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A Web GIS on Volcanoes of the World: Current Status, Monitoring, Historical Activity and Catalog Matt Stuemky Geography 591 - Web GIS Dr. Jennifer Swift University of Southern California Geographic Information Science & Technology Program May 3, 2009 Aerial photo of the Mount Redoubt volcano in Alaska, April 2009. (Photo source: U.S. Geological Survey – Volcano Hazards Program – Alaska Volcano Observatory) Introduction Volcanoes can be a source of both fascination and fear. When contemplating volcanoes from the fascination standpoint, one can’t help but admire the aesthetic beauty that many of them possess, whether seen from an airplane, up close from ground level, or for those who have done so, when climbing the steep flank of an active volcano in order to eventually stand at the edge of a steaming crater. The primary motivation to create an interactive web map application on volcanoes came about because of a general interest in natural hazards and the impacts they have on people and places. Studying volcanic activity in a variety of ways, from reading recent news coverage on the currently erupting Redoubt volcano in Alaska, to having personal experiences climbing several different active volcanoes in New Zealand and Mexico, served as inspiration to develop the Volcanoes of the World interactive web map. In a recent article in The Week Magazine, Keeping a Wary Eye on Volcanoes (2009), the author emphasizes the fear aspect. The article focuses on the eruptive potential of several volcanoes within the United States, and the ongoing monitoring efforts of agencies such as the U.S. Geological Survey. One example mentioned in the article is the Yellowstone volcanic region in Wyoming, indicated by geologists to be a place of particular concern. Many people may not even realize that Yellowstone is much more than a collection of thermal geysers and hot springs, it is in actuality a very large caldera, a seismically active region which has a history of massive volcanic eruptions on average every 600,000 years. It has been over 640,000 years since it last erupted violently. Regarding the likelihood of a devastating, worldwide-affecting eruption of Yellowstone, the author states, “Some geologists are worried that it might be sooner rather than later…it could happen next week—or possibly 50,000 years from now. Whenever it happens, it could potentially be a cataclysm affecting everyone in the entire U.S. and the world.” (Keeping a Wary Eye on Volcanoes, 2009) Significant volcanic eruptions such as Mount Saint Helens in Washington State in 1980, and Mount Pinatubo in the Philippines in 1991 are still relatively fresh in people’s memories. These two events pale in size compared to Yellowstone's past eruptions, yet they nevertheless demonstrated how volcanic eruptions not only have an immediate and destructive impact on people, infrastructure and economies living nearby but they can also have a long term impact worldwide, often for months or years, such as the climate effects caused by volcanic ash. P a g e 1 | Matt Stuemky Project Implementation Goals Each year, natural hazards, whether volcanoes, earthquakes, tsunamis, hurricanes or other type, take a huge toll in deaths, injuries, property damage, and economic loss. Dunbar (2007) states, “Much of this devastation can be reduced through existing mitigation techniques and greater public awareness of them. If people are aware of the risks from natural hazards faced by their communities, they are more likely to take steps to reduce potential losses.” The intent of this project was not to create an overly technical web GIS designed as an analysis tool for mapping volcano geomorphology, volcanic ash cloud dispersion modeling or a myriad of other technical facets of volcanoes. Such web maps can be found online, developed for academic and scientific research projects conducted by geologists and other specialists. These web maps typically focus on a specific volcano or volcanic region. The Volcanoes of the World web GIS is instead designed to be an educational tool and information resource for the general public. Dunbar (2007) writes about the importance of making available to the general public a variety of easyto-use, Internet-based resources for studying natural hazards, using (among other techniques) interactive maps as a tool to provide an integrated web-based GIS. She further states these web GIS should utilize databases containing earthquake, tsunami, and volcano information, as well as additional auxiliary geospatial data. The project implementation goals outlined below for the Volcanoes of the World project came about in part from some of Dunbar’s ideas of developing creative ways to use available online resources on natural hazards in order to both stimulate interest and to educate people. Extensive research has made it evident that very few volcano-themed web map applications exist. The ones that happen to feature volcanoes in some way do not seem to take full advantage of data sources that are available online. Some feature current activity reports issued by the U.S. Geological Survey and the Smithsonian Institution. Other interactive web maps depict volcano locations around the world but do not provide any current activity information. Fortunately, a variety of volcano-related datasets are freely available to the general public, from a variety of organizations and in a variety of formats. The data sources identified and implemented for this project, listed in Appendix A, represent only a portion of what is available online. Amateur web map mash-ups on natural hazards typically focus on earthquake activity. Only a few of these also include current volcano activity, typically shown as location markers on a map, but offer little else in the way of detailed information. Several professionally developed natural hazard themed web map applications do exist but, as with the amateur mash-ups, volcano information is not strongly emphasized beyond location identification. Two web GIS run by U.S. government agencies are the USGS Natural Hazards P a g e 2 | Matt Stuemky Support System (http://nhss.cr.usgs.gov) and the NGDC’s Natural Hazards system (http://map.ngdc.noaa.gov/website/seg/hazards/). Unfortunately, both web maps provide little or no current activity information on volcanoes. Alerts and current status information on earthquakes, wildfires, hurricanes, and severe weather seem to be more prominently featured on these web maps. Whether amateur or professional, no web GIS seems to exist that includes a volcano monitoring feature. Basic volcano monitoring can be incorporated into a web GIS by making use of some near real-time, remotely sensed satellite imagery as described by Davies (2007) and Krueger (2006). Also, live webcams pointed at volcanoes was determined to be another useful monitoring feature. Databases containing historical activity of volcanoes are currently available from the National Geophysical Data Center (NGDC) as discussed by Dunbar (2007) and Peduzzi (2005). According to Guffanti (2007), the U.S. Geological Survey is also working towards making historical databases available to the general public. Research turned up no web GIS that directly incorporates volcanic eruption history data from the NGDC, other than the natural hazards web GIS application on the NGDC website itself. Since other web GIS applications appear to only utilize one or two data sources on volcanoes, the main goal of the Volcanoes of the World project was to try to consolidate a variety of volcano-related data and display spatially-referenced features on a single, unified web map, using a simple, easy-to-use interface. The following five implementation goals were established for the project: 1) Current Status: provide the ability to show on the web map the locations and status reports of new and ongoing volcanic activity around the world based on information provided by the U.S. Geological Survey, Volcanic Ash Advisory Centers, and the Smithsonian Institution 2) Monitoring: integrate several near real-time, remotely sensed datasets designed to provide indicators of both new and ongoing volcanic activity around the world using data sources from several different organizations; integrate live webcams pointed at volcanoes as an additional monitoring feature 3) Historical Activity: provide the ability to identify locations and view summary reports of significant volcanic eruptions around the world using volcanic eruption history datasets from the NGDC 4) Volcano Catalog: provide the ability to easily search a