital map and geographic database produced can serve as a basis for future studies of the Technical Institute of Anbar.
This document summarizes a study that used remote sensing and GIS techniques to produce a digital land use map of the Technical Institute of Anbar in Iraq. Satellite imagery and attribute data were collected and digitized in ArcGIS to create vector data layers representing land use classes. The final digital map identified destroyed buildings, service buildings, green areas, sports facilities, and unused land. It found that 20% of the institute's area contained structures while 80% was unused land. The digital map and geographic database produced can serve as a basis for future studies of the Technical Institute of Anbar.
GIS Application Used in Urban Planning In IndiaIRJET Journal
This document discusses how geographic information systems (GIS) are used for urban planning in India. It provides an overview of GIS, describing it as a system for capturing, storing, analyzing, and managing spatially referenced data. GIS allows users to create maps, perform spatial queries and analysis, and visualize and model information. The document outlines how GIS is used in various aspects of urban planning like infrastructure development, transportation planning, and monitoring of health, sanitation, and other city services. It provides examples of how GIS aids in tasks like feasibility studies, land use planning, and public participation in the planning process. Overall, the document illustrates how Indian planners leverage GIS technologies to effectively plan and manage urban development.
Geographical Information Systems (GIS) allow users to collect, store, analyze and manage geographic data. GIS integrates various data layers like maps, satellite images, survey data and census records by linking them to a common spatial coordinate system. This allows for analysis of spatial patterns and relationships. Key functions of GIS include inputting data in digital formats, manipulating data for analysis and visualization purposes, managing large databases, performing spatial queries, conducting overlay and proximity analysis, and generating customized maps and reports. GIS has numerous applications in fields like agriculture, urban planning, natural resource management and more by helping users make informed decisions based on geographic factors and spatial relationships.
The document discusses how GIS is used across multiple disciplines including archaeology, economics, biology/ecology, political science, public administration, nursing/health, geology, history, environmental studies, engineering, and geography. GIS provides spatial analysis and mapping capabilities that help researchers, policymakers, and organizations understand patterns and make informed decisions in their respective fields.
Remote sensing and geographic information systems (GIS) analysis involves the use of technology to gather, manipulate, and analyze spatial data to understand a range of phenomena. Remote sensing entails obtaining information about the Earth's surface by examining data acquired by a device, which is at a distance from the surface, most often satellites orbiting the earth and airplanes. GIS are computer-based systems that are used to capture, store, analyze, and display geographic information. These two approaches are used widely, often together, to assess natural resources and monitor environmental changes. Social scientists can gain insights into fine spatial and temporal dynamics of a range of social phenomena in environmental contexts by analyzing time series of remote sensing data, by linking remote sensing to socioeconomic data using GIS, and developing with these data a range of digital models and analyses. This article examines remote sensing and GIS in general, with an emphasis on the former, and then explores how these approaches may be used together to address a range of issues. It also emphasizes the role of remote sensing and GIS for use by scientists, engineers & geologists in water resources management
The Mapping Revolution: Incorporating Geographic Information Systems in Gover...GovLoop
Since the beginning of civilization, humans have used images as a means to tell stories. We have used images to educate, entertain or to build a just and moral society. Our ancient ancestors would use images to remember stories and archive information for future generations. Similar to our ancient ancestors, we use images today to convey meaning, understand complex relationships and improve communication.
The use of mapping and geospatial technology is at the heart of story telling and improved communications. As the challenges of the public sector continue to grow in complexity, efficient and effective communication tools are essential. Today, government is more interconnected than ever before, and the complexity has led to increased integration between state, local and federal officials. At all levels of government, agencies are looking for solutions to find value and improve public sector decision-making through data. http://www.govloop.com/profiles/blogs/govloop-guide-the-mapping-revolution-incorporating-geographic-inf
1_GEOGRAPHIC INFORMATION SYSTEMSTEM.pptxLaleanePale
A geographic information system (GIS) is a framework for gathering, managing, and analyzing spatial data. GIS integrates data from various sources and organizes it into visualizations using maps and 3D scenes. This reveals patterns and relationships in the data to help users make better decisions. Key components of a GIS include hardware, software, people, data, and methods. Data comes in vector, raster, and tabular forms from various sources like maps, images, surveys, and databases. Common data input techniques are converting existing digital data, coordinate geometry, scanning, and digitizing.
