Animal migration tracking

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Radio-collared wolf in Yellowstone National Park Canis lupus with radio collar.jpg
Radio-collared wolf in Yellowstone National Park
Employee of US Fish and Wildlife Service tracking a mountain lion tagged with a radio collar Tracking Mountain Lions.jpg
Employee of US Fish and Wildlife Service tracking a mountain lion tagged with a radio collar

Animal migration tracking is used in wildlife biology, conservation biology, ecology, and wildlife management to study animals' behavior in the wild. One of the first techniques was bird banding, placing passive ID tags on birds legs, to identify the bird in a future catch-and-release. Radio tracking involves attaching a small radio transmitter to the animal and following the signal with a RDF receiver. Sophisticated modern techniques use satellites to track tagged animals, and GPS tags which keep a log of the animal's location. With the Emergence of IoT the ability to make devices specific to the species or what is to be tracked is possible. One of the many goals of animal migration research has been to determine where the animals are going; however, researchers also want to know why they are going "there". Researchers not only look at the animals' migration but also what is between the migration endpoints to determine if a species is moving to new locations based on food density, a change in water temperature, or other stimulus, and the animal's ability to adapt to these changes. Migration tracking is a vital tool in efforts to control the impact of human civilization on populations of wild animals, and prevent or mitigate the ongoing extinction of endangered species.

Contents

Technologies

A monarch butterfly shortly after tagging at the Cape May Bird Observatory Cape May Bird Observatory is one of the organizations that has a monarch identification tagging program. Plastic stickers are placed on the wing of the insect with identification information. Tracking information is used to study the migration patterns of monarchs, including how far and where they fly. Monarch Butterfly Danaus plexippus Tagged Closeup 3008px.jpg
A monarch butterfly shortly after tagging at the Cape May Bird Observatory Cape May Bird Observatory is one of the organizations that has a monarch identification tagging program. Plastic stickers are placed on the wing of the insect with identification information. Tracking information is used to study the migration patterns of monarchs, including how far and where they fly.

In the fall of 1803, American Naturalist John James Audubon wondered whether migrating birds returned to the same place each year. So he tied a string around the leg of a bird before it flew south. The following spring, Audubon saw the bird had indeed come back.

Scientists today still attach tags, such as metal bands, to track movement of animals. Metal bands require the re-capture of animals for the scientists to gather data; the data is thus limited to the animal's release and destination points.

Recent technologies have helped solve this problem. Some electronic tags give off repeating signals that are picked up by radio devices or satellites while other electronic tags could include archival tags (or data loggers). Scientists can track the locations and movement of the tagged animals without recapturing them using this RFID technology or satellites. These electronic tags can provide a great deal of data. Modern technologies are also smaller, minimizing the negative impact of the tag on the animal. [1]

Radio tracking

The right one of these two brush-tailed rock-wallabies is wearing a radio tracking collar. Petrogale penicillata with radio tracking collar - journal.pone.0063017.g001A.png
The right one of these two brush-tailed rock-wallabies is wearing a radio tracking collar.

Tracking an animal by radio telemetry involves two devices. Telemetry, in general, involves the use of a transmitter that is attached to an animal and sends out a signal in the form of radio waves, just as a radio station does. [2] A scientist might place the transmitter around an animal's ankle, neck, wing, carapace, or dorsal fin. Alternatively, they may surgically implant it as internal radio transmitters have the advantage of remaining intact and functioning longer than traditional attachments, being protected from environmental variables and wear. [3] The transmitter typically uses a frequency in the VHF band as antennas in this band are conveniently small. To conserve battery power the transmitter usually transmits brief pulses, perhaps one per second. A specialized radio receiver called a radio direction finding (RDF) receiver picks up the signal. The receiver is usually in a truck, an ATV, or an airplane. [2] The receiver has a directional antenna (usually a simple Yagi antenna) which receives most strongly from a single direction, and some means of indicating the strength of the received signal, either by a meter or by the loudness of the pulses in earphones. The antenna is rotated until the received radio signal is strongest; then the antenna is pointing toward the animal. To keep track of the signal, the scientist follows the animal using the receiver. This approach of using radio tracking can be used to track the animal manually but is also used when animals are equipped with other payloads. The receiver is used to home in on the animal to get the payload back.

