JP2004325091A - Cell count method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cell count method capable of accurately distinguishing cell sizes on tracks and counting cells in a short time. <P>SOLUTION: Since the starting location of data on a cell 1 on a track 2 is surely detected by both a determination window 5A for detecting "0s", provided for the first line of a scanning window 5 and a 1×1 determination window 5B for detecting "1s" provided for the second line of the scanning window 5, cell can be distinguished and cells can be counted, without duplicating and determining the same data, or without having to erase data in the window 5. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a cell counting method for counting cells of a certain range according to size for cells having various sizes.
[0002]
[Prior art]
Hereinafter, a conventional cell counting method for counting cells within a certain range by size for cells of various sizes injected into an analysis disk will be described with reference to the drawings.
[0003]
FIG. 5 is an explanatory diagram of a cell detection method in a conventional cell counting method. FIG. 5A shows a positional relationship between a cell as a measurement object on an analysis disk, a track, and a laser beam in the conventional cell counting method. FIG. 5B is an explanatory diagram of a method of determining the size of a cell using a window in a conventional cell counting method and counting by cell size.
[0004]
In FIG. 5A, reference numeral 1 denotes a cell which is a measurement object injected onto the analysis disk, reference numeral 2 denotes a track on the analysis disk, and reference numeral 3 denotes a laser beam which relatively moves on the analysis disk. A conventional analyzer injects a sample into an analysis disk and analyzes the number of specific cells among the cells 1 having various sizes existing in the sample. In such an analyzer, Tracks 2 are spirally formed on the analysis disk in the same manner as an optical disk such as a CD-ROM, and the laser beam 3 is controlled to move relatively on the tracks 2 when the analysis disk rotates. ing.
[0005]
On the other hand, the cell 1 to be measured is larger than the width of the track 2 and exists over a plurality of tracks 2. When the laser beam 3 moves on the track 2, the cell 1 is on the track 2. A signal change occurs in the laser light receiving unit depending on whether or not the signal is received. By processing this signal change, if it is determined that there is a cell 1, "1" is stored in the memory, otherwise "0" is stored in the memory. By detecting the length in the direction, the size of a plurality of cells is determined, and the number is counted for each size.
[0006]
As described above, a cell counting method for judging the size of a cell and counting the cells according to the size is as follows. A method of detecting and counting cells as objects by size is used.
[0007]
In the above-described cell counting method, for example, when an attempt is made to detect the number of cells having a size of six tracks from a plurality of cells having a size of 1 to 11 tracks, FIG. As shown in (1), first, scanning is performed using a window having a size of 6 × X1 while shifting one by one in the X direction, and the number of locations where “1” is included in each row of the window is counted.
[0008]
Next, scanning is performed using a window having a size of 7 × X1 while shifting one by one in the X direction, and the number of locations where “1” is included in each row of the window is counted.
[0009]
Thus, the number of cells existing over six or more tracks and the number of cells existing over seven or more tracks can be obtained, and the number of cells having the size of six tracks can be obtained from the difference.
[0010]
Here, X1 is an integer value larger than the range of “1” displacement due to disc rotation unevenness or signal detection variation, and even if a “1” displacement occurs in each track, it is detected from the same cell. Can be detected as "1".
[0011]
[Patent Document 1]
JP 2000-287077 A
[Problems to be solved by the invention]
However, in the measurement method based on the conventional cell counting method as described above, when X1 is large and the displacement of “1” in each track is small in the window movement after counting, the once detected arrays are overlapped. There is a possibility of reading.
[0013]
Further, for example, when an attempt is made to detect a cell having a size of six tracks, even a cell having a size of seven or more is detected again in the window scanning of the next row even if the cell is detected once.
[0014]
Therefore, in the conventional cell counting method, the portion detected in the window and counted once is converted from "1" to "0" so as not to be redundantly read as "1". When the detection is performed by switching the window size, it is necessary to repeat the measurement of whether or not there are cells on the track by scanning the windows of all the rows again, and it takes a long time to perform the measurement. Had.
[0015]
The present invention solves the above-mentioned conventional problems, and it is not necessary to re-measure the presence or absence of a cell a plurality of times on a track, and the cell size can be accurately determined in a short time. Provided is a cell counting method capable of determining and counting.