GEOSPATIAL TECHNOLOGY, CONCEPT, TECHNIQUES AND ITS COMPONENTS. pptxMalothSuresh2
Geospatial technology involves three major components: Geographic Information Systems (GIS), Global Positioning Systems (GPS), and Remote Sensing (RS). GIS is used for geospatial analysis and mapping across many industries. GPS uses satellites to determine location on Earth. Remote sensing collects imagery from space and aircraft. Together these tools capture spatial data to analyze resources and make informed decisions.
This project involves updating the geographic information system (GIS) database and maps for the existing electricity distribution network in Muzaffarabad, Pakistan. The network was originally developed in 2006 but has not been updated since 2010. The project will update the digital database and maps to reflect current infrastructure by collecting data on transformers, poles, conductors, and consumers. This updated GIS database will help improve planning, implementation, and operation of the electricity network by providing accurate spatial and non-spatial utility data to support decision making. The specific area of focus will be the 11kV City-4 feeder network within the 132kV Muzaffarabad grid.
GIS is a computer-based tool used and managed by people to efficiently capture, store, integrate, analyze and display spatial (geographically referenced) data & associated attribute data
This document provides an introduction to Geographic Information Systems (GIS) including definitions, components, and applications. It defines GIS as having three integrated parts: geographic, information, and systems. GIS combines hardware, software, data, people, and methods to capture, store, analyze, and display spatial data. Key applications of GIS include navigation, natural resource management, and environmental planning. The document also outlines the basic functions of GIS including capturing, storing, querying, analyzing, displaying, and presenting geographic data.
The International Journal of Engineering and Science (The IJES)theijes
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
GIS.INTRODUCTION TO GIS PACKAGES &GEOGRAPHIIC ANALYSISTessaRaju
A geographic information system (GIS) allows users to integrate and analyze spatial data from a variety of sources through mapping and visualization. GIS provides tools to gather, store, retrieve, analyze and output geographic data. Spatial analysis techniques in GIS, such as buffering, proximity analysis and overlay analysis, enable users to model and understand relationships within and between spatial datasets to gain insights and solve problems.
This document provides an overview of remote sensing and geographic information systems (GIS). It discusses how remote sensing works by capturing electromagnetic radiation from energy sources and sensors. GIS integrates location data with descriptive information to create, manage, analyze and map different types of data. The document outlines applications of remote sensing such as agriculture monitoring, disaster management and more. It also explains the use of GIS for tasks like data analysis, information sharing, and problem solving. In conclusion, remote sensing and GIS provide a powerful geospatial technology to collect and analyze geographic data.
A Geographic Information System (GIS) integrates hardware, software and data to capture, store, analyze and display spatially-referenced information. GIS allows users to view, understand, question, interpret, and visualize data in many ways that reveal relationships, patterns, and trends. Key components of a GIS include hardware, software, data, methods, and personnel with GIS expertise. GIS differs from other graphics systems in its ability to geo-reference data, use relational databases to link spatial and non-spatial data, and overlay multiple data layers in a single map.
Decentralized Justice in Gaming and EsportsFederico Ast
Discover how Kleros is transforming the landscape of dispute resolution in the gaming and eSports industry through the power of decentralized justice.
This presentation, delivered by Federico Ast, CEO of Kleros, explores the innovative application of blockchain technology, crowdsourcing, and incentivized mechanisms to create fair and efficient arbitration processes.
