Operators |
create_aniso_shape_model_xld — Prepare an anisotropically scaled shape model for matching from XLD contours.
create_aniso_shape_model_xld(Contours : : NumLevels, AngleStart, AngleExtent, AngleStep, ScaleRMin, ScaleRMax, ScaleRStep, ScaleCMin, ScaleCMax, ScaleCStep, Optimization, Metric, MinContrast : ModelID)
The operator create_aniso_shape_model_xld creates an anisotropically scaled shape model used for matching from the XLD contours passed in Contours. The XLD contours represent the gray value edges of the object to be searched for. In contrast to the operator create_aniso_shape_model, which creates a shape model from a template image, the operator create_aniso_shape_model_xld creates the shape model from XLD contours, i.e., without the use of a template image.
The output parameter ModelID is a handle for this model, which is used in subsequent calls to find_aniso_shape_model. The center of gravity of the smallest surrounding rectangle of the Contours that is parallel to the coordinate axes is used as the origin (reference point) of the model. A different origin can be set with set_shape_model_origin. The model is generated for multiple image pyramid levels and is stored in memory. If a complete pregeneration of the model is selected (see below), the model is generated at multiple rotations and anisotropic scales (i.e., independent scales in the row and column direction) on each level.
The number of pyramid levels is determined with the parameter NumLevels. It should be chosen as large as possible because by this the time necessary to find the object is significantly reduced. On the other hand, NumLevels must be chosen such that the model is still recognizable and contains a sufficient number of points (at least four) on the highest pyramid level. If not enough model points are generated, the number of pyramid levels is reduced internally until enough model points are found on the highest pyramid level. If this procedure would lead to a model with no pyramid levels, i.e., if the number of model points is already too small on the lowest pyramid level, create_aniso_shape_model_xld returns with an error message. If NumLevels is set to 'auto' , create_aniso_shape_model_xld determines the number of pyramid levels automatically. The computed number of pyramid levels can be queried using get_shape_model_params. In rare cases, it might happen that create_aniso_shape_model_xld determines a value for the number of pyramid levels that is too large or too small. If the number of pyramid levels is chosen too large, the model may not be recognized in the image or it may be necessary to select very low parameters for MinScore or Greediness in find_aniso_shape_model in order to find the model. If the number of pyramid levels is chosen too small, the time required to find the model in find_aniso_shape_model may increase. In these cases, the number of pyramid levels should be selected manually.
The parameters AngleStart and AngleExtent determine the range of possible rotations, in which the object can occur in the image. Note that the object can only be found in this range of angles by find_aniso_shape_model. The parameter AngleStep determines the step length within the selected range of angles. Hence, if subpixel accuracy is not specified in find_aniso_shape_model, this parameter specifies the accuracy that is achievable for the angles in find_aniso_shape_model. AngleStep should be chosen based on the size of the object. Smaller models do not have many different discrete rotations in the image, and hence AngleStep should be chosen larger for smaller models. If AngleExtent is not an integer multiple of AngleStep, AngleStep is modified accordingly. To ensure that for model instances without rotation angle values of exactly 0.0 are returned by find_aniso_shape_model, the range of possible rotations is modified as follows: If there is no positive integer value n such that AngleStart plus n times AngleStep is exactly 0.0, AngleStart is decreased by up to AngleStep and AngleExtent is increased by AngleStep.
The parameters ScaleRMin, ScaleRMax, ScaleCMin, and ScaleCMax determine the range of possible anisotropic scales of the object in the row and column direction. A scale of 1 in both scale factors corresponds to the original size of the model. The parameters ScaleRStep and ScaleCStep determine the step length within the selected range of scales. Hence, if subpixel accuracy is not specified in find_aniso_shape_model, these parameters specify the accuracy that is achievable for the scales in find_aniso_shape_model. Like AngleStep, ScaleRStep and ScaleCStep should be chosen based on the size of the object. If the respective range of scales is not an integer multiple of ScaleRStep and ScaleCStep, ScaleRStep and ScaleCStep are modified accordingly. To ensure that for model instances that are not scaled scale values of exactly 1.0 are returned by find_aniso_shape_model, the range of possible scales is modified as follows: If there are no positive integer values n and m such that ScaleRMin plus n times ScaleRStep is exactly 1.0 and ScaleCMin plus m times ScaleCStep is exactly 1.0, ScaleRMin and ScaleCMin are decreased by up to ScaleRStep and ScaleCStep, respectively, and ScaleRMax and ScaleCMax are increased such that the range of possible scales is increased by ScaleRStep and ScaleCStep, respectively.
Note that the transformations are treated internally such that the scalings are applied first, followed by the rotation. Therefore, the model should usually be aligned such that it appears horizontally or vertically in the model image.