[0016]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, a cell counting method according to claim 1 of the present invention provides a method of counting “0” or “1” obtained based on the presence or absence of cells of a plurality of sizes injected on an analysis disk. From the memory that stores the data array in which the binary data is plane-arranged as the horizontal direction X and the vertical direction Y, the size is expressed as a row × X with the X direction of the data array as a row and the horizontal direction X and the vertical direction Y The data array in the area is read by a scan window that can be moved to, the presence or absence of the cell is calculated based on the data, the cell size is determined, the cell size is determined, and the cell size is determined for each cell size. A cell counting method for counting the number of pixels, wherein a first determination is made as to whether or not the scanning window has a size of 1 × X1 (X1: a constant in an integer range) and all the areas become “0”. Wind And a second window for judging whether or not the area is “1” in a 1 × 1 size located at the center in the X direction of the first window in the row next to the first window. A third determination is made as to whether each row in the area has at least one “1” based on the size of Y × X1 (Y: a variable in an integer range) located on the next row of the second window. And a method of determining the cell size using the scanning window.
[0017]
As described above, when the data array is scanned and read in the scanning window, the second window is determined to be “1” in an area of the size of row × X = 1 × 1. Is not determined, the cell size can be determined for the cells on the track without duplicate determination of the same data, and the number of cells for each size can be counted.
[0018]
A cell counting method according to a second aspect of the present invention is the cell counting method according to the first aspect, wherein X1 is a value larger than a displacement range due to a variation in a sampling start point.
[0019]
As described above, since the data of the first window and the third window is determined by X1 which is larger than the displacement range as X, the position of "1" can be detected even if the sampling start point is displaced.
[0020]
The cell counting method according to claim 3 is the cell counting method according to claim 1 or 2, wherein the size of the cell to be detected is Y2 to Y3 (Y2 and Y3 are integers, and Y2 <Y3). Assuming that Y = Y2-1, reading of the data array in the area is started by the scanning window, and if the condition of the scanning window is matched, Y is set to Y2, Y2 + 1,. And a determination is made as to whether the condition matches the Y range condition, and the data array in the area is read until the condition no longer matches or Y = Y3. It is characterized by.
[0021]
As described above, the third window does not need to read the blank range when the scanning window is switched, and can reduce the time required for detection.
A cell counting method according to a fourth aspect is the cell counting method according to any one of the first to third aspects, wherein the presence / absence of the cell is determined by using a laser on a track on the analysis disk into which the cell is injected. The method is characterized by irradiating light and making a determination based on a change in the amount of light when received by a photodetector.
[0022]
As described above, the presence or absence of a cell on a track is determined only by a change in the amount of light when light is received by a photodetector by irradiating a laser beam. Since the data is stored, the complexity of data processing when a plurality of “1” s exist in one cell can be avoided.
[0023]
According to a fifth aspect of the present invention, in the cell counting method, binary data of “0” or “1” obtained based on the presence or absence of a plurality of size cells injected on the analysis disk is used in the horizontal direction X and the vertical direction. From a memory that stores a data array that is plane-arrayed as Y, a scanning window whose size is represented by row × X with the X direction of the data array as a row and that can be moved in the horizontal direction X and the vertical direction Y A cell counting method of reading the data array in the area, determining the presence or absence of the cell by calculating based on the data, determining the cell size, and counting the number of cells for each cell size. A first window for determining whether or not the entire area of the scanning window is “0” with a size of 1 × X1 (X1 is an integer variable); and a row next to the first window. so A second window which is located at the center of the first window in the X direction and has a size of 1 × 1 and determines whether or not the area is “1”; and a second window which is located next to the second window. A third window for determining whether each line in the area has a size of Y1 × X1 (Y1 is an integer variable) and includes at least one “1”, and a third window positioned at a line next to the third window And a fourth window for determining whether or not the entire area is "0" with a size of 1 × X1 (X1 is an integer variable), and the cell size is determined using this scanning window. Is determined.
[0024]
As described above, when the data array is scanned and read in the scanning window, the second window is determined to be “1” in an area of the size of row × X = 1 × 1. Data is not determined, the cell size can be determined by scanning the window only once for each desired detection size without duplicating the same data for the cells on the track. Another number can be counted.