Key Highlights:
- Introduction to Decentralized Justice: Learn about the foundational principles of Kleros and how it combines blockchain with crowdsourcing to develop a novel justice system.
- Challenges in Traditional Arbitration: Understand the limitations of conventional arbitration methods, such as high costs and long resolution times, particularly for small claims in the gaming sector.
- How Kleros Works: A step-by-step guide on the functioning of Kleros, from the initiation of a smart contract to the final decision by a jury of peers.
- Case Studies in eSports: Explore real-world scenarios where Kleros has been applied to resolve disputes in eSports, including issues like cheating, governance, player behavior, and contractual disagreements.
- Practical Implementation: Detailed walkthroughs of how disputes are handled in eSports tournaments, emphasizing speed, cost-efficiency, and fairness.
- Enhanced Transparency: The role of blockchain in providing an immutable and transparent record of proceedings, ensuring trust in the resolution process.
- Future Prospects: The potential expansion of decentralized justice mechanisms across various sectors within the gaming industry.
For more information, visit kleros.io or follow Federico Ast and Kleros on social media:
• Twitter: @federicoast
• Twitter: @kleros_io
This document provides an overview of geographic information systems (GIS). It defines GIS as a tool that integrates hardware, software and data to capture, manage, analyze and display spatially referenced information. The document outlines the typical components and functional parts of a GIS, including spatial data, computer tools, and specific applications. It also discusses how GIS can be used to make better decisions, improve communication, increase efficiency and manage information geographically.
TYBSC IT PGIS Unit I Chapter I- Introduction to Geographic Information SystemsArti Parab Academics
A Gentle Introduction to GIS The nature of GIS: Some fundamental observations, Defining GIS, GISystems, GIScience and GIApplications, Spatial data and Geoinformation. The real world and representations of it: Models and modelling, Maps, Databases, Spatial databases and spatial analysis
This document summarizes a study that used remote sensing and GIS techniques to produce a digital land use map of the Technical Institute of Anbar in Iraq. Satellite imagery and attribute data were collected and digitized in ArcGIS to create vector data layers representing land use classes. The final digital map identified destroyed buildings, service buildings, green areas, sports facilities, and unused land. It found that 20% of the institute's area contained structures while 80% was unused land. The digital map and geographic database produced can serve as a basis for future studies of the Technical Institute of Anbar.
This document summarizes a study that used remote sensing and GIS techniques to produce a digital land use map of the Technical Institute of Anbar in Iraq. Satellite imagery and attribute data were collected and digitized in ArcGIS to create vector data layers representing land use classes. The final digital map identified destroyed buildings, service buildings, green areas, sports facilities, and unused land. It found that 20% of the institute's area contained structures while 80% was unused land. The digital map and geographic database produced can serve as a basis for future studies of the Technical Institute of Anbar.
GIS Application Used in Urban Planning In IndiaIRJET Journal
This document discusses how geographic information systems (GIS) are used for urban planning in India. It provides an overview of GIS, describing it as a system for capturing, storing, analyzing, and managing spatially referenced data. GIS allows users to create maps, perform spatial queries and analysis, and visualize and model information. The document outlines how GIS is used in various aspects of urban planning like infrastructure development, transportation planning, and monitoring of health, sanitation, and other city services. It provides examples of how GIS aids in tasks like feasibility studies, land use planning, and public participation in the planning process. Overall, the document illustrates how Indian planners leverage GIS technologies to effectively plan and manage urban development.
Geographical Information Systems (GIS) allow users to collect, store, analyze and manage geographic data. GIS integrates various data layers like maps, satellite images, survey data and census records by linking them to a common spatial coordinate system. This allows for analysis of spatial patterns and relationships. Key functions of GIS include inputting data in digital formats, manipulating data for analysis and visualization purposes, managing large databases, performing spatial queries, conducting overlay and proximity analysis, and generating customized maps and reports. GIS has numerous applications in fields like agriculture, urban planning, natural resource management and more by helping users make informed decisions based on geographic factors and spatial relationships.
