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Instructors: Dr. George Bebis and Dr. Ali Erol. Presented by: Milind Zirpe.

This chapter explores various fingerprint classification techniques, including rule-based, syntactic, and structural approaches, highlighting their strengths and limitations. It discusses methods such as Galton-Henry classification and presents case studies like Karu and Jain's iterative regularization. Additionally, it covers the relational organization of low-level features into higher-level structures using directional image partitioning.

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Instructors: Dr. George Bebis and Dr. Ali Erol. Presented by: Milind Zirpe.

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  1. Fingerprint ClassificationHandbook of Fingerprint RecognitionChapter 5 (5-1 and 5-2)&Fingerprint Classification by Directional Image PartitioningRaffaele Cappelli, Alessandra Lumini,Dario Maio and Davide Maltoni. IEEE TRANSACTIONS ON PATTERN ANALYSIS AND MACHINE INTELLIGENCE, vol. 21, no. 5, pp. 402-421, 1999. Instructors: Dr. George Bebis and Dr. Ali Erol. Presented by: Milind Zirpe. CS 790Q (Fall 2005).

  2. Overview • Fingerprint Classification • Introduction. • Main classification techniques.

  3. Introduction • Need for fingerprint classification • Database of fingerprints may be very large (e.g. several million fingerprints). • Leads to long response time and hence unsuitable in real time applications. • To reduce the number of comparisons.

  4. Introduction • What is fingerprint classification ? Fingerprint classification refers to the problem of classifying a fingerprint to a class in a consistent and reliable way. • An approach A common strategy is to divide the fingerprint database into a number of bins, based on some predefined classes. A fingerprint to be identified is then required to be compared only to the fingerprints in a single bin of database based on its class.

  5. Introduction • Galton-Henry classification (Galton, 1892 and Henry, 1900).

  6. Introduction • A difficult pattern recognition problem

  7. Introduction • A difficult pattern recognition problem

  8. Classification Techniques

  9. Classification Techniques 1. Rule-based approaches Classification according to the number and position of the singularities (commonly used by human experts for manual classification).

  10. Classification Techniques a. Kawagoe and Tojo (1984) • Derive a coarse classification using type and position of singular points. • Finer classification is obtained by tracing the ridge line flow.

  11. Classification Techniques b. Karu and Jain (1996) An iterative regularization (smoothening orientation image with a 3x3 box filter) is done until a valid number of singular points are detected. This allows reducing noise and thus improves classification accuracy. • Criteria for differentiating between tented arches and loops Connect the two singularities with a straight line and measure the avg. difference between the local orientations along the line and the slope of the line. A fingerprint is classified as a tented arch if:

  12. Classification Techniques • Problems with Rule-based approaches: • Although simple, some problems arise in presence of noisy or partial fingerprints, where singularity detection can be extremely difficult. (Addressed to some extent by Karu and Jain (1996) approach). • May work well on rolled (nail to nail) fingerprint impressions scanned from cards, but are not suitable for dab (live-scan) fingerprint images, because delta points are often missing in these types of images.

  13. Classification Techniques 2. Syntactic approaches • A syntactic method describes patterns by means of terminal symbols and production rules. • Terminal symbols are associated to small groups of directional elements within the orientation image and represent a class. • A grammar is defined for each class and a parsing process is responsible for classifying each new pattern (Fu and Booth, 1986a, b).

  14. Classification Techniques a. Rao and Balck (1980) • A ridge line is analyzed and represented by a set of connected lines. • These lines are labeled according to the direction changes, thus obtaining a set of strings that are processed through ad hoc grammars or string-matching techniques to derive the final classification.

  15. Classification Techniques • Problems with Syntactic approaches: • Due to the great diversity of fingerprint patterns, syntactic approaches require very complex grammars whose inference requires complicated and unstable approaches.

  16. Classification Techniques 3. Structural approaches Based on the relational organization of low-level features into higher-level structures. This relational organization is represented by means of symbolic data structures (viz. trees and graphs), which allow a hierarchical organization of the information (Bunke, 1993).

  17. Classification Techniques a. Maio and Maltoni (1996) • The directional image is partitioned into several homogenous regular-shaped regions, which are used to build a relational graph summarizing the fingerprint macro-features. • Directional image is computed, over a discrete grid 32x32, using a robust technique proposed by Donahue and Rokhlin (1993). • A dynamic clustering algorithm, Maio and Maltoni (1996), is adopted to segment the directional image. • A relational graph is built by creating a node for each region and an arc for each pair of adjacent regions. • An inexact graph matching technique, derived from Bunke and Allermann (1983), is used to compute a “distance” vector between the graph and each class prototype graph.