For particularly large models, it may be useful to reduce the number of model points by setting Optimization to a value different from 'none' . If Optimization = 'none' , all model points are stored. In all other cases, the number of points is reduced according to the value of Optimization. If the number of points is reduced, it may be necessary in find_aniso_shape_model to set the parameter Greediness to a smaller value, e.g., 0.7 or 0.8. For small models, the reduction of the number of model points does not result in a speed-up of the search because in this case usually significantly more potential instances of the model must be examined. If Optimization is set to 'auto' , create_aniso_shape_model_xld automatically determines the reduction of the number of model points.
The parameter Metric determines the conditions under which the model is recognized in the image. If Metric = 'use_polarity' , the object in the image and the model must have the same contrast. If, for example, the model is a bright object on a dark background, the object is found only if it is also brighter than the background. If Metric = 'ignore_global_polarity' , the object is found in the image also if the contrast reverses globally. In the above example, the object hence is also found if it is darker than the background. The runtime of find_aniso_shape_model will increase slightly in this case. If Metric = 'ignore_local_polarity' , the model is found even if the contrast changes locally. This mode can, for example, be useful if the object consists of a part with medium gray value, within which either darker or brighter sub-objects lie. Since in this case the runtime of find_aniso_shape_model increases significantly, it is usually better to create several models that reflect the possible contrast variations of the object with create_aniso_shape_model_xld , and to match them simultaneously with find_aniso_shape_models. The above three metrics can only be applied to single-channel images. If a multichannel image is used as the model image or as the search image only the first channel will be used (and no error message will be returned). If Metric = 'ignore_color_polarity' , the model is found even if the color contrast changes locally. This is, for example, the case if parts of the object can change their color, e.g., from red to green. In particular, this mode is useful if it is not known in advance in which channels the object is visible. In this mode, the runtime of find_aniso_shape_model can also increase significantly. The metric 'ignore_color_polarity' can be used for images with an arbitrary number of channels. If it is used for single-channel images it has the same effect as 'ignore_local_polarity' . It should be noted that for Metric = 'ignore_color_polarity' the channels do not need to contain a spectral subdivision of the light (like in an RGB image). The channels can, for example, also contain images of the same object that were obtained by illuminating the object from different directions. Note that the first two metrics ('use_polarity' and 'ignore_global_polarity' ) can only be selected if all Contours provide the attribute 'edge_direction' , which defines the polarity of the edges. This attribute is available for contours created, e.g., with edges_sub_pix with the parameter Method set to, e.g., 'canny' . Otherwise, these two metrics can be selected with the operator set_shape_model_metric, which determines the polarity of the edges from an image.
With MinContrast, it can be determined which contrast the object edges must at least have in the recognition performed by find_aniso_shape_model. In other words, this parameter separates the object from the noise in the image. Therefore, a good choice is the range of gray value changes caused by the noise in the image. If, for example, the gray values fluctuate within a range of 10 gray levels, MinContrast should be set to 10. If multichannel images are used for the model and the search images, and if the parameter Metric is set to 'ignore_color_polarity' (see above) the noise in one channel must be multiplied by the square root of the number of channels to determine MinContrast. If, for example, the gray values fluctuate within a range of 10 gray levels in a single channel and the image is a three-channel image MinContrast should be set to 17. If the model should be recognized in very low contrast images, MinContrast must be set to a correspondingly small value. If the model should be recognized even if it is severely occluded, MinContrast should be slightly larger than the range of gray value fluctuations created by noise in order to ensure that the position and rotation of the model are extracted robustly and accurately by find_aniso_shape_model.
Optionally, a second value can be passed in Optimization. This value determines whether the model is pregenerated completely or not. To do so, the second value of Optimization must be set to either 'pregeneration' or 'no_pregeneration' . If the second value is not used (i.e., if only one value is passed), the mode that is set with set_system('pregenerate_shape_models',...) is used. With the default value ('pregenerate_shape_models' = 'false' ), the model is not pregenerated completely. The complete pregeneration of the model normally leads to slightly lower runtimes because the model does not need to be transformed at runtime. However, in this case, the memory requirements and the time required to create the model are significantly higher. It should also be noted that it cannot be expected that the two modes return exactly identical results because transforming the model at runtime necessarily leads to different internal data for the transformed models than pregenerating the transformed models. For example, if the model is not pregenerated completely, find_aniso_shape_model typically returns slightly lower scores, which may require setting a slightly lower value for MinScore than for a completely pregenerated model. Furthermore, the poses obtained by interpolation may differ slightly in the two modes. If maximum accuracy is desired, the pose of the model should be determined by least-squares adjustment.