catalog of volcanoes by name, geographic location, and/or type (cinder cone, shield volcano, stratovolcano, etc.) using a small relational database; display search results directly on the web map; provide summary information and a photo (if available) of the volcano and a direct link to more detailed information on the Smithsonian Institution Global Volcanism Program website 5) Other Layers: incorporate additional spatially-enabled datasets as optional overlays to the web map including earthquake activity, volcano activity news, and special thematic base maps P a g e 3 | Matt Stuemky Technology In addition to the implementation goals outlined in the previous section, the choice of web GIS technology used is the other major goal of the project: to what extent possible, utilize open source solutions rather than proprietary ones. The Volcanoes of the World web map application was designed in part as an attempt to significantly improve upon the user interfaces offered by other natural hazard themed web GIS, including the ones from the USGS and NGDC. Both systems use ArcIMS web mapping software from ESRI. Although intended to be comprehensive web applications, both are slow at displaying map features and are hindered with a somewhat dated user interface. Utilizing dynamic client-side web technologies such as Ajax combined with the popular Google Maps interface was deemed to be a desirable goal to make the Volcanoes of the World web map easy to use, responsive, and appealing to look at. The following list summarizes the key technology used for the project: Open source web mapping software: Google Maps API version 2.x with Ajax extensions Web programming languages: HTML, client-based JavaScript, server-based PHP with Curl extensions Vector point and line map features: multiple approaches used to process XML, KML, ASCII text, and GeoRSS datasets; a third-party Google Maps API extension called GeoXML (http://code.google.com/p/geoxml/) is used to process some of the data sources; all other point and line data are handled using native Google Maps API functions combined with JavaScript and PHP code Raster map features: Google Maps API GTileLayer and GMapType objects and JavaScript code used to retrieve and process raster datasets from WMS resources; raster datasets used for near real-time monitoring (i.e. satellite remote-sensed imagery as atmospheric indicators of volcanic activity) and for several additional thematic map types (i.e. world population density) Open source database: MySQL; an existing MySQL database called GIS located on the production web server was used for the implementation of the Volcano Catalog Web server hardware: Microsoft IIS for both development and production servers Applications and tools for project development: o o o o o o o Web browsers: Mozilla Firefox and Microsoft Internet Explorer Web programming (HTML, JavaScript, PHP): Adobe Dreamweaver CS4 Web page debugging: Firefox – built-in Error Console tool and Firebug third-party extension; Internet Explorer – built-in script debugger tool Database administration: Navicat for MySQL, MySQL Administrator, MySQL Query Browser Web server management: Internet Information Services (IIS) Manager on development server, Webhost4Life Control Panel web-based site management tools on production server Microsoft Excel: modify data used for the Volcano Catalog, import data into the MySQL database Microsoft Paint and Paint.NET: create and modify map icons and other images used for the web map application P a g e 4 | Matt Stuemky Implementation: Current Status The first and most important feature of the Volcanoes of the World project is one that prominently displays the locations of all actively monitored volcanoes that have new or ongoing activity, ones that have been issued alerts and have current status reports associated with them (Guffanti, 2007). Similar to the U.S. Geological Survey, government agencies in other countries are often tasked with monitoring historically active volcanoes and to issue public alerts and status reports as needed. However, it was beyond the scope of this project to try and incorporate all these data sources into the web map application. Instead, the goal was to utilize several of the most readily available data sources from the following three organizations: for volcanoes within the United States and its territories, the U.S. Geological Survey Volcano Hazards Program (USGS VHP); for all other volcanoes located around the world, the Volcanic Ash Advisory Centers (VAACs) and the Smithsonian Institution Global Volcanism Program (GVP). All volcano status summary and report information for a volcano is displayed directly on the map canvas simply by clicking a marker icon. Figure 1 below shows the first full implementation, Current Status, for the Volcanoes of the World web map. It depicts three different marker icons on the map, placed over the location of the Mount Redoubt volcano in Alaska. The USGS VHP and VAACs issue alerts and current status reports on a daily basis compared to the once-a-week updates from the Smithsonian Institution GVP. When the map is zoomed out to a small scale view, marker icons from the more frequently updated datasets will always be superimposed over the less frequently updated ones, but only in situations where multiple organizations have current status information for a particular volcano. Zooming in to a large scale view of a volcano, as shown in Figure 1, will make all marker icons accessible so the user can easily select each one individually. Figure 1 – first implementation example of the Volcanoes of the World web map: Current Status information from the USGS Volcano Hazards Program, Volcanic Ash Advisory Centers and Smithsonian Institution Global Volcanism Program; marker icons are placed on the web map in the vicinity of the Redoubt volcano P a g e 5 | Matt Stuemky U.S. Geological Survey – Volcano Hazards Program The U.S. Geological Survey (USGS) operates five independent Volcano Observatories: Alaska (AVO), Hawaii (AVO), Cascade Range (CVO), Yellowstone (YVO), and Mariana Islands (CNMI). Collectively, these observatories make up the USGS Volcanic Hazards Program (VHP). The VHP recently adopted a common National Volcano Early Warning System used for characterizing the level of unrest and eruptive activity of the approximately 170 volcanoes that the USGS VHP monitors within the United States and its territories. To provide a way of indicating whether or not a volcano has been elevated in status, based on either new or ongoing levels of unrest, this system implemented by the USGS VHP uses volcano alert level designations of Warning / Watch / Advisory / Normal / Unassigned combined with aviation (volcanic ash) color-code designations of Red / Orange / Yellow / Green. (Guffanti, 2007) As shown in Figure 2 below, the Current Status menu as implemented on the Volcanoes of the World web map identifies the specific icons used by the USGS VHP to indicate the current status of all volcanoes monitored within the United States and its territories. Figure 2 – Current Status menu P a g e 6 | Matt Stuemky The USGS VHP website uses a simple Google Maps interface to depict all monitored volcanoes. The maps emphasize volcanoes with an elevated alert status. Examples of these are the Cleveland and Redoubt volcanoes in Alaska and the Kilauea volcano in Hawaii. Additionally, several volcanoes currently at a Normal or Unassigned status are emphasized more prominently (by using larger-sized icons) on the USGS VHP web maps compared to all other volcanoes with the same Normal/Unassigned designation. This is because they are currently being more actively monitored than the others. In some cases it is because they have been raised to higher alert levels at various times in recent years because of eruption activity. Examples of these are Yellowstone in Wyoming and the Anatahan volcano in the Northern Mariana Islands region of the western Pacific Ocean. (USGS VHP, 2009; Guffanti, 2007) The USGS VHP web maps use two different XML files containing vector point data used to identify the locations of all these monitored volcanoes. The Volcanoes of the World web map utilizes these same two XML files as data sources. Using the Google Maps API, these two files are downloaded directly from the USGS Volcano Hazards Program web server the first time the Volcanoes of the World web map loads. JavaScript code is used to automatically parse the data and display onto the map a series of marker icons that correspond exactly to the volcano alert level/aviation color code icons used by the USGS VHP. As shown in