[0025]
A cell counting method according to a sixth aspect is the cell counting method according to the fifth aspect, wherein X1 is a value larger than a displacement range due to a variation in the sampling start point.
[0026]
As described above, since the data of the first window and the third window is determined by X1 which is larger than the displacement range as X, the position of "1" can be detected even if the sampling start point is displaced.
[0027]
A cell counting method according to a seventh aspect is the cell counting method according to the fifth or sixth aspect, wherein the presence or absence of the cell is determined by irradiating the track on the analysis disk into which the cell is injected with a laser beam. However, the method is characterized in that the determination is made based on a change in the amount of light when light is received by the photodetector.
[0028]
As described above, the presence or absence of a cell on a track is determined only by a change in the amount of light when light is received by a photodetector by irradiating a laser beam. Since the data is stored, the complexity of data processing when a plurality of “1” s exist in one cell can be avoided.
[0029]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a cell counting method according to an embodiment of the present invention will be specifically described with reference to the drawings.
(Embodiment 1)
The cell counting method according to the first embodiment of the present invention will be described.
[0030]
FIG. 1 is an explanatory diagram of a cell detection method in the cell counting method of the first embodiment. FIG. 1A shows cells and tracks as measurement objects on an analysis disk in the cell counting method of the first embodiment. FIG. 1B is an explanatory diagram of a method of determining the size of a cell using a window and counting by cell in the cell counting method according to the first embodiment.
[0031]
In FIG. 1A, reference numeral 1 denotes a cell which is a measurement object injected onto an analysis disk, 2 denotes a track on the analysis disk, and 3 denotes a laser beam which relatively moves on the analysis disk. The analyzer according to the first embodiment injects a sample into an analysis disk and analyzes the number of specific cells among cells 1 having various sizes existing in the sample. In the analysis apparatus, a track 2 is spirally formed on the analysis disk in the same manner as an optical disk such as a CD-ROM, and the laser beam 3 moves relatively on the track 2 when the analysis disk rotates. Is controlled as follows.
[0032]
On the other hand, the cell 1 to be measured is larger than the width of the track 2 and exists over a plurality of tracks 2. When the laser beam 3 moves on the track 2, the cell 1 is on the track 2. A signal change occurs in the laser light receiving unit depending on whether or not the signal is received. By processing this signal change, if it is determined that there is a cell 1, “1” is stored, otherwise “0” is stored in the memory 4 as a data array as shown in FIG. Store.
[0033]
In addition, the scanning window in the cell counting method according to the first embodiment basically has a size represented by a row × X with the X direction of the data array of the memory 4 as a row. As shown in FIG. For the data array of the memory 4, a first window 5 </ b> A that determines whether or not the entire area is “0” with a size of 1 × X1 (X1 is an integer constant); In the next row, a second window 5B which is located at the center of the first window 5A in the X direction and has a size of 1 × 1 and determines whether or not the area is “1”; And a third window 5C for determining whether each row in the area has at least one "1" with a size of Y.times.X1 (Y is an integer variable) located in the row of. And
[0034]
Such a scanning window 5 can be moved in the horizontal direction X and the vertical direction Y of the data array, and the scanning window 5 starts scanning from the upper left of the data array as a sampling start point and shifts one by one to the right. When the end of the line has been reached, the window is moved starting from the left end of the next line as the head, and a position matching the condition in each window is searched while shifting one by one from left to right.
[0035]
The size of the window 5C in the vertical direction Y differs depending on the cell size to be obtained. FIG. 2 shows a procedure for detecting a cell having a size of six tracks as an example.
[0036]
First, the size of the window 5C in the scanning window 5 is set to 5 × X1 (X1 = 7 in FIG. 2A), and the window is scanned rightward as shown in FIG. When the window reaches the end, the window is moved starting from the left end of the next line, and shifted one by one from left to right to search for a portion that satisfies the condition.
[0037]
The detection result by the scanning window 5 when all the search ranges are completed indicates the number of cells equal to or more than six tracks. In the data array in FIG. 2, when the search is performed in the above-described scanning window 5, as shown in FIG. 2B, three locations are detected as locations satisfying the condition, and there are three or more cells for six or more. Will be.