Another form of radio tracking that can be utilized, especially in the case of small bird migration, is the use of geolocators or "geologgers". [4] This technology utilizes a light sensor that tracks the light-level data during regular intervals in order to determine a location based on the length of the day and the time of solar noon. [4] While there are benefits and challenges with using this method of tracking, it is one of the only practical means of tracking small birds over long distances during migration. [4] [5]

Passive integrated transponders (PIT) are another method of telemetry used to track the movements of a species [4] Passive integrated transponders, or "PIT tags", are electronic tags that allow researchers to collect data from a specimen without the need to recapture and handle the animal. [6] Data is captured and monitored via electronic interrogation antennae, which records the time and location of the individual. [6] Pit tags are a humane method of tracking that has little risk of infection or mortality due to the limited contact necessary to monitor the specimens. They are also cost-efficient in that they can be used repeatedly should the need arise to remove the tag from the animal. [7]

Motus wildlife tracking network is a program by Birds Canada, it was launched in 2014 in the US and Canada, by 2022 there are more than 40,000 transmitters on various animals, mostly birds, and 1,500 receiver stations have been installed in 34 countries, most receivers are concentrated in the United States and Canada.

Satellite tracking

A saltwater crocodile with GPS-based satellite transmitter for migration tracking Crocodylus porosus with GPS-based satellite transmitter attached to the nuchal rosette - journal.pone.0062127.g002.png
A saltwater crocodile with GPS-based satellite transmitter for migration tracking

Receivers can be placed in Earth-orbiting satellites such as ARGOS. Networks, or groups, of satellites are used to track animals. Each satellite in a network picks up electronic signals from a transmitter on an animal. Together, the signals from all satellites determine the precise location of the animal. The satellites also track the animal's path as it moves. Satellite tracking is especially useful because the scientists do not have to follow after the animal nor do they have to recover the tag to get the data on where the animal is going or has gone. Satellite networks have tracked the migration and territorial movements of caribou, sea turtles, [8] whales, great white sharks, seals, elephants, bald eagles, ospreys and vultures. Additionally Pop-up satellite archival tags are used on marine mammals and various species of fish. There are two main systems, the above-mentioned Argos and the GPS. [9] Thanks to these systems, conservationists can find the key sites for migratory species. [9] Another form of satellite tracking would be the use of acoustic telemetry. This involves the use of electronic tags that emit sound in order for the researchers to track and monitor an animal within three dimensions, which is helpful in instances when large quantities of a species are being tracked at a time. [10]

IoT Tracking

IoT or the internet of things proves to be a potential resource for the future of wildlife tracking and research. This technology can range from Low Power Wide Area LWPA sensor networks attached to wildlife by safe adhesive to Cameras connected to the internet using machine learning to determine what images are interesting and categorize the photos. With LWPA, the applications are endless. All that needs to be done is to develop the sensors that attach to any animal. With the sensor's low power, changing the sensors’ batteries becomes less of a problem. The program Where's The Bear is a wildlife monitoring software by the Computer Science Department at the University of California Santa Barba. They use cameras as their sensors and machine learning to quantify the photos into empty pictures triggered by wind and rain. They are instead reporting those of different species of animals. To make the training process of the algorithm rapid, they used edited photos with animals inserted in the shot of the given sensors view to sense the different animals. This training was able to make the technology more accurate with fewer false positives and false negatives. This method increased the ability to categorize animals’ photos, proving a potential new technology for vast groups of people for commercial and public use

Stable isotopes

Sea turtle eggs being laid by the mother. Unhatched eggs can be used in stable isotope analysis. Logger eggs 01.jpg
Sea turtle eggs being laid by the mother. Unhatched eggs can be used in stable isotope analysis.