Figure 3 below, clicking these icons will display a pop-up information window showing summary and status information as well as a direct link to a volcano’s current status page on the USGS VHP website. All data shown in the pop-up information window is derived from the contents of the two XML files. Figure 3 – U.S. Geological Survey Volcano Hazards Program, Current Status on Redoubt volcano P a g e 7 | Matt Stuemky Volcanic Ash Advisory Centers Volcanic ash is a significant hazard to aviation. To ensure safe navigation for aircraft and monitor climatic impact, nine regional Volcanic Ash Advisory Centers (VAACs) have been established around the world. Two VAACs exist within the United States, in Washington DC and in Anchorage Alaska. Both VAACs are part of the National Oceanic and Atmospheric Administration (NOAA). All nine VAACS worldwide are tasked with tracking volcanic eruptions, in particular, monitoring all available satellite imagery for volcanic ash clouds. The VAACs issue several products whenever volcanic eruptions are detected. One of these is the Volcanic Ash Advisory Statement (VAAS), which includes text describing current volcanic activity and ash cloud position (Dunbar, 2007). As shown in the Current Status menu in Figure 2 above, the different colors of the marker icons used on the map are based on the alert level associated with the VAAS, either Red (Warning), Orange (Watch), Yellow (Advisory) or Grey (not assigned). The Darwin Volcanic Ash Advisory Centre, part of the Australian Bureau of Meteorology, consolidates and disseminates all active Volcanic Ash Advisory Statements (VAAS) issued from the nine different VAACs. The VAAS are issued via XML-based text products, including CAP alert feeds, Atom RSS feeds, and a KML file which are all continuously updated (refer to Appendix A: Data Sources). The KML file was selected for implementation into the Volcanoes of the World web map. The file is automatically downloaded the first time the web page loads and, using Google Maps API functions and JavaScript code, the data is parsed and displayed on the web map using unique, color-coded marker icons. As shown in Figure 4 below, clicking any of these markers will display a pop-up window containing the report summary as well as a direct link to the associated CAP alert page where additional information can be viewed. Figure 4 – Volcanic Ash Advisory Centers, Volcanic Ash Advisory Statement on Redoubt volcano P a g e 8 | Matt Stuemky Smithsonian Institution – Global Volcanism Program The U.S. Geological Survey collaborates with the Smithsonian Institution Global Volcanism Program to produce Weekly Volcanic Activity Reports, which are published on the GVP website itself as well as disseminated using an RSS data feed. The GVP weekly reports offer short summaries on both new and ongoing volcanic activity worldwide. More extensive monthly reports that incorporate images, graphics and monitoring data are also published on the GVP website (Guffanti, 2007) but are not available as an RSS feed or other type of dataset. The RSS dataset containing the Weekly Volcanic Activity Reports was selected for implementation into the Volcanoes of the World web map. Similar to the USGS VHP and VAAC data handling operations, the GVP data is loaded and processed the first time the web page loads and, using Google Maps API functions and JavaScript code, the data is parsed and displayed on the web map. As shown in Figure 5 below, a unique marker icon is used to represent each volcano that has a weekly status report issued by the Smithsonian Institution Global Volcanism Program. Figure 5 – Smithsonian Institution Global Volcanism Program, Weekly Status Report on Redoubt volcano P a g e 9 | Matt Stuemky Implementation: Monitoring The second major implementation of the Volcanoes of the World project was to include the ability to perform some basic monitoring of volcanic activity. A variety of datasets are available on the Internet that originate from numerous ground-based seismic, thermal and gas emission sensors installed on or near active volcanoes such as the Kilauea volcano in Hawaii (Davies, et al., 2008). However, a more practical, broad-based approach was sought, considering the scope and time constraints of this project. The solution was to utilize public datasets derived from satellite imagery, ones that can ideally be used to provide indicators of volcanic activity suitable for monitoring any volcano located around the world. In addition, the decision was made to incorporate a dataset of live webcams, specifically ones that are pointed at volcanoes, as an additional monitoring component for the web map application. Regarding the use of remotely-sensed data, Krueger (2006) describes in detail the so-called A-Train, a system of NASA satellites and the various different types of measuring instruments installed on board them. These instruments are used by scientists and researchers for a variety of studies including near real-time monitoring of volcanoes worldwide. Many of the details from Krueger’s presentation served as the basis for seeking out and obtaining datasets that contained this remotely-sensed imagery for the Volcanoes of the World web map. To implement the goal for a basic volcano monitoring, two types of near real-time, satellite remotesensed datasets were sought: those that provide atmospheric indicators and those that provide ground level thermal (hot spot) indicators. Volcano webcams are the third type of monitoring that was implemented. Figure 6 below shows the Monitoring menu as implemented for the Volcanoes of the World web map. Figure 6 – Monitoring menu P a g e 10 | Matt Stuemky 1. Atmospheric indicators As described by Krueger (2006), NASA maintains a powerful and diverse array of atmospheric monitoring instruments on board several different satellites. Research for this project made it evident that a large amount of publically-accessible satellite imagery was available. It was also clear that it was beyond the scope of this project to attempt to utilize all the available datasets. Organizations in both the public and private sector provide many different remotely-sensed datasets that could potentially be useful for volcano monitoring. However, further research revealed that several online resources such as those provided by NASA's Jet Propulsion Laboratory (JPL) and Goddard Earth Sciences Data and Information Services Center (GES DISC) provided more convenient access to the satellite imagery compared to others. For the atmospheric indicators monitoring component of the Volcanoes of the World web map, remote sensed imagery derived from several NASA satellite instrument systems were initially identified for implementation. These included the MODIS, AIRS and OMI instruments, as described below. All of these, except for the OMI-based datasets, were eventually implemented into the web map successfully. MODerate Resolution Imaging Spectroradiometer (MODIS) instrument: visual imagery Near real-time satellite imagery of the earth surface in the normal visual spectrum generally allows for observation of volcanic activity. The MODIS “Daily Planet” dataset, showing current cloud coverage worldwide, was selected as the primary atmospheric indicator monitoring layer for the web map. As with the Blue Marble “Next Generation” thematic map type described later, this tiled raster dataset is retrieved from the NASA Jet Propulsion Laboratory’s OnEarth WMS server. Earth is imaged continuously by the MODIS Terra satellite, with all imagery between 6 to 24 hours old. (NASA JPL OnEarth, 2009) Large volcanic eruptions can be relatively easy to identify using the MODIS “Daily Planet” dataset. However, normal, meteorological clouds may still obscure volcanic emissions (water vapor, steam, volcanic ash, etc.), especially with smaller, more short-term eruptions. If the volcano exhibits any sort of emissions that show up on the visual satellite imagery, the color of the clouds emanating from the volcano can provide some basic indicators of the type of emissions. For example, white-colored clouds generally indicate water vapor and steam combined with SO2 gases as shown in Figure 7 below. Brown-colored clouds are more indicative of volcanic ash (VA) as shown in Figure 8 below. P a g e 11 | Matt Stuemky Figure 7 – MODIS Terra “Daily Planet” image showing water vapor and steam cloud emissions from the Fernandina volcano located on the Galápagos Islands off the coast of Ecuador Figure 8 – MODIS Terra “Daily Planet” image showing volcanic ash (VA) cloud emissions from the Llaima volcano located in southern Chile