CS 128/ES 228 - Lecture 5a1 Working with Rasters.

Slides:

Advertisements

Similar presentations

CS 128/ES Lecture 9a1 Vector* Data Sources * mostly.

Advertisements

From portions of Chapter 8, 9, 10, &11. Real world is complex. GIS is used model reality. The GIS models then enable us to ask questions of the data by.

CS 128/ES Lecture 5a1 Working with Rasters.

NAPP Photo Five Pockets near Dubois. Google Earth.

With support from: NSF DUE in partnership with: George McLeod Prepared by: Geospatial Technician Education Through Virginia’s Community Colleges.

CS 128/ES Lecture 10a1 Raster Data Sources: Paper maps & Aerial photographs.

Raster Based GIS Analysis

CS 128/ES Lecture 4b1 Spatial Data Formats.

CS 128/ES Lecture 5b1 Vector Based Data. Great Rivalries in History Lincoln vs. Douglas “The first great Presidential Debates” Trekkies vs. Jedis.

CS 128/ES Lecture 4b1 Spatial Data Formats.

ANALYSIS 3 - RASTER What kinds of analysis can we do with GIS? 1.Measurements 2.Layer statistics 3.Queries 4.Buffering (vector); Proximity (raster) 5.Filtering.

CS 128/ES Lecture 5b1 Vector Based Data. CS 128/ES Lecture 5b2 Spatial data models 1.Raster 2.Vector 3.Object-oriented Spatial data formats:

You have just been given an aerial photograph that is not registered to real world coordinates. How do you display the aerial with other data layers that.

CS 128/ES Lecture 5a1 Raster Formats (II). CS 128/ES Lecture 5a2 Spatial modeling in raster format  Basic entity is the cell  Region represented.

GIS 200 Introduction to GIS Buildings. Poly Streams, Line Wells, Point Roads, Line Zoning,Poly MAP SHEETS.

CE Introduction to Surveying and Geographic Information Systems Donald J. Leone, Ph.D., P.E. eLearning Version Lecture 3.

CS 128/ES Lecture 5a1 Raster Formats (II). CS 128/ES Lecture 5a2 Spatial modeling in raster format  Basic entity is the cell  Region represented.

©2005 Austin Troy. All rights reserved Lecture 3: Introduction to GIS Part 1. Understanding Spatial Data Structures by Austin Troy, University of Vermont.

WILD 5750/6750 LAB 5 10/04/2010 IMAGE MOSAICKING.

CS 128/ES Lecture 4b1 Spatial Data Formats.

GIS Tutorial 1 Lecture 6 Digitizing.

Geographic Information System By: Scott Wiegal Mitchell Mathews.

Geography 241 – GIS I Dr. Patrick McHaffie Associate Professor Department of Geography Cook County, % population < 5.

Dr. David Liu Objectives  Understand what a GIS is  Understand how a GIS functions  Spatial data representation  GIS application.

9. GIS Data Collection.

Vector vs. Bitmap SciVis V

V Obtained from a summer workshop in Guildford County July, 2014

Spatial data Visualization spatial data Ruslan Bobov

Welcome to Mapping Tom Sellsted – City of Yakima, Washington Vladimir Strinski – Hitech Systems.

IIS for Image Processing Michael J. Watts

Image Registration January 2001 Gaia3D Inc. Sanghee Gaia3D Seminar Material.

Map Scale, Resolution and Data Models. Components of a GIS Map Maps can be displayed at various scales –Scale - the relationship between the size of features.

Objective Understand concepts used to create digital graphics. Course Weight : 15% Part Three : Concepts of Digital Graphics.

Coordinate Systems Global Coordinate System – Latitude, Longitude and elevation UTM – eastings and northings, reference points are the equator and the.

Vector vs. Bitmap

NAPP Photo Five Pockets near Dubois.

Spatial Data Integration Deana D. Pennington, PhD University of New Mexico.

Faculty of Applied Engineering and Urban Planning Civil Engineering Department Geographic Information Systems Vector and Raster Data Models Lecture 3 Week.

Geographic Information System GIS This project is implemented through the CENTRAL EUROPE Programme co-financed by the ERDF GIS Geographic Inf o rmation.

GIS Data Structure: an Introduction

Data input 1: - Online data sources -Map scanning and digitizing GIS 4103 Spring 06 Adina Racoviteanu.

GIS 1 GIS Lecture 6 Digitizing. GIS 2 Outline Digitizing Overview Digitizing Sources GIS Features Creating and Editing Shapefiles in ArcView Spatial Adjustments.

Chapter 3 Digital Representation of Geographic Data.

How do we represent the world in a GIS database?

