A geofence is a virtual "perimeter" or "fence" around a given geographic feature.[1] A geofence can be dynamically generated (as in a radius around a point location) or match a predefined set of boundaries (such as school zones or neighborhood boundaries).

Two geofences defined in a GPS application

The use of a geofence is called geofencing, and one example of use involves a location-aware device of a location-based service (LBS) user entering or exiting a geofence. Geofencing approach is based on the observation that users move from one place to another and then stay at that place for a while. This method combines awareness of the user's current location with awareness of the user's proximity to locations that may be of interest.[2] This activity could trigger an alert to the device's user as well as messaging to the geofence operator. This info, which could contain the location of the device, could be sent to a mobile telephone or an email account.

History

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Geofencing was invented in the early 1990s and patented in 1995 by American inventor Michael Dimino, using the first-of-its-kind GPS and GSM technology for tracking and locating anywhere on the globe from a remote location. Cellular geofencing for global tracking is cited in the United States Patent Office over 240 times by major companies such as IBM and Microsoft since 1995 and is first mentioned as:[3]

A global tracking system (GTS) for monitoring an alarm condition associated with and locating a movable object, the GTS comprising:

a cellular telephone located with the movable object;
a GPS (global positioning system) receiver located with the movable object, the GPS receiver being effective for providing data reflecting a present spacial position of the movable object, in terms of spacial latitude/longitude coordinates;
an interface between the GPS receiver and the cellular telephone, the interface being connected between the GPS receiver and the cellular telephone and including circuitry for transmitting the spacial coordinates from the GPS receiver through the telephone, wirelessly to a remote location; and
an alarm for detecting that the object has been moved, by calculating a spatial movement of the object which exceeds a predetermined distance based on information supplied by the GPS receiver, and the alarm initiating the transmission to the remote location the spatial coordinates from the GPS receiver when said movement of predetermined distance has been detected.

Working

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Geofencing uses technologies like GPS, or even IP address ranges, to build its virtual fence. In most cases, mobile phones are using combinations of positioning methods, e.g., Assisted GPS (A-GPS). "A-GPS uses assistance data received from the network to obtain a faster location calculation compared with GPS alone."[4] The global system of tracking and geofencing is supported by a group of subsystems based on global navigation satellite system (GNSS) services. Both horizontal and vertical accuracy of GNSS is just a few centimetres for baseline ≤ 5 km.[5] The Wide Area Augmentation System (WAAS) is used by devices equipped and used in North America—the accuracy is considered to be within 3 m at least 95% of the time.[6] These virtual fences can be used to track the physical location of the device active in the particular region or the fence area. The location of the person using the device is taken as geocoding data and can be used further for advertising purposes.

It is possible to monitor several geofences at once (multiple active geofences). The number of active geofences on Android devices is limited to 100 per app and per user.[7] It is possible to monitor different type of triggering activity for each geofence separately—entrance, exit, or dwell in the monitored area.

Types

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There are two types of geofencing—choice of type depends on the purpose of using geofencing in a given situation.

Active

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It uses GPS services for the entire time when the application is running and therefore consumes more battery as a result. The reason for the higher battery consumption is the fact that the service requires running in the foreground throughout the time of usage.

Passive

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This type does not require a constantly active state of the application and is able to run in the background. It is rather suitable for the process of data collection. It does not use GPS services, therefore cannot be used for an app depending on real time (sending notifications immediately, etc).

Pros and cons

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Advantages

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  • It is not necessary to implement any additional hardware for this method to function.
  • This service is available for both Android and iOS operating systems.
  • When properly implemented, you can expect accuracy in units of metres.

Disadvantages

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  • Higher battery consumption
  • Before it is possible to start using the geofencing method, it is necessary for a user to allow location tracking.

Applications

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Policing

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The FBI has used geofence warrants to identify rioters who participated in the 6 January Capitol attack.[8]

Safety

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Geofencing, used with child location services, can notify parents if a child leaves a designated area.[9]

It is also being used for flexible home controls and monitoring system—for example setting a phone to unlock the door or turn on the heating when arriving home.[10]

Geofencing used with location-based guns can restrict those firearms to fire only in locations where their firing is permitted, thereby making them unable to be used elsewhere.

