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Launching HMS Florida: A Community Engagement App-Based Workflow for Assessing Climate-Change Impacts on Cultural Sites

Part of: Digital Reviews

Published online by Cambridge University Press:  04 March 2025

Sarah E. Miller Open the ORCID record for Sarah E. Miller [Opens in a new window]
Sarah E. Miller*
Affiliation:
Florida Public Archaeology Network, Flagler College, Augustine, FL, USA; University of Florida, Gainesville, FL, USA
*
Email: [email protected]
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Overview

Mobile apps provide archaeologists a way to engage the public and local communities in efforts to protect heritage at risk. This article discusses community engagement apps used by archaeologists who specialize in collecting data about climate change and its impact on cultural sites. It provides an overview of the process by which the Florida Public Archaeology Network (FPAN) developed various workflows over the last few years to engage community member–scientists using digital tools. FPAN based this work on examples from cultural heritage management practice in Scotland. Because we were unable to directly adapt Scotland's app to our US context, we experimented with multiple other apps and tools to implement our workflows, including Arches, Solocator, ArcGIS Field Maps, and the Arrow GNSS receiver.

Type
Digital Review
Information
Advances in Archaeological Practice , Volume 12 , Special Issue 3: Monitoring Heritage at Risk Sites in Rapidly Changing Coastal Environments , August 2024 , pp. 322 - 329
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2025. Published by Cambridge University Press on behalf of Society for American Archaeology

Mobile smartphone applications, or apps, have become the norm for personal and professional data management. Such apps may also run on computer desktops or have web-browser-based versions, enabling a wide range of interactions, accessibility, and inputs. As mobile phones became commonplace and ever more powerful, scientists quickly recognized apps’ potential to open up their work to the public, enabling ordinary citizens to participate in research. For example, the prominent citizen-science app iNaturalist, which began as a master's degree project at the University of California at Berkeley, has enabled the public to record more than 49 million environmental observations (Wills Reference Wills2020). Within the discipline of archaeology, a variety of citizen-scientist apps allow volunteers to submit condition assessments and other data about sites in the field. To take advantage of the possibilities enabled by these apps, the Florida Public Archaeology Network (FPAN) organization has been developing the Heritage Monitoring Scouts (HMS Florida) program to engage the public in keeping track of heritage at risk (Miller and Murray Reference Miller and Murray2018). FPAN staff focused their efforts on mapping and monitoring coastal archaeological and historic sites that are threatened by climate-change-induced erosional processes. Several international projects that use apps for public engagement inspired HMS Florida, such as the ALERT Mobile App in France (Barreau et al. Reference Barreau, Sachet, López-Romero, Daire, Olomos-Benlloch, Addison, Guidi, De Luca and Pescarin2013; Olmos Benlloch et al. Reference Olmos Benlloch, López-Romero, Daire, Dawson, Nimura, López-Romero and Daire2017), the Archwilio App in Wales (Gerrard Reference Gerrard, Dawson, Nimura, López-Romero and Daire2017), ESRI's Collector for ArcGIS and Snap2MAP in Barbuda (Perdikaris et al. Reference Perdikaris, Bain, Boger, Grouard, Faucher, Rousseau, Persaud, Noël, Brown, Medina-Triana, Dawson, Nimura, López-Romero and Daire2017), the CITiZAN App in England (Wragg et al. Reference Wragg, Cohen, Milne, Ostrich, Nimura, Dawson, Nimura, López-Romero and Daire2017), and most significantly the ShoreUpdate App in Scotland (Table 1; Dawson et al. Reference Dawson, Hambly, Kelley, Lees and Miller2020; Dawson, Hambly, and Graham Reference Dawson, Hambly, Graham, Dawson, Nimura, López-Romero and Daire2017; Dawson, Nimura, et al. Reference Dawson, Nimura, López-Romero and Daire2017; Hambly et al. Reference Hambly, Boyd and Dawson2024). FPAN staff, however, could not directly adapt the ShoreUpdate App to their needs, both because of the markedly different settings and environmental conditions between the areas and the differences in some site categories. Therefore, over the course of several years, FPAN staff identified, tested, and deployed several different apps, working in unison, to form a more complete workflow for public heritage management in Florida.