Atmospheric InfraRed Sounder (AIRS) instrument: false color/infrared imagery and SO2 As part of the NASA Earth Observing System (EOS) project, the Aqua satellite was launched into Earth orbit in May 2002. On board the satellite is the Atmospheric Infrared Sounder (AIRS) instrument, one of six available monitoring instruments. AIRS data has been made available to the general public in various formats for several years. NASA GES DISC operates a WMS server housing near real-time datasets from AIRS. (NASA GES DISC, 2009) The following two datasets were selected for implementation in the Volcanoes of the World web map: P a g e 12 | Matt Stuemky AIRS Near Real Time False Color (RGB) dataset Using the visible channels of the AIRS instrument (ch3=red,ch2=green, ch1=blue) a false color image is produced of land, but provides the ability to distinguish different cloud types over land and water (NASA GES DISC, 2009) , including the unique signature of brown-colored ash-laden clouds emanating from a volcano. AIRS Near Real Time BT_diff_SO2 dataset Specific brightness temperature differences between BT(1361.44 cm-1) - BT(1433.06 cm-1) can be shown, which can indicate SO2 gas emissions from volcanoes (NASA GES DISC, 2009). As implemented on the web map, a legend graphic showing the BT_diff_S02 scale is automatically overlayed onto the top left-hand corner of the map when this layer is turned on. Figure 9 and Figure 10 below show examples of these datasets implemented on the web map. They depict an early April 2009 eruption episode of the Redoubt volcano located in Alaska. Figure 9 – AIRS False Color (infrared) image of volcanic ash (VA) cloud emissions drifting south from the Redoubt volcano P a g e 13 | Matt Stuemky Figure 10 – AIRS BT_diff SO2 image showing SO2 gas emissions drifting to the southeast of the Redoubt volcano Ozone Monitoring Instrument (OMI): SO2, NO2, BrO, aerosols, ozone As part of the NASA EOS program, the Aura satellite was launched into Earth orbit in July 2004. On board is the Ozone Monitoring Instrument (OMI) which is capable of measuring numerous air quality components including sodium dioxide (SO2), nitrogen dioxide (NO2), bromine monoxide (BrO) and aerosol sources (smoke, dust, and sulfates). OMI can also measure ozone concentrations, in part by measuring cloud coverage and air pressure at different levels of the troposphere. OMI is particular well-suited for monitoring volcanic gas emissions, with its ability to measure the SO2 levels (in metric tons) in the lowest 5 kilometers (approximately 3 miles) of the atmosphere. (NASA GES DISC, 2009) Krueger (2006) indicates that NASA and NOAA scientists as well as numerous other researchers worldwide are making use of OMI data for volcano related monitoring and research. It was determined that although technically available to the public, most near real-time OMI datasets are not currently available in a spatially-referenced format and delivery mechanism (i.e. WMS) for convenient incorporation into a web GIS. P a g e 14 | Matt Stuemky Although OMI data was not implemented at this time, it is worth noting that NOAA’s National Environmental Satellite, Data, and Information Service (NESDIS) operates an experimental web-based service using near-real time OMI SO2 imagery (http://satepsanone.nesdis.noaa.gov/pub/OMI/OMISO2/index.html). The plan is to eventually incorporate near real-time OMI data into the Volcanoes of the World web map, as additional layers for volcano monitoring, once they are more readily available from a WMS resource. MODIS instrument: Aerosols Tiny solid and liquid particles suspended in the atmosphere are called aerosols. Volcanic ash (VA) is one significant example of atmospheric aerosol. The MODIS instruments on board the Terra satellite (launched in 1999) and Aqua satellite (launched in 2002) are capable of measuring volcanic aerosols as well as numerous other sources of atmospheric aerosols. Some of this remotely-sensed aerosol data is compiled into an atmospheric indicator called the aerosol optical thickness (AOT) index. (NASA GES DISC, 2009) NASA operates a WMS server that makes AOT raster imagery available. Since the more comprehensive OMI datasets were not available for easy implementation, and given the time constraints of this project, the MODIS AOT data was instead selected for implementation as an atmospheric indicator layer for the web map. Figure 11 below shows an example of this implementation of MODIS AOT imagery on the web map. Figure 11 – MODIS AOT image showing volcanic ash (VA) / aerosol gas emissions from the Fuego volcano located in Guatemala P a g e 15 | Matt Stuemky 2. Ground level thermal (hot spot) indicators Infrared imaging capabilities provided by the MODIS instruments on board the Terra and Aqua satellites provide the ability to reveal thermal (hot spot) activity on the ground. One major application of this is by the United States Forest Service and other natural resource agencies around the globe who use MODIS infrared data for wildfire detection and monitoring. The infrared technology also lends itself to identifying other thermal events on the surface of the earth, including volcanic eruptions. MODVOLC Scientists at the University of Hawaii’s Institute of Geophysics and Planetology (HIGP) have developed an automated system which maps the global distribution of thermal hot spots in near real-time. Using unique filter methods and algorithms, the system is designed to detect the signature of volcanic eruptions, although large wildfires too are regularly detected by the system (HIGP, 2009). The primary objective of the MODIS Thermal Alert System, or MODVOLC, is to allow scientists to detect volcanic activity anywhere in the world within hours of its occurrence (Schmidt, 2004). Precise latitude and longitude values for each hot spot are obtained, processed, and stored into the MODVOLC system. The posting of the locations of volcanic thermal activity by MODVOLC is generally less than 24 hours after data acquisition (Davies, et al., 2008). This near realtime data is incorporated into a web map on the HIGP MODVOLC website. HIGP provides a publically-accessible, fixed-length, space-delimited ASCII text file that is updated continuously as the MODIS data is ingested into and processed by the MODVOLC system. This text file is implemented into the Volcanoes of the World web map. As soon as the user selects the MODVOLC layer option from the Monitoring menu, the most current version of the file is downloaded directly from the HIGP web server using the Google Maps API. It is then processed using JavaScript and displayed as small red marker points on the web map as shown in Figure 12 below. Figure 12 – MODVOLC hot spots on the Fernandina volcano located in the Galápagos Islands P a g e 16 | Matt Stuemky 3. Volcano webcams A dataset containing information on live webcam images of volcanoes was created as the final volcano monitoring layer for the web map. As soon as the user selects the Volcano webcams layer from the Monitoring menu, a local XML file is loaded and parsed, placing webcam marker icons on the map in their respective locations. Once the layer is loaded, any webcam image can be displayed simply by clicking the webcam marker icon on the map. The layer is particularly useful for monitoring volcanoes that are currently erupting, especially those volcanoes that have more than one webcam pointed at it. For example, the Redoubt volcano currently has two different webcams pointed at it, both maintained by the Alaska Volcano Observatory. The webcams dataset was manually created for this project. It is a small XML file containing multiple records, one for each webcam. Attributes include volcano name, location description of the volcano (country and/or region), location description of the webcam, and point coordinates (latitude and longitude) of the webcam. The file is stored in a folder called data, located on the same server where the web map application resides. Due to time constraints, only a small collection of operating volcano webcams were identified and added to the XML file. Over time, more will be added. Figure 13 below shows an example of an image from one of the geo-referenced volcano webcams displayed on the Volcanoes of the World web map. Figure 13 – Image from a volcano webcam located inside the crater of White Island, New Zealand P a g e 17 | Matt Stuemky Implementation: Historical Activity Current Status and Monitoring are designed to be the most commonly used features on the Volcanoes of the World web map because they are focused on keeping track of both new and ongoing