Stable isotopes are one of the intrinsic markers used for studying migration of animals. [11] One of the benefits of intrinsic markers in general, including stable isotope analysis, is that it does not require an organism to be captured and tagged and then recaptured at a later time. Each capture of an organism provides information on where it has been based on diet. The three types of intrinsic markers that can be used as tools for animal migration studies are: (1) contaminants, parasites and pathogens, (2) trace elements, and (3) stable isotopes. Certain geographic regions have specific stable isotope ratios that affect the chemistry of organisms foraging in those locations, this creates "isoscapes" that scientists can use to understand where the organism has been eating. A couple prerequisites must be met in order to use stable isotope analysis successfully: (1) the animal must have at least one light isotope of interest in specific tissues that can be sampled (this condition is almost always met since these light isotopes are building blocks of most animal tissues), and (2) the organism needs to migrate between isotopically different regions and these isotopes must be retained in the tissue in order for the differences to be measured. [11]

Stable isotope analysis has a lot of benefits and has been used in terrestrial and aquatic organisms. For example, stable isotope analysis has been confirmed to work in determining foraging locations of nesting loggerhead sea turtles. [12] Satellite telemetry was used to confirm that the location derived from the analysis were accurate to where these turtles actually traveled. This is important because it allows for greater sample sizes to be used in migration studies, since satellite telemetry is expensive and tissue, blood, and egg samples can be taken from the female turtles laying eggs. [12]

Importance

Electronic tags are giving scientists a complete, accurate picture of migration patterns. For example, when scientists used radio transmitters to track one herd of caribou, they learned two important things. First, they learned that the herd moves much more than previously thought. Second, they learned that each year the herd returns to about the same place to give birth. This information would have been difficult or impossible to obtain with "low tech" tags.

Tracking migrations is an important tool to better understand and protect species. For example, Florida manatees are an endangered species, and therefore they need protection. Radio tracking showed that Florida manatees may travel as far as Rhode Island when they migrate. This information suggests that the manatees may need protection along much of the Atlantic Coast of the United States. Previously, protection efforts focused mainly in the Florida area.

In the wake of the BP oil spill, efforts in tracking animals has increased in the Gulf. Most researchers who use electronic tags have only a few options: pop-up satellite tags, archival tags, or satellite tags. Historically these tags were generally expensive and could cost several thousands of dollars per tag. However, with current advancements in technology prices are now allowing researchers to tag more animals. With this increase in the number of species and individuals that can be tagged it is important to record and acknowledge the potential negative effects these devices might have. [13] [14]

See also

Related Research Articles

<span class="mw-page-title-main">Telemetry</span> Data and measurements transferred from a remote location to receiving equipment for monitoring

Telemetry is the in situ collection of measurements or other data at remote points and their automatic transmission to receiving equipment (telecommunication) for monitoring. The word is derived from the Greek roots tele, 'remote', and metron, 'measure'. Systems that need external instructions and data to operate require the counterpart of telemetry: telecommand.

<span class="mw-page-title-main">Bird ringing</span> Attachment of tag to a wild bird to enable individual identification

Bird ringing (UK) or bird banding (US) is the attachment of a small, individually numbered metal or plastic tag to the leg or wing of a wild bird to enable individual identification. This helps in keeping track of the movements of the bird and its life history. It is common to take measurements and examine conditions of feather molt, subcutaneous fat, age indications and sex during capture for ringing. The subsequent recapture or recovery of the bird can provide information on migration, longevity, mortality, population, territoriality, feeding behavior, and other aspects that are studied by ornithologists. Other methods of marking birds may also be used to allow for field based identification that does not require capture.

