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Ernest Valveny and 11 others. 2006. A general framework for the evaluation of symbol recognition methods.
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Ernest Valveny and Philippe Dosch. 2004. Symbol Recognition Contest: A Synthesis.
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Ernest Valveny and Philippe Dosch. 2004. Performance Evaluation of Symbol Recognition. In S. Marinai, A.D.(E.),, ed. Document Analysis Systems.354–365.
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Ernest Valveny and Philippe Dosch. 2006. A general framework for the evaluation of symbol recognition methods.
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Ernest Valveny and Philippe Dosch. 2007. A General Framework for the Evaluation of Symbol Recognition Methods.
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Ernest Valveny, Oriol Ramos Terrades, Joan Mas and Marçal Rusiñol. 2013. Interactive Document Retrieval and Classification. In Angel Sappa and Jordi Vitria, eds. Multimodal Interaction in Image and Video Applications. Springer Berlin Heidelberg, 17–30.
Abstract: In this chapter we describe a system for document retrieval and classification following the interactive-predictive framework. In particular, the system addresses two different scenarios of document analysis: document classification based on visual appearance and logo detection. These two classical problems of document analysis are formulated following the interactive-predictive model, taking the user interaction into account to make easier the process of annotating and labelling the documents. A system implementing this model in a real scenario is presented and analyzed. This system also takes advantage of active learning techniques to speed up the task of labelling the documents.
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Ernest Valveny and Miquel Ferrer. 2008. Application of Graph Embedding to Solve Graph Matchin Problems. Colloque International Francophone sur l’Ecrit et le Document.13–18.
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Ernest Valveny and Enric Marti. 2003. A model for image generation and symbol recognition through the deformation of lineal shapes. PRL, 24(15), 2857–2867.
Abstract: We describe a general framework for the recognition of distorted images of lineal shapes, which relies on three items: a model to represent lineal shapes and their deformations, a model for the generation of distorted binary images and the combination of both models in a common probabilistic framework, where the generation of deformations is related to an internal energy, and the generation of binary images to an external energy. Then, recognition consists in the minimization of a global energy function, performed by using the EM algorithm. This general framework has been applied to the recognition of hand-drawn lineal symbols in graphic documents.
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Ernest Valveny and Enric Marti. 2001. Learning of structural descriptions of graphic symbols using deformable template matching. Proc. Sixth Int Document Analysis and Recognition Conf.455–459.
Abstract: Accurate symbol recognition in graphic documents needs an accurate representation of the symbols to be recognized. If structural approaches are used for recognition, symbols have to be described in terms of their shape, using structural relationships among extracted features. Unlike statistical pattern recognition, in structural methods, symbols are usually manually defined from expertise knowledge, and not automatically infered from sample images. In this work we explain one approach to learn from examples a representative structural description of a symbol, thus providing better information about shape variability. The description of a symbol is based on a probabilistic model. It consists of a set of lines described by the mean and the variance of line parameters, respectively providing information about the model of the symbol, and its shape variability. The representation of each image in the sample set as a set of lines is achieved using deformable template matching.
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Ernest Valveny and Enric Marti. 2000. Deformable Template Matching within a Bayesian Framework for Hand-Written Graphic Symbol Recognition. Graphics Recognition Recent Advances, 1941, 193–208.
Abstract: We describe a method for hand-drawn symbol recognition based on deformable template matching able to handle uncertainty and imprecision inherent to hand-drawing. Symbols are represented as a set of straight lines and their deformations as geometric transformations of these lines. Matching, however, is done over the original binary image to avoid loss of information during line detection. It is defined as an energy minimization problem, using a Bayesian framework which allows to combine fidelity to ideal shape of the symbol and flexibility to modify the symbol in order to get the best fit to the binary input image. Prior to matching, we find the best global transformation of the symbol to start the recognition process, based on the distance between symbol lines and image lines. We have applied this method to the recognition of dimensions and symbols in architectural floor plans and we show its flexibility to recognize distorted symbols.
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