volcanic activity. However, incorporating some type of historical volcanic activity information is essential, especially for a web GIS that depicts natural hazards. Dunbar (2007) mentions the importance of having easy access to natural hazard information stored in long-term databases. These can be used to establish the past record of natural hazard event occurrences. Such databases can be used to educate the public about natural disaster hot spots around the globe and to help better understand overall trends with natural hazards. National Geophysical Data Center (NGDC) – Significant Volcanic Eruptions database The National Geophysical Data Center, a part of NOAA, regularly acquires, processes, and analyzes data on earthquakes, tsunamis, and volcanoes worldwide. They have established separate databases for each type of natural hazard (NGDC, 2009). Dunbar (2007) discusses the role of new web technologies, ones which allow interactive search and retrieval capabilities in order to simplify access to natural hazard databases such as the ones maintained by the NGDC. The NGDC assimilates historical volcano data from the Smithsonian Institution Global Volcanism Program and other organizations for their Significant Volcanic Eruptions database. The database contains records covering a period from approximately 4350 BC to present day. The database is updated annually and currently contains information on nearly 500 significant eruptions. All records are of volcanic eruptions that resulted in deaths, property damage, and/or generated a tsunami (Dunbar, 2007). The NGDC uses this and other natural hazards databases for their own web GIS application. However, the NGDC also furnishes a KML file for general public use, one that contains the exact same information contained in their Significant Volcanic Eruptions database. For implementation into the Volcanoes of the World web map, a copy of the NGDC’s Significant Volcano Eruptions KML file was obtained. In contrast with the “live data” downloaded from web servers operated by the USGS Volcano Hazards Program, Volcanic Ash Advisory Centers and Smithsonian Global Volcanism Program, the KML file from the NGDC is stored in a local folder called data, located on the same server where the web map application resides. It should be noted that some minor modifications were made to the KML file, to allow all hyperlinks for additional information to automatically open in a separate window when clicked by the user rather than navigating away from the Volcanoes of the World web page. Aside from that, the data is exactly the same as what is contained in the volcanoes database maintained by the NGDC. P a g e 18 | Matt Stuemky Figure 14 below shows how the volcanic eruptions data from the NGDC was implemented into the Historical Activity menu of the Volcanoes of the World web map application. Selectable layers under the Historical Activity menu allow the user to display one or more sets of volcanic eruption history. Five different layers are available, each based on a specific date range. For each record inside the KML file, a reference to a color triangle-shaped marker icon is used. These color-coded icons match exactly the symbols used by the NGDC in their volcanoes database. The color indicates the overall severity of a volcanic eruption. Figure 14 – Historical Activity menu Figure 15 below shows an implementation example of historical eruption activity on the web map. This example supports in part Dunbar’s (2007) idea of helping to educate the public about understanding the location of natural disaster hotspots, in this case, volcano hazards. Specifically, depicting both current and historical volcano activity features together on the web map can be rather eye-opening. Volcanic hot spots become immediately apparent and can give the user some indication where the highest risk areas are located. Figure 15 – Indonesia region showing several significant volcanic eruptions of varying severity since 1950 AD P a g e 19 | Matt Stuemky Implementation: Volcano Catalog The fourth major implementation of the Volcanoes of the World web map application was to develop the Volcano Catalog. The primary objective for developing this feature was to provide a volcano search function that was easy to use and to have the search results be integrated directly into the web map interface. The catalog is essentially a relational database table containing over 1500 records of volcanoes located around the globe. While approximately 1500 potentially active volcanoes exist worldwide, on average about 500 of these are active at any given time (Schmidt, 2004). The volcano catalog provides a way to quickly locate on the map and to read a brief summary on any of these volcanoes, whether they are currently active or not. Using standard database query procedures, the catalog can be used to search for volcanoes by name, geographic location, and/or type (cinder cone, shield volcano, stratovolcano, etc.). Search results will be processed and automatically pinpoint volcano locations directly on the web map using a unique marker icon. Smithsonian Institution Global Volcanism Program The Smithsonian Institution Global Volcanism Program maintains a database of over 1500 Holocene era volcanoes. These are volcanoes that have been active at some time in the past 12,000 years. Each volcano is given a unique volcano identification number (or VNUM), an identifier which is recognized internationally for each documented Holocene era volcano located around the world. (Smithsonian GVP, 2009) On the Smithsonian GVP website, a section titled “Volcanoes of the World” provides an interface to view information on all known and inferred Holocene volcanoes. Information available for each volcano includes location, elevation, eruption chronologies and geological characteristics. Images of most of the volcanoes are also available. (Guffanti, 2007) A subset of summary information is what forms the basis for the Volcano Catalog that was developed and implemented for the Volcanoes of the World web map. The Smithsonian Institution GVP makes available to the general public all their Holocene era volcano data. This data is used on the GVP website but is also made freely available with downloadable files, including a KML file for use in the Google Earth application and an Excel spreadsheet file. The Excel spreadsheet contains summary information on each of the over 1500 volcanoes in the GVP master database. One of the chief shortcomings of the GVP volcano information isn’t the content but, rather, how it’s accessed and displayed. For example, to locate a volcano or volcanoes on the GVP website, the user must use a standard search page to query by name or location. It works well but the search function and search results are not integrated directly with the web maps used on the GVP website. P a g e 20 | Matt Stuemky MySQL database, PHP scripts, XML parsing A MySQL database called gis_75487 had previously been created and configured on the production web server used for this project. A new table was created in this database, to be used for the Volcanoes of the World web map. To administer a MySQL database, a free set of downloadable client software tools are available on the MySQL product website. However, a variety of alternative database management software products are also available. One of the more popular ones is Navicat for MySQL which was used for all database management tasks for this project. Using the Navicat software, a new table called volcano_catalog was created in the gis_75487 database. Fields were then manually added to the table corresponding to the column headers in the Excel file obtained from the Smithsonian Institution GVP website. Once the table definition was created, Navicat's built-in import wizard tool was used to populate the volcano_catalog table, using the specific option to load data from an Excel file. Figure 16 below shows the end result of the import process, with 1535 records loaded. Figure 16 – MySQL database table named volcano_catalog populated with data imported from an Excel file obtained from the Smithsonian Institution GVP website Various implementation approaches are available to get data from a relational database to integrate with a Google Maps based web map application. However, the steps outlined in a technical document on MySQL and Google Maps written by Fox (2007) were used, with some minor variations, for the Volcanoes of the World web map. Using Fox's technique, the basic steps included using server-side PHP code to connect to the MySQL database and perform a query and output the