Automatic vehicle location is a means for automatically determining and transmitting the geographic location of a vehicle. This vehicle location data, from one or more vehicles, may then be collected by a vehicle tracking system to manage an overview of vehicle travel. As of 2017, GPS technology has reached the point of having the transmitting device be smaller than the size of a human thumb, able to run 6 months or more between battery charges, easy to communicate with smartphones — all for less than $20 USD.

Passive radar is a class of radar systems that detect and track objects by processing reflections from non-cooperative sources of illumination in the environment, such as commercial broadcast and communications signals. It is a specific case of bistatic radarpassive bistatic radar (PBR) – which is a broad type also including the exploitation of cooperative and non-cooperative radar transmitters.

Biotelemetry involves the application of telemetry in biology, medicine, and other health care to remotely monitor various vital signs of ambulatory patients.

Acoustic tags are small sound-emitting devices that allow the detection and/or remote tracking of organisms in aquatic ecosystems. Acoustic tags are commonly used to monitor the behavior of fish. Studies can be conducted in lakes, rivers, tributaries, estuaries or at sea. Acoustic tag technology allows researchers to obtain locational data of tagged fish: depending on tag and receiver array configurations, researchers can receive simple presence/absence data, 2D positional data, or even 3D fish tracks in real-time with sub-meter resolutions.

<span class="mw-page-title-main">Animal migration</span> Periodic large-scale movement of animals, usually seasonal

Animal migration is the relatively long-distance movement of individual animals, usually on a seasonal basis. It is the most common form of migration in ecology. It is found in all major animal groups, including birds, mammals, fish, reptiles, amphibians, insects, and crustaceans. The cause of migration may be local climate, local availability of food, the season of the year or for mating.

<span class="mw-page-title-main">GPS animal tracking</span> Remotely observe movement or migratory patterns in a wild animal using the Global Positioning System

GPS animal tracking is a process whereby biologists, scientific researchers, or conservation agencies can remotely observe relatively fine-scale movement or migratory patterns in a free-ranging wild animal using the Global Positioning System (GPS) and optional environmental sensors or automated data-retrieval technologies such as Argos satellite uplink, mobile data telephony or GPRS and a range of analytical software tools.

<span class="mw-page-title-main">Radio</span> Technology of using radio waves to carry information

Radio is the technology of communicating using radio waves. Radio waves are electromagnetic waves of frequency between 3 hertz (Hz) and 300 gigahertz (GHz). They are generated by an electronic device called a transmitter connected to an antenna which radiates the waves. They are received by another antenna connected to a radio receiver. In addition to communication, radio is used for radar, radio navigation, remote control, remote sensing, and other applications.

<span class="mw-page-title-main">GIS and aquatic science</span> Implementation of Geographic Information System

Geographic Information Systems (GIS) has become an integral part of aquatic science and limnology. Water by its very nature is dynamic. Features associated with water are thus ever-changing. To be able to keep up with these changes, technological advancements have given scientists methods to enhance all aspects of scientific investigation, from satellite tracking of wildlife to computer mapping of habitats. Agencies like the US Geological Survey, US Fish and Wildlife Service as well as other federal and state agencies are utilizing GIS to aid in their conservation efforts.

<span class="mw-page-title-main">Pop-up satellite archival tag</span> Form of electronic tracking of marine animals

Pop-up satellite archival tags (PSATs) are used to track movements of marine animals. A PSAT is an archival tag that is equipped with a means to transmit the collected data via the Argos satellite system. Though the data are physically stored on the tag, its major advantage is that it does not have to be physically retrieved like an archival tag for the data to be available making it a viable, fishery independent tool for animal behavior and migration studies. They have been used to track movements of ocean sunfish, marlin, blue sharks, bluefin tuna, swordfish and sea turtles to name a few species. Location, depth, temperature, oxygen levels, and body movement data are used to answer questions about migratory patterns, seasonal feeding movements, daily habits, and survival after catch and release, for examples.

