JP3574419B2 - Separation distance measurement system for objects near transmission lines - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention mainly provides a `` separation distance measurement system for objects close to a transmission line, which specifies the position of a tree or the like close to a transmission line bridged between steel towers and measures the separation distance between the overhead transmission line and the tree or the like. It is about. If the separation distance is shorter than a predetermined distance, the whole or part of the tree or the like is removed.
[0002]
BACKGROUND OF THE INVENTION
In the power transmission field, to prevent aerial discharge of overhead transmission lines, more stable and stable electricity is supplied by maintaining insulation and safe separation between trees and structures around the transmission lines and the transmission lines. There is a need to. For this purpose, the separation distance between the overhead transmission line from the power station to the substation and the substation to the substation and the trees or structures (such as antennas) between them is measured, and the distance and position are measured. BACKGROUND ART Cutting branches and trunks of trees and removing structures such as antennas have been performed.
[0003]
The following methods (a) to (i) have conventionally been known for investigating such nearby trees. Note that (a) to (i) in FIG. 35 correspond to those in the following description. However, illustration of (e) is omitted. Hereinafter, description will be made with reference to FIG.
[0004]
(A) First, conventionally, a method of measuring the vertical height using a measurement pole formed of a long telescopic rod made of glass fiber is most commonly performed. However, in the case of this method, it is necessary to measure the distance from the tower using a plan view or a distance measuring device or a tape measure. In addition, in the case of this method, it is necessary to go to a certain location of a nearby tree for measurement, which is troublesome. Further, there is a possibility that an error of several tens of cm may be caused due to the way of extending or bending the pole. In addition, there were dangerous tasks such as workers climbing trees. Furthermore, the withstand voltage of the inspection pole was 77 kV, and the separation measurement at 154 kV or more was dangerous.
[0005]
(B) Conventionally, measurement using a precision distance meter has also been performed. In this case, too, the distance from the tower is measured using a plan view, a distance measuring device, a tape measure, or a nearby tree is measured. It had to be measured under a certain line. In addition, this method is often used when the electric wire height is high, and in that case, it has been used together with the inspection pole. Therefore, a problem equivalent to or more than the problem in the case of using the above inspection pole occurs. Furthermore, in the case of this method, it is difficult to see the tree height because there are many branches and leaves of the tree.
[0006]
(C) Conventionally, measurement has also been performed using a transit, a light wave, or the like. In this case, the height is determined from the horizontal separation distance to the tree and the elevation angle to the top of the tree. Therefore, it is necessary to find the separation distance to the tree, which is inconvenient. Also in this case, it was necessary to measure the distance from the tower using a plan view, a distance measuring device, and a tape measure, or to measure under a line with a nearby tree. In addition, there are also problems such as heavy load transportation and outlook, and expensive equipment. In addition, this method requires a specialized surveying technique, and requires a long time to perform the operation.
[0007]
(D) It is also conceivable to use a laser range finder, but in this case, it is necessary to see from the vertical direction of the transmission line. In other words, it is necessary to have a position where the electric wires, trees, and the tower can be seen, but there were few sites where such conditions were met. Further, in the case of this method, technical knowledge is required and the method is expensive, so that it is not used much. Furthermore, in this method, it is necessary to specify a tree separately, and it is difficult to specify the tree when a plurality of trees are wrapped.
[0008]
(E) Other non-prism laser rangefinders are available, but are expensive and therefore have low utility.
[0009]
(F) Conventionally, aerial surveying using laser surveying is also known. However, in the case of this method, since it is necessary to perform laser measurement from the sky with a Cessna or a helicopter, there is a disadvantage that the cost is high. In addition, there is a problem that not only the separation of land owners is required, but also it is necessary to specify trees separately and it is difficult.
[0010]
(G) Also, as shown in Japanese Patent Application Laid-Open No. 9-97342, aerial surveying using photometry is known. However, in the case of this method as well, since it is necessary to measure from the sky with a Cessna or a helicopter, there is a disadvantage that the cost is high. In addition, in the case of this method, it is necessary to photograph the transmission line and the tree with "a plurality of cameras arranged so that the lens optical axis is parallel and the horizontal line is parallel", and the photographing conditions are strict. So I always had to shoot with two or more cameras at the same time. In addition, there is a problem that it takes a long time for analysis.
[0011]
(H) Conventionally, an overhead ground wire self-propelled tree separation measurement system using non-prism laser measurement is also known. In this system, a self-propelled aircraft was driven on an overhead ground line to detect lower phases and trees. However, in the case of this system, it is necessary to climb up to the top of the tower and measure not only while moving slowly on the average of about 300 m per span, but also to make two round trips. Required time and personnel. Also, it was necessary to carry a heavy object of 40 to 50 kg to the steel tower, and to climb the steel tower. In addition, there was a danger of falling or electric shock.