results into to an in-memory XML formatted data stream. Finally, using Google Maps API functions and JavaScript code, the XML data was parsed and marker icons were placed on the map canvas, similar to other implementation techniques used on the Volcanoes of the World web map for handling point-based features. P a g e 21 | Matt Stuemky Volcano Catalog search options, Google- like word suggest feature Figure 17 below shows a screenshot of the Volcano Catalog menu as implemented in the Volcanoes of the World web map. There are three search options available: Name, Location and Volcano Type. The Name and Location search fields are text input fields. The Volcano Type is a dropdown list populated with fixed values, only one which can be selected at a time. Any one or all three search fields can be used when performing a query. Also integrated in the Volcano Catalog search menu is a “word suggest” feature, which is designed to allow the user to more easily find matches as soon as they begin typing letters in either the Name or Location search fields. The functionality is very similar to a popular Google search integration feature found within the Firefox web browser and some websites. The word suggest feature is handled in the background by using a combination of client-side JavaScript and server-side PHP code to perform immediate queries in the MySQL database based on what the user types, rather than waiting for the user to click the Search button. It should be noted that although this implemented feature works, there is occasionally a performance issue because the web server where the MySQL database resides can be slow. As a consequence, the results will sometimes not display right away. Figure 17 below shows an example of the word suggest feature, based on the letters typed in by the user in the Name search field. A list of matches automatically appears immediately below the search field. The user can either select any one of the items from the list or continue typing in the search field. Figure 17 – Volcano Catalog menu P a g e 22 | Matt Stuemky Figure 18 below shows an example of how search results from the Volcano Catalog are displayed on the web map. As soon as the user clicks the Search button, data is fetched from the MySQL database using the techniques described above (Fox, 2007). White-colored triangle marker icons representing each volcano record retrieved from the query are placed onto the map canvas. Once all point markers have been loaded, the map will automatically be repositioned to the location of the first marker that was added. A pop-up information window for the first marker will automatically open, showing the summary information on the volcano, including a photo if available. A hyperlink located at the bottom of the window, when clicked, will automatically open a new tab or browser window and navigate to the volcano’s detailed information page on the Smithsonian Institution Global Volcanism Program website. Figure 18 – Volcano Catalog record shown on the web map with a pop-up information window displaying summary information and a photo of the Arenal volcano located in Costa Rica P a g e 23 | Matt Stuemky Implementation: Other Layers The final implementation phase of the Volcanoes of the World web map application involved conducting additional research to identify other spatially-enabled datasets that would enhance the web map features already implemented, in order to provide a more complete web GIS. Ideally, these would be items that could be easily incorporated as additional map layers without a lot of extra time and effort involved, considering the time constraints of the project. Figure 19 below shows the Other Layers menu with the various options that are currently available. Figure 19 – Other Layers menu U.S. Geological Survey Earthquake Hazards Program: Earthquakes and Tectonic plate boundaries The U.S. Geological Survey Earthquake Hazards Program (EHP) provides several spatially-enabled datasets in a GeoRSS-based XML format, suitable for easy implementation into a web GIS. (USGS EHP, 2009) The following EHP data sources were selected for implementation into the web map: Earthquakes – past week Tectonic plate boundaries / major fault lines As implemented, locations of earthquake events from the past week are available as a map layer, using a threshold of either Magnitude 5.0+ or Magnitude 2.5+. Magnitude strength of each earthquake event shown on the web map is represented by colored-coded markers as shown in Figure 20 below. This layer is most useful when zoomed in to a seismically active region (i.e. Alaska) where numerous earthquake markers will typically be displayed on the map. Identifying recent earthquakes in the vicinity of a currently active volcano can be useful for analysis. Turning on the layer depicting tectonic plate boundaries and major fault lines provides some additional insight by showing their proximity to recent earthquakes and active volcanoes. P a g e 24 | Matt Stuemky Figure 20 – Earthquake events of different magnitude located in the Aleutian Islands region of Alaska Volcano Live – volcano activity news by John Seach John Seach is an adventure traveler who specializes in studying volcanoes up close. He has worked on many television documentaries chronicling his travel and volcano explorations. John Seach is the founder of Volcano Live, a news and adventure travel website devoted to information on volcanoes around the world. His website provides an RSS news feed on recent volcano activity. (Volcano Live, John Seach, 2009) The RSS news feed was selected for implementation into the web map. Implementation was accomplished in part by using an RSS to GeoRSS conversion process as described in the Testing and Technical Issues section below. Thematic maps Datasets suitable for use as special thematic map types (base map layers) were selected from the OnEarth project, part of NASA’s Jet Propulsion Laboratory, and from Columbia University’s Socioeconomic Data and Applications Center (SEDAC) and the Center for International Earth Science Information Network (CIESIN). To implement these custom map types for the Volcanoes of the World web map, WMS servers operated by NASA JPL OnEarth and SEDAC/CIESIN were used to retrieve the following tiled raster imagery: Blue Marble “Next Generation” Population Density Natural Disaster Hotspots (Seismic Hazards) P a g e 25 | Matt Stuemky These datasets do not display real-time features like the satellite-based imagery used for volcano monitoring do. However, they do enhance the web map beyond the standard map types available within the Google Maps API, to provide options for performing additional spatial analysis. Blue Marble “Next Generation” is a 500-meter true color earth dataset enhanced with shading of both land topography and ocean bathymetry. It is designed to offer a realistic view of the earth’s surface without any clouds obscuring surface features. Imagery is derived from the MODIS Terra satellite. Twelve different Blue Marble datasets corresponding to each month of the year are available from the OnEarth WMS server, each depicting different seasonal dynamics. For example, a Blue Marble dataset for the month of January shows a more pronounced presence of snow in higher elevations of the northern hemisphere compared to a Blue Marble dataset for the month of August. (NASA JPL OnEarth, 2009) The specific Blue Marble dataset used for the Volcanoes of the World web map corresponds to the current month. Population Density is a dataset from SEDAC that provides estimates of human population for the year 2010. It is but one of several global population datasets that SEDAC makes available for past and future years. Natural Disaster Hotspots is a natural hazards dataset from SEDAC that is based on earthquake/seismic history around the world. (Columbia University SEDAC CIESIN, 2009) The use of a seismic hazards dataset is useful because earthquakes and volcanoes often occur in close proximity to each other, especially in areas where tectonic plates are subducting under one another and/or major fault lines exist. A legend graphic is automatically overlayed in the top left-hand corner of the map canvas whenever the Population Density and Natural Disaster Hotspots thematic map layers are turned on. Figure 21 – California region using each of the three thematic map types Blue Marble “Next Generation”, Population Density and Natural Disaster Hotspots P a g e 26 | Matt Stuemky Testing & Technical Issues This section briefly describes some testing scenarios that were used once the Volcanoes of the World web map application