GIST 4302/5302: Spatial Analysis and Modeling

Similar documents
GIST 4302/5302: Spatial Analysis and Modeling

GIST 4302/5302: Spatial Analysis and Modeling

GIST 4302/5302: Spatial Analysis and Modeling Lecture 1: Overview

Spatial Analysis and Modeling (GIST 4302/5302) Guofeng Cao Department of Geosciences Texas Tech University

SYLLABUS SEFS 540 / ESRM 490 B Optimization Techniques for Natural Resources Spring 2017

GEOG 3340: Introduction to Human Geography Research

ENVIRONMENT AND NATURAL RESOURCES 3700 Introduction to Spatial Information for Environment and Natural Resources. (2 Credit Hours) Semester Syllabus


Introduction to Geographic Information Systems

GEOG 377 Introduction to Geographic Information Systems, Spring, 2002 Page: 1/6

Geog418: Introduction to GIS Fall 2011 Course Syllabus. Textbook: Introduction to Geographic Information Systems edited by Chang (6th ed.

GTECH 380/722 Analytical and Computer Cartography Hunter College, CUNY Department of Geography

Introduction to GIS (GEOG 401) Spring 2014, 3 credit hours

Stellar Astronomy 1401 Spring 2009

Geography 1103: Spatial Thinking

Cornell University CSS/NTRES 6200 Spatial Modelling and Analysis for agronomic, resources and environmental applications. Spring semester 2015

GTECH Advanced GIS Fall 2013 Wednesday, 5:35 9:15 PM

Chemistry 8 Principles of Organic Chemistry Spring Semester, 2013

LEHMAN COLLEGE CITY UNIVERSITY OF NEW YORK DEPARTMENT OF ENVIRONMENTAL, GEOGRAPHIC, AND GEOLOGICAL SCIENCES CURRICULAR CHANGE

Physics 112 for class and recitation WF 10:10 a.m. - 10:40 a.m. or by appointment

Linear Algebra. Instructor: Justin Ryan

Texts 1. Required Worboys, M. and Duckham, M. (2004) GIS: A Computing Perspective. Other readings see course schedule.

Lab Assistant: Kathy Tang Office: SSC 2208 Phone: ext

AS 101: The Solar System (Spring 2017) Course Syllabus

GTECH 380/722 Analytical and Computer Cartography Hunter College, CUNY Department of Geography

GEOG 508 GEOGRAPHIC INFORMATION SYSTEMS I KANSAS STATE UNIVERSITY DEPARTMENT OF GEOGRAPHY FALL SEMESTER, 2002

Physics Fundamentals of Astronomy

Physics Fundamentals of Astronomy

An Introduction to Geographic Information Systems (Fall, 2007)

Historical Geology, GEOL 1120 (final version) Spring 2009

Department of Civil and Environmental Engineering. CE Surveying

CAS GE 365 Introduction to Geographical Information Systems. The Applications of GIS are endless

Page 1 of 5 Printed: 2/4/09

GIS FOR PLANNING. Course Overview. Schedule. Instructor. Prerequisites. Urban Planning 792 Thursday s 5:30-8:10pm SARUP 158

CHEM 4725/8725 Organometallic Chemistry. Spring 2016

GEOL 103: Dynamic Earth

Physics 343: Modern Physics Autumn 2015

AMSC/MATH 673, CLASSICAL METHODS IN PDE, FALL Required text: Evans, Partial Differential Equations second edition

CHEM 660: Systematic Inorganic Chemistry Spring 2017 M/W/F, 12:00-12:50pm, 1003 Malott Hall. Syllabus

SYLLABUS Stratigraphy and Sedimentation GEOL 4402 Fall, 2015 MWF 10:00-10:50AM VIN 158 Labs T or W 2-4:50 PM

PHYSICS 206, Spring 2019

Physics 105 Spring 2017

STATISTICAL AND THERMAL PHYSICS

Comparative Vertebrate Anatomy Biol 241 Fall 2017

Chemistry 2281G: Inorganic Chemistry of the Main Group Elements

Labs: Chelsea Ackroyd Office Location: FMAB 005 Office Hours: M 08:45 11:45 AM or by appointment

GIS and Spatial Analysis


SYLLABUS Sedimentology GEOL 3402 Spring, 2017 MWF 9:00-9:50AM VIN 158 Labs W 2-4:50 PM