Table 1. List of Apps and Tools Used by Site Stewardship Programs.

Note : App/Tools marked with an asterisk indicate those developed based on SCAPE's ShoreUpdate App.

Learning from Scotland: The ShoreUpdate App

Through our personal connections and professional collaborations, FPAN staff first gained significant experience with the use of citizen-science apps in archaeology in Scotland. The Scotland Coastal Archaeology and the Problem of Erosion (SCAPE) initiative created the Scotland Coastal Heritage and Response Project and willingly shared details of their ShoreUpdate App (SCHARP; Dawson et al. Reference Dawson, Hambly, Kelley, Lees and Miller2020; https://scapetrust.org/). The ShoreUpdate App has been quite successful in engaging community volunteers in digitally documenting archaeological sites at risk from climate change. One of its important functions is to record the geographical points for each archaeological site, together with an assessment form, which can be continuously edited and updated. This allows members of the public to help update status information for each site (Figure 1).

Figure 1. SCAPE's Scottish Coastal Heritage at Risk Project map available to the public and volunteers (image from the SCAPE Trust website, https://scapetrust.org/sites-at-risk/).

Among those who monitor archaeological sites in the United States, there has been an interest in trying to develop apps that can be used locally by state, tribal, and federal agencies. In the United States there are fewer examples of apps used by site stewardship programs (Table 1). Some examples from local contexts include the CitPres App for Bodie, California (Lercari and Jaffke Reference Lercari and Jaffke2020) and the South Park Site Stewards program in Colorado (Miller, Rubinson, et al. Reference Miller, Rubinson, Padon, Zabecki, Raschkow and Lowe2022). Statewide, the Utah Cultural Site Stewardship Program (2022) currently uses the Survey 123 App to collect site visit information (Miller, Rubinson, et al. Reference Miller, Rubinson, Padon, Zabecki, Raschkow and Lowe2022). Apps under development include the Nevada Site Stewardship Program (Samantha Rubinson, personal communication 2024) and the Maine Midden Minders (Newsom et al. Reference Newsom, Scott, Kelley and Allen2023).

However, none of these apps fit the needs of site stewardship programs created specifically to engage the public in tracking changes to sites over time exacerbated by climate change. In contrast, the open-source code and model of the ShoreUpdate App do provide an excellent model to emulate. As the director at the Florida Public Archaeology Network (FPAN), I was inspired to start the Heritage Monitoring Scouts (HMS Florida) program in 2016 by what I observed at SCAPE and SCHARP (Miller and Murray Reference Miller and Murray2018). As part of this effort, FPAN hoped to develop a ShoreUpdate-like app for surveying statewide archaeological sites (Miller Reference Miller, Orser, Funari, Lawrence, Symonds and Zarankin2020; Miller, Ayers-Rigsby, et al. Reference Miller, Ayers-Rigsby, LeFebvre, Walker, Murray and Kangas2024; Miller, Murray, et al. Reference Miller, Murray, Kemp, Lee, Simmons-Jenkins, Cochran and Gaillard2024; Rubinson and Miller Reference Rubinson, Miller, Reetz and Sperling2024).

Directly adapting the ShoreUpdate App to the US context, however, did not prove easy. First, in the United States, archaeologists are bound by state and federal laws that protect site location information from being shared publicly. Thus, the georeferenced, end-user friendly public view of the site location points displayed on the ShoreUpdate App for Scotland could not be replicated in the United States (Figure 1). Second, unlike in the United Kingdom, no national database of archaeological sites exists in the United States: data are managed differently state by state and among various federal and tribal land-managing units (Bollwerk et al. Reference Bollwerk, Gupta and Smith2024; Kansa et al. Reference Kansa, Kansa, Anderson, Wells, Meyers, Yerka and Hess2021)—although in recent years there have been increasing calls for the development of such a national database (Anderson et al. Reference Anderson, Bissett, Yerka, Wells, Kansa, Kansa, Myers, Carl DeMuth and White2017; Kansa et al. Reference Kansa, Kansa, Wells, Yerka, Myers, DeMuth, Bissett and Anderson2018; Ortman and Altschul Reference Ortman and Altschul2023). Finally, Apple and Android apps need constant updating, but FPAN was not able to budget for making a custom app that would be sustainable into the future.

