actel

^{of non-interactive code*}

Overview

If you are using acoustic telemetry to track animals as they move inside a study area or as they migrate somewhere, actel is the package for you. By bringing together the study area configuration and the recorded detections, actel provides a systematic way of analysing animal migration and residency data.

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Main functions:

1. explore()

explore() allows you to quickly get a summary of your data. You can use explore() to get a general feel for the study results, and check if the input files are behaving as expected. It is also a good candidate if you just want to validate your detections for later use in other analyses.

2. migration()

The migration() analysis runs the same initial checks as explore(), but on top of it, it analyses the animal behaviour. By selecting the arrays that lead to success, you can define whether or not your animals survived the migration. Additional plots help you find out if some animal/tag has been acting odd. Multiple options allow you to tweak the analysis to fit your study perfectly.

3. residency()

The residency() analysis runs the same initial checks as explore(), but, similarly to migration, explores particular points of the animal behaviour. If you want to know where your animals were in each day of the study, how many animals were in each section each day, and other residency-focused variables, this is the analysis you are looking for!

Unlock actel’s full potential

To truly learn how to operate actel, you must read the package vignettes. These have been arranged so that you can prepare your analysis as you learn; quite soon you will get your first results!

Here are some examples:

Movement tables:

Array	Detections	First station	Last station	First time	Last time	Time travelling	Time on array
River1	14	St.1	St.2	2019-05-15 10:30:00	2019-05-15 13:00:00	25:20:14	2:30:00
River2	3	St.4	St.4	2019-05-15 13:50:00	2019-05-15 14:40:00	0:50:00	0:50:00
River3	8	St.5	St.6	2019-05-15 16:00:00	2019-05-15 16:20:00	1:20:00	0:20:00
Fjord2	21	St.10	St.11	2019-05-16 15:10:00	2019-05-16 18:00:00	22:50:00	2:50:00
Sea1	1	St.18	St.18	2019-05-18 09:45:00	2019-05-18 09:45:00	15:45:00	0:00:00

Detection graphics

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Times of arrival and summary information

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Array efficiency and tag progression

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Individual residency

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Global residency

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Installing actel

CRAN version: 1.3.0

actel is available on CRAN. To install the latest stable version, simply run:

install.packages("actel")

Development version

If you would like to install the latest updates (which have not been integrated to CRAN yet), you can run the line below. Note that you need to have the package remotes installed!

remotes::install_github("hugomflavio/actel", build_opts = c("--no-resave-data", "--no-manual"), build_vignettes = TRUE)

Have a look at the manual:

After installing, you should read the manual, which can now be found in actel’s website.

Note:

If you are getting “pandoc document conversion” errors during the package installation, try installing the newest version of pandoc, restarting R and trying again.

^{* interactive code (i.e. code that expects user input) cannot be
tested automatically using codecov and, as such, was excluded from the
codecov scope.}

Works using or relating to actel

2023 (13)