[0012]
(I) An overhead transmission line self-propelled tree measuring instrument is also known. In this case, the self-propelled machine is run on the lower-phase electric wire to detect the lower phase and trees. However, in the case of this system as well, it is necessary to climb up to the lower phase arm of the tower and measure not only while slowly moving about 300 m per span, but also to make two reciprocations. Required time and personnel. In addition, it was necessary to carry a heavy object of 40 to 50 kg to the steel tower, and to ascend to the steel tower. Further, although the present invention can be applied to a line of 77 to 154 kV, the voltage of a transmission line passing through a mountain area or the like is mostly 154 kV or more. Further, application to a multiple conductor is structurally unreasonable, and further, there is an inconvenience that if a spacer is present, the process cannot proceed.
[0013]
The present invention has been made in view of the above circumstances, and its main purpose is to enable easy, easy-to-use operation by anyone, to enable fast, accurate and accurate measurement / measurement / analysis by a small number of people, and to reduce costs. It is an object of the present invention to provide a light-weight and safe "separation distance measuring system for objects close to power transmission lines".
[0014]
[Means for Solving the Problems]
In order to achieve the above object, the system for measuring the separation distance of an object close to a transmission line according to the present invention is configured such that a transmission line of a known line type is bridged between transmission line supporting structures whose shape, dimensions, and arrangement are known. , A system that specifies the position of an object such as a tree close to the power transmission line and measures the separation distance between the object and the power transmission line, Two or more pieces of image information taken in a state where the transmission line supporting structure and the object are included from two or more shooting positions are input, and the image information is captured and collected by a digital camera, and in each photographic image The direction of the optical axis at the time of photographing is determined for each photographic image based on the transmission line support structure and the photographing position, and an object with spatial coordinates is simply projected parallel to the optical axis on a projection plane perpendicular to this optical axis. The transformation formula between the coordinates of the photographic image and the spatial coordinates is obtained for each photographic image through being represented by the projected two-dimensional coordinates and the depth, and being represented through a single point through the focal point. By determining two or more spatial coordinate points from two or more virtual depths and the two-dimensional coordinates on the projection plane for each of the depths for the object on each image, the direction to the object in spatial coordinates is determined. It is, Based on the intersection of the direction to the object obtained for each image, the actual position of the object is obtained, and a virtual wire equation in design is obtained using the line type information of the transmission line, etc. Preferably Correct this to the actual transmission line type currently being wired based on the transmission line on the image, and determine the separation distance between the object and the transmission line based on the position of the object and the transmission line type It is characterized by.
[0016]
Further, in addition to the above configuration, the system for measuring the separation distance of a transmission line proximity object according to the present invention relates to the shape and dimensions of a transmission line support structure, transmission line span information, and a photographic image for spatial coordinate recognition. Information, information on the shooting position coordinates are used, and for the transmission line type application, transmission line span information, transmission line type information, weather and temperature at the shooting date / time are used, and the transmission line diameter is used. The interval information, span length, ground height difference, installation angle of the transmission line support structure, transmission line angle, tension, design temperature, the number of conductors, the number of lines, and the like, the transmission line type information, Includes cross-sectional area, wire diameter / number, wire outer diameter, wire unit weight, elastic modulus, expansion coefficient, tensile strength, density, load coefficient, examination temperature, etc. , Including the coordinates of the transmission line support structure and the coordinates of the object on the photograph. It is characterized in.
[0017]
As described above, the transmission line type returns the three-dimensional information of the transmission line modeled based on the design conditions such as the transmission line type information to the photographic image, rather than the virtual one in the design. It is preferable to correct the difference from the transmission line to the actual one.
[0018]
By the way, the system is realized by a server on a network, and is connected to a site of the system via a network from a terminal having a communication function and uploaded, and the position of the target and the target It is also possible to provide a system for measuring the separation distance between objects near the transmission line, wherein the separation distance between the object and the transmission line is determined.
[0019]
In addition, at least two images are collected. Is one From two or more photographing positions on one side of the transmission line support structure side, the other transmission line support structure and the object may be photographed and collected in a state where they are included, but the shape and arrangement are known. It is needless to say that the image collection method can be appropriately changed as long as the object and the object such as a tree are captured. For example, among the images collected at least two, the first image is taken in a state where the other transmission line support structure and the target object are included from the imaging position on the one transmission line support structure side. On the other hand, while collecting, the second image may be captured and collected from a capturing position on the other transmission line support structure side in a state where the one transmission line support structure and the target object are included.
[0020]
Further, the photographing position itself does not necessarily need to be directly known from the beginning, and naturally includes a case where the photographing position is indirectly known. For example, the shooting position may be determined based on the transmission line support structure in the photographic image.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the system for measuring the separation distance between objects near a transmission line according to the present invention will be described in more detail based on embodiments.
[0022]
The separation distance measurement system according to the present embodiment captures the separation distance between a transmission line and an object that grows or exists near the transmission line (a tree, a structure such as an antenna on a building roof, or the like) from two or more known positions. This is measured by analyzing an image (photo file). It is possible to analyze from two or more images by a twin-lens stereo matching method or the like. In addition, by using information (focal length and the like) specific to an image, images captured under various conditions, such as standard imaging and zoom imaging, can be handled as analysis targets.