The document discusses how GIS is used across multiple disciplines including archaeology, economics, biology/ecology, political science, public administration, nursing/health, geology, history, environmental studies, engineering, and geography. GIS provides spatial analysis and mapping capabilities that help researchers, policymakers, and organizations understand patterns and make informed decisions in their respective fields.
Remote sensing and geographic information systems (GIS) analysis involves the use of technology to gather, manipulate, and analyze spatial data to understand a range of phenomena. Remote sensing entails obtaining information about the Earth's surface by examining data acquired by a device, which is at a distance from the surface, most often satellites orbiting the earth and airplanes. GIS are computer-based systems that are used to capture, store, analyze, and display geographic information. These two approaches are used widely, often together, to assess natural resources and monitor environmental changes. Social scientists can gain insights into fine spatial and temporal dynamics of a range of social phenomena in environmental contexts by analyzing time series of remote sensing data, by linking remote sensing to socioeconomic data using GIS, and developing with these data a range of digital models and analyses. This article examines remote sensing and GIS in general, with an emphasis on the former, and then explores how these approaches may be used together to address a range of issues. It also emphasizes the role of remote sensing and GIS for use by scientists, engineers & geologists in water resources management
The Mapping Revolution: Incorporating Geographic Information Systems in Gover...GovLoop
Since the beginning of civilization, humans have used images as a means to tell stories. We have used images to educate, entertain or to build a just and moral society. Our ancient ancestors would use images to remember stories and archive information for future generations. Similar to our ancient ancestors, we use images today to convey meaning, understand complex relationships and improve communication.
The use of mapping and geospatial technology is at the heart of story telling and improved communications. As the challenges of the public sector continue to grow in complexity, efficient and effective communication tools are essential. Today, government is more interconnected than ever before, and the complexity has led to increased integration between state, local and federal officials. At all levels of government, agencies are looking for solutions to find value and improve public sector decision-making through data. http://www.govloop.com/profiles/blogs/govloop-guide-the-mapping-revolution-incorporating-geographic-inf
1_GEOGRAPHIC INFORMATION SYSTEMSTEM.pptxLaleanePale
A geographic information system (GIS) is a framework for gathering, managing, and analyzing spatial data. GIS integrates data from various sources and organizes it into visualizations using maps and 3D scenes. This reveals patterns and relationships in the data to help users make better decisions. Key components of a GIS include hardware, software, people, data, and methods. Data comes in vector, raster, and tabular forms from various sources like maps, images, surveys, and databases. Common data input techniques are converting existing digital data, coordinate geometry, scanning, and digitizing.
GEOSPATIAL TECHNOLOGY, CONCEPT, TECHNIQUES AND ITS COMPONENTS. pptxMalothSuresh2
Geospatial technology involves three major components: Geographic Information Systems (GIS), Global Positioning Systems (GPS), and Remote Sensing (RS). GIS is used for geospatial analysis and mapping across many industries. GPS uses satellites to determine location on Earth. Remote sensing collects imagery from space and aircraft. Together these tools capture spatial data to analyze resources and make informed decisions.
This project involves updating the geographic information system (GIS) database and maps for the existing electricity distribution network in Muzaffarabad, Pakistan. The network was originally developed in 2006 but has not been updated since 2010. The project will update the digital database and maps to reflect current infrastructure by collecting data on transformers, poles, conductors, and consumers. This updated GIS database will help improve planning, implementation, and operation of the electricity network by providing accurate spatial and non-spatial utility data to support decision making. The specific area of focus will be the 11kV City-4 feeder network within the 132kV Muzaffarabad grid.