GEOL 443 SYLLABUS. Igneous and Metamorphic Petrology, Spring 2013 Tuesday & Thursday 8:00 a.m. 9:15 a.m., PLS Date Subject Reading

Introduction to Oceanography Cabrillo College, Spring Semester, 2018 Instructors: David Schwartz & Lauren Hanneman

GIS and Forest Engineering Applications FE 257 Lecture and laboratory, 3 credits

GEOG 105 THE DIGITAL EARTH Spring 2017

GIST 4302/5302: Spatial Analysis and Modeling

HGP 470 GIS and Advanced Cartography in Social Science

INTRODUCTION TO NUCLEAR AND PARTICLE PHYSICS Physics 4/56301 SPRING 2016 INSTRUCTOR:

GEOLOGY 100 Planet Earth Spring Semester, 2007

AGRY 545/ASM 591R. Remote Sensing of Land Resources. Fall Semester Course Syllabus

CLASSICAL ELECTRODYNAMICS I Physics 6/75203 SPRING 2013

PH 610/710-2A: Advanced Classical Mechanics I. Fall Semester 2007

PHYS 480/580 Introduction to Plasma Physics Fall 2017

Dr. LeGrande M. Slaughter Chemistry Building Rm. 307E Office phone: ; Tues, Thurs 11:00 am-12:20 pm, CHEM 331D

CHEM 333 Spring 2016 Organic Chemistry I California State University Northridge

SYLLABUS. Chem 4235, Spring 2015 Inorganic Chemistry Lab Dr. Jack Lu

HISTORY 1XX/ DH 1XX. Introduction to Geospatial Humanities. Instructor: Zephyr Frank, Associate Professor, History Department Office: Building

Syllabus. Units: 4. Term, Day, Time: Spring, 2018, Monday and Wednesday 2:00 4:15 p.m. Location: AHF 145A

CHEE 3321 (Required) Analytical Methods for Chemical Engineers

Dr. Stephen J. Walsh Department of Geography, UNC-CH Fall, 2007 Monday 3:30-6:00 pm Saunders Hall Room 220. Introduction

Southwestern College CHEM /62 Preparation for General Chemistry Spring Semester 2012

Angelina College Science and Mathematics Chemistry 1305 Introductory Chemistry General Syllabus

Chemistry 565 / 665 BIOPHYSICAL CHEMISTRY. - Spring

Astronomy 102/104: Our Solar System MWF 11:15-12:05P, Uris Auditorium Spring 2008 Course Syllabus

General Chemistry I (CHE 1401)

URP 4273 Section 3058 Survey Of Planning Information Systems (3 Credits) Spring 2017

Physics 141 Course Information

Chemistry A Course Syllabus

Physics 141 Course Information

WEST LOS ANGELES COLLEGE. CHEMISTRY 60 SYLLABUS Spring 2014

Physics 9, Introductory Physics II Spring 2010

Geographic Systems and Analysis

University of Wisconsin-Eau Claire CHEM 103: General Chemistry- Syllabus Spring 2014

Syllabus, General Chemistry I, CHM 1142 Section TCAA, Fall, 2008 McCall Hall, Room 318 MWF 9:00-9:50 AM

Physics Observational Methods in Astronomy

Multivariable Calculus

CHEMISTRY 210 SYLLABUS Spring 2007 General Chemistry II

GEO391 (Statistical Data Analysis for GIS) Winter Quarter 2015 Department of Geography DePaul University

GEOGRAPHY 4132/5132. Spatial Modeling for Social and Economic Applications McEniry 432 T\TH 2:00-3:15

USP/PLSI 493: Methods of Planning Data Analysis (4 credits) San Francisco State University Spring 2011

Geospatial Analysis in Cultural Anthropology

Michelle Liu, Neelay Phadke, Dogan Gidon W 5-6 in Hildebrand 100-D

Instructor Dr. Tomislav Pintauer Mellon Hall Office Hours: 1-2 pm on Thursdays and Fridays, and by appointment.