[0023]
In order to specify the position of a tree or the like and measure the separation distance between the tree 2 and the transmission line 10 using the present system, first, from one of the towers 1A, the tree 2 as an object and the other tower 1 It is necessary to capture image data by taking a camera in a state including 1B. The state of this on-site work is shown in the conceptual diagram of FIG. In addition, as shown in FIG. 2, a minimum of two photographs are taken, one each from the left and right sides of one of the towers 1A. As a result, as shown in FIG. 3, two photographs including the counterpart tower 1B and the trees 2 are collected.
[0024]
As an analysis method, first, a perspective transformation matrix for each image is created from the known data, and a three-dimensional direction vector in a spatial coordinate system from the shooting position to the target is calculated. From the plurality of three-dimensional direction vectors obtained in this way, the spatial coordinates of the object can be specified, and the distance from the transmission line coordinates at the position of the object determined by the transmission line equation can be obtained. Note that distortion of an image due to lens distortion, characteristics unique to the photographing machine, and the like are corrected in advance based on characteristics of the photographing machine to be used, information, and information on the image.
[0025]
In the system of the present embodiment, data as shown in the table of FIG. 4 is adopted as the known data. In the figure, at least three points on the transmission line supporting structure are adopted as the shape and dimensions of the transmission line supporting structure (such as a steel tower). In the case of a steel tower, the tip of an arm is usually used. In the present embodiment, for example, referring to the schematic diagram of an example of the tower 1 shown in FIG. 5, the heights of the respective arms 11 to 13 and the tower top (ground) 14, and the upper part of the post 15 supporting the arms The width of the vent 16, the width from the center to the tip of each of the left and right arms (for example, the first arm to the third arm) 11 to 13, the width from the center to the edge of the uppermost tower 14, and the like are adopted. Note that the center of the lower end of the tower is the reference point 17 of the space coordinates.
[0026]
In the transmission line span information, the span length is a horizontal distance between reference points such as adjacent steel towers. In addition, the ground height difference is defined as L. The vertical distance between (formation levels). The tower angle is a horizontal tilt angle (a swing angle of the tower) of the counterpart tower with respect to the photographing tower. Then, half of the transmission line angle is generally set as the tower angle. The tension is the maximum working tension. The number of conductors includes single conductors, multiple conductors, and four conductors. As for the number of lines, it is common that three arms protruding in the same direction constitute one line.
[0027]
Regarding the diameter and number of twisted wires in the transmission line type information, data is provided for two types in the case of a double line. The electric wire unit weight is the weight per meter. Tensile strength is the tensile strength. The load coefficient is a load related to wind (lateral shake) or snow (ice), and the study temperature is a temperature in the worst season (the worst condition transmission line temperature in the wind, the worst condition temperature in the stationary state).
[0028]
Among the information on the image, the tower shape coordinates or the object coordinates are the coordinates of the tower or the object on the photographic image. In practice, a photographic image taken by a digital camera is taken into a computer and displayed on its display, and then coordinates of a position designated by a mouse or the like are adopted.
[0029]
Regarding the coordinates of the photographing position, for example, when the photographing is performed at the center of the post section of the steel tower, the coordinates of the point may be specified. As the weather and the temperature, those at the time of shooting, or preferably at the time of shooting are employed.
[0030]
In order to associate the coordinates of the photographic image with the actual spatial coordinates, a perspective transformation matrix is created for all target images. The perspective transformation matrix is information for performing bidirectional coordinate transformation between a spatial coordinate system (actual three-dimensional coordinates) and an image coordinate system (coordinates on a photographic image). The geometric information includes a surface coefficient of a projection plane, shooting position coordinates, a plane projection matrix, and a virtual focal length.
[0031]
Among them, the plane coefficient of the projection plane indicates a three-dimensional plane coefficient on a space coordinate axis of an image projection plane (for example, a film plane) of the photographing machine. The photographing position coordinates indicate the center of the lens of the photographing machine, and are three-dimensional coordinates on a space coordinate axis.
[0032]
The plane projection matrix is a matrix for converting spatial coordinates into image coordinates or inversely converting image coordinates into spatial coordinates. This plane projection matrix does not include the convergence of light rays by the lens. The plane projection matrix can be calculated from the surface coefficient of the projection plane.
[0033]
The virtual focal length indicates a focal length required when considering the convergence of light rays by a lens.
[0034]
A description will be given of coordinate axes that are prerequisites for specifying the position of an object from image information.
First, spatial coordinate axes (world coordinates) as shown in FIG. 6 were set in order to recognize the actual space where the transmission line, the tower, the object, and the like exist. This origin was set as the steel tower reference point on the image capturing side. Then, the y-axis was taken horizontally from the reference point of the photographing-side tower toward the reference point of the counterpart tower. In addition, the x axis was taken rightward at right angles to the y axis. Further, the z-axis is perpendicular to the x- and y-axis planes and is taken in the upward direction.
[0035]
Note that, even when there is a height difference between the towers, the x and y axes were horizontal (perpendicular to the direction of gravity) as shown in FIG. The height difference is a level difference between the reference point of the photographing-side tower and the reference point of the partner-side tower, and is determined to be positive or negative in the z-axis direction.
