There is a hidden revolution going on: geography is moving from niche to the mainstream. GIS for Web Developers introduces Geographic Information Systems (GIS) in simple terms and demonstrates hands-on uses. With this book, you’ll explore popular websites like maps.google.com, see the technologies they use, and learn how to create your own. Written with the usual Pragmatic Bookshelf humor and real-world experience, GIS for Web Developers makes geographic programming concepts accessible to the common developer.
require the installation of a plugin for the application to be used in a browser. Flex and Silverlight both fall short as languages for mobile development and both require the use of a plugin for the application to run in a browser.
What this book covers
Chapter 2, Creating Maps and Adding Layers, teaches you how to create a map and add layers to the map. You will learn how to create an instance of the Map class, add layers of data to the map, and display this information on a web page. The Map class is the most fundamental class in the API as it provides the canvas for your data layers and any subsequent activities that occur in your application. However, your map is useless until you add layers of data. There are several types of data layers that can be added to a map, including tiled, dynamic, and feature. Readers will learn more about each of these layer types in this chapter.
Chapter 3, Adding Graphics to the Map, teaches the reader how to display temporary points, lines, and polygons in GraphicsLayer on the map. GraphicsLayer is a separate layer that always resides on top of other layers and stores all the graphics associated with the map.
Chapter 4, The Feature Layer, offers additional capabilities, apart from inheriting from GraphicsLayer, such as the ability to perform queries and selections. Feature layers are also used for online editing of features. Feature layers differ from tiled and dynamic map service layers, because feature layers bring geometry information to the client computer to be drawn and stored by the web browser. Feature layers
potentially cut down on round trips to the server. A client can request the features it needs, and perform selections and queries on those features without having to request more information from the server.
navigation and drawing toolbars.
Chapter 6, Performing Spatial and Attribute Queries, covers the ArcGIS Server Query Task, which allows you to perform attribute and spatial queries against data layers in a map service that have been exposed. You can also combine these query types to perform a combination attribute and spatial query.
Chapter 7, Identifying and Finding Features, covers two common operations found in any GIS application. These operations require that the user click a feature on the map in the case of identification, or perform a query in the case of finding features. In either case, information about particular features is returned. In this chapter, the reader will learn how to use the IdentifyTask and FindTask objects to obtain
information about features.
Chapter 8, Turning Addresses into Points and Points into Addresses, covers the use of the Locator task to perform geocoding and reverse geocoding. Geocoding is the process of assigning a coordinate to an address, while reverse geocoding assigns an address
to a coordinate.
Chapter 9, Network Analyst Tasks, allows you to perform analyses on street networks, such as finding the best route from one address to another, finding the closest school, identifying a service area around a location, or responding to a set of orders with a
fleet of service vehicles.
the built-in gesture support.
The last decade has seen a boom in people becoming acclimated to location technology. Most users may not fully realize that they’re using location technology when they get an alert on their phone that there’s traffic on the way home, or when they get a coupon from an app on their phone for a local restaurant. Smart phones are no longer simply devices for making phone calls, texting, and checking email. For many people, they’ve not only replaced the heavy and clumsy map book that your passenger used to help you navigate, but these “phones” have also replaced the expensive indash GPS systems in our vehicles. It’s so easy today to say the name of a store or venue into your phone, and in seconds receive turn-by-turn directions. That’s not to say that these directions may not try to direct you into a lake, but there’s no denying that location technology has become part of our daily lives. We gladly share our current locations with friends and family with as much fervor as when we shared a photo a few
years ago. Maps and the information they can convey are great tools that developers should take time to learn to use.
A few years ago, I was tasked with upgrading an enterprise GIS application and bringing it into the modern non-mainframe era. Esri had just started releasing Web APIs for use with their technology. At the time, I built my application with the Flex API, and I delved deep into the world of ActionScript and Flex modular development, but it always felt a bit heavy-handed.
Web mapping/GIS is the process of designing, implementing, generating and delivering maps, geospatial data and Geographic Information Systems (GIS) functionality or services on the Web. Primarily focusing on technological issues, this field increasingly includes theoretic aspects such as cartographic design, theory and principles, social and organizational issues and applications. Given the recent advances led by mainstream Information Technology (IT) developers, the need to examine these issues becomes increasingly critical.
This book volume, Advances in Web-based GIS, Mapping Services and Applications, aims at examining both theoretical/technological advancements and social/organizational issues in the field of web-based GIS and mapping services and applications. It presents an overall view of current progress and achievements with considerable technical details and examples.
