Access the full text.
Sign up today, get DeepDyve free for 14 days.
F. Leccese, M. Cagnetti, Andrea Calogero, D. Trinca, S. Pasquale, S. Giarnetti, L. Cozzella (2014)
A New Acquisition and Imaging System for Environmental Measurements: An Experience on the Italian Cultural HeritageSensors (Basel, Switzerland), 14
M. Ojo, S. Giordano, G. Procissi, Ilias Seitanidis (2018)
A Review of Low-End, Middle-End, and High-End Iot DevicesIEEE Access, 6
M. Maceli, Elena Villaespesa, S. Adams (2019)
Environmental Monitoring of Archival Collections: An Exploratory Study of Professionals' Data Monitoring Dashboard Needs and Related Challenges
Kristian Hentschel, D. Jacob, Jeremy Singer, M. Chalmers (2016)
Supersensors: Raspberry Pi Devices for Smart Campus Infrastructure2016 IEEE 4th International Conference on Future Internet of Things and Cloud (FiCloud)
Shancang Li, Lida Xu, Shanshan Zhao (2015)
The internet of things: a surveyInformation Systems Frontiers, 17
(2019)
Pricing and sign Up
Bhagya Silva, Murad Khan, K. Han (2018)
Internet of Things: A Comprehensive Review of Enabling Technologies, Architecture, and ChallengesIETE Technical Review, 35
(2019b)
LoRaWAN security
(2019a)
The things network console
P. Londero, Theresa Fairbanks-Harris, P. Whitmore (2016)
An Open-Source, Internet-of-Things Approach for Remote Sensing in MuseumsJournal of the American Institute for Conservation, 55
(2002)
Nara 1571 – archival storage standards
(2019)
The things network
(2019)
MQTT
Pallavi Sethi, S. Sarangi (2017)
Internet of Things: Architectures, Protocols, and ApplicationsJ. Electr. Comput. Eng., 2017
L. Peralta, A. Abreu, L. Brito (2013)
Environmental Monitoring based on Wireless Sensor Network via Mobile Phone
(2019b)
Telegraf open source server agent | InfluxData
(2019)
Teach, learn, and make with Raspberry Pi – Raspberry Pi
A. Mecocci, A. Abrardo (2014)
Monitoring Architectural Heritage by Wireless Sensors Networks: San Gimignano — A Case StudySensors (Basel, Switzerland), 14
(2019)
Preservation management | onset HOBO data logger
(2019b)
Particle | device cloud
(2019)
Adafruit feather M0 with RFM95 LoRa radio – 900MHz – RadioFruit
(2019)
Grafana: the open observability platform | grafana labs
(1995)
Environmental Guidelines for the Storage of Paper Records (NISO TR-01-1995)
(2019a)
About eClimate notebook
F. Viani, M. Salucci, P. Rocca, G. Oliveri, A. Massa (2012)
A multi-sensor WSN backbone for museum monitoring and surveillance2012 6th European Conference on Antennas and Propagation (EUCAP)
(2019b)
Image permanence institute | PEM2® datalogger
L. Brito, L. Peralta (2008)
Wireless Sensor Networks Applied to Museums' Environmental Monitoring2008 The Fourth International Conference on Wireless and Mobile Communications
(2019c)
Security checklist for the internet of things – an essential guide to securing connected products
(2019)
Overview – bluetooth mesh networking
Yuwei Zhang, Wei Ye (2011)
Design and placement of light monitoring system in museums based on wireless sensor networks2011 International Symposium on Advanced Control of Industrial Processes (ADCONIP)
(2019)
About LoRaWAN®
Marcel Großmann, Steffen Illig, Cornelius Matejka (2017)
Environmental Monitoring of Libraries with MonTreAL
S. Pujar, K. Satyanarayana (2015)
Internet of Things and libraries, 62
M. Bacci, C. Cucci, A. Mencaglia, A. Mignani (2008)
Innovative Sensors for Environmental Monitoring in MuseumsSensors (Basel, Switzerland), 8
Henoc Agbota, J. Mitchell, M. Odlyha, M. Strlič (2014)
Remote Assessment of Cultural Heritage Environments with Wireless Sensor Array NetworksSensors (Basel, Switzerland), 14
F. Mesas-Carrascosa, D. Santano, José Larriva, R. Cordero, R. Fernández, A. García-Ferrer (2016)
Monitoring Heritage Buildings with Open Source Hardware Sensors: A Case Study of the Mosque-Cathedral of CórdobaSensors (Basel, Switzerland), 16
F. D’Amato, P. Gamba, E. Goldoni (2012)
Monitoring heritage buildings and artworks with Wireless Sensor Networks2012 IEEE Workshop on Environmental Energy and Structural Monitoring Systems (EESMS)
(2019)
About ESP MESH (Wi-Fi)
(2019a)
Mesh IoT network
S. Aparicio, M. Martínez-Garrido, J. Ranz, R. Fort, M. Izquierdo (2016)
Routing Topologies of Wireless Sensor Networks for Health Monitoring of a Cultural Heritage SiteSensors (Basel, Switzerland), 16
Patricia Morris (2009)
Achieving a Preservation Environment with Data Logging Technology and MicroclimatesCollege & Undergraduate Libraries, 16
(2019a)
InfluxDB: purpose-built open source time series database | InfluxData
J. Brooke (1996)
SUS: A 'Quick and Dirty' Usability Scale
Mahdad Esmaeili, A. Dehnavi, H. Rabbani (2017)
3D Curvelet-Based Segmentation and Quantification of Drusen in Optical Coherence Tomography ImagesJ. Electr. Comput. Eng., 2017
Meifang Zhang, Yushi Wang (2015)
Energy efficiency approaches in archives and library buildings in ChinaArchival Science, 15
Cultural heritage archives rely on environmental monitoring devices, such as dataloggers or more complex networked systems, to ensure collection preservation through collecting temperature, humidity, light and/or air quality measures. Existing systems are often costly, inflexible and do not use a modern, internet of things (IoT) approach. This paper aims to determine the suitability of currently popular general-purpose IoT devices, standards and technologies to the environmental monitoring needs of archivists, as well as identify any challenges.Design/methodology/approachThis paper describes an exploratory study detailing the design, construction and usability testing of a do-it-yourself datalogger and data dashboard system, which seeks to manage previously identified trade-offs in cost, required technical skill and maintainability.FindingsThe environmental monitoring system presented met archivists’ needs well and was generally noted to be easy-to-use, efficient and an improvement on existing systems. This suggests that an IoT approach can support archivists’ needs in this area.Research limitations/implicationsPotential limitations of this study include lack of archival staff with sufficient technical training to maintain such a system and the rapid pace of IoT evolution yielding unstable and constantly changing technologies.Practical implicationsThe system design presented in this work provides a blueprint for cultural heritage organizations desiring a fuller-featured, lower cost environmental monitoring system for archival collections.Originality/valueThis research takes a novel user-centered, open-source, IoT approach to construct an environmental monitoring system that is designed directly from archivists’ requirements and is extensible for future needs.
Records Management Journal – Emerald Publishing
Published: Jul 22, 2020
Keywords: Archives; Environmental monitoring; Datalogger; Internet-of-things
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.