[0036]
The main spatial coordinates include a photographing position (center of the photographing machine lens) Wc and an arm right position War and an arm left position Wal as respective coordinates obtained from the counterpart tower shape. In addition, each coordinate obtained from the shape of the photographing tower is also recognized as spatial coordinates. For the image, the shooting position has one coordinate, but the arm position has a plurality of coordinates due to the shape of the steel tower.
[0037]
On the other hand, in order to recognize a position on an image photographed by the photographing machine, image coordinate axes (picture coordinates) are set as shown in FIG. In this case, the center of the photographic image was the origin (0, 0), the right side was the x-axis, and the upper side was the y-axis. The main image coordinates include an arm right position Par and an arm left position Pal.
[0038]
Now, if a digital camera is used to photograph a counterpart tower with a known shape, dimensions, and arrangement from the known position of the shooting-side tower with a known distance, how the tower, shape, dimensions, and arrangement on the photograph image The optical axis is required to determine whether the image was taken in any direction. In addition, at the time of photography, in addition to the counterpart tower, at least a part of the transmission line bridged between the towers, and an object such as a tree close to the transmission line are photographed. In addition, for example, at least two photographic images from the left and right sides of the post part of the tower are photographed and used for analysis.
[0039]
A perspective transformation matrix is created for the captured photographic image. Describing the components of this perspective transformation matrix, the perspective transformation matrix is represented by a projection plane on a spatial coordinate axis and a focal point. This projection plane is a plane perpendicular to the optical axis and can be regarded as equivalent to a photographic image plane. Actually, the real image and the virtual image are point-symmetric via the focal point, but are conceptually as shown in FIG.
[0040]
The image coordinates represented in the photographic image can be transformed into spatial coordinates via the projection plane. Similarly, spatial coordinates can be transformed into image coordinates via a projection plane. For this coordinate conversion, a plane projection matrix is used. In this case, as shown in FIG. 10, it is assumed that everything on the spatial coordinates is simply projected on the projection plane parallel to the optical axis. The projection direction is uniquely determined from the surface coefficient of the projection plane.
[0041]
Thereby, as shown in FIG. 11, the spatial coordinates can be represented by the two-dimensional coordinates on the projection plane simply projected on the projection plane and the depth from the projection plane. That is, the vertical distance from the projection plane to the space coordinates is the depth distance.
[0042]
On the other hand, when the spatial coordinates are converted into image coordinates via the projection plane, the photograph is perspective one-point, so it is necessary to converge using the focal coordinates after the plane projection conversion. These states are shown in FIG.
[0043]
Looking at the state of the projection plane, as shown in FIG. 13, the image is converged toward the center of the image, and the distance is determined by the depth. When the plane coefficients of the projection plane are known, the intersections between the three-dimensional line segments of Wc, War, and Wal and the projection plane are Par ′ and Pal ′. Then, Par is obtained by a method as shown in FIG.
[0044]
By the way, as described above, in order to obtain a projection plane, it is necessary to obtain an optical axis as a direction vector collimated by the imaging device. The direction vector referred to here is a normal vector of the imaging plane. This normal vector is obtained by a method as shown in FIG. 16 with reference to FIG.
[0045]
This is conceptually shown in FIG. 17, where the line segment P ₀ P ₁ ~ P ₀ P ₃ Read the pixel value of ₀ P ₁ ~ P ₀ P ₃ And OP ₀ More OP ₁ ~ OP ₃ Find the length of T ₁ ~ T ₃ Point P on the extension connecting ₁ ~ P ₃ Coordinates of length OP ₁ ~ OP ₃ , P ₁ ~ P ₃ Is obtained, and if a normal passing through 0 is obtained, it becomes the optical axis.
[0046]
A plane projection matrix is calculated from the obtained normal vector by an equation as shown in FIG. Then, the Wc and Wa groups are coordinate-transformed using the plane projection matrix. The coordinates after the conversion are obtained by the equations shown in FIG.
[0047]
Further, as shown in FIG. 20, a virtual focal length is obtained from the distance from each coordinate of Wa ′ with respect to Wc ′ after the coordinate conversion. Then, f was calculated for all the given point groups, and the average value was used as the virtual focal length f in the target image.
[0048]
The projection plane is represented by ax + by + cz + d = 0. Here, a, b, and c are plane coefficients of the plane, and have the same values as the normal vectors Qa, Qb, and Qc described above. A projection plane separated from Wc in the direction of the normal vector (Qa, Qb, Qc) by a virtual focal length (f) is obtained. Then, by substituting the Wc coordinates for the x, y, and z components of the above equation, the d value can be obtained.
[0049]
Next, the position of the object is specified. That is, the position on the spatial coordinate axis of the tree or the existing structure growing near the transmission line is specified. Originally, it is a position specification for measuring the distance from the transmission line, so the target is a top or a branch tip for a tree, and the top or a corner for a structure.
[0050]
Here, as shown in FIG. 21, the camera is directed from the left and right photographing positions (A) and (B) of one of the towers (the photographing-side tower) to the adjacent other tower (the other-side tower). Consider a case in which an image is taken including an object that is likely to be close to an electric wire. In this case, by taking a picture of the counterpart tower having a known shape, dimensions, and arrangement separated by a known distance from the known shooting position, from the state of the counterpart tower shown in the photographic image, the camera of the counterpart by the method described above. An optical axis is required. Therefore, a projection plane perpendicular to the optical axis is also required.
