JP2002028154A - Image display method, image display system, and abnormal shadow candidate detection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To observe detailed conditions of an abnormal shadow candidate, and read a whole image in an image display system. SOLUTION: This image display system comprising a display means 1 to display abnormal shadow candidates P1, P2 and the whole body of an image (a whole image) P0 detected by an abnormal shadow candidate detection system 20, is provided with a second picture element density converting means 3 to display the abnormal shadow candidates P1, P2 in their number of picture elements as read and obtained, a first picture element density converting means 2 to display the whole image P0 in a reduced number of picture elements from that read and obtained, and a display layout setting means 4 to set layout in a display range in the display means 1 to display abnormal shadow candidates P1", P2" of equal magnification with a converted picture element density in a display range different from a range where a contracted whole image P0' with a converted picture element density is displayed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image display method and an image display system, and an abnormal shadow candidate detection system using the image display system. More specifically, the present invention relates to an abnormal shadow candidate portion detected based on an image and an entire image. And improvement of the display.

[0002]

2. Description of the Related Art Conventionally, in a medical field, a radiation image of a patient is photographed, and a film on which the obtained radiation image is recorded is read on a shakasten for interpretation.
They are used to diagnose injuries and other conditions. In recent years, instead of directly exposing a radiation image to a film,
The radiation image is stored in a stimulable phosphor sheet (radiation image conversion panel) for storing and storing the radiation image, and the excitation light is applied to the stimulable phosphor sheet to emit the stimulated emission light in a light amount corresponding to the stored and stored radiation image. To obtain a digital image signal, and then print the digital image signal as a visible image on an image recording carrier such as a film (radiation image recording and reading system (computed radiography). ); JP-A-55-12429
Nos. 56-11395 and 56-11397).

According to such a radiation image recording and reading system, by performing various signal processing on the digital image signal, the gradation characteristics and frequency characteristics of the output visible image are more suitable for image reading than before. The diagnostic performance based on images can be improved.

A digital image signal obtained by reading is analyzed using a computer, and abnormal shadows such as tumor shadows and microcalcification shadows appearing in the image are automatically detected, so that the image reader's image is read. A system has been developed which secures a certain detection level even when the image reading proficiency is low and is useful for diagnosis (computer-assisted image diagnosis (abnormal shadow candidate detection) system; Japanese Patent Application Laid-Open No. 8-294479).

This system automatically detects candidates for a tumor shadow in an image by evaluating the degree of concentration of a density (signal value) gradient vector of a digital image signal (mammography) of a breast obtained mainly by a breast cancer screening. Or by performing morphological operations (dilation, erosion, opening, closing, etc.) on digital image signals to automatically detect candidates for microcalcification shadows. This system detects abnormal shadow candidates such as image formation. The abnormal shadow candidates detected by this system are marked on a mammography by, for example, a rectangular ROI (region of interest) frame, and the CRT or the liquid crystal display device is used. Can be used for diagnosis by displaying it on the printer or printing it on a diagnostic film.

[0006]

The image used for detecting an abnormal shadow candidate by the abnormal shadow candidate detection system is read at an extremely high reading resolution, for example, 5 cycles / mm or more. Reading resolution. Then, an image having such a high reading resolution, that is, an image having an extremely large number of pixels is converted to a CRT image.
When an image is displayed on an image display device such as an LCD or an LCD, it is practically impossible to reproduce the entire image on the display device in a single frame while substantially maintaining the number of read pixels. That is, for example, when a six-section image is read at a vertical resolution of 10 lines / mm, a resolution of approximately 2500 lines is required in the vertical direction for the entire image, whereas a normal display device has about 1600 lines per frame. It has only resolving power and cannot display the entire image in one frame.

For this reason, generally, the pixel count of the entire image is reduced by the pixel density conversion means provided in the image display device so that the number of pixels of the entire image is equal to or less than the number of displayable pixels of the image display device.
The whole image is displayed in one frame by converting the pixel density of the entire image and displaying the image after the pixel density conversion on the display surface.