GIS is a computer-based tool used and managed by people to efficiently capture, store, integrate, analyze and display spatial (geographically referenced) data & associated attribute data
This document provides an introduction to Geographic Information Systems (GIS) including definitions, components, and applications. It defines GIS as having three integrated parts: geographic, information, and systems. GIS combines hardware, software, data, people, and methods to capture, store, analyze, and display spatial data. Key applications of GIS include navigation, natural resource management, and environmental planning. The document also outlines the basic functions of GIS including capturing, storing, querying, analyzing, displaying, and presenting geographic data.
The International Journal of Engineering and Science (The IJES)theijes
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
GIS.INTRODUCTION TO GIS PACKAGES &GEOGRAPHIIC ANALYSISTessaRaju
A geographic information system (GIS) allows users to integrate and analyze spatial data from a variety of sources through mapping and visualization. GIS provides tools to gather, store, retrieve, analyze and output geographic data. Spatial analysis techniques in GIS, such as buffering, proximity analysis and overlay analysis, enable users to model and understand relationships within and between spatial datasets to gain insights and solve problems.
This document provides an overview of remote sensing and geographic information systems (GIS). It discusses how remote sensing works by capturing electromagnetic radiation from energy sources and sensors. GIS integrates location data with descriptive information to create, manage, analyze and map different types of data. The document outlines applications of remote sensing such as agriculture monitoring, disaster management and more. It also explains the use of GIS for tasks like data analysis, information sharing, and problem solving. In conclusion, remote sensing and GIS provide a powerful geospatial technology to collect and analyze geographic data.
A Geographic Information System (GIS) integrates hardware, software and data to capture, store, analyze and display spatially-referenced information. GIS allows users to view, understand, question, interpret, and visualize data in many ways that reveal relationships, patterns, and trends. Key components of a GIS include hardware, software, data, methods, and personnel with GIS expertise. GIS differs from other graphics systems in its ability to geo-reference data, use relational databases to link spatial and non-spatial data, and overlay multiple data layers in a single map.
Decentralized Justice in Gaming and EsportsFederico Ast
Discover how Kleros is transforming the landscape of dispute resolution in the gaming and eSports industry through the power of decentralized justice.
This presentation, delivered by Federico Ast, CEO of Kleros, explores the innovative application of blockchain technology, crowdsourcing, and incentivized mechanisms to create fair and efficient arbitration processes.
Key Highlights:
- Introduction to Decentralized Justice: Learn about the foundational principles of Kleros and how it combines blockchain with crowdsourcing to develop a novel justice system.
- Challenges in Traditional Arbitration: Understand the limitations of conventional arbitration methods, such as high costs and long resolution times, particularly for small claims in the gaming sector.
- How Kleros Works: A step-by-step guide on the functioning of Kleros, from the initiation of a smart contract to the final decision by a jury of peers.
- Case Studies in eSports: Explore real-world scenarios where Kleros has been applied to resolve disputes in eSports, including issues like cheating, governance, player behavior, and contractual disagreements.
- Practical Implementation: Detailed walkthroughs of how disputes are handled in eSports tournaments, emphasizing speed, cost-efficiency, and fairness.
- Enhanced Transparency: The role of blockchain in providing an immutable and transparent record of proceedings, ensuring trust in the resolution process.
- Future Prospects: The potential expansion of decentralized justice mechanisms across various sectors within the gaming industry.
For more information, visit kleros.io or follow Federico Ast and Kleros on social media:
• Twitter: @federicoast
• Twitter: @kleros_io
Honeypots Unveiled: Proactive Defense Tactics for Cyber Security, Phoenix Sum...APNIC
Adli Wahid, Senior Internet Security Specialist at APNIC, delivered a presentation titled 'Honeypots Unveiled: Proactive Defense Tactics for Cyber Security' at the Phoenix Summit held in Dhaka, Bangladesh from 23 to 24 May 2024.
Securing BGP: Operational Strategies and Best Practices for Network Defenders...APNIC
Md. Zobair Khan,
Network Analyst and Technical Trainer at APNIC, presented 'Securing BGP: Operational Strategies and Best Practices for Network Defenders' at the Phoenix Summit held in Dhaka, Bangladesh from 23 to 24 May 2024.