[0051]
Then, in order to determine the actual position of the target on the photographic image, first, the direction from the shooting position to the target (direction vector on spatial coordinates) is determined from the target represented on each photograph. The direction to the target when one-point fluoroscopy is performed can be known from the line connecting the focal point and the target using a photographic image by the same method as the method shown in FIGS. 12 and 13. What is necessary is just to convert to coordinates.
[0052]
For this purpose, two virtual depths (for example, span length and camera position) are specified for the target object, and the direction at the time of one-point perspective is used to specify the target depth for each virtual depth. The two-dimensional coordinates on the projection plane when the object is simply projected on the projection plane can be obtained. Thereby, two points on the space coordinates are obtained from the two-dimensional coordinates and the depth. Therefore, if a line connecting these two points is obtained, it is the direction on the actual spatial coordinates from the shooting position to the object. In this way, it is possible to determine the position of the object by obtaining the direction from each photographing position to the object from each of the two photographs and obtaining the intersection thereof.
[0053]
As described above, the direction vector in the spatial coordinate axis from the shooting position to the target is calculated for each image, and the intersection of the direction vectors is performed for two or more photographic images of the same target. The point is the position of the object.
[0054]
That is, since the space coordinate axis is unique information regardless of each image, a three-dimensional line segment may be formed from the direction vector, and the intersection of a straight line in space may be calculated. In addition, depending on the imaging accuracy and the analysis accuracy, there is a possibility that one point in the space does not intersect, but in this case, the midpoint of the line segment indicating the shortest distance between the straight lines is taken as the object position. This is grasped as an analysis error, and improvement in accuracy can be expected by using a camera having a high resolution or increasing the number of target shot images.
[0055]
Finally, the calculation of the separation distance between the target object and the transmission line is performed. Based on the shapes of the photographing side and the counterpart tower, transmission line span information, transmission line type information, and shooting day weather, the transmission line The three-dimensional position is obtained. In other words, a transmission line formula for the bridging shape (hanging shape) of the transmission line is obtained from various data. For the transmission line type, a catenary type is originally used, but in addition, a parabolic type and other theoretical expressions similar to the catenary type are widely used, and an appropriate type is adopted.
[0056]
For the separation distance between the transmission line and the object, calculate the spatial coordinates of the transmission line under the design conditions at the position in the space where the object exists, calculate the horizontal distance and vertical distance between the two points, and separate from them. (The shortest distance) may be calculated. Then, preferably, a lateral vibration due to a change in wind and temperature is also examined. That is, it is preferable to estimate the distance between the transmission line and the target object by imagining the vertical and horizontal deviations (sag and lateral deflection) of the transmission line when the wind and temperature are the worst conditions.
[0057]
However, in practice, the wiring is not carried over with an error of ± 0 in the design conditions, and an error may occur when the distance between the transmission line position and the object under the design conditions is obtained. Therefore, at least two or more three-dimensional coordinates of the transmission line modeled under the design conditions are returned on the photograph, and the transmission line position under the design conditions arranged on the photograph is changed to the actual transmission line position on the photograph. By calculating the actual overhead line condition value, and by giving it to the transmission line formula, the spatial coordinates between the actual transmission line and the object are determined, and the horizontal distance, vertical distance, It is preferable to calculate the separation distance (the shortest distance).
[0058]
That is, it is desirable to correct the design / theoretical transmission line formula to the actual transmission line formula based on the transmission line in the portion shown in the photographic image. In this case, even if the transmission line at the position of the object is not shown in the photograph, it is possible to specify the position of the transmission line at the position of the object. When the transmission line at the position of the object is shown in the photograph, the transmission line position on the photograph may be used as it is.
[0059]
By the way, in the present embodiment, the separation distance between the transmission line and the object (the tip of a tree, an antenna, or the like) on a plane perpendicular to the longitudinal direction of the transmission line is determined. The shortest separation distance in the direction may be measured.
[0060]
Next, an example of an actual measurement actual field result will be described using the method described above. The photographing is performed at a temperature of 30 ° C., and information on the tower diameter (transmission line distance information) shown in FIG. 22, the tower information (shape and dimensions of the transmission line supporting structure) shown in FIG. 24, the wire specification information (transmission line type information) is known. In order to study the effectiveness of this system, as shown in FIG. 25, the position of the object and the distance between the object and the transmission line were determined in advance by surveying.
[0061]
First, using a digital camera, two pictures are taken from the shooting tower. Thereby, two pieces of image information of the reference image and the comparison image are collected. It should be noted that the information of each photographing position of the reference image and the comparison image is known as shown in FIG. 26 and FIG.
[0062]
Each of these pieces of image information is taken into a personal computer, and by specifying a desired location in the image displayed on the display by clicking with a mouse or the like, image coordinates (pixel information) at that location are collected. Here, as shown in FIG. 28, the coordinates of each arm position of the counterpart tower and the vertex of the tree as the object are obtained.