Becker, A., Fielder, D. S., Lowry, M. B., & Taylor, M. D. (2023). Suitability of saltmarsh creeks as release locations for stocked Mulloway (Argyrosomus japonicus). Estuarine, Coastal and Shelf Science, 108455. https://doi.org/10.1016/j.ecss.2023.108455
Davey, J., Clarke, T. M., Niella, Y., Dennis, J. D., & Huveneers, C. (2023). Seasonal variation in space use and residency of the southern eagle ray Myliobatis tenuicaudatus in a temperate ecosystem. Marine Ecology Progress Series, 705, 77–94. https://doi.org/10.3354/meps14232
Davies, P., Britton, J. R., Castro-Santos, T., Crundwell, C., Dodd, J. R., Nunn, A. D., Velterop, R., & Bolland, J. D. (2023). Tracking anadromous fish over successive freshwater migrations reveals the influence of tagging effect, previous success and abiotic factors on upstream passage over barriers. Canadian Journal of Fisheries and Aquatic Sciences. https://doi.org/10.1139/cjfas-2022-0196
Dhellemmes, F., Aspillaga, E., Rittweg, T., Alós, J., Möller, P., & Arlinghaus, R. (2023). Body size scaling of space use in coastal pike (Esox lucius) in brackish lagoons of the southern Baltic Sea. Fisheries Research, 260, 106560. https://doi.org/10.1016/j.fishres.2022.106560
Dhellemmes, F., Aspillaga, E., & Monk, C. T. (2023). ATfiltR: A solution for managing and filtering detections from passive acoustic telemetry data. MethodsX, 10, 102222. https://doi.org/10.1016/j.mex.2023.102222
Flink, H., Tibblin, P., Hall, M., Hellström, G., & Nordahl, O. (2023). Variation among bays in spatiotemporal aggregation of Baltic Sea pike highlights management complexity. Fisheries Research, 259, 106579. https://doi.org/10.1016/j.fishres.2022.106579
Höhne, L., Freese, M., Pohlmann, J.-D., Diekmann, M., Fladung, E., Huisman, J. B. J., Hanel, R., & Marohn, L. (2023). Overestimating management progress—Modelled vs. Monitored silver eel escapement in a North Sea draining river. ICES Journal of Marine Science, fsad122. https://doi.org/10.1093/icesjms/fsad122
Huisman, J. B. J., Höhne, L., Hanel, R., Kuipers, H., Schollema, P. P., & Nagelkerke, L. (2023). Factors influencing the downstream passage of European silver eels (Anguilla anguilla) through a tidal sluice. Journal of Fish Biology, (in press). https://doi.org/10.1111/jfb.15398
Kraft, S., Gandra, M., Lennox, R. J., Mourier, J., Winkler, A. C., & Abecasis, D. (2023). Residency and space use estimation methods based on passive acoustic telemetry data. Movement Ecology, 11(1), 12. https://doi.org/10.1186/s40462-022-00364-z
Kressler, M. M., Dall, S. R. X., & Sherley, R. B. (2023). A framework for studying ecological energy in the contemporary marine environment. ICES Journal of Marine Science, 80(6), 1580–1593. https://doi.org/10.1093/icesjms/fsad082
Nordli, E., Strøm, J., Bøhn, T., Thorstad, E., Serra-Llinares, R., Nilsen, R., & Bjørn, P. (2023). Behaviour and habitat use of first-time migrant Arctic charr: Novel insights from a subarctic marine area. Marine Ecology Progress Series, 709, 77–90. https://doi.org/10.3354/meps14279
O’Connor, B. (2023). Linking spatial stream network modeling and telemetry data to investigate thermal habitat use by adult arctic grayling [Master of Science, University of Northern British Columbia]. https://doi.org/10.24124/2023/59378
van Leeuwen, C. H. A., de Leeuw, J. J., van Keeken, O. A., Volwater, J. J. J., Seljee, F., van Aalderen, R., van Emmerik, W. A. M., & Bakker, E. S. (2023). Multispecies fish tracking across newly created shallow and deep habitats in a forward-restored lake. Movement Ecology, 11(1), 43. https://doi.org/10.1186/s40462-023-00405-1

2022 (5)