[0038]
Next, the size of the window 5C is set to 6 × X1, and in the same manner as above, the window 5C is shifted one by one from the left to search for a portion satisfying the condition. In this way, the detection result by the scanning window 5 when all the search ranges are completed indicates the number of cells equal to or more than seven tracks. In the data array in FIG. 2, as shown in FIG. 2 (c), two locations are detected as locations satisfying the condition, and there are two cells of seven or more.
[0039]
From the above, the number of cells existing over six or more tracks and the number of cells existing over seven or more tracks are obtained, and the number of cells having the size of six tracks is obtained from the difference therebetween. Can be. Thus, it can be seen that one cell having a size of six exists in the data array of FIG. Here, X1 is an integer value larger than the variation range of the data array.
[0040]
Since the detection conditions other than the detection positions shown in FIGS. 2B and 2C do not satisfy the detection conditions of each of the windows 5A, 5B, and 5C of the scanning window 5, data is not read redundantly as in the related art. In this way, there is no need to delete the data, and the data need not be measured again.
(Embodiment 2)
A cell counting method according to the second embodiment of the present invention will be described.
[0041]
FIG. 3 is an explanatory diagram of a cell detection method in the cell counting method according to the second embodiment. FIG. 3A is a diagram illustrating a cell and a track as measurement objects on an analysis disk in the cell counting method according to the second embodiment. FIG. 3B is a diagram illustrating a method of determining the size of a cell using a window and counting by cell size in the cell counting method according to the second embodiment.
[0042]
In FIG. 3A, reference numeral 1 denotes a cell which is a measurement object injected onto the analysis disk, 2 denotes a track on the analysis disk, and 3 denotes a laser beam which relatively moves on the analysis disk.
[0043]
Note that, in the cell counting method of the second embodiment, the steps up to the point where the data array is stored in the memory 4 are the same as those of the first embodiment, and a description thereof will be omitted.
[0044]
The size of the scanning window in the cell counting method of the second embodiment is basically represented by a row × X with the X direction of the data array of the memory 4 as a row, and as shown in FIG. A first window 6A for determining whether or not the entire area is “0” with a size of 1 × X1 (X1 is an integer variable), and a data array next to the first window 6A A second window 6B that is located at the center of the first window 6A in the X direction in the row and has a size of 1 × 1 and determines whether or not the area is “1”, and a row next to the second window 6B A third window 6C for determining whether or not each line in the area has at least one “1” based on the size of Y1 × X1 (Y1 is an integer variable) located next to the third window 6C 1 × X1 (X1 is an integer variable) The scanning window 6 includes a fourth window 6D for determining whether or not the entire area is “0”.
[0045]
Such a scanning window 6 can be moved in the horizontal direction X and the vertical direction Y of the data array, and the scanning window 6 starts scanning from the upper left of the data array which is a sampling start point and shifts one by one to the right. When the end of the line has been reached, the window is moved starting from the left end of the next line as the head, and a position matching the condition in each window is searched while shifting one by one from left to right.
[0046]
The size of the window 6C in the vertical direction Y differs depending on the cell size to be obtained. FIG. 4 shows a procedure for detecting a cell having a size of six tracks as an example.
[0047]
First, the size of the window 6C in the scanning window 6 is set to 5 × X1 (X1 = 7 in FIG. 4A), and the scanning window 6 is scanned from the upper left to the right in the data array as shown in FIG. After moving to the end of the line, move the window starting from the left end of the next line, and shift one by one from left to right to search for a portion that satisfies the condition.
[0048]
The detection result by the scanning window 6 when all the search ranges have been completed indicates the number of cells for six tracks. In the data array shown in FIG. 4, when the search is performed in the above-described scanning window 6, it is detected as a location satisfying the condition in one location of the scanning window 6 shown in FIG. There will be individuals.
[0049]
Since the detection condition of the scanning window 6 is not satisfied at positions other than the detection position by the scanning window 6 shown in FIG. 4B, there is no need to delete the data so as not to read the data redundantly, and to measure the data again. You don't have to.
[0050]
As a result, it is not necessary to re-measure the presence or absence of the cell on the track a plurality of times, and the cell size can be determined and counted accurately in a short time.