  18. Classification Techniques Class prototype graphs Fig.3. Main steps. The intermediate results produced during the classification of a Left Loop fingerprint are shown.

  19. Classification Techniques • Advantages: • The relational graphs are invariant with respect to displacement and rotation of image. • The technique neither requires any position alignment nor any normalization. • In principle, can be directly used for classification of partial fingerprints (i.e., matching a graph with a sub graph). • Problems with Structural approaches: • It is not easy to robustly partition the orientation image into homogenous regions, especially in poor quality fingerprints. (Resolved to some extent by Cappelli et al. (1999) using template-based matching).

  20. Classification Techniques 4. Multiple classifier-based approaches Different classifiers offer complementary information about the patterns to be classified. This motivates combining of different approaches for the fingerprint classification task.

  21. Classification Techniques a. Candela et al. (1995) • Based on Neural Network and Rule-based approaches. • The system is called as PCASYS (Pattern-level Classification Automation SYStem). • A probabilistic neural network is coupled with an auxiliary ridge tracing module, specifically designed to detect whorl fingerprints.

  22. Classification Techniques Fig. A functional scheme of the PCASYS.

  23. Classification Techniques b. Jain, Prabhakar, and Hong (1999) • Two stage classification strategy based on Statistical and Neural Network approaches. • Stage 1: A k-nearest neighbor classifier is used to find the two most likely classes from a FingerCode feature vector (section 4.6). • Stage 2: A specific neural network, trained to distinguish between the two classes, is utilized to obtain the final decision. A total of 10 neural networks are trained to distinguish between each possible pair of classes.

  24. Classification Techniques

  25. Fingerprint Classification by Directional Image Partitioning Raffaele Cappelli, Alessandra Lumini,Dario Maio and Davide Maltoni. IEEE TRANSACTIONS ON PATTERN ANALYSIS AND MACHINE INTELLIGENCE, vol. 21, no. 5, pp. 402-421, 1999.

  26. Overview • Fingerprint Classification by Directional Image Partitioning • Introduction. • The new approach. • Fingerprint retrieval. • Experimental results. • Conclusion.

  27. Introduction • The relational graph approach has some problems in obtaining analogous segmentation from similar directional images. • Influenced too much by local ridge-line orientation changes, start point of clustering routines. • The new approach uses dynamic masks for directional image partitioning. • It is translation and rotation invariant and does not require the singularities to be detected.

  28. Introduction Fig. 4. The segmentation of two Left Loop fingerprints.

  29. The New Approach • Overview of the new approach. • Directional image computation and enhancement. • Dynamic mask definition. • Directional image partitioning with Dynamic masks. • Generation of a set of Prototype masks. • Classification.

  30. Overview of the new approach • The basic idea of the new approach is to perform a “guided” segmentation of the directional image with the aim of drastically reducing the degrees of freedom during the partitioning process, conferring stability to the solutions. • A set of dynamic masks, directly derived from the most common fingerprint classes, are used to guide the partitioning. • The inexact graph matching step is simplified and embedded in the segmentation step.

  31. Overview of the new approach Fig. 6. Classification of a Left Loop fingerprint by means of the dynamic masks approach.

  32. Directional image computation and enhancement • Directional image computation: • The finger area is separated from the background and its quality is improved by a filtering in the frequency domain. • The R.M. Stock and C.W. Swonger (1969) method is applied to calculate directional elements. Each element is represented by a vector v. • Directional image enhancement: • Regularization: Regularization of directional elements by local averaging on 3x3 windows W.

  33. Directional image computation and enhancement • Directional image enhancement (contd.): • Attenuation: Attenuation of the border elements by applying a Gaussian-like function which progressively reduces the element magnitude moving from the center towards the borders. where distc(v) returns the distance in blocks of v origin from the directional image center and s determines the scale of the Gaussian function.

  34. Directional image computation and enhancement • Directional image enhancement (contd.): • Strengthening: We use a strengthening function (str) which increases the significance of each element according to the irregularity degree of its 3x3 neighborhood, without requiring the singularities to be explicitly detected. returns 0 if all the vectors are parallel to each other and its value approaches 1 when discordance increases. The resulting directional image is made up of vectors ve such that: where is a weighting factor.