If a complete pregeneration of the model is selected, the model is pregenerated for the selected angle and scale range and stored in memory. The memory required to store the model is proportional to the number of angle steps, the number of scale steps, and the number of points in the model. Hence, if AngleStep, ScaleRStep, or ScaleCStep are too small or AngleExtent or the range of scales are too big, it may happen that the model no longer fits into the (virtual) memory. In this case, AngleStep, ScaleRStep, or ScaleCStep must be enlarged or AngleExtent or the range of scales must be reduced. In any case, it is desirable that the model completely fits into the main memory, because this avoids paging by the operating system, and hence the time to find the object will be much smaller. Since angles can be determined with subpixel resolution by find_aniso_shape_model, AngleStep >= 1° and ScaleRStep, ScaleCStep >= 0.02 can be selected for models of a diameter smaller than about 200 pixels. If AngleStep = 'auto' or ScaleRStep, ScaleCStep = 'auto' is selected, create_aniso_shape_model_xld automatically determines a suitable angle or scale step length, respectively, based on the size of the model. The automatically computed angle and scale step lengths can be queried using get_shape_model_params.
If a complete pregeneration of the model is not selected, the model is only created in a reference pose on each pyramid level. In this case, the model must be transformed to the different angles and scales at runtime in find_aniso_shape_model. Because of this, the recognition of the model might require slightly more time.
Note that pregenerated shape models are tailored to a specific image size. For runtime reasons using images of different sizes during the search with the same model in parallel is not supported. In this case, copies of the same model must be used, otherwise the program may crash!
The XLD contours passed in Contours should have been scaled to approximately the average size of the object in the search images. This means that the products and should be approximately equal to 1.
Note that, in contrast to the operator create_aniso_shape_model, it is not possible to specify a minimum size of the model components. To avoid small model components in the shape model, short contours can be eliminated before calling create_aniso_shape_model_xld with the operator select_contours_xld.
This operator returns a handle. Note that the state of an instance of this handle type may be changed by specific operators even though the handle is used as an input parameter by those operators.
Input contours that will be used to create the model.
Maximum number of pyramid levels.
Default value: 'auto'
List of values: 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 'auto'
Smallest rotation of the pattern.
Default value: -0.39
Suggested values: -3.14, -1.57, -0.79, -0.39, -0.20, 0.0
Extent of the rotation angles.
Default value: 0.79
Suggested values: 6.29, 3.14, 1.57, 0.79, 0.39
Restriction: AngleExtent >= 0
Step length of the angles (resolution).
Default value: 'auto'
Suggested values: 'auto' , 0.0175, 0.0349, 0.0524, 0.0698, 0.0873
Restriction: AngleStep > 0 && AngleStep <= pi / 16
Minimum scale of the pattern in the row direction.
Default value: 0.9
Suggested values: 0.5, 0.6, 0.7, 0.8, 0.9, 1.0
Restriction: ScaleRMin > 0
Maximum scale of the pattern in the row direction.
Default value: 1.1
Suggested values: 1.0, 1.1, 1.2, 1.3, 1.4, 1.5
Restriction: ScaleRMax >= ScaleRMin
Scale step length (resolution) in the row direction.
Default value: 'auto'
Suggested values: 'auto' , 0.01, 0.02, 0.05, 0.1, 0.15, 0.2
Restriction: ScaleRStep > 0
Minimum scale of the pattern in the column direction.
Default value: 0.9
Suggested values: 0.5, 0.6, 0.7, 0.8, 0.9, 1.0
Restriction: ScaleCMin > 0
Maximum scale of the pattern in the column direction.
Default value: 1.1
Suggested values: 1.0, 1.1, 1.2, 1.3, 1.4, 1.5
Restriction: ScaleCMax >= ScaleCMin
Scale step length (resolution) in the column direction.
Default value: 'auto'
Suggested values: 'auto' , 0.01, 0.02, 0.05, 0.1, 0.15, 0.2
Restriction: ScaleCStep > 0
Kind of optimization and optionally method used for generating the model.
Default value: 'auto'
List of values: 'auto' , 'no_pregeneration' , 'none' , 'point_reduction_high' , 'point_reduction_low' , 'point_reduction_medium' , 'pregeneration'
Match metric.
Default value: 'ignore_local_polarity'
List of values: 'ignore_color_polarity' , 'ignore_global_polarity' , 'ignore_local_polarity' , 'use_polarity'
Minimum contrast of the objects in the search images.
Default value: 5
Suggested values: 1, 2, 3, 5, 7, 10, 20, 30, 40
Handle of the model.
If the parameters are valid, the operator create_aniso_shape_model_xld returns the value 2 (H_MSG_TRUE). If necessary an exception is raised. If the parameter NumLevels is chosen such that the model contains too few points, the error 8510 is raised.
read_contour_xld_dxf, edges_sub_pix, select_contours_xld
find_aniso_shape_model, find_aniso_shape_models, get_shape_model_params, clear_shape_model, write_shape_model, set_shape_model_origin, set_shape_model_param, set_shape_model_metric
create_shape_model_xld, create_scaled_shape_model_xld
Matching
Operators |