Even in Scotland, the use of apps for archaeology has changed over time, given the shifting needs of the SCAPE organization. It therefore recently built a second app, the SCAPE App, that differs from the ShoreUpdate App in several ways. First, the SCAPE App is not heavily promoted to the public because it is intended for use only by a few qualified individuals; in contrast, the ShoreUpdate App encouraged as many community volunteers to participate as possible. However, the SCAPE team found that further training would be required to maintain quick response and quality control (QRQC). Second, the focus of data collection in the SCAPE App moved from recording condition assessments for thousands of sites to recording linear geographic data of the erosional edges along the shorelines of key threatened sites.

Developing a Workflow for Florida: The Heritage Monitoring Scouts (HMS) Program

Given the limitations of directly adapting the ShoreUpdate App to use in Florida, FPAN sought new ways to build infrastructure to engage the public in monitoring at-risk sites. In a first attempt at a program called Heritage Monitoring Scouts (HMS Florida; Miller and Murray Reference Miller and Murray2018), FPAN used simple digital tools to reach out to all residents of and visitors to Florida, similar to what the SCHARP project did. The original site monitoring form, approved by the Florida Bureau of Archaeological Research, asked the observer to rate archaeological sites into good, fair, and poor categories during a condition assessment. The form also included useful fields replicated from the ShoreUpdate app, as well as other site stewardship programs in the United Kingdom and the United States. When the program launched in 2016, the system was built by combining basic Google docs and spreadsheets to include a “Scout Report” (condition assessment) with a sign-in: this information comprised the HMS Florida database. QRQC was relatively easy to track initially but became quite complicated as the scale grew larger, with multiple scouts recording multiple sites and some sites recorded repeatedly by the same or different participants.

Similar to SCAPE's SCHARP project, FPAN's HMS Florida program has also evolved from a condition assessment tool to collecting other critical data documenting changes to sites over time, particularly shorelines (Miller and Murray Reference Miller and Murray2018). While working with SCAPE in Scotland on the Learning from Loss project in 2018, I learned to use an Arrow global navigation satellite system (GNSS) receiver to collect shoreline data. I brought this methodology to FPAN as a template to use in HMS Florida protocols. Scotland's SCAPE App integrates these functions, but again the limitations on data sharing and the cost of app development prevented HMS Florida from being able to directly adopt that app to the US context. FPAN instead moved forward with developing an HMS Florida database using the open source Arches platform from the Getty Conservation Institute and World Monuments Fund (https://archesproject.org; Dalgity et al. Reference Dalgity, Myers and Patterson2022; Myers et al. Reference Myers, Dalgity, Avramides, Wuthrich, Ionnides, Fritsch, Leissner, Davies, Remondino and Caffo2012). Arches allows for restrictions on data entry and use that limit access to the public and volunteers (Figure 2).

Figure 2. Heat map of archaeological sites in Florida in HMS Florida Arches Database (image from the HMS Florida Arches Database, https://hms.fpan.us/).

Filling in the Gaps: Supplemental Apps for Florida

FPAN also needed ways to collect other types of data with the help of community volunteers, in addition to that collected in our adaptation of the Arches database. To provide additional functionality, FPAN explored using a variety of different apps, including the Solocator App for placing metadata into photographs, the ArcGIS Field Maps App for collecting spatial data, and the Arrow GNSS equipment with its EOS Tools Pro App for measuring locational information. These are all out-of-the-box commercial apps that were built for other purposes but can be adapted by archaeologists.

The Solocator App overlays a top banner and other information onto a user's photographs that contain GNSS coordinates of the photo's location, including elevation and a timestamp, and even records the direction the user was facing when taking the picture (Figure 3; https://solocator.com/). This functionality helps overcome the challenge of managing photographs taken during a community-driven monitoring project. An industrial pack upgrade for this app, costing only 99 cents, allows the user to add custom text in two fields at the bottom. For HMS Florida, FPAN staff use the first field to record a site number or project name. The second field is generally used to indicate whether the photograph is of a feature or an artifact or otherwise describes the content. Solocator thus obviated the need for training scouts to produce and maintain complex photo logs. Users can simply upload their Solocator-enhanced photographs directly into the HMS Florida Arches database and site forms. FPAN also uses Solocator in its Cemetery Resource Protection Training (CRPT) program and for site checks requested by the state or other heritage partners.