  35. Directional image computation and enhancement Fig. 7. Enhancement of a directional image: the map in the arrow-box shows the most irregular regions as revealed by the str function. The parameters are: s = 9.6 and l = 112.

  36. Dynamic mask definition • Dynamic masks have been introduced in order to decrease the degrees of freedom during the partitioning process. • Each mask is characterized by a set of vertices defining the borders of the regions which determine the segmentation. • Some vertices can be locally moved to best fit the fingerprint image singularities, which can occupy different positions within fingerprints of the same class. Fig. 8. The singularity positions in three different Left Loop fingerprints.

  37. Dynamic mask definition • Formally, a dynamic mask is defined as a 6-tuple: M = , where: • V = is a set of vertices p. • P = is a set of polygonal regions whose vertices are in V. • is a relation, encoding the dependency of the dependent vertices from the mobile ones. Each dependent vertex is anchored to exactly one mobile vertex. • encodes a relation between some region pairs. For each pair Pi, Pj, whose orientation difference is significant, the triplet . • is a function which associates to each mobile vertex a mobility window which limits the vertex movements during the mask adaptation. • is a function which indicates, for each pair in the dependent vertex movement on the basis of the corresponding mobile vertex movement.

  38. Dynamic mask definition Fig. 9. An example of dynamic mask definition. Fixed vertices are denoted by empty circles, the mobile ones by black circles, and the dependent ones by gray circles. The dashed boxes denote the mobility windows associated to the mobile vertices. An arrow from a mobile vertex pi to a dependent vertex pj indicates the dependence of pj on pi.

  39. Directional image partitioning with Dynamic masks • Let MT,Q be the steady mask obtained by the dynamic mask M as a result of the following transformations: • a global rotation-displacement T = where and denote the global mask displacement and denotes the global mask rotation. • a set of mobile vertex displacements Q = { (dx1, dy1), (dx2, dy2), ... }; (dxi, dyi) denotes the displacement of the vertex pi with respect to its initial position. • The application of a steady mask MT,Q to a directional image D consists in superimposing MT,Q on D and deriving a segmentation R = {R1, R2, ..., Rn} where each region Ri is made up of the directional elements internal to the polygon Pi.

  40. Directional image partitioning with Dynamic masks • The cost Csm(MT,Q, D) of the application of MT,Q to D is given by the sum of two terms: where: First term: Var(Ri) is proportional to the variance of the directional elements in Ri and C0 is a parameter which introduces a penalty proportional to the number of regions in M in order to balance the possibility of obtaining lower costs by segmenting the directional image into several small regions. Second term: returns the difference between the avg. orientations of regions Ri and Ri; returns the difference between qi, qj;μis the weight of the orientation difference contribution, and returns the number of triplets in .

  41. Directional image partitioning with Dynamic masks • The application cost of a dynamic mask M to a directional image D is computed by determining the minimum cost over all the possible steady masks MT,Q :

  42. Directional image partitioning with Dynamic masks Fig. 10. Adaptation of the mask defined in Fig. 9 to three different images of the same Left Loop fingerprint.

  43. Generation of a set of Prototype masks Fig. 11. Prototype mask creation. The mask area is larger than the directional image to allow the border elements to be considered during the mask displacement.

  44. Generation of a set of Prototype masks Fig. 11 (contd.). Prototype mask creation. The mask area is larger than the directional image to allow the border elements to be considered during the mask displacement.

  45. Generation of a set of Prototype masks Fig. 12. The five prototype masks derived from the classes Arch, Left Loop, Right Loop, Tented Arch, and Whorl. The vertex positions, the mobility windows, and the dependencies on mobile vertices are graphically shown.

  46. Generation of a set of Prototype masks Fig. 12 (contd.). Example of application of each mask to a fingerprint belonging to the corresponding class.

  47. Classification • Let Mi, i = 1..s be the prototype masks and D the directional image to be classified; the feature vector wD resulting from the mask application is: where low component values denote high similarity with the corresponding prototype mask. • wD can be normalized as: • The normalization enables: • working within the fixed range [0, 1]; this makes fingerprint indexing through spatial data structures easier. • dealing with differently contrasted images: The image contrast is related to the magnitude of the directional elements; hence, it can determine an increase or a reduction of all the costs.

  48. Classification Fig. 13. The figure shows the segmentation obtained by applying the prototype masks defined in Fig. 12 to some sample fingerprints (only one example is provided for each class); the corresponding normalized feature vectors are shown on the right in the form of histograms.

  49. Classification Fig. 13. (contd.)

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