However, an interpreter such as a doctor who uses image interpretation for diagnosing a disease wants to perform detailed observation interpretation on an abnormal shadow candidate portion extracted from the entire image, regardless of the entire image. It is desired to enlarge and display that part (abnormal shadow candidate part) in the entire image to be displayed.

Therefore, the applicant of the present application performs image processing for enlarging the abnormal shadow candidate portion in the entire image, displays the enlarged abnormal shadow candidate portion separately from the entire image, and displays the portion in the entire image. Proposed an abnormal shadow candidate detection system that makes it easy to read images
No. 294479).

By the way, the whole image for display described above is subjected to pixel density conversion by the image display device and is once reduced, and it is not reasonable to further expand the abnormal shadow candidate portion.

The present invention has been made in view of the above circumstances, and makes it possible to read an abnormal image candidate extracted from the entire image in detail while making it possible to read the entire image on one screen. It is an object of the present invention to provide an image display method, an image display system, and an abnormal shadow candidate detection system.

[0012]

According to the image display method and the image display system of the present invention, when the total number of pixels of an image to be displayed is larger than the number of displayable pixels of the image display device, the whole image is displayed. Apply the pixel density conversion to reduce the number of pixels and display the whole, and for the abnormal shadow candidate part extracted from the image, separately from the whole image, the original number of pixels or more pixels By satisfying the requirement, it is possible to observe the entire image at a glance while making it possible to observe the abnormal shadow candidate portion in detail, and to eliminate the irrational process of once reducing and then enlarging.

That is, the first image display method of the present invention is as follows.
In an image display method for displaying an image on an image display device,
When displaying an entire image having a larger number of pixels than the number of displayable pixels of the image display device on the image display device, so that the number of pixels of the entire image is equal to or less than the number of displayable pixels of the image display device, While the whole image is subjected to pixel density conversion and displayed on the image display device, an abnormal shadow candidate portion extracted from the whole image based on the whole image is
Pixel density conversion so that the number of pixels is equal to or more than the number of pixels of the corresponding portion in the entire image before the pixel density conversion, and displaying the image on the image display device separately from the entire image after the pixel density conversion. It is a feature.

Here, the number of pixels of the whole image means, for example, the number of pixels when reading an image recorded on an image recording carrier such as a film, a radiation detector, or a stimulable phosphor sheet;
It refers to the number of pixels of an image obtained by the subsequent signal processing and the like, and refers to the number of pixels of an image input to an image display device that finally displays a visible image.

When the pixel density of the whole image is converted so that the number of pixels of the whole image is equal to or less than the number of displayable pixels of the image display device, the number of pixels of the whole image (original whole image) input to the image display device is changed. For example, when 2500 pixels × 2000 pixels are displayed on an image display device having a resolution of about 1600 pixels × 1200 pixels, for example, the entire image of 2500 pixels × 2000 pixels falls within the range of 1600 pixels × 1200 pixels. As described above, this means that the number of pixels is reduced by performing pixel thinning or interpolation processing.

The abnormal shadow candidate portion extracted from the whole image is obtained by analyzing an image signal using a computer and automatically extracting an abnormal shadow such as a tumor shadow or a microcalcification shadow appearing in the image. Abnormal shadow candidate detection system
294479) or the like, or a portion that includes the abnormal shadow candidate and its vicinity.

The pixel density conversion of the abnormal shadow candidate portion so that the number of pixels is equal to or larger than the number of pixels of the corresponding portion in the entire image before the pixel density conversion means that the entire image before the pixel density conversion is, for example, 2500 pixels as described above. × 2000 pixels, and when the abnormal shadow candidate portion (corresponding portion) in the entire image is, for example, 100 pixels × 100 pixels, the number of pixels (100 pixels × 100 pixels) or a larger number of pixels (eg, 120 pixels) This means that the pixel density is converted so that it becomes (pixel × 120 pixels). When the number of pixels is not changed, it is not necessary to substantially perform the pixel density conversion. However, for example, an interpolation process capable of freely adjusting the sharpness (Japanese Patent Laid-Open No. 9-321981)
) May be applied to adjust the sharpness while maintaining the same number of pixels as the original number of pixels. This interpolation processing is performed by an interpolation operation having relatively high sharpness (for example, the Cubic
Interpolation coefficient of spline interpolation calculation and interpolation calculation with relatively low sharpness (for example, Bee spline (B spline)
The interpolation coefficient is obtained by performing a weighted average of the interpolation coefficient and the interpolation coefficient of the interpolation operation, and is a process that can vary the sharpness of the image after the interpolation process continuously.