[0063]
Based on the above information, the unit vector of the optical axis for each image is obtained as shown in FIG. 29, and based on the information, as shown in FIG. 30, the direction vector of the optical axis and the plane projection transformation matrix Is calculated. Then, a virtual focal length for each image is calculated from the information as shown in the lower part of FIG.
[0064]
From the obtained perspective transformation matrix, as shown in FIG. 31, information (reference point + direction vector) for specifying a tree position in each image is calculated. Then, the position where the tree is actually located is specified from the reference point and the direction vector indicating the tree position calculated for each image, and the separation distance from the separately calculated transmission line position coordinates is calculated as shown in FIG. did. FIG. 33 shows the result of comparison with the actual survey result. When the actual survey result and the analysis result of the system were compared, a value of 1 mm was obtained for Tree 1 and a value of 27 mm was obtained for Tree 2 for the separation distance. This value increases or decreases depending on the accuracy of the photographing machine and the equipment used for analysis, but it has been confirmed that it is practical.
[0065]
According to the system of the above embodiment, the distance between the towers is relatively long, around 500 m (300 to 700 m), and the position of the target object can be obtained from the photograph image taken in an environment with relatively little parallax. The distance between the object and the transmission line can be accurately grasped.
[0066]
In addition, in the conventional general method, two people (a tower climber and a watcher watching the safety from the ground) are on the tower side, and two people are on the tree Katari side (the target tree is actually signaled by the towerer's signal). A total of four workers were needed, one who decides on the situation and a person who roughly assists in the decision from a place a little away (a place where they can see the transmission line and trees). According to the above, on-site work can be completed by two people, a photographer who ascends to a tower and shoots a tree kamari and a counterpart tower, and a watcher who watches over the tower from below. In other words, it is only necessary to take pictures at the site, and at the office, it is only necessary to analyze the pictures with an analysis measurement program.
[0067]
In addition, it is possible to accurately measure the information on the photographing tower, the other party's tower, the span information, the line type, etc., and to make this information into a database and make the user interface easy to understand, so that anyone can use it. In addition, anyone can achieve the same result, and there is no need to be an expert.
[0068]
Since lens distortion correction can be simplified and can be applied to a plurality of types of cameras, measurement can be performed without special equipment by using a generally sold digital camera having, for example, 1.3 million pixels or more.
[0069]
Since measurement can be performed with a single camera, there is no need to carry heavy objects such as light waves. Moreover, unlike the conventional aerial survey, it is not necessary to simultaneously photograph with two cameras arranged in a predetermined state.
[0070]
Work is possible without approaching a power line or the like, and it is not necessary to go to a place where an object such as a tree is present, so safety is ensured. In the conventional method, it is necessary to move on a steep slope, a cliff, a rocky road, or other road, which is not only troublesome and time-consuming, but also dangerous, but according to this system, it is necessary to go to a tree location Disappears.
[0071]
In addition, since the position of the transmission line could not be specified from the direction of the transmission line (lateral direction), it could only be measured by a photograph (image) from above, but this system specifies the transmission line. It is possible to measure the separation distance even from photographs (images) taken from the ground (horizontal direction (transmission line direction, line vertical direction)), from above and below from the ground.
[0072]
By the way, based on the captured image information, the position of the designated object is specified, the separation distance between the object and the transmission line is calculated, and the result is output according to the present embodiment. The computer program can be distributed as various computer-readable recording media such as a CD-ROM and a floppy disk. This computer program can also be transmitted and supplied to various terminals via a communication line.
[0073]
Further, a server connected to one or more terminals via a network (for example, the Internet) may enable the processing of the present embodiment. In that case, the server receives the required data transmitted from the terminal, performs analysis processing such as calculation of the separation distance based on the received data, returns the result to the terminal, and returns the result to the terminal side. What is necessary is just to be able to grasp the result. For example, preprocessing of image information is performed by software of each client terminal, necessary data (for example, data as shown in FIG. 4) is uploaded to the server, analyzed by the server, and the result is transmitted to the client terminal. Configure to reply. In this case, since it is not necessary to transmit large-capacity image data itself to the server, it is possible to speed up the processing.
[0074]
In addition, analysis is performed by connecting to a server via the Internet from a terminal equipped with a WWW browser, uploading an image on a web page of the website, inputting various data, designating a position, and the like. The result may be displayed on the terminal. Alternatively, it is conceivable to transmit image information and the like as an attached file of an e-mail, perform analysis on the server side that has received the image information, and report the result by an e-mail or the like.
[0075]
The method of collecting at least two images can be appropriately changed. FIG. 34 shows a variation of the image collection method.
FIG. 9A shows a case where the other tower is photographed from two or more photographing positions of one tower as described in the above embodiment. In this case, it is needless to say that each image is taken in a state where the other tower and the target tree are included. FIG. 2B shows a case in which at least one photo is taken from each of the two towers in a state where the other tower and the target tree are included.
[0076]
Further, FIG. 3 (C) shows that two images are collected from at least one of two or more arbitrary positions in a state where at least one of the towers and the target tree are included, and the photographing position is specified from the photograph image, and the photographing position is specified. In this case, the same analysis as in the above embodiments is performed using the values. In this case, in addition to the focal length of the camera, the shooting position can be set to a known position based on the shape, size, arrangement, direction, and the like of the tower. Also in this case, each image may be taken in a state including the tower on the same side, or one of the images may include one of the towers and the other may include the other tower. May be taken with the camera.