KubeCon & CloudNative Con 2024 Artificial Intelligent
Geographic Information System.pdf
1. Marathwada Shikshan Prasarak Mandal’s
Deogiri Institute of Engineering and Management Studies,
Aurangabad
Survey Report
On
Taluka Sports Complex, Paithan
Submitted By
Sandesh Sanjay Bandal (36106)
Sumit Santosh Kolhe (36122)
TY-B
For Continuous Assessment-1 of GIS
Dr. Babasaheb Ambedkar Technological University
Lonere (M.S.)
Department of Computer Science and Engineering
Deogiri Institute of Engineering and Management Studies,
Aurangabad
(2021- 2022)
2. Google Earth
Google Earth is a unique geo-mapping and tagging program that uses composite imagery to
form a comprehensive, interactive map of the Earth. By stitching together more than a billion
satellite and aerial images, the application provides a versatile tool that allows individuals and
groups to track climate change, discover unknown geographic and ecological features, and
record our history.
This digital cartography tool continues to be a useful resource for governments, private
organizations and individuals who want to track and tag geographic data to myriad ends. By
collecting and curating enormous amounts of data, Google has made it possible for
conservationists to observe the shifting patterns of flora and fauna on a global scale, for
governments to observe the growth of cities worldwide, and for individuals to tell their
personal stories in a unique way.
Google Earth has several countries like the United States, Canada and the United Kingdom
covered to street level, so you can zoom in and view road names and local businesses and get
directions from here to there. The database has a good amount of information on other
regions like Western Europe, India and Japan as well, but the rest of the world is hit or miss.
While you can zoom in and get a pretty good look at the Egyptian pyramids, you can't see
street names or find a grocery store in the area. Google is constantly adding more information
to its databases, though, and the maps are getting better with each update.
3. This brings us to another source of Google Earth's data: the Google search engine. Part of
what makes Google Earth, so addictive is its collaboration with Google search. As you now
know from the "How to Find the Fun Stuff" section, when you're viewing a city, you can
search for coffee shops, restaurants, grocery stores, bars and tons of other businesses in the
vicinity, and you can click on them to get detailed information from the Google search
engine. Users can also add a business location to a map by clicking on "Add/Edit a Business
Listing" in the Google Earth toolbar.
A geographic information system (GIS) is a framework for gathering, managing, and
analysing data. Rooted in the science of geography, GIS integrates many types of data. It
analyses spatial location and organizes layers of information into visualizations using maps
and 3D scenes. With this unique capability, GIS reveals deeper insights into data, such as
patterns, relationships, and situations—helping users make smarter decisions.
A geographical information system (GIS) is a computer system for capturing, storing,
checking, integrating, manipulating, analysing and displaying data related to positions on the
Earth's surface. It is thus a way of linking databases with maps, to display information,
perform spatial analyses or develop and apply spatial models.
How does GIS work?
GIS technology applies geographic science with tools for understanding and collaboration. It
helps people reach a common goal: to gain actionable intelligence from all types of data.
GIS applications are tools that allow users to create interactive queries (user-created
searches), analyse spatial information, edit data in maps, and present the results of all these
operations. GIS (more commonly GIScience) sometimes refers to geographic information
science (GIScience), the science underlying geographic concepts, applications, and systems.
Since the mid-1980s, geographic information systems have become valuable tool used to
support a variety of city and regional planning functions.
TECHNOLOGY
Modern GIS technologies use digital information, for which various digitized data creation
methods are used. The most common method of data creation is digitization, where a hard
copy map or survey plan is transferred into a digital medium through the use of a CAD
program, and geo-referencing capabilities. With the wide availability of ortho-rectified
imagery (from satellites, aircraft, Helikites and UAVs), heads-up digitizing is becoming the
main avenue through which geographic data is extracted. Heads-up digitizing involves the
tracing of geographic data directly on top of the aerial imagery instead of by the traditional
method of tracing the geographic form on a separate digitizing tablet (heads-down digitizing).