Other applications include sending an alert if a vehicle is stolen,[11] and notifying rangers when wildlife stray into farmland.[12]

A geofence can be used for location-based messaging for tourist safety and communication.[13]

In 2015, US Senator Charles Schumer proposed a law requiring drone manufacturers to build geofencing constraints into unmanned aerial vehicle navigation systems that would override the commands of the unsophisticated operator, preventing the device from flying into protected airspace.[14][15]

In the workplace

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Geofencing is critical to telematics. It allows users of the system to draw zones around places of work, customer's sites and secure areas. These geofences when crossed by an equipped vehicle or person can trigger a warning to the user or operator via SMS or email.

In some companies, geofencing is used by the human resource department to monitor employees working in special locations, especially those doing field works. Using a geofencing tool, an employee is allowed to log his or her attendance using a GPS-enabled device when within a designated perimeter.

Geofencing, in a security strategy model, provides security to wireless local area networks. This is done by using predefined borders (e.g., an office space with borders established by positioning technology attached to a specially programmed server). The office space becomes an authorized location for designated users and wireless mobile devices.[16][page needed]

Satellite

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During the use of Starlink satellites in the Russo-Ukrainian War, SpaceX used geofencing to limit the use of Starlink Internet services outside the borders of Ukraine such as in Russian-occupied territories in Ukraine.[17]

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Applications of geofencing extend to advertising and geomarketing. Geofencing solution providers allow marketers and advertisers to precisely choose the exact location that their ads show up on. Geofencing uses different types of targeting to identify zip codes, street addresses, GPS coordinates using latitude and longitude, as well as IP targeting.

Geofencing enables competitive marketing tactics for advertisers and marketers to grab the attention of in-market shoppers in their competitive store location, large scale events such as concerts, sports events, conferences, etc. in stadiums, convention centers, malls, outlets, parks, neighborhoods. For example: at a concert, a digital ad relating to the performer or an affiliated company could be sent to only those people in the venue.

For example, a local auto-dealership builds a virtual boundary within a few square miles from its dealership's location to target car buyers within the same neighborhood. This way they limit their ad spending on prospects who are more likely to purchase in order to get a better ROI. Using tracking technologies to identify devices where the ads were shown, geofencing solution providers are able to provide walk-in attribution for their advertising. This means that using a geofencing solution, companies can now track the customers who walked into the showroom after seeing the ad. This level of attribution provides better visibility and analytics for marketers to spend their advertising budget wisely.

A local service business may only be interested in (a) likely clients (b) within a service region or catchment basin. Broadcasting or advertising more extensively brings irrelevant responses and wastes energy, time, money, and opportunity. Electronic advertising can identify and target only desired market objects (people).

Business

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Target Corporation settled for $5 million with the San Diego City Attorney in April 2022, promising to audit and improve pricing procedures, after a San Diego complaint that the company used geofencing to raise prices when a customer entered a store.[18]