The contents address: 1) constant updating of related web and geospatial technologies as well as the revolution of web mapping caused by mainstream IT vendors such as Google, Yahoo and Microsoft; 2) increased interest in geospatial information technologies from the industry; and 3) increasing demand from the general public for prompt and effective online access to geospatial information. All contributing chapters were advised to consider: 1) inclusion of recent technological advancements, especially new developments under Web 2.0, map mashups, neogeography, and the like; 2) balanced theoretical discussions and technical implementations; 3) commentary on the current stages of development; and 4) prediction of future developments over the next decade.
The original recommended topics and themes, as listed in the call for chapter proposals, include:
• Web 2.0, neogeography, and map mashups
• Technologies providing new service-oriented, distributed architectures, e.g., web services,
SOA, P2P, grid computing, etc.
• Technologies enhancing web interaction with maps and spatial representations, e.g., Ajax, SVG, GeoRSS, etc.
• Advances in virtual earth technologies
• Open source and open standards as related to web GIS/mapping
• Web-based spatial decision support
• Applications in public participation
• Geospatially-enabled workflow processes for automating web-based geospatial services
• Content and knowledge mapping
• Social mapping and networking
• New service and application models such as SaaS
• Data quality and integration, date policies, privacy and ownership
• Quality of web-based geospatial services and processes
• Impact of Web 2.0 on enterprise-wide web GIS/mapping and location services
While many of these topics have been addressed in this book volume, we feel that what needs to be further studied is related to social and organizational issues in the field of webbased GIS and mapping services and applications, as well as an assessment of the impact of Web 2.0 and more recently emerged web 3.0 on enterprise-wide web GIS/mapping and location services. We would like to see more research into, for example, data policies, privacy and
ownership, quality assurance and acceptable use policies, especially for crowd-sourcing and community-generated geographic content technologies and and applications.
In addition to the introductory chapter, the book includes 20 accepted chapters after double-blind peer review processes, which are organized into the following six sections:
SECTION 1: INTRODUCTION
An introductory chapter is included to present an overview of recent advances in web-based GIS, mapping services and applications, and identified some of issues and challenges faced by researchers and professionals in the field.
SECTION 2: ANALYTICAL AND GEOSPATIAL WEB SERVICES
This section includes six chapters focusing on various state-of-the-art geographic information web and processing services, ranging from analytical, simulation and virtual visualization uses to building web services and mashups.
SECTION 3: PERFORMANCE
Three chapters included in this section present some recent studies on techniques and solutions to enhance the performance of web mapping and services.
SECTION 4: AUGMENTATION AND MOBILE MAPPING
Mobile applications are increasingly using better positioning techniques and augmented reality. The three chapters in this section describe recent developments and advances in geolocating using a range of positioning systems, and augmented systems and environments for use in mobile mapping.
For many interactive Webmapping applications the data should be converted from a GIS format. ArcView Shapefiles are a common source format for GIS data exchange. This format can be read and written by many commercial and open source GIS applications. The OGR Simple Features Library can be used to convert from different formats to the ESRI shapefile format. The “ogis2svg.pl” converter builds on the freely available “shp2pgsl” converter developed by the Postgis project. The ogis2svg.pl converter takes the text input from shp2pgsql and converts it to SVG files. (more…)
Ahmad Munir2, M. Nurdin1, dan Paharuddin2
1Pemerintah Kota Bontang
Sekolah Tinggi Teknologi Bontang
Jl. Awang Long No 1. Bontang
2Universitas Hasanuddin Makassar
Jl. P. Kemerdekaan Km 11 Tamalanrea Makassar
Rapid exploitation of natural resources has increased pollution rate that has affects on ecosystems. In Indonesia, the damage of water quality becomes important issue. Due to damage of water quality, the government has to spend a large amount of money in order conserve water quality. Since the regional autonomy is being involved, management of watershed becomes important issue. Because of many watersheds are occupied by more than one regional authority, therefore it is very hard to get an ideal integrated management for optimizing water resources.
The purpose of this paper is to describe the procedure in developing Open Management Interface in order to optimize water management in term of minimizing erosion and sedimentation rate. The system was developed using Java, PHP and HTML and some supporter program such as MySQL, SVG Vew and ArcView were used to develop spatial database. The input data for the model consists of five spatial data: erosivity factor, erodibility, length-slope factor, land cover factor and conservation factor. All the spatial data were being converted into html format.