by Kathryn Keranen and Robert Kolvoord
Esri Press, 2016
216 pages. $79.99, softcover.
ISBN: 978-1-58948-429-0
Review by: Greg March
Making Spatial Decisions Using GIS and Lidar: A Workbook, is the third book in the Making Spatial Decisions series. This tutorial is geared towards users who have basic GIS skills and want to learn how to integrate and analyze Light Detection and Ranging (lidar) data as part of a GIS project to solve problems and create high resolution maps. Below is the four-step workflow described in the book:
The table of contents includes ten modules, each with a unique scenario. Each module includes three projects. The first project provides the user with step-by-step instructions to help solve the main issue posed in the scenario. The second involves a similar challenge, but without step-by-step instructions: the user should rely on what they have learned in the first project to help solve the main problem in the second. The third project includes an “on your own” section with different challenges to choose from.
The first five modules involve the situation of a fictional company asked to complete work for the cities of Baltimore, MD (Project 1) and San Francisco, CA (Project 2). Projects 1 and 2 each come with four recommended deliverables and a set of step-by-step instructions. What’s nice about Project 1 is that it also includes a set of computer screen shots to help the user follow along. Project 2 does not include screenshots, in order to make things a bit more challenging. Project 3 provides a nice list of topics, from which the user can choose their own project based on their interest. These topics include forest characterization / canopy height and density, flood modeling, finding faults, geomorphic mapping, stream slope, archeology field campaigns, mining / calculation of ore volumes, and wind farm optimization.
MODULE 1: BASIC LIDAR TECHNIQUES
In this first scenario, your GIS company is tasked to check the quality of some LAS (lidar) data, conduct an analysis, edit the lidar data, and then produce both 2D and 3D surface and profile maps.
MODULE 2: 2D AND 3D MODELS
Using lidar data in a GIS, your GIS company has been tasked to build raster and terrain models of the cities of Baltimore and San Francisco.
MODULE 3: VOLUMETRIC ANALYSIS AND SHADOW MAPS
The two cities have limited above-ground parking and need to explore possibilities for underground parking. Your GIS company has been tasked to determine how much land would need to be excavated where new buildings are under development. The cities also need a shadow map to guide decisions on where eating areas with benches will be constructed.
MODULE 4: VISIBILITY ANALYSIS AND COMPARISON
Again, the two cities want to provide their residents with continuous cell phone coverage and have employed a new telecommunications company to produce a visibility analysis that includes generating a viewshed using digital surface models (DSMs) with the use of lidar data. Where problematic coverage areas occur, line-of-sight analysis is performed.
MODULE 5: SURGING SEAS
Baltimore and San Francisco want your GIS company to create new flood insurance rate maps (FIRMs) for the Federal Emergency Management Agency (FEMA) to be accessible via ArcGIS Online so that citizens can type in their address and access accurate information for their area. These new FIRMs should be constructed using the following hurricane inundation zones: 5 feet above normal, 8 feet above normal, 12 feet above normal, and 18+ feet above normal.
Modules 1–5 all use the same data so there is only one data folder for them all, plus one results folder for each project.
These modules involve solving a set of campus-based problems centered around an alliance between James Madison University and the University of San Francisco. Both modules use the same data so there is one folder for data and one for results.
MODULE 6: CORRECTED 3D CAMPUS MODELING
Before each campus can determine where to add solar panels on rooftops, university researchers will use features from the lidar data to reclassify (correct) lidar feature classification codes where errors had been found. Researchers will then use ArcScene to visualize the campus (in 3D) as a surface and as set of contours.
MODULE 7: LOCATION OF SOLAR PANELS
Once the new lidar feature classification codes have been set, the researchers at James Madison and San Francisco will create rooftop (heat) maps to determine where solar panels will be placed for maximum operational efficiency.
Modules 8–10 each use different sets of data so there are separate folders for each scenario.
MODULE 8: SHORELINE CHANGE AFTER HURRICANE SANDY
The United States Geological Survey (USGS) has hired your GIS company to analyze changes to the New Jersey and New York shoreline after Hurricane Sandy. With the use of pre- and post-event lidar data, the USGS would like your company to produce pre- and post-event elevation maps to document elevation decline from erosion, shoreline retreat, and the deposit of soil due to wave surge.
MODULE 9: FOREST VEGETATION HEIGHT
This module involves forest vegetation height and how land managers can use lidar data to better manage forest ecosystems. Using lidar to track forest evolution, The Nature Conservancy’s Virginia and Pennsylvania chapters wish to determine canopy height as a substitute for the age of the forest. This is done by subtracting the bare earth surface (DEM) from the first return surface (DSM).
MODULE 10: DEPRESSIONAL WETLAND DELINEATION FROM LIDAR
This last module focuses on identifying the location of depressional wetlands using lidar. The State of Florida wants to establish a wetlands center in order to perform advanced research by comparing traditional delineation methods (on-site fieldwork with a topographic map) with new methods performed off-site using lidar. The State would like a comprehensive comparative analysis of depressional wetlands that documents and compares results of the traditional methods versus the new.
This workbook follows the general format of the others in the Making Spatial Decisions series, but with an improved layout, making it easier to follow than earlier ones.
In the Introduction, on page xii, there is a set of bullets that list skills the user should have (such as a basic knowledge of lidar and how it is used) prior to taking the tutorial. While there is a description of basic lidar terminology, a comprehensive glossary would have been helpful.
Downloading the instructional materials from the Esri Press “Book Resources” webpage was easy. I tested the GIS data in the scenarios using ArcGIS Desktop 10.3.1 with Windows 7 and the screenshots look the same as the ones in the book. Sometimes screenshots can look a bit different (between ArcGIS versions), which could make following the tutorial more difficult.
There are very helpful screenshots in this workbook to aid the user with completing the scenarios, but adding additional screenshots to the first few modules could better prepare the user to successfully complete all of the project scenarios within the workbook. As I followed a few of the scenarios, it wasn’t always easy to get through them. Some steps didn’t have enough information to guide the user, or there was information missing that could leave the user scratching their head. I have an intermediate skill level using ArcGIS, with a basic knowledge of lidar, and I had trouble understanding what was being asked at times and/or what to do next. Some examples:
Some of the instructional steps within the scenarios require the provision of more information if users are to complete each scenario. As with most GIS tutorials, individuals who take this tutorial by themselves or as a group should expect to devote a significant amount of time to working through each scenario.
This book lends itself best to a classroom setting where students can ask questions of their instructor, or fellow students who have been through the workbook scenarios. Individuals who take this tutorial solo, and without having a basic understanding of lidar and how it functions, could have some difficulty getting through it. Taking this tutorial in a classroom setting where students are divided into small groups would be to the individuals’ advantage vs. taking it on their own.
It is noted in the Acknowledgements section that the workbook was created with contributions from students and teachers from the Geospatial Semester held at James Madison University, and that high school students who participated in the Geospatial Semester helped test each module in order to provide feedback.
All-in-all, this is a useful tutorial workbook for individuals who already have a basic knowledge of lidar and possess basic GIS skills. Although some of the instructional steps for following the scenarios would benefit from being a bit more detailed, the authors did well in creating real-world scenarios that represent a variety of disciplines, and the workbook enables users with GIS experience to expand their skill set (utilizing lidar) to solve problems that face the environment. I would recommend this workbook to university faculty (from select academic disciplines) with the suggestion that they integrate the workbook as part of an Introduction to Lidar course or Remote Sensing Technology course.