Perfect fingerprint orientation fields by locally adaptive global models

Gottschlich, Carsten; Tams, Benjamin; Huckemann, Stephan

doi:10.1049/iet-bmt.2016.0087

Cited by 13 publications

(13 citation statements)

References 52 publications

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“…In conclusion we remark that new algorithms for generating realistic synthetic orientation fields have to be developed. The recently proposed XQD model Gottschlich et al (2017) could be used for this purpose, realistically linking curvature with conformality indeces. Until their arrival, one may rely on orientation fields from real fingerprints (as implemented by RFC Imdahl et al (2015)).…”

Section: Discussionmentioning

confidence: 99%

Möbius Moduli for Fingerprint Orientation Fields

et al. 2017

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which are determined by the singular points and a rotation. This approximation is very coarse, e.g. for fingerprints with no singular points (arch type), the zero-pole model's OF has parallel lines. Quadratic differential (QD) models, which are obtained from zero-pole models by adding suitable singularities outside the observation window, approximate real fingerprints much better. For example, for arch type fingerprints, parallel lines along the distal joint change slowly into circular lines around the nail furrow. Still, QD models are not fully realistic because, for example along the central axis of arch type fingerprints, ridge line curvatures usually first increase and then decrease again. It is impossible to model this with QDs, which, due to complex analyticity, also produce conformal fields only. In fact, as one of many applications of the new descriptor, we show, using histograms of curvature and conformality index (log of the absolute value of the Möbius modulus), that local deviation from conformality in fingerprints occurs systematically at high curvature which is not reflected by state of the art fingerprint models as are used, for instance, in the well known synthetic fingerprint generation tool SFinGe and these differences robustely discriminate real prints from SFinGe's synthetic prints.

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Section: Discussionmentioning

confidence: 99%

Möbius Moduli for Fingerprint Orientation Fields

et al. 2017

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“…Ridge orientation field is computed using the technique introduced in [12], where the dominant ridge orientation field is calculated by combining the gradient estimates within a window of size w × w centered at location (i, j): where and are the gradient magnitudes in the and directions, respectively, is in the range [0, ]. We applied Sobel operator to compute and because it has been extensively used to compute the gradients of fingerprints [13]- [15]. The Gaussian filter is applied to smooth the orientation of a window and to suppress noise as follows:…”

Section: ) Co-occurrence Of Ridge Orientationsmentioning

confidence: 99%

“…A fingerprint contains connected ridges. The distance between ridges is an important visual cue for fingerprint recognition [1,34], but it offers difficulty when dealing with fingerprint sensor interoperability [12][13][14][15]. Figure 5 exhibits four fingerprints and their thinned versions.…”

Section: ) Co-occurrence Of Ridge Orientationsmentioning

confidence: 99%

Alignment-Free Cross-Sensor Fingerprint Matching Based on the Co-Occurrence of Ridge Orientations and Gabor-HoG Descriptor

et al. 2019

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The existing automatic fingerprint verification methods are designed to work under the assumption that the same sensor is installed for enrollment and authentication (regular matching). There is a remarkable decrease in efficiency when one type of contact-based sensor is employed for enrolment and another type of contact-based sensor is used for authentication (cross-matching or fingerprint sensor interoperability problem,). The ridge orientation patterns in a fingerprint are invariant to sensor type. Based on this observation, we propose a robust fingerprint descriptor called the co-occurrence of ridge orientations (Co-Ror), which encodes the spatial distribution of ridge orientations. Employing this descriptor, we introduce an efficient automatic fingerprint verification method for cross-matching problem. Further, to enhance the robustness of the method, we incorporate scale based ridge orientation information through Gabor-HoG descriptor. The two descriptors are fused with canonical correlation analysis (CCA), and the matching score between two fingerprints is calculated using city-block distance. The proposed method is alignment-free and can handle the matching process without the need for a registration step. The intensive experiments on two benchmark databases (FingerPass and MOLF) show the effectiveness of the method and reveal its significant enhancement over the state-of-the-art methods such as VeriFinger (a commercial SDK), minutia cylindercode (MCC), MCC with scale, and the thin-plate spline (TPS) model. The proposed research will help security agencies, service providers and law-enforcement departments to overcome the interoperability problem of contact sensors of different technology and interaction types.INDEX TERMS biometrics; fingerprint sensor interoperability; cross-sensor fingerprint matching; fingerprint verification; feature-level fusion

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“…() and Gottschlich et al . () such that the nearly parallel friction ridges above the crease are oriented vertically, so that the positive horizontal axis points into the distal direction; Fig. .…”

Section: Testing For Anisotropic Growthmentioning

confidence: 99%

“…Semiautomated alignment (FVC2002 DB2 database finger 7, print 4) of crease lines along the vertical axis, using the (extended) quadratic differential tool fromHuckemann et al (2008) andGottschlich et al (2017), such that the horizontal axis coincides with the distal axis (2017) such that the nearly parallel friction ridges above the crease are oriented vertically, so that the positive horizontal axis points into the distal direction;Fig. 3.…”

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Detecting Anisotropy in Fingerprint Growth

Markert

Krehl

Gottschlich

et al. 2019

Journal of the Royal Statistical Society Series C: Applied Statistics

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Summary From infancy to adulthood, human growth is anisotropic, much more along the proximal–distal axis (height) than along the medial–lateral axis (width), particularly at extremities. Detecting and modelling the rate of anisotropy in fingerprint growth facilitate the use of children's fingerprints for long‐term biometric identification. Using standard fingerprint scanners, anisotropic growth is highly overshadowed by the varying distortions created by each imprint, and it seems that this difficulty has hampered to date the development of suitable methods, detecting anisotropy, let alone designing models. We provide a tool chain to detect statistically anisotropy in planar shape and its preferred axis. For this we develop a new anisotropic growth model with a Procrustes‐type algorithm and a new parametric and non‐parametric neighbourhood hypothesis test, tunable to measurement accuracy. In application to fingerprint growth, we require only a standard fingerprint scanner and a minutiae matcher. Taking into account realistic distortions caused by pressing fingers on scanners, our simulations based on real data indicate that, for example, already in rather small samples (56 matches) we can significantly detect proximal–distal growth if it exceeds medial–lateral growth by only around 5%. Our method is well applicable to future data sets of child fingerprint time series. We provide an implementation of our algorithms and tests with matched minutiae pattern data.

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Perfect fingerprint orientation fields by locally adaptive global models

Cited by 13 publications

References 52 publications

Möbius Moduli for Fingerprint Orientation Fields

Möbius Moduli for Fingerprint Orientation Fields

Alignment-Free Cross-Sensor Fingerprint Matching Based on the Co-Occurrence of Ridge Orientations and Gabor-HoG Descriptor

Detecting Anisotropy in Fingerprint Growth

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