Censusing and monitoring black rhino (Diceros bicornis) using an objective spoor (footprint) identification technique

An objective, non-invasive technique was developed for identifying individual black rhino from their footprints (spoor). Digital images were taken of left hind spoor from tracks (spoor pathways) of 15 known black rhino in Hwange National Park, Zimbabwe. Thirteen landmark points were manually placed on the spoor image and from them, using customized software, a total of 77 measurements (lengths and angles) were generated. These were subjected to discriminant and canonical analyses. Discriminant analysis of spoor measurements from all 15 known animals, employing the 30 measurements with the highest F-ratio values, gave very close agreement between assigned and predicted classification of spoor. For individual spoor, the accuracy of being assigned to the correct group varied from 87% to 95%. For individual tracks, the accuracy level was 88%. Canonical analyses were based on the centroid plot method, which does not require pre-assigned grouping of spoor or tracks. The first two canonical variables were used to generate a centroid plot with 95% confidence ellipses in the test space. The presence or absence of overlap between the ellipses of track pairs allowed the classification of the tracks. Using a new ‘reference centroid value’ technique, the level of accuracy was high (94%) when individual tracks were compared against whole sets (total number of spoor for each rhino) but low (35%) when tracks were compared against each other. Since tracks with fewer spoor were more likely to be misclassified, track sizes were then artificially increased by summing smaller tracks for the same rhino. The modified tracks in a pairwise comparison gave an accuracy of 93%. The advantages, limitations and practical applications of the spoor identification technique are discussed in relation to censusing and monitoring black rhino populations.

[1]  M. Watve,et al.  Tiger census: role of quantification , 1993 .

[2]  N. Strien Report on a preparatory mission for the implementation of the "Singapore proposals" for captive breeding of Sumatran rhinoceros (Dicerorhinus sumatrensis) as part of a conservation strategy for the species , 1985 .

[3]  K. S. Smallwood,et al.  A rigorous technique for identifying individual mountain lions Felis concolor by their tracks , 1993 .

[4]  R. Schenkel,et al.  The Javen rhinoceros (Rh. sondaicus Desm.) in Udjung Kulon Nature Reserve. Its ecology and behavior. Field study 1967 and 1968. , 1969, Acta tropica.

[5]  N. L. Johnson,et al.  Multivariate Analysis , 1958, Nature.

[6]  Byron K. Williams,et al.  Some Observations of the Use of Discriminant Analysis in Ecology , 1983 .

[7]  K. ESTIMATING TIGER Panthera tigris POPULATIONS FROM CAMERA-TRAP DATA USING CAPTURE RECAPTURE MODELS , 2022 .

[8]  P. Stander Spoor counts as indices of large carnivore populations: the relationship between spoor frequency, sampling effort and true density , 1998 .

[9]  Philip Riordan,et al.  Unsupervised recognition of individual tigers and snow leopards from their footprints , 1998 .

[10]  S. Alibhai,et al.  Effects of immobilization on fertility in female black rhino ( Diceros bicornis ) , 2001 .

[11]  L. Waits,et al.  Noninvasive genetic tracking of the endangered Pyrenean brown bear population , 1997, Molecular ecology.

[12]  Bryan F. J. Manly,et al.  Multivariate Statistical Methods : A Primer , 1986 .

[13]  P. Burman,et al.  Identifying individual mountain lions Felis concolor by their tracks: refinement of an innovative technique , 1999 .