Geoprocessing is a GIS operation used to manipulate spatial data. A typical geoprocessing
operation takes an input dataset, performs an operation on that dataset, and returns the result
of the operation as an output dataset. Common geoprocessing operations include geographic
feature overlay, feature selection and analysis, topology processing, raster processing, and
4. data conversion. Geoprocessing allows for definition, management, and analysis of
information used to form decisions.
Many different types of information can be compared and contrasted using GIS. The system
can include data about people, such as population, income, or education level. It can include
information about the landscape, such as the location of streams, different kinds of
vegetation, and different kinds of soil. It can include information about the sites of factories,
farms, and schools, or storm drains, roads, and electric power lines.
With GIS technology, people can compare the locations of different things in order to
discover how they relate to each other. For example, using GIS, a single map could include
sites that produce pollution, such as factories, and sites that are sensitive to pollution, such as
wetlands and rivers. Such a map would help people determine where water supplies are most
at risk.
GIS Maps
Once all the desired data have been entered into a GIS system, they can be combined to
produce a wide variety of individual maps, depending on which data layers are included. One
of the most common uses of GIS technology involves comparing natural features with human
activity.
For instance, GIS maps can display what man-made features are near certain natural features,
such as which homes and businesses are in areas prone to flooding.
GIS technology also allows users to “dig deep” in a specific area with many kinds of
information. Maps of a single city or neighbourhood can relate such information as average
income, book sales, or voting patterns. Any GIS data layer can be added or subtracted to the
same map.
GIS maps can be used to show information about numbers and density. For example, GIS can
show how many doctors there are in a neighbourhood compared with the area’s population.
With GIS technology, researchers can also look at change over time. They can use satellite
data to study topics such as the advance and retreat of ice cover in polar regions, and how that
coverage has changed through time. A police precinct might study changes in crime data to
help determine where to assign officers.
5. INTRODUCTION
Taluka Sports Complex, Paithan. Complex area was founded in 2007 with an aim to fulfil the
Sports activity needs in the society. Core values of the organization are quality, professionalism
and sportsman spirit. It has increased the fitness ratio of people who have access to this
organization. It has also been a location to celebrate sports day as we can carry many activities,
competitions such as tennis, cricket, football, badminton, boxing, squash, athletics, gymnastics,
etc.
The Sports Complex has several sports divisions such as:
1) Tennis
2) Football
3) Gymnastic
4) Boxing
5) Squash
6) Cricket
6. Longitude and Latitude: -
1) Total Land Area: 1.48 Acres
Google Earth: -
Points Latitude Longitude
P1 19°28'44"N 75°22'45"E
P2 19°28'47"N 75°22'48"E
P3 19°28'44"N 75°22'52"E
P4 19°28'42"N 75°22'46"E
7. Actual Location: -
Points Latitude Longitude
P1 19°28'45"N 75°22'45"E
P2 19°28'47"N 75°22'48"E
P3 19°28'44"N 75°22'51"E
P4 19°28'42"N 75°22'46"E
Snapshots of Measurement by Compass:
P1 P2
8. P3 P4
Difference:
Points Latitude Longitude
P1 2.22m NIL
P2 NIL NIL
P3 NIL NIL
P4 NIL 2.22m
In point P1 (top-right), there is a difference in Latitude value is of 0 0 3 N & 0 0 1 E in
Longitude in Google earth and actual values. Similarly, in point P4 (bottom-right) 0 0 2 N & 0
0 4 E, in C (bottom-left) 0 0 3 N & 0 0 2 E are the differences in between values located by
google earth and actual values of Latitude and Longitude values.
9. Conclusion: -
There is a slight difference in latitudes and longitudes when calculated from Google Earth or
other Mapping services and the values obtained after physically tracing the area.