Figure 3. The Solocator App can add metadata about a photograph, such as position and directional information, directly into the photograph (image from the Solocator website, https://solocator.com/).

HMS Florida also makes use of the ArcGIS Field Maps App to collect spatial data, especially information about shifting shorelines (https://www.esri.com/en-us/arcgis/products/arcgis-field-maps/overview). As with any geographic information system (GIS) software, Field Maps allows for the collection of point and linear data that are often associated with photographs and other attached data. FPAN found it to be relatively easy to train volunteers to help map shorelines and individual artifacts in this app while scouting for erosional edges. When engaging the public, however, archaeologists need to be mindful of varying definitions for shorelines or for at-risk heritage in general (Cochran et al. Reference Cochran, Miller, Wholey, Gougeon, Gaillard, Murray and Parker2023; Gaillard et al. Reference Gaillard, Luciano, Sundin, Weber and Smith2024; Kangas et al. Reference Kangas, LeFebvre, Green, Ayers-Rigsby, Bear, De La Torre Salas and Karim2024). FPAN trains land managers, project teams, and volunteers to identify the erosional edge and use consistent terminology when recording linear observations. Archaeologists engaged in this work need to track dynamic shorelines that shift, collapse, or create benches halfway down a bluff. Another reason we use ArcGIS Field Maps is to reconcile locational data. Often, FPAN staff find during site checks that previously recorded sites and cemeteries are incorrectly placed on the map. Reconciliation occurs when the field supervisor and the database manager compare recorded site boundaries and adjust for new, more accurate data from the field.

For HMS Florida, FPAN uses an Arrow Gold GNSS receiver to capture precise locational information into the mobile GIS (https://eos-gnss.com/). Such affordable GNSS hardware has recently become crucial for fieldwork in archaeology and heritage at risk (Cobb et al. Reference Cobb, Earley-Spadoni and Dames2019). FPAN staff use the EOS Tools Pro App to configure and run the Arrow Gold, an app built by the device's manufacturer. When dealing with shifting shorelines across broad landscapes, archaeologists must find ways to describe a dynamic environment with fixed points. The Dynamic Coasts projects (Muir et al. Reference Muir, Richardson-Foulger, Hurst and Rennie2022) serve as an example of how the Arrow Gold GNSS data could fit into the needs of an interdisciplinary team working in Scotland.

All practitioners run into some challenges with using GNSS receivers in the field. When used alone, the satellite data may provide accuracies around or less than a meter, but differential GNSS (dGNSS) would be required for centimeter-level accuracy. In Florida, researchers have access to free dGNSS positional corrections from a Real-Time Kinetic (RTK) network through a Florida Department of Transportation account. Elsewhere, however, subscribing to such a service can be expensive, and it may not function well across state or national boundaries. Then there are the problems posed by trees and other types of terrestrial cover, as well as interference to the satellite signals, which have to be carefully accommodated, often requiring multiple recording attempts and careful cross-checking of the results.

New Apps on the Horizon

At FPAN, staff are continually keeping an eye out for new potential apps to use in our community collaboration efforts. The Heritage at Risk Committee of the Society for Historical Archaeology (SHA) and the Climate Change Strategies and Response Committee of the Society for American Archaeology often sponsor sessions to pilot such new apps. For example, at the SHA conference in Lisbon in 2023, Bonnie Newsom and colleagues (Reference Newsom, Scott, Kelley and Allen2023) shared a prototype for a new app developed for the Maine Midden Minders program (https://umaine.edu/middenminders/). Their iOS app, developed using the Swift programming framework, relies on Apple's ARKit and RealityKit libraries to integrate useful augmented reality (AR) enabled workflows (Liang Reference Liang2021). With its use of lidar scanning, plane detection, and raycasting, field testing of this custom app at Acadia National Park in Frazer Point Winter Harbor, Maine, has proved promising.

