Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Australian Systematic Botany Australian Systematic Botany Society
Taxonomy, biogeography and evolution of plants
Shopping Cart: ( empty )
You are here: Home > Journals > SB > SB08003
RESEARCH ARTICLE
Contents Vol 22(1)

Phyllometric parameters and artificial neural networks for the identification of Banksia accessions

Giuseppe Messina A B , Camilla Pandolfi A , Sergio Mugnai A C , Elisa Azzarello A , Kingsley Dixon B and Stefano Mancuso A
+ Author Affiliations
- Author Affiliations

A Department of Horticulture, University of Florence, Viale delle Idee 30, 50019 Sesto Fiorentino (FI), Italy.

B School of Plant Biology, University of Western Australia, 35 Stirling Highway, Crawley, WA 6907, Australia.

C Corresponding author. Email: sergio.mugnai@unifi.it

Australian Systematic Botany 22(1) 31-38 https://doi.org/10.1071/SB08003
Submitted: 15 January 2008  Accepted: 19 January 2009   Published: 11 March 2009

Abstract

Taxonomic identification is traditionally carried out with dichotomous keys, or at least computer-based identification keys, often on the basis of subjective visual assessment and frequently unable to detect small differences at subspecies and varietal ranks. The aims of the present work were to (1) clearly discriminate a wide group of accessions (species, subspecies and varieties) belonging to the genus Banksia on the basis of 14 phyllometric parameters determined by image analysis of the leaves, and (2) unequivocally identify the accessions with a relatively simple back-propagation neural-network (BPNN) architecture (single hidden layer) in order to develop a complementary method for fast botanical identification. The results indicate that this kind of network could be effectively and successfully used to discriminate among Banksia accessions, as the BPNN enabled a 93% unequivocal and correct simultaneous identification. Our BPNN had the advantage of being able to resolve subtle associations between characters, and of making incomplete data (i.e. absence of Banksia flower parameters such as the colour or size of styles) useful in species diagnostics. This method is relatively useful; it is easy to execute as no particular competences are necessary, equipment is low cost (scanner connected to a PC and software available as freeware) and data acquisition is fast and effective.


Acknowledgements

The authors thank Kings Park and Botanic Garden staff (Dr Matthew Barrett, Russell Barrett, Mr Bob Dixon) and the institution for hosting this project (providing plant material, scanner, travelling expenses) and for assistance with the identification of Banksia; Mr and Mrs Collins, owners of ‘The Banksia Farm’, for access to their collection of Banksia species from eastern Australia.


References


Al-Haddad L, Morris CW, Boddy L (2000) Training radial basis function neural networks: effects of training set size and imbalanced training sets. Journal of Microbiological Methods 43, 33–44.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed | open url image1

Balfoort HW, Snoek J, Smits JRM, Breedveld LW, Hofstraat JW, Ringelberg J (1992) Automatic identification of algae: neural network analysis of flow cytometric data. Journal of Plankton Research 14, 575–589.
Crossref | GoogleScholarGoogle Scholar | open url image1

Boddy L, Morris CW, Wilkins MF, Al-Haddad L, Tarran GA, Jonker RR, Burkill PH (2000) Identification of 72 phytoplankton species by radial basis function neural network analysis of flow cytometric data. Marine Ecology Progress Series 195, 47–59.
Crossref | GoogleScholarGoogle Scholar | open url image1

Chesmore D (2000) Methodologies for automating the identification of species. In ‘Proceedings of inaugural meeting of the BioNET-INTERNATIONAL group for computer-aided taxonomy (BIGCAT)’. (Eds D Chesmore, L Yorke, P Bridge, S Gallagher) pp. 3–12. BioNET-INTERNATIONAL Monthly Bulletin. (BioNET-INTERNATIONAL: London)

Chesmore D (2007) The automated identification of taxa: concepts and applications. In ‘Automated taxon identification in systematics: theory, approaches and applications’. (Ed. N MacLeod) pp. 83–100. (CRC Press: Boca Raton, FL)

Chesmore D, Ohya E (2004) Automated identification of field-recorded songs of four British grasshoppers using bioacoustic signal recognition. Bulletin of Entomological Research 94, 319–330.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed | open url image1