Edwards, M. L., McCallister, M., Brewster, L. R., Bangley, C. W., Curtis, T. H., Ogburn, M. B., & Ajemian, M. J. (2022). Multi-year assessment of immature bull shark Carcharhinus leucas residency and activity spaces in an expansive estuarine nursery. Marine Ecology Progress Series, 695, 125–138. https://doi.org/10.3354/meps14113
Hewitt, D. E., Niella, Y., Johnson, D. D., Suthers, I. M., & Taylor, M. D. (2022). Crabs Go With the Flow: Declining Conductivity and Cooler Temperatures Trigger Spawning Migrations for Female Giant Mud Crabs (Scylla serrata) in Subtropical Estuaries. Estuaries and Coasts. https://doi.org/10.1007/s12237-022-01061-1
Hollins, J., Pettitt-Wade, H., Gallagher, C. P., Lea, E. V., Loseto, L. L., & Hussey, N. E. (2022). Distinct freshwater migratory pathways in Arctic char (Salvelinus alpinus) coincide with separate patterns of marine spatial habitat-use across a large coastal landscape. Canadian Journal of Fisheries and Aquatic Sciences. https://doi.org/10.1139/cjfas-2021-0291
Thorkildsen, T. B. (2022). Anadromous Arctic charr: Mapping of migration and habitat use in Isfjorden, Svalbard [Master thesis, Norwegian University of Life Sciences, Ås]. https://nmbu.brage.unit.no/nmbu-xmlui/handle/11250/3018496
Thorstensen, M. J., Vandervelde, C. A., Bugg, W. S., Michaleski, S., Vo, L., Mackey, T. E., Lawrence, M. J., & Jeffries, K. M. (2022). Non-Lethal Sampling Supports Integrative Movement Research in Freshwater Fish. Frontiers in Genetics, 13. https://www.frontiersin.org/articles/10.3389/fgene.2022.795355

2021 (7)

Flávio, H., & Baktoft, H. (2021). actel: Standardised analysis of acoustic telemetry data from animals moving through receiver arrays. Methods in Ecology and Evolution, 12(1), 196–203. https://doi.org/10.1111/2041-210X.13503
Flávio, H., Caballero, P., Jepsen, N., & Aarestrup, K. (2021). Atlantic salmon living on the edge: Smolt behaviour and survival during seaward migration in River Minho. Ecology of Freshwater Fish, 30(1), 61–72. https://doi.org/10.1111/eff.12564
Niella, Y., Smoothey, A. F., Taylor, M. D., Peddemors, V. M., & Harcourt, R. (2021). Environmental Drivers of Fine-Scale Predator and Prey Spatial Dynamics in Sydney Harbour, Australia, and Adjacent Coastal Waters. Estuaries and Coasts. https://doi.org/10.1007/s12237-021-01020-2
Nordli, E. (2021). The behaviour of anadromous Arctic charr during their first marine migration [Master thesis, Arctic University of Norway]. https://munin.uit.no/handle/10037/21752
Winter, E. R. (2021). The movement ecology of common bream Abramis brama in a highly connected wetland using acoustic telemetry. [Doctoral thesis, Bournemouth University]. http://eprints.bournemouth.ac.uk/35141/
Winter, E. R., Hindes, A. M., Lane, S., & Britton, J. R. (2021a). Movements of common bream Abramis brama in a highly connected, lowland wetland reveal sub-populations with diverse migration strategies. Freshwater Biology, 66(7), 1410–1422. https://doi.org/10.1111/fwb.13726
Winter, E. R., Hindes, A. M., Lane, S., & Britton, J. R. (2021b). Acoustic telemetry reveals strong spatial preferences and mixing during successive spawning periods in a partially migratory common bream population. Aquatic Sciences, 83(3), 52. https://doi.org/10.1007/s00027-021-00804-9

2020 (2)

Flávio, H., Kennedy, R., Ensing, D., Jepsen, N., & Aarestrup, K. (2020). Marine mortality in the river? Atlantic salmon smolts under high predation pressure in the last kilometres of a river monitored for stock assessment. Fisheries Management and Ecology, 27(1), 92–101. https://doi.org/10.1111/fme.12405
Niella, Y., Flávio, H., Smoothey, A. F., Aarestrup, K., Taylor, M. D., Peddemors, V. M., & Harcourt, R. (2020). Refined Shortest Paths (RSP): Incorporation of topography in space use estimation from node-based telemetry data. Methods in Ecology and Evolution, 11(12), 1733–1742. https://doi.org/10.1111/2041-210X.13484

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