On Using Physical Analogies for Feature and Shape Extraction in Computer Vision

Nixon, Mark S.; Liu, Xin U.; Direkoğlu, Cem; Hurley, David J.

doi:10.1093/comjnl/bxp070

Cited by 18 publications

(10 citation statements)

References 20 publications

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“…We present a new 3D approach based on using a physical analogy [5] to separate intersecting regions. The approach is anisotropic and does not require a model or previous knowledge about the regions of interest.…”

Section: Fig 1 Ct Image Of Roman Coins Inside a Jarmentioning

confidence: 99%

Pressure Based Segmentation in Volumetric Images

Alathari

Nixon

2013

Advances in Visual Computing

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Abstract. Analysing Roman coins found in archaeology sites has been traditionally done manually by an operator using volumetric image slices provided by a computed tomography scanner. In order to automate the counting process, a good segmentation for the coins has to be achieved to separate the touching surfaces of the coins. Separating touching surfaces in volumetric images has not yet attracted much attention. In this paper we propose a new method based on using a form of pressure to separate the intersecting surfaces. We analogise the background of the image to be filled with an ideal gas. The pressure at a point has an inverse relationship with the volume of homogeneous material surrounding it. By studying the pressure space, the locations of intersecting surfaces are highlighted and encouraging segmentation results are achieved. Our analysis concerns a selection of images, naturally demonstrating success, together with an analysis of the new technique's sensitivity to noise. IntroductionComputed tomography imaging is an increasingly popular source for information about three dimensional objects, with many applications ranging from medical to industrial. Scans can contain multiple objects with the same density or single objects containing smaller ones with similar density. The placement of the objects in the 3D space can be random and in some cases the surfaces of those objects touch which makes it difficult to separate them using conventional thresholding and segmentation techniques, motivating development of a higher level process. An example of such a problem is the CT scanned jar ( Fig. 1) which contains a set of Roman coins. This set of data contains coins with similar density randomly placed with different orientations and locations within the jar. The problem associated with this particular set of data relies in the high attenuation factor for the material from which the coins are made which in turn increases the chance of touching surfaces in the volumetric image especially for the coins in the centre of the jar. Separating objects with the same density and texture is challenging due to the absence of techniques for detecting in 3D the regions of intersection between the objects, impeding the possibility of counting the coins.Pressure Based Segmentation in Volumetric Images 239 Fig. 1. CT image of Roman coins inside a jarMany approaches have been developed to solve the problem of separating touching objects in two dimensional (2D) space. The two main application concern separating rice grains [1] and counting cells in microscope images [2]. A traditional approach involves thresholding, corner detection and joining points of interest to create a binary image of disconnected objects. On the other hand, there is no such technique for 3D image analysis. The literature provides some model-based methods that have been used to separate left and right lungs [3]. The search for regions of interest uses images where lungs intersect, to minimize the computational demands. Edge or surface detection can be appli...

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Section: Fig 1 Ct Image Of Roman Coins Inside a Jarmentioning

confidence: 99%

Pressure Based Segmentation in Volumetric Images

Alathari

Nixon

2013

Advances in Visual Computing

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“…Results also show that this technique can detect moving-edges in image sequences without using the background image. Note that the preliminary version and the summary of this work were presented in (Direkoglu and Nixon, 2006;Nixon et al, 2009), respectively. In this paper, we extend the basis and evaluation of the new technique.…”

Section: Using Heat Flow In Image Analysismentioning

confidence: 99%

Moving-edge detection via heat flow analogy

Direkoğlu

Nixon

2011

Pattern Recognition Letters

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a b s t r a c tIn this paper, a new and automatic moving-edge detection algorithm is proposed, based on using the heat flow analogy. This algorithm starts with anisotropic heat diffusion in the spatial domain, to remove noise and sharpen region boundaries for the purpose of obtaining high quality edge data. Then, isotropic and linear heat diffusion is applied in the temporal domain to calculate the total amount of heat flow. The moving-edges are represented as the total amount of heat flow out from the reference frame. The overall process is completed by non-maxima suppression and hysteresis thresholding to obtain binary movingedges. Evaluation, on a variety of data, indicates that this approach can handle noise in the temporal domain because of the averaging inherent of isotropic heat flow. Results also show that this technique can detect moving-edges in image sequences, without background image subtraction.

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“…It is still an on-going and open research topic to segment image regions for various practical purposes [3][4][5][6][7]. In recent years, nature-inspired methods have attracted more and more research attention, in which the mechanisms in nature are imitated and adjusted in novel algorithms for image segmentation, and promising results have been obtained in such preliminary works [8,9]. In this paper, inspired by the physical P-N junction, the self-balancing mechanism of carrier diffusing and drifting is adopted in a novel segmentation framework, in which the region structure of image is formed by dynamic carrier diffusing and drifting.…”

Section: Introductionmentioning

confidence: 99%

A novel physics-inspired method for image region segmentation by imitating the carrier immigration in semiconductor materials

2017

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Abstract.A novel method for image region segmentation is proposed, which is inspired by the carrier immigration mechanism in semiconductor materials. The carrier diffusing and drifting are simulated in the proposed model, and the sign distribution of net carrier at the model's balance state is exploited for region segmentation. The experiments have been done for test images and real world images, which prove the effectiveness of the proposed method.

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On Using Physical Analogies for Feature and Shape Extraction in Computer Vision

Cited by 18 publications

References 20 publications

Pressure Based Segmentation in Volumetric Images

Pressure Based Segmentation in Volumetric Images

Moving-edge detection via heat flow analogy

A novel physics-inspired method for image region segmentation by imitating the carrier immigration in semiconductor materials

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