Lab 4

Introduction

Where is the safest place to live on the west coast? People moving to the west coast may be asking themselves this, because it is a region that is located within the ring of fire on the edge of the Pacific plate. This region is known for its intense tectonic plate movement causing many earthquakes and volcanoes to form. To guarantee safety, I have created a map showing areas of the west coast that are at least 50 kilometers away from any volcano and/or earthquake site. I have also included smaller areas within these safe areas that show places within 20 kilometers of a hospital. I would like this map to help people that are moving to Washington, Oregon or California to find the safest place to live according to the sites of volcanoes and earthquakes. This map may also be used for insurance purposes, and a reference for building/company safety codes and regulations.

Data Sources

To answer my geographic research question I obtained the volcano and earthquake feature class data from the “Mastering ArcGIS” geodatabase (mgis.gdb). I then also obtained the hospital data from the ESRI census geodatabase (Esri2013.DBO.USACensus). I do have some data concerns with my project such as the scale; it may be too small to really showcase the regions I wanted to emphasize. Also is the data frame in an appropriate projected coordinate system? There are always many coordinate systems that may be appropriate but I hope the North American Equidistant Conic portrays the data in a sufficient manner. 

Methods

To get started with this project I first added a States map and a counties map from the mgis geodatabase, selected the states Washington, Oregon and California via select by attributes and created a layer of these selected features and named it States_of_interest I did the same step for the counties layer and named it Counties_of_interest. I then deleted the layer containing the entire United States. I proceeded to add the volcano layer and earthquake layer and clipped those by the states of interest to only focus on the volcanoes and earthquakes within Washington, Oregon and California; these layers were named volcanoes_clipped and earthquakes_clipped. Next I added the hospital layer from the census geodatabase and also clipped this layer by the states of interest.

Now all data points lie within Washington, Oregon and California. The next step was to buffer the earthquakes_clipped layer and the volcanoes_clipped layer. I made the buffer 50 kilometers around the points and created the layers Distance_from_Volcanoes and Distance_from_Earthquakes. I then used the union tool to bring these two buffered layers together and called it Distance_from_Volcanoes_and_Earthquakes. Next I used the erase tool to “punch out” the buffered layers from the Counties_of_interest to clearly see the areas that were considered safe, and named this layer Safe_Distance2.

Once I had my safe distance from both the volcanoes and earthquakes I started applying tools to the hospitals_clipped layer. I first buffered it for 10 kilometers and realized this was not a sufficient buffer. I then buffered it again for 20 kilometers and was much happier with the results. I then took the buffered hospital layer and intersected it with the Safe_Distance2 layer. I wanted to show areas that were within 20 kilometers of a hospital that were also in the area declared safe. This is how I obtained my answer of areas Near_hospitals_and_Safe.

Figure 1: Data flow Model of how I obtained my answer of areas near hospitals and also in the safe area.

Results

As you can see from the map, the safety buffer covers much of the area. The green area shows regions considered safe on the west coast, and the smaller yellow areas depict places that are within 20 kilometers of a hospital and in the safe area. These places are the most ideal places to live on the west coast but green areas will do as well.

Figure 2: Map of West coast depicting safe areas to live. 

Evaluation

I like that our final project was mostly independent. It allowed us to use the skills we have been learning the entire semester and really tested our knowledge. I am grateful that Professor C. Hupy checked and graded our data flow model before we started so we could get started on the right track. If asked to repeat this project there may have been a couple things I would have changed. I would have liked to include crime data, but that was not a part of the preapproved data making it more difficult to include. I also would maybe focus on one of the states Washington, Oregon or California; I think right now the map may look too overwhelming. Also next time I may ask a geographical research question that is biology related, since that is the field I am majoring in and hope to work for the Minnesota DNR one day. There were a few challenges I faced during this project such as saving my data to the Q drive, a very simple but easy to forget task. I had to go back a few times and redo some of my tasks to make sure they were in the correct folder. I also created some buffers that were not to my liking, so I had to play around with that a little. Overall this was a great project to do, I really feel like I have a handle on the GIS tools.

GIS I: Lab 3 Suitable Bear Habitat

GIS I: Lab 3 Suitable Areas for Bear Habitat

o Sources: Include the sources of the data. You could even provide a link to the Michigan Center for Geographic Information.

Goal

The goal of this lab was to become familiar with various spatial vector tools as well as non-spatial tools and apply them to finding suitable bear habitat within a study area in Marquette county in Michigan.

Background

We were given a scenario to find the most suitable areas for bear habitat in this particular study area in Marquette county. These areas suitable enough to be set aside for bears had to be within suitable land cover types (Mixed Forest Land, Forested Wetlands and Evergreen Forest Land), 500 meters of a stream, within DNR management lands, and 5 kilometers away from Urban or Built up lands. We then used various tools such as intersect, buffer, erase etc. to complete the scenario and find our answer of suitable areas for bears that met the criteria. 

Methods

To create this map I used many spatial vector tools such as intersect, buffer, erase and dissolve. Intersect allows the data to be combined and produce an output layer with features that have attribute data from both layers. Buffer can create a layer that is less than or equal to a specified distance from one or more features. This tool came in handy when I had to find suitable land for bears that was within 500 meters of a stream and when finding land that was 5 kilometers away from Urban or Built up lands (after also using the erase tool). The erase tool is a type of extraction, it is similar to a buffer but extracts that data like a cookie cutter. And lastly the dissolve tool removes any interior boundaries based on a shared attribute. Below is an image of the data flow model I used for each objective of this lab, and below that is a picture of the python codes I used for objective 8. 

