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interimage:attributes_description [2010/06/23 11:33] castejon |
interimage:attributes_description [2012/07/17 20:47] (current) rsilva |
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* **yGeoCenter** - y geo-coordinate of the object centroid. | * **yGeoCenter** - y geo-coordinate of the object centroid. | ||
* **membership** or **p** - confidence in the object with regard to its classification. | * **membership** or **p** - confidence in the object with regard to its classification. | ||
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===== Shape Attributes ===== | ===== Shape Attributes ===== | ||
- | * area: Returns the area of the given polygon, in number of pixels. | + | * **area** - Returns the real area of the given polygon. |
- | * bBoxArea: Returns the bounding box area of the given polygon, in number of pixels. | + | * **bBoxArea** - Returns the real bounding box area of the given polygon. |
- | * perimeter: Returns the perimeter of the polygon, considering the amount of pixels in its border. | + | * **perimeter** - Returns the real perimeter of the given polygon. |
- | * fractalDimension: Returns the fractal dimension of a given polygon, which is calculated by the following equation: | + | * **fractalDimension** - Returns the fractal dimension of a given polygon, which is calculated by the following equation: |
{{ :interimage:fractal.png }} | {{ :interimage:fractal.png }} | ||
Where P is the polygon perimeter and A is the area. | Where P is the polygon perimeter and A is the area. | ||
- | * perimeterAreaRatio: Calculates the ratio between the perimeter and the area of a polygon. | + | * **perimeterAreaRatio** - Calculates the ratio between the perimeter and the area of a polygon. |
- | * compacity: Returns the compacity of a given polygon, which is calculated by the following equation: | + | * **compacity** - Returns the compacity of a given polygon, which is calculated by the following equation: |
{{ :interimage:compacity.png }} | {{ :interimage:compacity.png }} | ||
Where P is the polygon perimeter and A is the area. | Where P is the polygon perimeter and A is the area. | ||
- | * density: The density of a polygon is calculated by the ratio between its area and its Radius (the maximum distance between the polygon centroid and all its vertices). | + | * **density** - The density of a polygon is calculated by the ratio between its area and its Radius (the maximum distance between the polygon centroid and all its vertices). |
- | * length: The Length of a polygon is the height of its bounding box. | + | * **length** - The Length of a polygon is the height of its bounding box. |
- | * width: The Width of a polygon is calculated by the width of its bounding box. | + | * **width** - The Width of a polygon is calculated by the width of its bounding box. |
- | * contiguity: Contiguity index assesses the spatial connectedness of pixels within a polygon to provide an index of boundary configuration. | + | * **contiguity** - Contiguity index assesses the spatial connectedness of pixels within a polygon to provide an index of boundary configuration. |
- | * gyrationRadius: This attribute equals the mean distance between each pixel in the polygon and the polygon centroid. | + | * **gyrationRadius** - This attribute equals the mean distance between each pixel in the polygon and the polygon centroid. |
- | * angle: The main angle of a polygon. It is obtained by calculating the best elliptic fit, and the angle of the bigest radius of the ellipse corresponds to the polygon angle. | + | * **angle** - The main angle of a polygon. It is obtained by calculating the best elliptic fit, and the angle of the biggest radius of the ellipse corresponds to the polygon angle. |
- | * ellipticFit: Finds the best ellipse which fits outside the polygon and returns the ratio between the polygon area and the ellipse area. | + | * **ellipticFit** - Finds the best ellipse which fits outside the polygon and returns the ratio between the polygon area and the ellipse area. |
- | * squareness: This attribute fits the minimum rectangle outside the polygon and calculates the ratio between the polygon area and the area of this rectangle. The most close to 1 is this attribute, the most similar to a rectangle the polygon is. | + | * **squareness** - This attribute fits the minimum rectangle outside the polygon and calculates the ratio between the polygon area and the area of this rectangle. The t closest to 1 is this attribute, the most similar to a rectangle the polygon is. |
