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http://dx.doi.org/10.3837/tiis.2021.10.013

Classifying Indian Medicinal Leaf Species Using LCFN-BRNN Model  

Kiruba, Raji I (Department of CSE, R.M.D Engineering College)
Thyagharajan, K.K (Department of ECE, R.M.D Engineering College)
Vignesh, T (Department of Master of Computer Application SRM Institute of Science and Technology)
Kalaiarasi, G (Department of Computer Science and Engineering, Sathyabama Institute of Science and Technology)
Publication Information
KSII Transactions on Internet and Information Systems (TIIS) / v.15, no.10, 2021 , pp. 3708-3728 More about this Journal
Abstract
Indian herbal plants are used in agriculture and in the food, cosmetics, and pharmaceutical industries. Laboratory-based tests are routinely used to identify and classify similar herb species by analyzing their internal cell structures. In this paper, we have applied computer vision techniques to do the same. The original leaf image was preprocessed using the Chan-Vese active contour segmentation algorithm to efface the background from the image by setting the contraction bias as (v) -1 and smoothing factor (µ) as 0.5, and bringing the initial contour close to the image boundary. Thereafter the segmented grayscale image was fed to a leaky capacitance fired neuron model (LCFN), which differentiates between similar herbs by combining different groups of pixels in the leaf image. The LFCN's decay constant (f), decay constant (g) and threshold (h) parameters were empirically assigned as 0.7, 0.6 and h=18 to generate the 1D feature vector. The LCFN time sequence identified the internal leaf structure at different iterations. Our proposed framework was tested against newly collected herbal species of natural images, geometrically variant images in terms of size, orientation and position. The 1D sequence and shape features of aloe, betel, Indian borage, bittergourd, grape, insulin herb, guava, mango, nilavembu, nithiyakalyani, sweet basil and pomegranate were fed into the 5-fold Bayesian regularization neural network (BRNN), K-nearest neighbors (KNN), support vector machine (SVM), and ensemble classifier to obtain the highest classification accuracy of 91.19%.
Keywords
Chan-Vese segmentation; Leaky Capacitance and Fired Neuron (LCFN); time sequence; Bayesian Regularization Neural Network (BRNN); computer vision;
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