Angelina College Science and Mathematics Chemistry 1105 Introductory Chemistry Internet General Syllabus

University of Houston-Clear Lake PHYS Modern Physics (Summer 2015) Syllabus 3:00-5:50pm Bayou 3324

INTEGRATING GEOSPATIAL PERSPECTIVES IN THE ANTHROPOLOGY CURRICULUM AT THE UNIVERSITY OF NEW MEXICO (UNM)

Course Syllabus Phy320L - Modern Physics Laboratory Spring 1999

Emerging Issues in Geographic Information Science (GEP680): Projections, Scale, Accuracy, and Interpolation Lehman College, Spring 2017

CHEMISTRY 104 Summer Course Information

Feb. 12, To: The UGC From: Patricia LiWang for Natural Sciences faculty RE: Proposed Physical Biochemistry course.

Michael Harrigan Office hours: Fridays 2:00-4:00pm Holden Hall

Transcription:

GIST 4302/5302: Spatial Analysis and Modeling Spring 2016 Lectures: Tuesdays & Thursdays 12:30pm-1:20pm, Science 234 Labs: GIST 4302: Monday 1:00-2:50pm or Tuesday 2:00-3:50pm GIST 5302: Wednesday 2:00-3:50pm Course Homepage: http://www.gis.ttu.edu/gist4302 Instructor: Guofeng Cao Teaching Assistant: Ashely Morris Office: Holden Hall 211 Office: Holden Hall 209 Office Hours: Th 1:30pm-3:30pm Office Hours: M,W 10:00-11:00am Email: guofeng.cao@ttu.edu Email: ashley.morris@ttu.edu This syllabus is tentative and subject to change 1 Course description With the continuing advances of technological development, spatial data have been easily and increasingly available in the past decades and becoming important information sources in daily decision makings. This class is intended for students (undergraduate and graduate students) from relevant disciplines (e.g., geography, geology, environmental science and social sciences) who are interested in analysis of spatial data. Students will be encouraged to engage this course with their thesis/dissertation topics and research interests. This course will introduce fundamental concepts and commonly used methods in quantitative analysis of spatial data. Specifically, this course includes: Representation of spatial data (fundamentals in spatial databases) Concepts in spatial analysis and spatial statistics Spatial analysis methods for various types of spatial data (spatial points, networks, and areal/lattice data), including overlay/suitability analysis, spatial statistical methods such as exploratory spatial data analysis (e.g., Moran s I), spatial interpolation (e.g. kriging) and spatial regression. A lab/discussion session (approximately 2 hours) follows the lecture for students to gain hands-on experiences on real-world datasets by using multiple software tools. The software packages utilized in lab sessions include ArcGIS, Open GeoDa, R or Matlab. Students (graduate students in particular) with expertise or interest in the statistical package R or Matlab are encouraged to use them but it is not required. 1

2 Prerequisites Prerequisites of this course includes an understanding of basic algebra, general statistics (e.g., knowledge of statistical significance) and matrix manipulations, and working knowledge of at least one GIS software packages, e.g. ArcGIS, which could be fulfilled with GIST 3300/5300. However, students from different disciplines are welcome, please contact the instructor should there any question about the prerequisites. 3 Learning outcomes After completing this course, the undergraduate students of this class are expected to learn how to: formulate real-world problems in the context of geographic information systems and spatial analysis apply appropriate spatial analytical methods to solve the problems utilize mainstream software tools (commercial or open-source) to solve spatial problems communicate results of spatial analysis in the forms of writing and presentation In addition to the above, the graduate students of this class are expected to learn the concept of spatial uncertainty commonly used spatial statistical methods work and connect them to the thesis and dissertation work evaluation and assessment of the results of alternative methods 4 Readings The main course text is: O Sullivan, David and David J. Unwin (2010), Geographic Information Analysis, 2nd Edition, John Wily & Sons. The first edition of this book works in the most cases as well. The following books will be helpful for some topics of this class. Additional readings and handouts ill be suggested as the class progresses. 2