When the number of pixels is larger than the number of pixels in the original image, the number of pixels may be increased by an interpolation process. In this case, the above-described interpolation process of Japanese Patent Application Laid-Open No. 9-321981 is applied. You may.

Displaying the entire image subjected to the pixel density conversion in this way and the abnormal shadow candidate portion (may include a nearby area) subjected to the pixel density conversion is referred to as “displaying the entire image”. Includes an abnormal shadow candidate portion that has been subjected to pixel density conversion at the same conversion rate as that of the entire image, and is extracted separately from such an entire image and has a pixel density at a conversion rate different from that of the entire image. This means that the converted abnormal shadow candidate portion is further displayed. As a result, on the image display device, the entire image is displayed in one frame, and the abnormal shadow candidate portion is displayed with the number of pixels equal to or more than the original number of pixels. Are displayed larger than the abnormal shadow candidate part as a part of the displayed whole image. Therefore, while the whole image can be read on one screen, the abnormal shadow candidate portion extracted from the whole image and displayed larger than the corresponding portion in the whole image can be observed in detail. Can be rational because there is no need to perform a reduction process (pixel density conversion process for reducing the number of pixels) and then an enlargement process (pixel density conversion process for increasing the number of pixels).

It is preferable that the abnormal shadow candidate portion displayed separately from the whole image is displayed in a display area of the image display device which is different from the area where the whole image is displayed. The display may be superimposed on a part of the entire image as long as there is no.

Further, regarding the abnormal shadow candidate portion displayed separately from the whole image, the image is easily read.
It is preferable to perform image processing such as gradation processing and frequency processing. Further, such image processing may be performed on the entire image.

Note that, with the same number of pixels as the abnormal shadow candidate portion displayed separately from the whole image, a partial region of the whole image is
It may be displayed separately from the entire image, and by scrolling so as to change the partial area of the entire image, it is possible to sequentially observe the entire image as a partially displayed area that is greatly displayed. , It is possible to cope with the case where it is desired to observe the area other than the abnormal shadow candidate part in detail,
Very convenient.

Further, the whole image and the abnormal shadow candidate part and a partial area in the whole image may be further enlarged or reduced at the same enlargement / reduction ratio and displayed.

According to a second image display method of the present invention, in the above-described first image display method of the present invention, pixel density conversion is not performed on the extracted abnormal shadow candidate portion.
The original number of pixels is displayed on an image display device separately from the entire image after the pixel density conversion.

That is, in a second image display method according to the present invention, in the image display method for displaying an image on an image display device, an entire image having a larger number of pixels than the displayable number of the image display device is displayed on the image display device. When displaying on the device, the whole image is displayed on the image display device by converting the pixel density of the entire image so that the number of pixels of the entire image is equal to or less than the number of displayable pixels of the image display device, and the pixel density conversion is performed. And displaying the abnormal shadow candidate portion extracted from the whole image before the image processing on the image display device with the same number of pixels and separately from the whole image after the pixel density conversion. As described above, the second image display method of the present invention is substantially the same as the first image display method except that the pixel density conversion is not performed on the abnormal shadow candidate portion. The same effect as described above can be obtained.

A first image display system according to the present invention is a system for implementing the first image display method according to the present invention, wherein the image display system includes image display means for displaying an image. First pixel density conversion means for performing pixel density conversion on the entire image so that the entire image having a larger number of pixels than the number of displayable pixels of the image display means is equal to or less than the number of displayable pixels of the image display means; An abnormal shadow candidate portion extracted from the whole image based on the whole image before the pixel dense conversion is converted to a pixel number that is equal to or larger than the number of pixels of a corresponding portion in the whole image before the pixel density conversion. A second pixel density conversion unit for performing density conversion, and an entire image obtained by performing the pixel density conversion by the first pixel density conversion unit and a pixel density conversion obtained by the second pixel density conversion unit. Display layout setting means for setting a display layout of the whole image after the pixel density conversion and the abnormal shadow candidate portion so as to display the abnormal shadow candidate portion separately on the image display means. Things.