8. Specifics on Digitizing & Layout tips 1 Week 6 Specifics on Digitizing and More tips on a Layout.

Raster Concepts.

Raster data models Rasters can be different types of tesselations SquaresTrianglesHexagons Regular tesselations.

GIS Data Structures How do we represent the world in a GIS database?

DIGITAL IMAGE. Basic Image Concepts An image is a spatial representation of an object An image can be thought of as a function with resulting values of.

1 Overview Importing data from generic raster files Creating surfaces from point samples Mapping contours Calculating summary attributes for polygon features.

 DEM from USGS ◦ Digitized version of 1:24,000 topo quadrangle ◦ Vertical accuracy  5m, 30m resolution  KML files, digitized from Google Earth.

CS 101 – Sept. 14 Review Huffman code Image representation –B/W and color schemes –File size issues.

Remcom Inc. 315 S. Allen St., Suite 416  State College, PA  USA Tel:  Fax:   ©

Raster Data Model. How to Represent Point Features in Raster Data Models.

Spatial Data Models Geography is concerned with many aspects of our environment. From a GIS perspective, we can identify two aspects which are of particular.

Digital Image Processing Lecture - 6 Autumn 2009.

Guilford County SciVis V104.03

Data Storage & Editing GEOG370 Instructor: Christine Erlien.

UNIT 3 – MODULE 3: Raster & Vector

Vector vs. Bitmap. Vector Images Vector images (also called outline images) are images made with lines, text, and shapes. Test type is considered to be.

BITMAPPED IMAGES & VECTOR DRAWN GRAPHICS

Data Processing Systems

Geographic Information Systems “GIS”

Vector vs. Bitmap.

Spatial Analysis: Raster

Lecture 2 – Spatial Data Preparation

GIS Lecture: Geodatabases and Aerial Photography

The Raster Data Model Llano River, Mason Co., TX 9/13/2016

Specifics on Digitizing and More tips on a Layout

Spatial Analysis: Raster

Presentation transcript:

CS 128/ES Lecture 5a1 Working with Rasters

CS 128/ES Lecture 5a2 Spatial modeling in raster format  Basic entity is the cell  Region represented by a tiling of cells  Cell size = resolution  Attribute data linked to individual cells

CS 128/ES Lecture 5a3 Issue #1 - resolution Larger cells:  less precise spatial fix  line + boundary thickening  features too close overlap - less detail possible

CS 128/ES Lecture 5a4 Why not always use tiny cells?  Data inputs may have limited spatial resolution - pixel size for aerial, satellite photos - reliability of coordinate measurements  Size of data files  Speed of analysis

CS 128/ES Lecture 5a5 Issue #2 - determining cell values  Data inputs may already contain cell values: aerial, satellite photos  Cell values may be assigned: “pseudocolors”  Ultimately all cell values must be coded numerically

CS 128/ES Lecture 5a6 Image depth minimum = 1 bit B/W image or P/A data 8-bit image = 256 levels of gray (can be pseudo- colored) 24-bit image = true-color. Each primary color has separate layer

CS 128/ES Lecture 5a7 Determining cell values

CS 128/ES Lecture 5a8 Fuzzy set classification

CS 128/ES Lecture 5a9 Filtering raster data  Neighborhood averaging  Smoothes “holes” and transitions  Other techniques available Chang 2002, p. 203

CS 128/ES Lecture 5a10 Issue #3 - layers in raster format Each layer must be referenced in common coordinates Thematic data can be combined and revised (reclassified)

CS 128/ES Lecture 5a11 Analysis by raster overlay

CS 128/ES Lecture 5a12 Lack of spatial registration

CS 128/ES Lecture 5a13 Georeferencing raster images Spatial coordinates may be absent or purely map coordinates (i.e. inches from one corner) Control points: point features visible on both the image and the map Linear or nonlinear transformations “Rubber sheeting”

CS 128/ES Lecture 5a14 Issue #4 – mosaicking rasters

CS 128/ES Lecture 5a15 Raster mosaicking: adjusting color values Histogram matching: Computer compiles histogram of color (or gray) values in 1 tile 2 nd tile’s colors adjusted to match

CS 128/ES Lecture 5a16 Raster mosaicking: matching edges Matching edges: Edge feathering Cutline feathering

CS 128/ES Lecture 5a17 Raster data editing

CS 128/ES Lecture 5a18 Clip to rectangle...

CS 128/ES Lecture 5a19 … vs. clip to shapefile

CS 128/ES Lecture 5a20 Summary A huge amount of spatial data are available in raster format Rasters make excellent “base maps” Easy to layer but watch coordinate systems! Difficult/impossible to edit or reproject USGS Digital Raster Graphic (DRG) Quadrangle (1:24,000 scale - UTM Zone 17, NAD 27)