See also

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References

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  1. ^ Rouse, Margaret (December 2016). "What is geo-fencing (geofencing)?". WhatIs.com. Newton, Massachusetts: TechTarget. Retrieved 26 January 2020.
  2. ^ Namiot, Dmitry; Sneps-Sneppe, Manfred (2013). "Geofence and Network Proximity". In Balandin, Sergey; Andreev, Sergey; Koucheryavy, Yevgeni (eds.). Internet of Things, Smart Spaces, and Next Generation Networking. Lecture Notes in Computer Science. Vol. 8121. Berlin, Heidelberg: Springer. pp. 117–127. arXiv:1303.5943. doi:10.1007/978-3-642-40316-3_11. ISBN 978-3-642-40316-3. S2CID 15873599.
  3. ^ "Telephone operable global tracking system for vehicles". United States Patent Office. December 1995.
  4. ^ Namiot, Dmitry (2 December 2022). "GeoFence services | Namiot | International Journal of Open Information Technologies". International Journal of Open Information Technologies. 1 (9): 30–33. Retrieved 2 December 2022.
  5. ^ Khomsin, Ira Mutiara Anjasmara, Danar Guruh Pratomo, and Wahyu Ristanto (2019). "Accuracy Analysis of GNSS (GPS, GLONASS and BEIDOU) Obsevation [sic] for Positioning" (PDF). E3S Web of Conferences. 94: 01019. Bibcode:2019E3SWC..9401019K. doi:10.1051/e3sconf/20199401019. S2CID 165073579 – via The Authors.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  6. ^ United States. Federal Aviation Administration, ed. (31 October 2008). "Global Positioning System wide area augmentation system (WAAS) performance standard". {{cite journal}}: Cite journal requires |journal= (help)
  7. ^ "Create and monitor geofences". Android Developers. Retrieved 2 December 2022.
  8. ^ Harris, Mark (30 September 2021). "How a Secret Google Geofence Warrant Helped Catch the Capitol Riot Mob". Wired. Retrieved 10 November 2021.
  9. ^ De Lara, Eyal; Anthony LaMarca; Mahadev Satyanarayanan (2008). Location Systems: An Introduction to the Technology Behind Location Awareness. Synthesis Lectures on Mobile and Pervasive Computing, Lecture #4. Morgan & Claypool Publishers. p. 88. ISBN 978-1-59829-581-8 – via Google Books.
  10. ^ Amudha, S.; Sankar, S. Sasi Rekha; Rajkumar, Mishra Neel; Jain, Aayush (21 June 2019). "Enhancement of smart home automation system using secure geofence concept in IoT". AIP Conference Proceedings. 2112 (1): 020036. Bibcode:2019AIPC.2112b0036A. doi:10.1063/1.5112221. ISSN 0094-243X. S2CID 198339104.
  11. ^ "Motorcycle Tracker Updates Every 15 Seconds". Motorcycle USA. 23 January 2009. Archived from the original on 31 January 2009. Retrieved 26 January 2009. Courtesy True Tracker Pro
  12. ^ "Kenya's elephants send text messages to rangers". CBS News. Associated Press. 11 October 2008. Archived from the original on 13 October 2008. Retrieved 26 January 2020.
  13. ^ "Location Based Messaging for Tourist Safety and Communication" (PDF). UgoRound Australia Pty Ltd. July 2017. Archived from the original (PDF) on 26 September 2017. Retrieved 26 January 2020.
  14. ^ "Todd Humphreys: Don't Overregulate Drones". Alcalde. 18 March 2015. Retrieved 5 April 2015.
  15. ^ Schumer, Charles (19 August 2015). "Schumer proposes law". Retrieved 15 December 2015.
  16. ^ Hamid Jahankhani, A G Hessami, Feng Hsu: Global security, safety, and sustainability : 5th international conference, ICGS3 2009, London, UK, 1–2 September 2009 : proceedings. ISBN 978-3-642-04061-0
  17. ^ Kim, Victoria (8 September 2023). "Elon Musk Acknowledges Withholding Satellite Service to Thwart Ukrainian Attack". The New York Times. ISSN 0362-4331. Retrieved 10 September 2023.
  18. ^ Norfleet, Nicole (29 April 2022). "Target pays $5 million in settlement over pricing accuracy allegations". Star Tribune. Retrieved 29 April 2022.

Further reading

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  • De Lara, Eyal; Anthony LaMarca, Mahadev Satyanarayanan (2008). Location Systems: An Introduction to the Technology Behind Location Awareness. Morgan & Claypool Publishers. p. 88. ISBN 978-1-59829-581-8.
  • Anthony C. Ijeh, Allan J. Brimicombe, David S. Preston, Chris O. Imafidon (2009) "Geofencing in a Security Strategy Model." In Global Safety and Sustainability: 5th International Conference Proceedings. Jahankhani, H.; Hessami, A.G.; Hsu, F. (Eds.) p.104-111 © Springer-Verlag Berlin Heidelberg 2009. ISBN 978-3-642-04061-0