GenTag-package {GenTag}R Documentation

Generate Color Tag Sequences

Description

Implement a coherent and flexible protocol for animal color tagging. 'GenTag' provides a simple computational routine with low CPU usage to create color sequences for animal tag. First, a single-color tag sequence is created from an algorithm selected by the user, followed by verification of the combination uniqueness. Three methods to produce color tag sequences are provided. Users can modify the main function core to allow a wide range of applications.

Details

The DESCRIPTION file:

Package: GenTag
Type: Package
Title: Generate Color Tag Sequences
Version: 1.0
Date: 2019-06-21
Author: Carlos Biagolini-Jr.
Maintainer: Carlos Biagolini-Jr.<c.biagolini@gmail.com>
Description: Implement a coherent and flexible protocol for animal color tagging. 'GenTag' provides a simple computational routine with low CPU usage to create color sequences for animal tag. First, a single-color tag sequence is created from an algorithm selected by the user, followed by verification of the combination uniqueness. Three methods to produce color tag sequences are provided. Users can modify the main function core to allow a wide range of applications.
License: GPL (>= 2)

Index of help topics:

GenTag-package          Generate Color Tag Sequences
allequal                All equal tag sequence sample
erc                     Estimates remaining color
escode                  Empty synonym code
escombination           Empty synonym combination
esdataset               Empty synonym dataset
genseq                  Color tag combination generator
lifexp                  Life expectancy tag sequence sample
pre_used                Pre-used combinations combinations
scy                     Summary color year
vfrequency              Variable frequency tag sequence sample

Implement a coherent and flexible protocol for animal color tagging. 'GenTag' provides a simple computational routine with low CPU usage to create color sequences for animal tag. First, a single-color tag sequence is created from an algorithm selected by the user, followed by verification of the combination uniqueness. Three methods to produce color tag sequences are provided. Users can modify the main function core to allow a wide range of applications.

Author(s)

Carlos Biagolini-Jr.

Maintainer: Carlos Biagolini-Jr.<c.biagolini@gmail.com>

References

Alisauskas & Lindberg (2002). Effects of neckbands on survival and fidelity of White-fronted and Canada geese captured as non-breeding adults. doi: 10.1080/02664760120108575 Broughton (2015). Low incidence of leg and foot injuries in colour-ringed Marsh tits Poecile palustris. doi: 10.1080/03078698.2015.1059610 Burley (1986). Sex-ratio manipulation in color-banded populations of Zebra finches. doi: 10.1111/j.1558-5646.1986.tb05744.x Burley, Krantzberg & Radman (1982). Influence of colour-banding on the conspecific preferences of Zebra finches. doi: 10.1016/S0003-3472(82)80055-9 Calvo & Furness (1992). A review of the use and the effects of marks and devices on birds. doi: 10.1080/03078698.1992.9674036 Cresswell, Lind, Quinn, Minderman & Whitfield, (2007). Ringing or colour-banding does not increase predation mortality in Redshanks Tringa totanus. doi: 10.1111/j.2007.0908-8857.3925.x Cuthill, Hunt, Cleary, & Clark (1997). Colour bands, dominance, and body mass regulation in male Zebra finches (Taeniopygia guttata). doi: 10.1098/rspb.1997.0151 Fiske & Amundsen (1997). Female bluethroats prefer males with symmetric colour bands. doi: 10.1006/anbe.1996.0436 Gil, Graves, Hazon, & Wells, (1999). Male attractiveness and differential testosterone investment in Zebra finch eggs. doi: 10.1126/science.286.5437.126 Griesser, Schneider, Collis, Overs, Guppy, Guppy, Takeuchi, Collins, Peters & Hall (2012). Causes of ring-related leg injuries in birds - evidence and recommendations from four field studies. doi: 10.1371/journal.pone.0051891 Jennions (1998). The effect of leg band symmetry on female-male association in Zebra finches. doi: 10.1006/anbe.1997.0579 Johnsen, Fiske, Amundsen, Lifjeld, & Rohde (2000). Colour bands, mate choice and paternity in the Bluethroat. doi: 10.1006/anbe.1999.1274 Johnsen, Lifjeld, & Rohde (1997). Coloured leg bands affect male mate-guarding behaviour in the Bluethroat. doi: 10.1006/anbe.1996.0437 Johnson, Dalton & Burley (1993). Preferences of female American goldfinches (Carduelis tristis) for natural and artificial male traits. doi: 10.1093/beheco/4.2.138 Kosinski (2004). The removal of colour rings by Greenfinches Carduelis chloris. doi: 10.1080/03078698.2004.9674304 McCrea & Morgan (2014). Analysis of capture-recapture data. Boca Raton, Chapman and Hall/CRC. Nietmann & Ha (2018). Site-specific incidence of ring-related injuries in Rufous fantails Rhipidura rufifrons. doi: 10.1080/03078698.2018.1505109 Pierce, Stevens, Mulder & Salewski (2007). Plastic colour rings and the incidence of leg injury in Flycatchers (Muscicapidae, Monarchidae). doi: 10.1080/03078698.2007.9674365 Schlich & Kempenaers (2018). The immediate impact of ringing, blood sampling and PIT-tag implanting on the behaviour of Blue tits Cyanistes caeruleus. doi: 10.5253/arde.v106i1.a8 Sedgwick & Klus (1997). Injury due to leg bands in Willow flycatchers. Song, Liu, Booksmythe & Ding (2017). Effects of individual-based preferences for colour-banded mates on sex allocation in Zebra finches. doi: 10.1093/beheco/arx069 Sutherland (2006). Ecological census techniques: a handbook (2nd ed.). New York, Cambridge University Press. Weiser et al (2018). Effects of leg flags on nest survival of four species of Arctic-breeding shorebirds. doi: 10.1111/jofo.12264 Zann (1994). Effects of band color on survivorship, body condition and reproductive effort of free-living Australian Zebra finches. doi: 10.2307/4088512

Examples

genseq(30, 4,c("Black","Blue","Brown","Gray","Green"))

[Package GenTag version 1.0 Index]