- | * circleness: It is calculated by the following equation: | + | * **circleness** - It is calculated by the following equation: |
{{ :interimage:circle.png }} | {{ :interimage:circle.png }} | ||
Where A is the polygon area and R is the maximum distance between the polygon centroid and all its vertices. | Where A is the polygon area and R is the maximum distance between the polygon centroid and all its vertices. | ||
- | * shapeIndex: Returns the shape index of a given polygon, which is calculated by the following equation: | + | * **shapeIndex** - Returns the shape index of a given polygon, which is calculated by the following equation: |
{{ :interimage:shapeindex.png }} | {{ :interimage:shapeindex.png }} | ||
Where P is the polygon perimeter and A is the area. | Where P is the polygon perimeter and A is the area. | ||
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===== Spectral Statistical Attributes ===== | ===== Spectral Statistical Attributes ===== | ||
- | * **Amplitude** - | + | * **Amplitude** - represents the difference between the maximum and minimum pixel values of an object for the given image layer **L**. |
- | * **Brightness** - | + | * **Brightness** - represents the brightness of an image object. |
- | * **Correlation** - Correlation is a similarity measures between two data sets under an absolute scale between [-1,1]. It is calculated as showed by the next formula: | + | * **Correlation** - Correlation is a similarity measure between two data sets under an absolute scale between [-1,1]. It is calculated as shown by the next formula: |
{{ interimage:att_correlation.gif }} | {{ interimage:att_correlation.gif }} | ||
- | * **Covariance** - The covariance value represents the similarity degree between two data sets showing how correlated they are. Higher data correlation leads to higher covariance values. The calculus is showed by the following formula where N is the number of image elements for one given area. X(i) are the element values for each given index "i". | + | * **Covariance** - The covariance value represents the similarity degree between two data sets showing how correlated they are. Higher data correlation leads to higher covariance values. The calculus is shown by the following formula where N is the number of image elements for one given area. X(i) are the element values for each given index "i". |
{{ interimage:att_covariance.gif }} | {{ interimage:att_covariance.gif }} | ||
- | * **Entropy** - This is a randomness statistical measure that can be used to describe some texture features. Higher data randomness leads to higher entropy values. The calculus is done as showed by the next formula, where n is the number of distinct image element values and p(xi) is the occurrence frequence associated to that pixel value.: | + | * **Entropy** - This is a randomness statistical measure that can be used to describe some texture features. Higher data randomness leads to higher entropy values. The calculus is done as shown by the next formula, where n is the number of distinct image element values and p(xi) is the occurrence frequence associated to that pixel value.: |
{{ interimage:att_entropy.gif }} | {{ interimage:att_entropy.gif }} | ||
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* **MinPixelValue** - The minimum pixel value found inside one region for the given image band/channel. | * **MinPixelValue** - The minimum pixel value found inside one region for the given image band/channel. | ||
- | * **Mode** - Represents the most frequent value among a set of values. There are cases where mode value cannot exist and there are cases where its value it is not garanteed to be unique. Examples: | + | * **Mode** - Represents the most frequent value among a set of values. There are cases where a mode value cannot exist and there are cases where its value is not guaranteed to be unique. Examples: |
* 1,1,3,3,5,7,7,7,11,13 : Mode 7 | * 1,1,3,3,5,7,7,7,11,13 : Mode 7 | ||
- | * 3,5,8,11,13,18 : Mode value does not exists. | + | * 3,5,8,11,13,18 : Mode value does not exist. |
* 3,5,5,5,6,6,7,7,7,11,12 : Two mode values - 5 and 7 (bimodal). | * 3,5,5,5,6,6,7,7,7,11,12 : Two mode values - 5 and 7 (bimodal). | ||
- | * **Ratio** - | + | * **Ratio** - represents the amount that layer **L** contributes to the total brightness of an image object. |
- | * **StdDeviation** - The standart deviation represents the numerical data dispersion degree surrounding the mean. It is defined by: | + | * **StdDeviation** - The standard deviation represents the numerical data dispersion degree surrounding the mean. It is defined by: |