[0077]
【The invention's effect】
As described above in detail, according to the system for measuring the distance between objects close to a transmission line according to the present invention, anyone can easily handle the system easily, and it is possible to perform measurement / measurement / analysis quickly and accurately with a small number of people, thereby reducing costs. Can be achieved. Moreover, it is lightweight and safe.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram showing an example of an on-site work at the time of collecting image information by a photograph for a separation distance measurement by the system of the present invention.
FIG. 2 is a schematic plan view of FIG.
FIG. 3 is a diagram showing an example of photographic images respectively taken from the left and right sides of a steel tower by the methods shown in FIGS. 1 and 2.
FIG. 4 is a diagram showing an example of information provided as known data in an embodiment of the system of the present invention.
FIG. 5 is a schematic view showing an example of a steel tower shape.
FIG. 6 is a schematic diagram showing spatial coordinate axes used in one embodiment of the system of the present invention.
FIG. 7 is a schematic diagram showing a handling method when there is a height difference between towers on the spatial coordinate axis of FIG. 6;
FIG. 8 is a schematic diagram illustrating image coordinate axes used in one embodiment of the system of the present invention.
FIG. 9 is a perspective transformation diagram for explaining a perspective transformation matrix used in one embodiment of the system of the present invention.
FIG. 10 is a plan view illustrating a plan projection matrix used in an embodiment of the system of the present invention.
FIG. 11 is a block diagram showing a state of coordinate conversion using a plane projection matrix.
FIG. 12 is a one-point perspective view illustrating a coordinate transformation used in one embodiment of the system of the present invention.
13 is a convergence diagram showing a projection plane in FIG.
14 is a convergence calculation diagram based on FIG.
FIG. 15 is a conceptual diagram illustrating calculation of a normal vector in one embodiment of the system of the present invention.
FIG. 16 is a diagram showing a calculation state for considering normal vector calculation with reference to FIG. 15;
FIG. 17 is a conceptual diagram for explaining calculation of the direction of the optical axis in one embodiment of the system of the present invention.
FIG. 18 is a diagram showing a planar projection matrix and the like in one embodiment of the system of the present invention.
FIG. 19 is a diagram showing a coordinate conversion formula using the plane projection matrix of FIG. 18;
FIG. 20 is a conceptual diagram for explaining calculation of a virtual focal length in one embodiment of the system of the present invention.
FIG. 21 is a conceptual diagram for describing an object position identification in one embodiment of the system of the present invention.
FIG. 22 is a diagram showing tower span specification information for a test of an embodiment of the system of the present invention.
FIG. 23 is a diagram showing tower information for a test of an embodiment of the system of the present invention.
FIG. 24 is a diagram showing wire specification information for testing the embodiment of the system of the present invention.
FIG. 25 is a diagram showing object information obtained by a survey for comparison with a measurement result by the present system in a test of the embodiment of the system of the present invention.
FIG. 26 is a diagram showing reference image shooting position information for a test of an embodiment of the system of the present invention.
FIG. 27 is a diagram showing comparative image shooting position information for a test of an embodiment of the system of the present invention.
FIG. 28 is a diagram showing pixel information obtained from a reference image and a comparison image for a test of an embodiment of the system of the present invention.
FIG. 29 is a diagram showing information of a unit vector of an optical axis obtained from a reference image and a comparative image for a test of an embodiment of the system of the present invention.
FIG. 30 is a diagram showing information of a plane projection transformation matrix and a virtual focal length obtained in a test of an embodiment of the system of the present invention.
FIG. 31 is a diagram showing information for specifying a tree position obtained in the test of the embodiment of the system of the present invention.
FIG. 32 is a diagram showing information on tree positions obtained in a test of an embodiment of the system of the present invention.
FIG. 33 is a diagram comparing a result obtained in a test of an embodiment of the system of the present invention with a survey result of FIG. 25;
FIG. 34 is a diagram showing a variation of a photographing method for analysis by the system of the present invention.
FIG. 35 is a schematic view showing an example of a conventional method of measuring a separation distance between objects close to a transmission line.
[Explanation of symbols]