Figure 1: Data Flow Model used to complete this lab

Figure 2: Python coding to complete objective 8

Results

Below is the map I created of the Suitable areas for bears. It shows, in pink, the areas that are suitable for bears and meet the following criteria, areas near 500 meters of a stream, areas that fall within their top 3 habitats and areas 5 kilometers away from any urban development. In light purple shows areas that meet the criteria except that they are within 5 kilometers of urban development. It is clear that the norther third of this study area has land that can be set aside for bears.

Sources

All Data Downloaded from the State of Michigan Open GIS Data http://gis.michigan.opendata.arcgis.com/

Landcover is from USGS NLCD 

• http://www.mcgi.state.mi.us/mgdl/nlcd/metadata/nlcdshp.html

DNR management units

• http://www.dnr.state.mi.us/spatialdatalibrary/metadata/wildlife_mgmt_units.htm

Streams from

• http://www.mcgi.state.mi.us/mgdl/framework/metadata/Marquette.html 

GIS 1: Lab 2

Goal

The goal of this lab was to retrieve data from the U.S. Census Bureau and create our own unique map using an attribute of our choice from this data.

Methods

We learned valuable skills from this process such as, adding the U.S Census Bureau data to ArcMap, joining attribute tables together, and building a web map. From this experience I also learned how to communicate effectively with my classmates to overcome some of the challenges I encountered.

Results

I found the results to be very interesting. I decided to map Women of the age 21 in Wisconsin because that is the demographic I currently fall under. The counties with a higher percentage of women age 21, are found in the counties Eau Claire, Dunn, Pierce, La Crosse, Grant, and Portage. Most of these counties have college Universities located in them, this would explain the higher percentage of women age 21.

Sources

U.S Census Bureau 2010

Map

Link to Web-Map

http://uwec.maps.arcgis.com/home/webmap/viewer.html?webmap=6fb9dc2ad2d84ad682400eb667cfd401

GIS I Lab 1: Base Data

The Confluence Project

The Confluence Project is an exciting project underway at the confluence of the Eau Claire and Chippewa River. It is will be a multi-purpose building including retail and commercial space on the first floor and apartments on the remaining 5 floors. These apartments will be available for both students and non student tenants. It is a collaborative effort by many that is sure to look beautiful and bring the community together. 

Methods

Civil Divisions Map

The Civil Divisions map displays the confluence project (proposed site) within the Municipality Types. You can clearly see that it is located in the municipal type of city. To create this map I first added an imagery base map to see real world objects in relation to the data I would be adding. Next I added the Civil Divisions feature class to the map and changed the display to 50% transparency to see the basemap through the Civil Divisions layer. The Proposed site was the last feature class to be added and then made a bright red color to be seen easily by viewers. I then added a callout box to show the proposed site in another way.

Census Boundaries Map

The Census Boundaries is a map that shows population density (population/sp. miles). In this map you can see that the Confluence Project is in an area of relatively high population for the area. To create this map I first added the imagery basemap to see objects in relation to the data I would be adding. Next I added the block groups and tracts feature classes and changed the display to 50% transparency to see the basemap through these layers. The last layer to be added was the proposed site which again I made red to be easily seen by those looking at the map.

PLSS Features Map

The PLSS Features Map shows the viewer how the map divides Eau Claire into its indicated township, range and section according to the Public Land Survey System of Wisconsin. This way you can find the exact location of the confluence project. For this map I first added the Imagery basemap, then the PLSS Quarter Quarter feature class. I changed the display of the PLSS Quarter Quarter layer to hollow with a bright outline, so the basemap could show through. Lastly the Proposed site feature class was added which I made red to see it easily. 

EC City Parcel Data 

The Eau Claire City Parcel Data shows Eau Claire's parcel areas and centerlines as a reference. To create this map I first added the Imagery basemap then the parcel area, centerline, and water feature classes. I changed the display of the parcel area to hollow with a bright outline so the lines could be seen easily on the imagery basemap. I also changed the water display to 50% transparency so it was more visually pleasing. Lastly I made the proposed site red.

Zoning Map

The zoning map displays the various zoning classes in Eau Claire. To create this map I first added the imagery basemap. I then added the zoning class feature and went into symbology to group the zoning classes based on similar features. The zoning classes that are shown are commercial, central business districts, industrial, public properties, residential and transportation. I then changed the display to 50% transparency to let the basemap show through. Lastly I added the centerlines and proposed site feature classes and made them bright colors to be seen easily.

Voting Districts Map

The Voting Districts Map shows the various voting districts within Eau Claire. To create this map I first added the imagery basemap. Next I added the voting districts feature class and changed the display to 50% transparency to allow the imagery map to show through. I then labeled the districts by their voting district number. Lastly I added the proposed site and made it red so it could be easily seen. 

Results

Sources

UWEC (2015). Investing in Support of the Confluence Project.

http://www.uwec.edu/Foundation/what/buildings/Confluence.htm

Eau Claire City and County Geodatabases (2013).