{{ interimage:att_stddev.gif }} | {{ interimage:att_stddev.gif }} | ||
- | * **SumPixelsValues** - Represents the sum of all elements values inside on area for one given image band/channel. | + | * **SumPixelsValues** - Represents the sum of all element values inside an area for one given image band/channel. |
- | * **Variance** - Like the standart deviation, the variance also represents the numerical data dispersion degree surrounding the mean but in the original data values scale. It is defined by: | + | * **Variance** - Like the standard deviation, the variance also represents the numerical data dispersion degree surrounding the mean but in the original data value scale. It is defined by: |
{{ interimage:att_variance.gif }} | {{ interimage:att_variance.gif }} | ||
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===== Texture Attributes ===== | ===== Texture Attributes ===== | ||
- | The texture attributes are based on the co-occurence gray scale matrix (GLCM) described by the following references: | + | The texture attributes are based on the co-occurrence gray scale matrix (GLCM) described in the following references: |
- | * Textural Features for Image Classification - Robert M. Haralick, K. Shanmugam, Its'hak Dinstein. Systems, Man and Cybernetics, IEEE Transactions on In Systems, Man and Cybernetics, IEEE Transactions on, Vol. 3, No. 6. (1973), pp. 610-621. | + | * Textural Features for Image Classification - Robert M. Haralick, K. Shanmugam, Its'hak Dinstein. Systems, Man and Cybernetics, IEEE Transactions on Systems, Man and Cybernetics, IEEE Transactions on, Vol. 3, No. 6. (1973), pp. 610-621. |
* Computer and Robot Vision - Robert M. Haralick - Addison-Wesley Publishing Company. | * Computer and Robot Vision - Robert M. Haralick - Addison-Wesley Publishing Company. | ||
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- | * **Angular2ndMomentGLCM (a.k.a. EnergyGLCM)** - Returns the square sum of image points pairs occurrences under one pre-defined direction. The returned values range is between [0,1]. For those images without variations the value will be 1. The calculus is showed on the next formula where "i" and "j" are adjacent image points values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. | + | * **Angular2ndMomentGLCM (a.k.a. EnergyGLCM)** - Returns the square sum of image point pairs occurrences under one pre-defined direction. The returned value range is between [0,1]. For those images without variations the value will be 1. The calculus is shown on the next formula where "i" and "j" are adjacent image point values under one pre-defined direction. p(i,j) is the probability of that co-occurrence over the image. |
{{ interimage:att_angular2ndmomentglcm.gif }} | {{ interimage:att_angular2ndmomentglcm.gif }} | ||
- | * **ContrastGLCM** - Returns a contrast intensity measure between one image point and its neighborhood. For those images without variations the contrast value will be zero. The calculus is showed on the next formula where "i" and "j" are adjacent image points values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. | + | * **ContrastGLCM** - Returns a contrast intensity measure between one image point and its neighborhood. For those images without variations the contrast value will be zero. The calculus is shown on the next formula where "i" and "j" are adjacent image point values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. |
{{ interimage:att_contrastglcm.gif }} | {{ interimage:att_contrastglcm.gif }} | ||
- | * **DissimilarityGLCM** - Returns one intensity measure quite similar to contrast between one point and its neighborhood. But the difference it that this measure has linear increments. The calculus is showed on the next formula where "i" and "j" are adjacent image points values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. | + | * **DissimilarityGLCM** - Returns one intensity measure quite similar to contrast between one point and its neighborhood. But the difference it that this measure has linear increments. The calculus is shown on the next formula where "i" and "j" are adjacent image point values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. |
{{ interimage:att_dissimilarityglcm.gif }} | {{ interimage:att_dissimilarityglcm.gif }} | ||
- | * **EntropyGLCM** - | + | * **EntropyGLCM** - Like the simple statistical entropy the GLCM entropy also is a statistical measure of image data randomness. The difference is that it uses frequencies of gray level co-ocurrences instead of using point value frequencies. The co-ocurrence matrix is used and the calculus is shown by the next formula where "i" and "j" are adjacent image point values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. |