A data storage tag (DST), also sometimes known as an archival tag, is a combination of a data logger and multiple sensors that record data at predetermined intervals. DSTs usually have a large memory size and a long lifetime: most are supported by batteries that allow the tag to record positions for several years. Alternatively some tags are solar powered and allow the scientist to set their own interval; this then allows data to be recorded for significantly longer than battery-only powered tags.

Tour de Turtles: A Sea Turtle Migration Marathon, or simply Tour de Turtles, is an annual online migration-tracking event hosted by the Caribbean Conservation Corporation. Endangered sea turtles are monitored using an attached but harmless satellite tracking device. Caribbean Conservation Corporation biologists gather satellite tracking information in order to better understand sea turtle migration patterns. Understanding sea turtle migration patterns would allow for sea turtle conservation groups to lobby for more sea turtle protection in proven areas with higher sea turtle populations. Sea turtles are the participants for the Tour de Turtle marathon. Participating sea turtles are tracked as they race to be the first to complete a 2,620-kilometre (1,628 mi) journey that is estimated to last three months. Tour de Turtles aims to increase awareness about different sea turtle species and the threats to their survival. The turtle to first swim the 1,628 miles wins the marathon.

<span class="mw-page-title-main">Light level geolocator</span>

A light level geolocator, light-level logger or global location sensor (GLS) is a lightweight, electronic archival tracking device, usually used in bird migration research to map migration routes, identify important staging areas, and sometimes provide additional ecological information. A geolocator periodically records ambient light level to determine location.

<span class="mw-page-title-main">RF module</span> Electronic device to transmit and receive RF signals

An RF module is a (usually) small electronic device used to transmit and/or receive radio signals between two devices. In an embedded system it is often desirable to communicate with another device wirelessly. This wireless communication may be accomplished through optical communication or through radio-frequency (RF) communication. For many applications, the medium of choice is RF since it does not require line of sight. RF communications incorporate a transmitter and a receiver. They are of various types and ranges. Some can transmit up to 500 feet. RF modules are typically fabricated using RF CMOS technology.

The history of wildlife tracking technology involves the evolution of technologies that have been used to monitor, track, and locate many different types of wildlife. Many individuals have an interest in tracking wildlife, including biologists, scientific researchers, and conservationists. Biotelemetry is "the instrumental technique for gaining and transmitting information from a living organism and its environment to a remote observer".

<span class="mw-page-title-main">ICARUS Initiative</span>

The ICARUS Initiative, short for International Cooperation for Animal Research Using Space, is an international effort to track the migratory patterns of small flying animals using radio transmitters. The project began in 2002 and the tracking system was installed on the International Space Station (ISS) in August 2018, switched on in July 2019, and began operations in September 2020. The director for the ICARUS project is Martin Wikelski, director of the Max Planck Institute of Animal Behavior in Radolfzell, Germany.

<span class="mw-page-title-main">Coded wire tag</span> Device used to tag and track animals

A coded wire tag (CWT) is an animal tagging device, most often used for identifying batches of fish. It consists of a length of magnetized stainless steel wire 0.25 mm in diameter and typically 1.1 mm long. The tag is marked with rows of numbers denoting specific batch or individual codes. The tag is usually injected into the snout or cheek of a fish so that it may be tracked for research or fisheries management.

<span class="mw-page-title-main">Wildlife radio telemetry</span> Tool to track the movement and behavior of animals

Wildlife radio telemetry is a tool used to track the movement and behavior of animals. This technique uses the transmission of radio signals to locate a transmitter attached to the animal of interest. It is often used to obtain location data on the animal's preferred habitat, home range, and to understand population dynamics. The different types of radio telemetry techniques include very high frequency (VHF) transmitters, global positioning system (GPS) tracking, and satellite tracking. Recent advances in technology have improved radio telemetry techniques by increasing the efficacy of data collection. However, studies involving radio telemetry should be reviewed in order to determine if newer techniques, such as collars that transmit the location to the operator via satellites, are actually required to accomplish the goals of the study.