Clark JY (2003) Artificial neural network for species identification by taxonomists. Biosystems 72, 131–147.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Clark JY (2004) Identification of botanical specimens using artificial neural networks. In ‘Proceedings of the 2004 IEEE symposium on computational intelligence in bioinformatics and computational biology (CIBCB)’. pp. 87–94. (CIBCB: La Jolla, CA)

Clark JY, Warwick K (1998) Artificial keys for botanical identification using a multilayer perceptron neural network (MLP). Artificial Intelligence Review 12, 95–115.
Crossref | GoogleScholarGoogle Scholar | open url image1

Do MT, Harp JM, Norris KC (1999) A test of a pattern recognition system for identification of spiders. Bulletin of Entomological Research 89, 217–224.
Crossref | GoogleScholarGoogle Scholar | open url image1

Du JX, Huang DS, Wang XF, Gu X (2007) Shape recognition based on neural networks trained by differential evolution algorithm. Neurocomputing 70, 896–903. open url image1

Gaston KJ, O’Neill MA (2004) Automated species identification: why not? Philosophical Transactions of the Royal Society of London. B 359, 655–667.
Crossref | GoogleScholarGoogle Scholar | open url image1

George AS (1981) The genus Banksia L.f. (Proteaceae). Nuytsia 3, 239–473. open url image1

George AS (1988) New taxa and notes on Banksia L.f. (Proteaceae). Nuytsia 6, 309–317. open url image1

George AS (1999) Banksia. In ‘Flora of Australia. Vol. 17B, Proteaceae 3. Hakea to Dryandra’. (Ed. A Wilson) pp. 175–251. (ABRS/CSIRO: Melbourne)

Giacomini M, Ruggiero C, Calegari L, Bertone S (2000) Artificial neural network based identification of environmental bacteria by gas-chromatographic and electrophoretic data. Journal of Microbiological Methods 43, 45–54.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed | open url image1

Ginoris YP, Amaral AL, Nicolau A, Ferreira EC, Coelho MAZ (2007) Recognition of protozoa and metazoa using image analysis tools, discriminant analysis, neural networks and decision trees. Analytica Chimica Acta 595, 160–169.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed | open url image1

Hernández-Borges J, Corbella-Tena R, Rodriguez-Delgado MA, Garcia-Montelongo FJ, Havel J (2004) Content of aliphatic hydrocarbons in limpets as a new way for classification of species using artificial neural networks. Chemosphere 54, 1059–1069.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Mancuso S (2002) Discrimination of grapevine (Vitis vinifera L.) leaf shape by fractal spectrum. Vitis 41, 137–142. open url image1

Mancuso S, Nicese FP (1999) Identifying olive (Olea europaea L.) cultivars using artificial neural networks. Journal of the American Society for Horticultural Science 124, 527–531. open url image1

Mancuso S, Ferrini F, Nicese FP (1999) Chestnut (Castanea sativa L.) genotype identification: an artificial neural network approach. Journal of Horticultural Science & Biotechnology 74, 777–784. open url image1

Mariño SI, Tressens SG (2001) Artificial neural networks application in the identification of three species of Rollinia (Annonaceae). Annales Botanici Fennici 38, 215–224. open url image1

Mast AR, Givnish TJ (2002) Historical biogeography and the origin of stomatal distributions in Banksia and Dryandra (Proteaceae) based on their cpDNA phylogeny. American Journal of Botany 89, 1311–1323.
Crossref | GoogleScholarGoogle Scholar | CAS | open url image1

Mast AR, Thiele K (2007) The transfer of Dryandra R.Br. to Banksia L.f. (Proteaceae). Australian Systematic Botany 20, 63–71.
Crossref | GoogleScholarGoogle Scholar | open url image1

Mast AR, Jones EH, Havery SP (2005) An assessment of old and new DNA sequence evidence for the paraphyly of Banksia with respect to Dryandra (Proteaceae). Australian Systematic Botany 18, 75–88.
Crossref | GoogleScholarGoogle Scholar | CAS | open url image1