[0051]
【The invention's effect】
As described above, according to the present invention, the determination window provided on the first line of the scanning window for detecting 0 and the 1 × 1 determination window provided on the second line of the scanning window for detecting 1 provide a track on the track. By reliably detecting the start position of the data for the cell, the cell size can be determined and counted without duplicating the same data without erasing the data in the window.
[0052]
Therefore, it is not necessary to re-measure the presence or absence of a cell on a track a plurality of times, and the cell size can be determined and counted accurately in a short time.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a cell detection method in a cell counting method according to a first embodiment of the present invention; FIG. 2 is an explanatory diagram of window scanning in the first embodiment; FIG. 3 is a cell of a second embodiment of the present invention; FIG. 4 is an explanatory diagram of a cell detection method in a counting method. FIG. 4 is an explanatory diagram of window scanning in the first embodiment. FIG. 5 is an explanatory diagram of a cell detection method in a conventional cell counting method.
1 Cell 2 Track 3 Laser beam 4 Memory 5, 6 Scanning window 5A, 6A, 6D 1 × X1 (X1 is an integer constant) window 5B, 6B 1 × 1 window 5C, 6C Y × X1 (Y is an integer Variable) window

Claims (7)

A memory storing a data array in which binary data of “0” or “1” obtained based on the presence or absence of a plurality of size cells injected on the analysis disk is arranged in a horizontal direction X and a vertical direction Y The data array in the area is read by a scanning window whose size is represented by a row × X with the X direction of the data array as a row and which can be moved in the horizontal direction X and the vertical direction Y, and A cell counting method for calculating the presence or absence of the cell based on data, determining the cell size, and counting the number of cells for each cell size, wherein the scanning window is 1 × X1 (X1: A first window for determining whether or not the entire area becomes “0” in the size of (integer of an integer range), and a position next to the first window in the X direction center of the first window A second window for determining whether or not the area is “1” with a size of 1 × 1, and Y × X1 (Y: a variable in an integer range) located on the next line of the second window And a third window for determining whether or not each row in the area has at least one "1" in the size of the area, and the cell size is determined using the scanning window. Cell counting method. 2. The cell counting method according to claim 1, wherein X1 is a value larger than a displacement range due to a variation in a sampling start point. The size of the cell to be detected is set in the range of Y2 to Y3 (Y2 and Y3 are integers, Y2 <Y3), and Y = Y2-1, and reading of the data array in the area by the scanning window is started. When the condition is matched, Y is sequentially changed to Y2, Y2 + 1,... At the matched position, and it is determined whether or not the condition matches the range condition of Y. 3. The cell counting method according to claim 1, wherein the data array in the area is read until Y3 is reached. 4. The method according to claim 1, wherein the presence or absence of the cell is determined by irradiating a track on the analysis disk into which the cell is injected with a laser beam and changing a light quantity when the track is received by a photodetector. 5. Cell counting method. A memory storing a data array in which binary data of “0” or “1” obtained based on the presence or absence of a plurality of size cells injected on the analysis disk is arranged in a horizontal direction X and a vertical direction Y The data array in the area is read by a scanning window whose size is represented by a row × X with the X direction of the data array as a row and which can be moved in the horizontal direction X and the vertical direction Y, and A cell counting method for calculating the presence or absence of the cell by calculating based on data, determining the cell size, and counting the number of cells for each cell size, wherein the scanning window is 1 × X1 (X1 is A first window for determining whether or not the entire area becomes “0” according to the size of an integer variable), and a line next to the first window, which is located at the center of the first window in the X direction. A second window for determining whether or not the area is “1” with a size of 1 × 1, and a size of Y1 × X1 (Y1 is an integer variable) located in a row next to the second window Now, a third window for determining whether each row in the area contains at least one "1", and a 1 × X1 (X1 is an integer variable) located in a row next to the third window A cell counting method, comprising: a scanning window including a fourth window for determining whether or not the entire area becomes “0” in size, and using the scanning window to determine the cell size. 6. The cell counting method according to claim 5, wherein X1 is a value larger than a displacement range due to a variation in the sampling start point. 7. The cell count according to claim 5, wherein the presence or absence of the cell is determined by irradiating the track on the analysis disk into which the cell has been injected with a laser beam and changing the amount of light when the photodetector receives the laser beam. Method.

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