Here, the first pixel density converting means performs processing for reducing the number of pixels by thinning out the pixels of the input image, or processing for reducing the number of pixels by performing interpolation processing on the input image. Etc. may be applied. Further, the second pixel density conversion means may increase the number of pixels by interpolating the input image, or output the input image with the same number of pixels. Even when the sharpening is performed, for example, the sharpness is continuously changed from an interpolation operation having relatively high sharpness (for example, Cubic spline interpolation operation) to an interpolation operation having relatively low sharpness (for example, B-spline interpolation operation). A 1: 1 magnification process using an interpolation process (see Japanese Patent Application Laid-Open No. 9-321981) that can perform the above process may be applied. Note that the pixel density conversion means in which the first pixel density conversion means and the second pixel density conversion means are functionally integrated may be replaced with these two pixel density conversion means. further,
The partial area of the whole image may be provided with another pixel density conversion means for displaying the same number of pixels as the abnormal shadow candidate part displayed separately from the whole image.
The pixel density conversion means may also have the function of the other pixel density conversion means.

The display layout setting means sets the display layout so that the abnormal shadow candidate portion after the pixel density conversion is displayed in a display area of the image display means which is different from the area where the whole image after the pixel density conversion is displayed. Preferably, the layout is set, but the layout may be set so as to be displayed so as to be superimposed on a part of the entire image as long as the interpretation of the entire image is not hindered.

Preferably, the apparatus further comprises image processing means for performing gradation processing and / or frequency processing on an abnormal shadow candidate portion displayed separately from the whole image. The means may be configured to perform such image processing on the entire image subjected to the pixel density conversion.

A second image display system according to the present invention is a system for implementing the second image display method according to the present invention, and has a second pixel density in the above-described first image display system according to the present invention. Except that it does not include the conversion means, it is substantially the same as the first image display system.

That is, according to a second image display system of the present invention, in an image display system provided with image display means for displaying an image, the entire image having a larger number of pixels than the displayable number of the image display means is converted into the whole image. A pixel density conversion means (corresponding to a first pixel density conversion means in the first image display system of the present invention) for performing a pixel density conversion on the whole image so as to be equal to or less than the number of displayable pixels of the image display means; The whole image obtained by the pixel density conversion by the pixel density conversion means is displayed on the image display means with the number of pixels after the pixel density conversion, and the whole image is displayed based on the whole image before the pixel density conversion. The pixel density is set such that the abnormal shadow candidate portion extracted from the image is displayed on the image display means separately from the whole image after the pixel density conversion with the same number of pixels. It is characterized in that a display layout setting means for setting a display layout of the entire image and the abnormal shadow candidate part of 換後.

Note that the second image display system of the present invention may be configured to further include another pixel density conversion means.

An abnormal shadow candidate detection system according to the present invention detects an abnormal shadow candidate based on an image obtained by reading, and maintains the read image size of the detected abnormal shadow candidate. By displaying and displaying the entire image in a reduced size, it is possible to observe the detailed state of the abnormal shadow candidate and to make the entire image readable.

That is, the abnormal shadow candidate detection system according to the present invention includes the above-described image display system according to the present invention as a part of the abnormal shadow candidate detection system. An abnormal shadow candidate detecting means for extracting an abnormal shadow candidate portion from the entire image before the conversion based on the entire image.

Here, the abnormal shadow candidate detecting means analyzes an image signal using a computer and automatically extracts abnormal shadows such as tumor shadows and microcalcification shadows appearing in the image. An abnormal shadow candidate detecting means in a system (Japanese Patent Laid-Open No. 8-294479, etc.) can be applied.