de Smith, Michael J., Paul A. Longley and Michael F. Goodchild (2013), Geospatial Analysis: A Comprehensive Guide to Principles, Techniques and Software Tools, 4th Edition. Available in both print and web (free!) version at http://www.spatialanalysisonline.com Fotheringham, A.S., Brundson, C., and M. Charlton (2003), Geographically Weighted Regression, John Wiley & Sons. For the lab assignments, you have different options of software tools to choose from. If using ArcGIS, you might find the following book helpful: Allen, David W. (2011), GIS Tutorial 2, Spatial Analysis Workbook for ArcGIS 10, Esri Press. Mitchell, A. (2009), The ESRI Guide to GIS Analysis, vol. 2: spatial measurements and statistics, ESRI Press. if using R: Bivand Roger S., Pebesma, Edzer J., and Gmez-Rubio, Virgilio (2008), Applied Spatial Data Analysis with R, Springer. if using Matlab: Martinez, W.L. and Martinez, A.R. (2007), Computational Statistics Handbook with MATLAB, 2nd Edition, Taylor & Francis Chapman & Hall/CRC. 5 Assessment There are two written exams in this course (a midterm and a final), lab exercises, and a final project that includes a project proposal and final report. Graduate students will have extra questions for the lab and the exams, and higher standard for the final project outcomes. The exams are used to assess your understanding of the basic concepts discussed in the lecture, and the format of the exams will consist of a combination of multiple choice, short answer and short essay questions. The purpose of the final project is to provide experiences for students to apply the methods and tools learned from this class to real-world spatial problems. Topics of the final project could be related to the spatial aspect of a thesis or another course work. The proposal associated with the final project should include a clear description of the proposed problems with appropriate background literatures justifying the motivation, description of the collected data sources, and methodology adopted 3

to address the problem. When the project proposal is due (Nov.3rd), students are expected to have collected the necessary data at hand. The final project will require a presentation of about 6-10 mins (PechaKucha style: http://en.wikipedia.org/wiki/pecha_kucha), and a final project report. Students are encouraged to start thinking of project ideas early in the semester, and communicate them with the instructor and the TA for feedbacks and comments. 6 Grading Each exam, lab exercise and final project is worth 100 points, and the final points will be a combination of these three elements according to the following weights: two written exams: 30% (each 15%) six (out of nine) lab exercises: 40% (each 6.6%) final project proposal (5%), presentation (10%) and paper (15%) : 30% To ensure a specific grade in this course you must meet the following minimum requirements: A - 90%, B - 80%, C - 70%, D - 60%. 7 University policy Academic honesty (OP 34.12): http://www.depts.ttu.edu/opmanual/ OP34.12.pdf Students with disabilities (OP 34.22): http://www.depts.ttu.edu/ opmanual/op34.22.pdf Students absence for observance of a religious holy day (OP 34.19): http://www.depts.ttu.edu/opmanual/op34.19.pdf 4

8 Course outline Week# Lecture Dates Lecture Topics Readings Lab/Discussion Topics 1 Jan. 21th Overview of the course No lab 2 Jan. 26 Introduction to spatial data analysis O S&U ch.1 2 Jan. 28rd Spatial data representation and spatial operations O S&U ch.1, 10 Review of map projections and overview of ArcMap 3 Feb. 2 & 4 Spatial data representation and spatial operations O S&U ch.1, 10 Spatial query: Finding what s inside 4 Feb. 9 Probability and statistics review O S&U appendix A-B 4 Feb. 11th Pitfalls and potentials of spatial data O S&U ch.2 Spatial query: Finding what s nearby 5 Feb. 16 & 18 Spatial point pattern analysis O S&U ch.4-5 Build a model builder 6 Feb. 23 & 25 Spatial point pattern analysis O S&U ch.4-5 Point pattern analysis 7 Mar. 1 & 3 Spatial statistics of area objects, exploratory spatial analysis O S&U ch.7 Mapping with GeoDa 8 Mar. 8 Review and student project discussion 8 Mar. 10 Exam I Student project discussion 10 Mar. 15 & 17 Sprint break 9 Mar. 12 & 24 Simple linear regressions and spatial regression F&B&C ch.2,5 Descriptive spatial statistics using GeoDa 11 Mar. 29 & 31 Simple linear regressions and spatial regression F&B&C ch.2,5 Spatial Regression using GeoDa 12 Apr. 5 & 7 Introduction to geostatistics (kriging) O S&U ch.8-9 Spatial interpolation using ArcGIS 13 Apr. 12 & 14 Introduction to geostatistics (kriging) O S&U ch.8-9 Proposal due (data should be ready) & Student project 14 Apr. 19 & 21 Spatial uncertainty O S&U ch.8-9 Student project 15 Apr. 26 & 28 Frontiers of spatial analysis O S&U (1st Edition) ch. 13 Student project 16 May. 3 & May. 5 Project presentation Project presentation 17 May. 10 Review 17 May. 17 Exam II Student project report due

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback