کد مقاله | کد نشریه | سال انتشار | مقاله انگلیسی | نسخه تمام متن |
---|---|---|---|---|
536384 | 870505 | 2014 | 11 صفحه PDF | دانلود رایگان |
Human movement modeling can be of great interest for the design of pattern recognition systems relying on the understanding of the fine motor control (such as on-line handwriting recognition or signature verification) as well as for the development of intelligent systems involving in a way or another the processing of human movements. In this paper, we briefly list the different models that have been proposed in order to characterize the handwriting process and focus on a representation involving a vectorial summation of lognormal functions: the Sigma–lognormal model. Then, from a practical perspective, we describe a new stroke extraction algorithm suitable for the reverse engineering of handwriting signals. In the following section it is shown how the resulting representation can be used to study the writer and signer variability. We then report on two joint projects dealing with the automatic generation of synthetic specimens for the creation of large databases. The first application concerns the automatic generation of totally synthetic signature specimens for the training and evaluation of verification performances of automatic signature recognition systems. The second application deals with the synthesis of handwritten gestures for speeding up the learning process in customizable on-line recognition systems to be integrated in electronic pen pads.
• A summary of the theoretical and practical topics that I presented at ICFHR 2010, as a Keynote speaker.
• The modeling of human movements based on a vectorial summation of lognormal functions.
• Two new stroke extraction algorithms suitable for the reverse engineering of handwriting signals.
• Automatic generation of synthetic signatures for training and evaluating of verification systems.
• Synthesis of handwritten gestures for speeding up learning in customizable recognition systems.
Journal: Pattern Recognition Letters - Volume 35, 1 January 2014, Pages 225–235