As mentioned earlier, FPAN uses the Arches open-source software to host the HMS Florida database. Recently, FPAN staff tested the Arches Collector app, which can download offline information before fieldwork is conducted and allows users to directly collect new data in the field using a smartphone; this information is later uploaded to the central database. Our pilot projects with this app have thus far uncovered some challenges due to our customization of the backend database setup in the Arches software. When future updates make the Arches Collector App easier to deploy for archaeological monitoring, FPAN staff anticipate it will be a good fit for statewide site stewardship programs (Miller, Rubinson, et al. Reference Miller, Rubinson, Padon, Zabecki, Raschkow and Lowe2022).

Conclusion

As with all archaeological data, it can be challenging to collect and maintain spatial information associated with heritage sites that are at risk from climate change (Klehm Reference Klehm2023), particularly in the US context with its heterogeneous data information universe (Bollwerk et al. Reference Bollwerk, Gupta and Smith2024). As archaeologists, we see the value in collaborating with communities in this process, both to keep up with our dynamically changing natural environment and to encourage public interest in archaeology (Anderson et al. Reference Anderson, Miller and Wright2024; Gunnarsdóttir Reference Gunnarsdóttir2023; Miller and Wright Reference Miller and Wright2023). Thus, while building out the HMS Florida public monitoring project, FPAN has turned to a variety of free and affordable digital apps to create a workflow to match our data collection needs (Murray et al. Reference Murray, Miller and Kemp2024). At the core of our project, HMS Florida uses the free Arches database, and FPAN hopes to one day use the related Arches Collector mobile app in the field. For now, HMS Florida uses a suite of readily available apps to monitor the changing conditions of archaeological sites, especially along the coast. From 2019 to 2021, FPAN monitored 580 sites as part of a Special Category grant that resulted in 94 site form updates and 13 new sites recorded (Miller et al. Reference Miller, Murray and Kemp2021). Countries and states cannot manage what they do not know about, and verification of site location significantly addresses the impacts of sea-level rise and erosion modeling.

Community volunteers in Florida are trained to use Solocator to capture photographic information with embedded metadata. They also often learn to use ArcGIS Field Maps to document locational information and upload images for site assessments, usually in tandem with an Arrow GNSS receiver. FPAN staff are inspired by the work done in Scotland with the ShoreUpdate and SCAPE apps, and we hope that others will create such sustainable, transferable, and easy-to-navigate programs. In the United States, more centralization and standardization of data are necessary to support field monitoring and make our practices more consistent. Through engaging the public and broadly sharing data, archaeologists can gain a better understanding of how our coastal heritage is at risk from climate change.

Acknowledgments

I am indebted to Tom Dawson, Joanna Hambly, Elinor Graham, and Tanya Venture for their friendship and willingness to collaborate across the Atlantic. Thanks to Mike Arrowsmith for developing the ShoreUpdate and SCAPE App. Mike made himself available many times to talk through how FPAN might be able to learn and borrow from SCAPE. I also thank my colleagues at FPAN who contributed uncountable hours, months, and years to develop and implement HMS Florida. Finally, I am grateful to the editors and reviewers of this article, Peter J. Cobb and David G. Anderson. I deeply appreciate the collaborative effort made to publish this article in this special issue.

Funding Statement

Funding for the Northeast Regional center of the Florida Public Archaeology Network at Flagler College comes from a reoccurring grant from University of West Florida from 2006 to present.

Data Availability Statement

The SCAPE, Solocator, ArcGIS Field Maps, and EOS Tools Pro apps are available for download from the Apple and Android app stores.

Competing Interests

The author declares none.

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Figure 0

Table 1. List of Apps and Tools Used by Site Stewardship Programs.

Figure 1

Figure 1. SCAPE's Scottish Coastal Heritage at Risk Project map available to the public and volunteers (image from the SCAPE Trust website, https://scapetrust.org/sites-at-risk/).

Figure 2

Figure 2. Heat map of archaeological sites in Florida in HMS Florida Arches Database (image from the HMS Florida Arches Database, https://hms.fpan.us/).

Figure 3

Figure 3. The Solocator App can add metadata about a photograph, such as position and directional information, directly into the photograph (image from the Solocator website, https://solocator.com/).