<span class="mw-page-title-main">Motus (wildlife tracking network)</span> Wildlife tracking network

Motus is a network of radio receivers for tracking signals from transmitters attached to wild animals. Motus uses radio telemetry for real-time tracking. It was launched by Birds Canada in 2014 in the US and Canada.

References

  1. Kingdon, Amorina (22 January 2018). "Are Scientific Tracking Tags Hurting Wild Animals?". Hakai Magazine . Retrieved 26 January 2018.
  2. 1 2 "Technology and Development at the USDA Forest Service, Satellite/GPS Telemetry for Monitoring Lesser Prairie Chickens". www.fs.fed.us. Retrieved 2017-03-02.
  3. Original text (in public domain):"Internal radio transmitters have the advantage of remaining intact and functioning longer than traditional attachments. Implanted transmitters also are protected from extrinsic variables such as environmental elements and wear (Eagle et al. 1984)." (Lander et al. 2005) http://digitalcommons.unl.edu/cgi/viewcontent.cgi?article=1191&context=usdeptcommercepub (accessed 29 November 2012)
  4. 1 2 3 4 "Animal Migration Research, Jeff Kelly Lab". www.animalmigration.org. Retrieved 2017-03-02.
  5. Stutchbury, Bridget J. M.; Tarof, Scott A.; Done, Tyler; Gow, Elizabeth; Kramer, Patrick M.; Tautin, John; Fox, James W.; Afanasyev, Vsevolod (2009-02-13). "Tracking Long-Distance Songbird Migration by Using Geolocators". Science. 323 (5916): 896. Bibcode:2009Sci...323..896S. doi:10.1126/science.1166664. ISSN   0036-8075. PMID   19213909. S2CID   34444695.
  6. 1 2 "PIT Tag Information Systems (PTAGIS) | Pacific States Marine Fisheries Commission". www.psmfc.org. Retrieved 2017-03-02.
  7. "Passive Integrated Transponder (PIT) Tags in the Study of Animal Movement | Learn Science at Scitable". www.nature.com. Retrieved 2017-03-02.
  8. SEATURTLE.ORG - Global Sea Turtle Network
  9. 1 2 Northern Bald Ibis Project
  10. "Acoustic Telemetry Fisheries Research". www.htisonar.com. Retrieved 2017-03-02.
  11. 1 2 Tracking animal migration with stable isotopes. Hobson, Keith Alan, 1954-, Wassenaar, Leonard I. Amsterdam: Academic Press. 2008. ISBN   9780123738677. OCLC   228300275.{{cite book}}: CS1 maint: others (link)
  12. 1 2 Ceriani, Simona A.; Roth, James D.; Evans, Daniel R.; Weishampel, John F.; Ehrhart, Llewellyn M. (2012-09-20). "Inferring Foraging Areas of Nesting Loggerhead Turtles Using Satellite Telemetry and Stable Isotopes". PLOS ONE. 7 (9): e45335. Bibcode:2012PLoSO...745335C. doi: 10.1371/journal.pone.0045335 . ISSN   1932-6203. PMC   3447946 . PMID   23028943.
  13. Bell, S. C.; El Harouchi, M.; Hewson, C. M.; Burgess, M. D. (2017). "No short- or long-term effects of geolocator attachment detected in Pied Flycatchers Ficedula hypoleuca". Ibis. 159 (4): 734–743. doi:10.1111/ibi.12493.
  14. Weiser, E. L.; et al. (2016). "Effects of geolocators on hatching success, return rates, breeding movements, and change in body mass in 16 species of Arctic-breeding shorebirds". Movement Ecology. 4 (12): 734–743. doi:10.1111/ibi.12493. PMC   4850671 . PMID   27134752.