was fully developed with all Current Status, Monitoring, Historical Activity, Volcano Catalog, and Other Layers features available for use. The primary goal of final testing was to evaluate how well the different datasets integrated together to form a complete web GIS, by using the different layers at the same time to perform some basic spatial analyses. Also, several technical issues that arose during testing are described below. Testing example: analyzing a currently active volcano using various layers on the web map Marker icons on the map representing volcanoes monitored by the USGS Volcano Hazards Program offer the single best indicator for quickly identifying where the most current volcano activity is in the United States and its territories. Indicators for Advisory/Yellow, Watch/Orange, or Warning/Red are easy to identify on the map because the icons are larger and stand out more easily compared to those volcanoes with a Normal or Unassigned status. For quickly identifying current volcanic activity for the rest of the world, the VAAC Volcanic Ash Advisory marker icons on the map are the best ones to look for. Both the USGS VHP and VAAC update their datasets several times a day. If a particular volcano has been identified with a Current Status marker on the map, and the user wishes to investigate further, the logical first task would be to zoom in the map over that location, click the marker icon itself to display the pop-up information window, and read the summary information. Optionally, the user may click the hyperlink at the bottom of the summary to open a new page in the web browser showing more detailed information on the volcano. Next, the user can go to the Monitoring menu and turn on, one by one, the various atmospheric indicators layers to see if there is any evidence of volcanic ash (VA) clouds, water vapor/steam clouds, SO2, or other emissions coming from the volcano. Since the output of volcano eruptions can vary greatly based on geographic location, prevailing climate factors, current weather conditions (including normal meteorological cloud cover), and geochemical makeup of the volcano itself, it should always be assumed that certain atmospheric indicators may not always be present. However, a moderate to large eruption will almost always show evidence of VA in some of the satellite imagery. Also, turning on the MODVOLC layer will often display one or more red markers, indicating thermal hot spots, directly on or near a currently active volcano. One of the main reasons for using the Monitoring feature of the Volcanoes of the World web map is to provide P a g e 27 | Matt Stuemky confirmation of new or ongoing activity as indicated by any Current Status information that is shown for a particular volcano. Using options under the Historical Activity menu, the user can determine if there are any records of significant volcanic eruptions of a particular volcano, or if other nearby volcanoes had significant eruptions in the past. The Volcano Catalog can also be useful when looking at a currently active volcano. The user can type in the first few characters of the volcano name (“Redoubt”) or the location of the volcano (“Alaska”) and then click the Search button to have a Volcano Catalog marker appear on the map and automatically display summary information and a photo. Turning on other layers such as earthquakes under the Other Layers menu and volcano webcams under the Monitoring menu can provide the user with additional opportunities to evaluate the severity of a current volcanic eruption. For example, numerous minor magnitude earthquakes have occurred in the vicinity of the Redoubt volcano since March 2009 and weekly earthquake events feature prominently on the web map when the layer is turned on. Viewing imagery provided by two different webcams maintained by the Alaska Volcano Observatory that are currently pointed at Redoubt can also be quite interesting. In recent weeks, these two webcams have occasionally shown very dramatic views of large volcanic ash clouds emanating from the top of the mountain! Figure 22 – Testing example: analyzing the currently active Redoubt volcano P a g e 28 | Matt Stuemky Testing example: Volcano Catalog The Volcano Catalog is designed to be used to quickly search on volcanoes around the world. Not only can the user search on volcanoes by Name or Location or Type they can also search using all three of these parameters. One simple example that demonstrates the spatial accuracy of the Volcano Catalog data when overlayed on the web map is to do a search by Location. This will identify on the map only those volcanoes that exist within the border of a particular country or region. For example, as shown in Figure 23 below, when using the Volcano Catalog, typing in “Costa Rica” in the Location text box and clicking the Search button will place ten marker icons on the map. There are many other volcanoes located geographically nearby, just on the other side of the border in Nicaragua, but only the Costa Rican volcanoes will be shown. Figure 23 – Testing example: Volcano Catalog search for all volcanoes located within Costa Rica Technical issue: Incorporating datasets from WMS sources using the Google Maps API Using the Google Maps API objects GTileLayer and GMapType and JavaScript code, a series of custom map types (base map layers), were created by retrieving tiled raster data from WMS resources. Some of these base map layers, such as the MODIS Terra “Daily Planet” and AIRS, are used as atmospheric indicator options for near real-time volcano monitoring. Other are implemented as special thematic maps, including the Blue Marble “Next Generation”, Population Density and Natural Disaster Hotspots which were added as options under the Other Layers menu. As with the standard Google Maps API map types (Street Map, Satellite, Terrain), the custom map layers automatically place fixed-size raster image tiles onto the map canvas as the user zooms in and out and moves around the map. Testing revealed that these WMS-derived images were sometimes slow to load and occasionally failed to load at all. The time of day and WMS server used often seemed to be factors in how reliably the imagery would load onto the map. No viable solution to this intermittent problem was found. P a g e 29 | Matt Stuemky Technical issue: Limiting zoom levels on all custom map types Testing revealed that tiled raster imagery retrieved from WMS sources did not generally offer a level of resolution that was satisfactory once certain large-scale zoom levels were reached. The resolution of some datasets was worse (i.e. AIRS False Color) than others (i.e. MODIS Terra Daily Planet). The solution was to write a small function in JavaScript designed to manipulate the Google Maps API to limit zoom levels for each of the different custom map types that were created for the Volcanoes of the World web map. Technical issue: RSS to GeoRSS conversion RSS data sources can be geo-referenced. Although various solutions exist to achieve this, a web-based tool on the GeoNames website allows this conversion to be performed easily (GeoNames, 2009). Conversion of the RSS data provided by the Smithsonian Institution GVP into GeoRSS format was required. A small PHP script was created and configured to run as a scheduled task once a week (Wednesday evening) on the web server where the Volcanoes of the World web map application resides. Its purpose is to fetch a copy of the current Weekly Volcanic Activity Reports RSS feed directly from the Smithsonian GVP website and then convert it into GeoRSS format using the GeoNames utility, and save it as a local file in a folder named data located on the same server where the web map application resides. This same RSS to GeoRSS conversion process was also applied to the Volcano Live RSS feed, except that the PHP script used for fetching the data is configured as a scheduled task that runs every six hours instead of once a week. Technical issue: use of “live data” and keeping the web map “current” Many features displayed on the Volcanoes of the World web map use data that are updated frequently by the organizations they are obtained from. Refer to Appendix A: Data Sources to view these update frequencies (some are estimates). Data retrieved from the U.S. Geological Survey Volcano Hazards Program and Earthquake Hazards Program, Volcanic Ash Advisory Centers, all NASA satellite imagery except Blue Marble, MODVOLC, and Volcano Live are all considered “live data” sources. This is in contrast with other web map features, such as Historical Activity which uses KML files