[0036]

According to the image display method and the image display system of the present invention, when the total number of pixels of the image to be displayed is larger than the number of displayable pixels of the image display device, the whole image has the same number of pixels. A reduced pixel density conversion is applied, while
Since the abnormal shadow candidate portion extracted from the image has the same number of pixels as the original number of pixels or more than the entire image, the entire image subjected to the pixel density conversion is entirely displayed on the image display device (image display device). Means), the whole image can be read at a glance, and the abnormal shadow candidate portion extracted separately from this whole image is displayed with the number of pixels equal to or more than the original number of pixels, so that it is displayed. The abnormal shadow candidate portion as a part of the entire image thus displayed is displayed larger, and the abnormal shadow candidate portion can be observed in detail. Since the abnormal shadow candidate is not once subjected to reduction processing (pixel density conversion processing for decreasing the number of pixels) and then to enlargement processing (pixel density conversion processing for increasing the number of pixels), the processing is not performed. Can be made reasonable.

The abnormal shadow candidate detection system of the present invention can also provide the same functions and effects as those of the above-described image display method and image display system of the present invention.

[0038]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, specific embodiments of an image display method and an image display system according to the present invention will be described with reference to the drawings.

FIG. 1 is a diagram showing the configuration of an embodiment of the first image display system of the present invention which implements the first image display method of the present invention. The illustrated image display system 10 includes:
An abnormal shadow candidate (a tumor shadow candidate P1 and a microcalcification shadow candidate P2) detected by an external abnormal shadow candidate detection system 20 based on an image signal S0 obtained by reading the mammography P0 as shown in FIG. An image display system having an image display means for displaying an entire image (whole image) P0, wherein an entire image P0 having a larger number of pixels than can be displayed by the image display means 1 is displayed on the image display means 1. So that the total image P
A first pixel density conversion means 2 for performing a pixel density conversion on 0,
The abnormal shadow candidate portions extracted by the abnormal shadow candidate detection system 20 (meaning rectangular regions including the abnormal shadow candidates P1 and P2 and their neighboring regions; hereinafter, referred to as local regions) R1 and R2 are subjected to pixel density conversion. Pixel density conversion is performed by the second pixel density conversion means 3 and the first pixel density conversion means 2 for performing pixel density conversion so as to maintain the number of pixels of the corresponding portions R1 and R2 in the previous whole image P0. An entire image (hereinafter, referred to as a reduced overall image) P0 'and local regions (hereinafter, referred to as equal-size local regions) R1 ", R2" obtained by performing pixel density conversion by the second pixel density converting means 3 are separately imaged. The reduced whole image P is displayed on the display unit 1.
A display layout setting means 4 for setting a display layout of 0 'and the same-size local regions R1 ", R2".

Here, the abnormal shadow candidate detection system 20
Is obtained by comparing the input image signal S0 representing the entire image P0 with the abnormal shadow candidates P1,
Predetermined signal processing is performed so as to detect P2 (see FIG. 2), and a rectangular region including each of the detected abnormal shadow candidates P1, P2 to each neighboring region is an abnormal shadow candidate portion (local region) R1. , R2.

The image display means 1 is a monitor having a display surface with a vertical resolution of about 1000 lines. The image signal S0 is
For example, it is a signal obtained by reading the entire image P0 of six slices at a resolution of about 2500 lines. As a result, the image S
0 cannot be displayed on one screen of the image display means 1 in its read size (number of pixels).

The second pixel density conversion means 3 outputs the signals SR1, R2 representing the local regions R1, R2 input as described above.
The local area signals SR1 and SR2 are subjected to processing so that the display means 1 displays SR2 with the same number of pixels, and the signals SR1 "and SR2" representing the equal-size local areas R1 "and R2".
And outputs it to the display layout setting means 4. On the other hand, the first pixel density conversion means 2 displays the entire image P0 on the entire screen of the image display means 1 in order to display the entire input image P0 on the entire screen.
0, a signal S representing a reduced whole image P0 'by performing a pixel density conversion process so that the number of pixels is approximately 40%.
This has the function of outputting to the display layout setting means 4 as 0 '.