+ | {{ interimage:att_entropyglcm.gif }} | ||
- | * **HomogeneityGLCM** - | + | * **HomogeneityGLCM** - Returns a value representing the distance between the distribution of co-ocurrence matrix elements and those diagonal elements. The returned value range is between [0,1]. For images with low value, variation the returned value will be near zero. The calculus is shown by the next formula where "i" and "j" are adjacent image point values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. |
+ | {{ interimage:att_homogeneityglcm.gif }} | ||
- | * **MeanGLCM** - | + | * **MeanGLCM** - The GLCM mean value is expressed in function of the frequency of co-occurrence of image elements related to their neighborhood under one pre-defined direction. The calculus is showed by the next formula where "i" and "j" are adjacent image points values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. |
+ | {{ interimage:att_meanglcm.gif }} | ||
- | * **QuiSquareGLCM** - | + | * **QuiSquareGLCM** - This metric can be understood as a form of energy normalization expressed in function of the linear dependency gray levels for image elements. The calculus is shown by the next formulas where "i" and "j" are adjacent image point values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. Pj is the marginal probability for that co-ocurrence. |
+ | {{ interimage:att_quisquareglcm_1.gif }} | ||
+ | {{ interimage:att_quisquareglcm_2.gif }} | ||
+ | {{ interimage:att_quisquareglcm_3.gif }} | ||
- | * **StdDeviationGLCM** - | ||
+ | * **StdDeviationGLCM** - The standard deviation is a measure that represents the value dispersion around a GLCM mean value. The GLCM standard deviation calculus differs from the simple standard deviation because the use of co-occurrence frequencies. The calculus is shown by the next formula where "i" and "j" are adjacent image point values under one pre-defined direction. p(i,j) is the probability of that co-ocurrence over the image. | ||
+ | {{ interimage:att_stddeviationglcm.gif }} | ||
===== Neighborhood Attributes ===== | ===== Neighborhood Attributes ===== | ||
- | * **existenceOf** - existence of an neighbor object belonging to the selected class **C** in a certain range **R** (in pixels) around the image object. If at least one object is found the value is 1 (true), othewise it would be 0 (false). The distance between the image object and its neighbors is calculated considering their centroids. If (**R**=0) only direct neighbors will be considered. | + | * **existenceOf** - existence of an neighbor object belonging to the selected class **C** in a certain range **R** (in pixels) around the image object. If at least one object is found the value is 1 (true), otherwise it would be 0 (false). The distance between the image object and its neighbors is calculated considering their centroids. If (**R**=0) only direct neighbors will be considered. |
* **numberOf** - number of neighbor objects belonging to the selected class **C** in a certain range **R** (in pixels) around the image object. The distance between the image object and its neighbors is calculated considering their centroids. If (**R**=0) only direct neighbors will be considered. | * **numberOf** - number of neighbor objects belonging to the selected class **C** in a certain range **R** (in pixels) around the image object. The distance between the image object and its neighbors is calculated considering their centroids. If (**R**=0) only direct neighbors will be considered. | ||
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* **meanDiffToNeighbors** - mean difference of the layer **L** mean value of an image object to the layer **L** mean value of direct neighbors (**R**=0) or all neighbor objects inside the range **R** (**R**>0). The differences are weighted with regard to the shared border (**R**=0) or the area covered by the neighbor objects inside the range (**R**>0). The distance between the image object and its neighbors is calculated considering their centroids. | * **meanDiffToNeighbors** - mean difference of the layer **L** mean value of an image object to the layer **L** mean value of direct neighbors (**R**=0) or all neighbor objects inside the range **R** (**R**>0). The differences are weighted with regard to the shared border (**R**=0) or the area covered by the neighbor objects inside the range (**R**>0). The distance between the image object and its neighbors is calculated considering their centroids. | ||
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