stored in a local folder on the web server, and the Volcano Catalog which uses data stored in a local MySQL database on the web server. Two solutions have been implemented to keep the web map “current”. If the web map remains displayed in a web browser continuously, the page will automatically reload every two hours. Additionally, the user can manually refresh the web map at any time simply by clicking the button. This will restore the default map view, automatically reload the latest data from all Current Status layers, and reset all other spatial layers that rely on live data so they will display the most current information when selected. P a g e 30 | Matt Stuemky Final Result Volcanoes of the World web map application: http://gis.manyjourneys.com/volcanoes/ When the web map application first loads, the default map view is worldwide, positioned over the Pacific Ring of Fire. This is the Pacific Ocean basin, a region on Earth where the largest numbers of volcanic eruptions and earthquakes occur. The default map type used is the Google Maps hybrid map (satellite with map labels). The default spatial layers shown are Current Status features representing the most recent alert levels and status information issued by the U.S. Geological Survey Volcano Hazards Program, Volcanic Ash Advisory Centers, and Smithsonian Institution Global Volcanism Program. To maintain a simple, clean user interface, all features are organized into JavaScript-driven menus positioned at the top of the screen. The rest of the screen is devoted to the map, which includes standard Google Maps controls for zoom, move, and map type. The map canvas automatically fills the web browser window based on its current height and width. Figure 24 – Volcanoes of the World web map application P a g e 31 | Matt Stuemky The Volcanoes of the World web map, as implemented for the class project, is intended to only be the first phase of the application. Additional enhancements are planned. For example, the near real-time monitoring feature was determined to be one of the most important implementations of the web map. One of the next objectives is to enhance the monitoring feature further by incorporating some of the newest and more comprehensive datasets derived from instruments on board NASA satellites, for example, OMI SO2, once they are available from a WMS resource. Long term, the plan is to use the Volcanoes of the World web map application as a foundation to build a more comprehensive "geo hazards" web GIS used for monitoring a variety of geological natural hazards including volcanoes, earthquakes, tsunamis, and landslides. This is in contrast with meteorological (weather) type natural hazards such as tornadoes, thunderstorms, hurricanes/typhoons, floods, and wildfires which already seem to be fairly well represented on the World Wide Web with well-designed interactive web map applications. P a g e 32 | Matt Stuemky References Davies A.G., et al. (2008). The Model-Based Volcano Sensor Web: Progress in 2007. Presented at the 2008 NASA Earth Science Technology Conference - ESTC2008. Retrieved on April 6, 2009 from http://esto.nasa.gov/conferences/estc2008/papers/Davies_Ashley_A7P3.pdf Columbia University Socioeconomic Data and Applications Center, Center for International Earth Science Information Network. (2009). Website: http://sedac.ciesin.columbia.edu/ Dunbar, P. (2007). Increasing public awareness of natural hazards via the Internet. Natural Hazards, 42: pp. 529-536. Fox, Pamela, et al. (April 2007). Using PHP/MySQL with Google Maps. Retrieved on March 15, 2009 from http://code.google.com/support/bin/answer.py?answer=65622&topic=11364&ctx=sibling GeoNames.org. RSS to GeoRSS converter. (2009). Website: http://www.geonames.org/rss-to-georss-converter.html Guffanti, M., et al. (2007). Technical-Information Products for a National Volcano Early Warning System. United States Geological Survey: Open File Report 2007-1250. Retrieved on April 6, 2009 from http://pubs.usgs.gov/of/2007/1250 Hawaii Institute of Geophysics and Planetology, MODVOLC. (2009). Website: http://modis.higp.hawaii.edu/ Keeping a wary eye on volcanoes. (2009, March 27). The Week Magazine, 9(405). Retrieved on April 6, 2009 from http://www.theweek.com/article/index/94425/Keeping_a_wary_eye_on_volcanoes Krueger, A. et al. (2006, October 3). NASA research satellite data for volcanic aviation hazards. Presented at the Support to Aviation Control Service (SACS) workshop at Belgian Institute for Space Aeronomy. Retrieved on April 6, 2009 from http://sacs.aeronomie.be/workshop/talks1/Krueger_NASA_Oct2006.ppt National Aeronautics and Space Administration, Jet Propulsion Laboratory, OnEarth. (2009). Website: http://onearth.jpl.nasa.gov/ National Aeronautics and Space Administration, Goddard Earth Sciences Data and Information Services Center. (2009). Website: http://daac.gsfc.nasa.gov/ National Geophysical Data Center, Natural Hazards. (2009). Website: http://www.ngdc.noaa.gov/hazard/ Peduzzi, P., Dao, H. and Herold, C. (2005). Mapping Disastrous Natural Hazards Using Global Datasets. Natural Hazards, 35: pp. 265–289. Schmidt, L.J. (2004). Sensing Remote Volcanoes. Website: http://earthobservatory.nasa.gov/Features/monvoc/ Smithsonian Institution Global Volcanism Program. (2009). Website: http://www.volcano.si.edu/ United States Geological Survey Earthquake Hazards Program. (2009). Website: http://earthquake.usgs.gov/ United States Geological Survey Volcano Hazards Program. (2009). Website: http://volcanoes.usgs.gov/ Volcano Live, John Seach. (2009). Website: http://www.volcanolive.com/ P a g e 33 | Matt Stuemky Appendix A: Data Sources Organization / Reference URL / Dataset description Source format – type Update frequency NASA - Near Earth Observing (NEO) system / Goddard Earth Sciences Data and Information Services Center (GES DISC) http://disc.sci.gsfc.nasa.gov/ AIRS false color/RGB - indicator of volcanic SO2 emissions and volcanic clouds, AIRS infrared BT_diff_SO2 - indicator of volcanic SO2 emissions MODIS aerosol optical thickness - primarily an indicator of volcanic ash WMS – tiled raster (png) WMS – tiled raster (png) WMS – tiled raster (png) Every 6-24 hours Every 6-24 hours Every 12-24 hours NASA – Near Earth Observing (NEO) system / JPL OnEarth http://onearth.jpl.nasa.gov/ Daily Planet – visual view of the Earth showing current cloud coverage Blue Marble – MODIS-derived true color dataset showing seasonal dynamics WMS – tiled raster (jpeg) WMS – tiled raster (jpeg) Every 6-24 hours Annually Columbia University – Socioeconomic Data and Applications Center (SEDAC), Center for International Earth Science Information Network (CIESIN) http://sedac.ciesin.columbia.edu/mapserver/ Population Density – datasets available for 1990, 2000, 2005, 2010, 2015 Natural Disaster Hotspots – dataset on Seismic Activity/Volcanic Hazard zones WMS – tiled raster (png) WMS – tiled raster (png) Undetermined Undetermined U.S. Geological Survey - Volcano Hazards Program (VHP) http://volcanoes.usgs.gov/ Current Status (primary) – status of most actively monitored volcanoes Current Status (other) – status of other volcanoes in U.S. and its territories XML – point XML – point 1-2 times daily 1-2 times daily Smithsonian Institution – Global Volcanism Program (GVP) http://www.volcano.si.edu/ Current Status – weekly reports of new/ongoing volcanic activity worldwide Summary info on 1500+ Holocene era volcanoes worldwide RSS (to GeoRSS) – point Excel (XLS) / KML Once a week (Wed PM) Undetermined Volcanic Ash Advisory Centers (VAAC) http://www.ssd.noaa.gov/VAAC/washington.html Current Status – reports of current Volcanic Ash Advisories KML – point Every 30 minutes ASCII TEXT – point Every 12-24 hours National Geophysical Data Center (NGDC) http://www.ngdc.noaa.gov/hazard/hazards.shtml Significant Volcanic Eruptions – 400+ eruptions from 4350 BC to Present KML - point Annually U.S. Geological Survey - Earthquake Hazards Program http://earthquake.usgs.gov/ Earthquakes – past 7 days worldwide, magnitude 5.0+ and magnitude 2.5+ Tectonic plate boundaries and major fault lines XML – point KML – polyline Every 5-30 minutes Infrequently Volcano Live – John Seach http://www.volcanolive.com/ News on recent volcanic eruptions RSS (to GeoRSS) – point 1-2 times daily Volcano webcams - manually created dataset Approximately 25 geo-referenced webcams pointed at volcanoes XML – point Varies by webcam Hawaii Institute of Geophysics and Planetology – MODVOLC http://modis.higp.hawaii.edu/ Ground level thermal (hot spots) worldwide - used for possible indicators of volcanic activity P a g e 34 | Matt Stuemky