Morgan A, Boddy L, Mordue JEM, Morris CW (1998) Evaluation of artificial neural networks for fungal identification, employing morphometric data from spores of Pestalotiopsis species. Mycological Research 102, 975–984.
Crossref | GoogleScholarGoogle Scholar | open url image1

Morris CW, Boddy L, Allman R (1992) Identification of basidiomycete spores by neural network analysis of flow cytometry data. Mycological Research 96, 697–701.
Crossref |
open url image1

Mouwen DJM, Capita R, Alonso-Calleja C, Prieto-Gómez J, Prieto M (2006) Artificial neural network based identification of Campylobacter species by Fourier transform infrared spectroscopy. Journal of Microbiological Methods 67, 131–140.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed | open url image1

Mugnai S, Pandolfi C, Azzarello E, Masi E, Mancuso S (2008) Camellia japonica L. genotypes identified by an artificial neural network based on phyllometric and fractal parameters. Plant Systematics and Evolution 270, 95–108.
Crossref | GoogleScholarGoogle Scholar | open url image1

O’Neill MA (2007) DAISY: a practical computer-based tool for semi-automated species identification. In ‘Automated taxon identification in systematics: theory, approaches and applications’. (Ed. N MacLeod) pp. 101–113. (CRC Press: Boca Raton, FL)

Pandolfi C , Mugnai S , Azzarello E , Masi E , Mancuso S (2006) Fractal geometry and neural networks for the identification and characterization of ornamental plants. In ‘Floriculture, ornamental and plant biotechnology: advances and topical issues. Vol. IV’. (Ed. J Teixiera da Silva) pp. 213–225. (Global Science Books: Kyoto)

Sahin N, Aydin S (2006) Identification of oxalotrophic bacteria by neural network analysis of numerical phenetic data. Folia Microbiologica 51, 87–91.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed | open url image1

Smits JRM, Breedveld LW, Derksen MJW, Kateman G, Balfoort HW, Snoek J, Hofstraat JW (1992) Pattern classification with artificial neural networks: classification of algae, based upon flow cytometer data. Analytica Chimica Acta 258, 11–25.
Crossref | GoogleScholarGoogle Scholar | CAS | open url image1

Thiele K, Ladiges PY (1994) The Banksia integrifolia L.f. species complex (Proteaceae). Australian Systematic Botany 7, 393–408.
Crossref | GoogleScholarGoogle Scholar | open url image1

Thiele K, Ladiges PY (1996) A cladistic analysis of Banksia (Proteaceae). Australian Systematic Botany 9, 661–733.
Crossref | GoogleScholarGoogle Scholar | open url image1

Vaňhara J, Muráriková N, Malenovský I, Havel J (2007) Artificial neural networks for fly identification: a case study from the genera Tachina and Ectophasia (Diptera, Tachinidae). Biologia 62, 462–469.
Crossref | GoogleScholarGoogle Scholar | open url image1

Walsh S , MacLeod N , O’Neill MA (2007) O spot the penguin: can reliable taxonomic identifications be made using isolated foot bones? In ‘Automated taxon identification in systematics: theory, approaches and applications’. (Ed. N MacLeod) pp. 225–238. (CRC Press: Boca Raton, FL)

Weeks PJD, Gaston KJ (1997) Image analysis, neural networks, and the taxonomic impediment to biodiversity studies. Biodiversity and Conservation 6, 263–274.
Crossref | GoogleScholarGoogle Scholar | open url image1

Wheeler QD (2007) Digital innovation and taxonomy’s finest hour. In ‘Automated taxon identification in systematics: theory, approaches and applications’. (Ed. N MacLeod) pp. 18–23. (CRC Press: Boca Raton, FL)

Wilkins MF, Boddy L, Morris CW, Jonker RR (1999) Identification of phytoplankton from flow cytometry data by using radial basis function neural networks. Applied and Environmental Microbiology 65, 4404–4410.
CAS | PubMed |
open url image1

Zurada F , Jacek M (1992) ‘Introduction to artificial systems.’ (PWS Publishing: Pacific Grove, CA)