1 Transmission line support structure (pylon, etc.)
1A Shooting Tower
1B Counter Tower
2 Objects (trees, etc.)
10 Transmission line
11-13 arm

Claims (9)

A transmission line of a known line type is bridged between transmission line support structures whose shape, dimensions, arrangement, etc. are known, and the position of an object such as a tree near the transmission line is specified, and the object A system for measuring the separation distance between the power transmission line and
Two or more image information taken in a state where the transmission line support structure and the object are included from two or more shooting positions are input,
The image information is captured and collected by a digital camera,
Based on the transmission line support structure and the photographing position in each photographic image, the direction of the optical axis at the time of photographing is obtained for each photographic image,
On a projection plane perpendicular to this optical axis, it is assumed that an object in space coordinates is represented by two-dimensional coordinates and depth simply projected parallel to the optical axis, and is also represented by a single point perspective through a focal point. The transformation formula between the coordinates of the photographic image and the spatial coordinates is obtained for each photographic image,
For an object on each image, by obtaining two or more spatial coordinate points from two or more virtual depths and the two-dimensional coordinates on a projection plane for each of the depths, a direction to the object in spatial coordinates is obtained. ,
Based on the intersection of the direction to the object determined for each image, the actual position of the object is determined,
Using the line type information of the transmission line, the transmission line type is determined,
A separation distance measuring system for an object near a transmission line, wherein a separation distance between the object and the transmission line is obtained based on a position of the object and a transmission line type. The image information is captured and collected from two or more known imaging positions on one transmission line support structure side in a state where the other transmission line support structure and the object are included. The system for measuring a separation distance between objects near a transmission line according to claim 1. Of the image information collected at least two,
The first image information is collected from a known imaging position on one side of the transmission line support structure, and is captured in a state where the other transmission line support structure and the target object are included,
The second image information is captured and collected from a known imaging position on the other transmission line supporting structure side in a state where the one transmission line supporting structure and the target object are included. Item 4. A system for measuring a separation distance between objects close to a transmission line according to Item 1. 4. The system for measuring a separation distance between objects near a transmission line according to claim 1, wherein the photographing position is obtained based on a transmission line support structure in a photographic image. 5. For spatial coordinate recognition, the shape and dimensions of the transmission line support structure, transmission line span information, information on photographic images, and information on shooting position coordinates are used,
For transmission line type application, transmission line span information, transmission line type information, weather and temperature at shooting date / time are used,
The transmission line span information includes span length, ground height difference, installation angle of the transmission line support structure, transmission line angle, tension, design temperature, number of conductors, number of lines, and the like,
The transmission line type information includes cross-sectional area, twisted wire diameter / number, wire outer diameter, wire unit weight, elastic modulus, expansion coefficient, tensile strength, density, load coefficient, study temperature, etc.
2. The separation distance between objects close to a transmission line according to claim 1 , wherein the information related to the photographic image includes a focal length, a correction coefficient, a shape coordinate of the transmission line supporting structure on the photograph, and an object coordinate. Measurement system. The transmission line type is characterized in that the three-dimensional information of the transmission line modeled according to the design conditions such as the transmission line type information is returned to the photographic image, and the difference from the transmission line on the photograph is corrected to the actual one The distance measuring system for an object near a transmission line according to any one of claims 1 to 5 . The system is realized by a server on a network,
From a terminal having a communication function, via the network, via the information connected to the site of the present system and uploaded, a position of the object and a separation distance between the object and the transmission line are obtained. The system for measuring the separation distance of an object near a transmission line according to any one of claims 1 to 6 . A transmission line of a known line type is bridged between transmission line support structures whose shape, dimensions, arrangement, etc. are known, and the position of an object such as a tree near the transmission line is specified, and the object In order to measure the separation distance between
Receiving input of two or more image information taken by a digital camera in a state where the transmission line support structure and the object are included from two or more shooting positions,
A step of obtaining the direction of the optical axis at the time of photographing for each photograph image based on the transmission line support structure and the photographing position in each photograph image ,
On a projection plane perpendicular to the optical axis, an object in actual space coordinates is represented by two-dimensional coordinates and depth simply projected parallel to the optical axis, and is also represented by a single point perspective through the focal point. Obtaining a conversion formula between the coordinates of the photographic image and the spatial coordinates for each photographic image ,
Obtaining a direction to the object in spatial coordinates by obtaining two or more spatial coordinate points from two or more virtual depths and the two-dimensional coordinates on the projection plane for each of the depths for the object on each image; When,
Determining the actual position of the object based on the intersection of the directions to the object determined for each image;
Using a line type information of the transmission line to obtain a transmission line formula;
Obtaining a separation distance between the object and the transmission line based on the position of the object and the transmission line type,
A program to be executed by a computer. A transmission line of a known line type is bridged between transmission line support structures whose shape, dimensions, arrangement, etc. are known, and the position of an object such as a tree near the transmission line is specified, and the object A method for measuring the separation distance between the power transmission line and
Collecting two or more image information with a digital camera in a state where the transmission line support structure and the object are included from two or more shooting positions,
Based on the transmission line support structure and the photographing position in each photograph image, the direction of the optical axis at the time of photographing is obtained for each photograph image ,
On a projection plane perpendicular to this optical axis, it is assumed that an object in space coordinates is represented by two-dimensional coordinates and depth simply projected parallel to the optical axis, and is also represented by a single point perspective through a focal point. , A conversion formula between the coordinates of the photographic image and the spatial coordinates is obtained for each photographic image ,
For an object on each image, by obtaining two or more spatial coordinate points from two or more virtual depths and the two-dimensional coordinates on a projection plane for each of the depths, a direction to the object in spatial coordinates is obtained,
Determining the actual position of the object based on the intersection of the direction to the object determined for each image,
Using transmission line type information, etc., find the transmission line formula,
A method for measuring a separation distance between objects close to a transmission line, wherein a separation distance between the target object and the transmission line is obtained based on a position of the object and a transmission line type.

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