The display layout setting means 4 is adapted to provide a radiation-free area (radiation direct irradiation area, which does not hinder the interpretation of the subject (breast) image in the reduced whole image P0 '; Means the area directly reaching the record carrier such as a radiation detector, a film, a stimulable phosphor sheet, etc.), and display the reduced whole image signal S0 ', And an operation of applying a layout setting process to the equal-size local area signals SR1 ″ and SR2 ″. Note that this layout may be set in advance, or a radiogram interpreter may be able to appropriately select from several preset layout patterns.

Next, the operation of the image display system 10 of the present embodiment will be described.

First, a mammography P as shown in FIG.
The image signal S0 obtained by reading “0” is input to the external abnormal shadow candidate detection system 20. The abnormal shadow candidate detection system 20 performs predetermined signal processing (e.g., for example, on the input image signal S0 representing the entire image P0 so as to detect abnormal shadow candidates P1 and P2 existing in the entire image P0. In addition to performing iris filter processing and morphology calculation processing, a rectangular area including each of the detected abnormal shadow candidates P1 and P2 in the vicinity is set as local areas R1 and R2. And the signals SR1 and SR2 representing the local regions R1 and R2 set in this way are:
The whole image signal S0 is input to the first pixel density conversion means 2 while being input to the second pixel density conversion means 3 of the image display system 10 of the present embodiment.

The second pixel density conversion means 3 calculates the number of pixels (vertical resolution) when the original whole image signal S0 is obtained by reading the input local area signals SR1 and SR2.
Conversion processing is performed so as to maintain (2,500 lines), and the same-size local region signals SR1 ″ and SR2 ″ are obtained. On the other hand, the first pixel density conversion means 2
Represents the whole image P with respect to the input whole image signal S0.
Pixel density conversion processing adapted to the resolving power (vertical resolution: 1000 lines) of the image display means 1 was performed so that the whole of 0 (2,500 vertical resolutions) could be displayed on one screen of the image display means 1 and obtained. The reduced whole image signal S0 'is output to the layout setting means 4.

The layout setting means 4 outputs the reduced whole image P
0 ', the reduced whole image signal S0' and the same-size image are displayed so that the same-size local regions R1 "and R2" are superimposed and displayed on the radiation-free portion region that does not hinder the interpretation of the subject (breast) image. A layout setting process is performed on the local region signals SR1 ″ and SR2 ″, and the reduced whole image signal S set in the layout is set.
0 ′ and the same-size local area signals SR1 ″ and SR2 ″ are output to the image display means 1.

The reduced whole image signal S0 'having the display layout set as described above and the same-size local region signal SR1 ",
The image display means 1 to which SR2 "has been input is the reduced whole image P0 'represented by the reduced whole image signal S0' and the same size local region images R1", R2 "represented by the same size local region image signals SR1", SR2 ", respectively. Are displayed on the display surface as shown in FIG. 3 according to the set layout.

As a result, as for the abnormal shadow candidates P1 and P2, which are regions of interest for the reader, the detailed state can be observed by the local regions R1 "and R2" in which the original number of pixels is maintained. The positional relationship between the abnormal shadow candidates P1 and P2 in the entire image P0 can be interpreted at a glance simultaneously with the local images R1 'and R2' as abnormal shadow candidates P1 'and P2' on the reduced overall image P0 '. In addition, it is possible to enhance the diagnostic reading performance of the display image.

Note that the image display system of this embodiment performs processing for a single mammography.
In mammography, the images of the left and right breasts are often displayed on the same display surface at the same time for image interpretation. In this case, the layout setting means 4 for example, as shown in FIG. 'And P10' are simultaneously displayed on the display surface 1 while the whole images P0 and P10 are displayed.
, The abnormal shadow candidates P1, P2, and P11 respectively detected as the same size local regions R1 ″, R2 ″, and R11 ″ obtained by the second pixel density conversion means 3 are respectively reduced overall images P0 ′, P10 ′. May be displayed at the same time in accordance with the display area.

The ROI frames respectively defining the local regions R1 'and R2' displayed in the reduced overall image P0 'can be moved within the reduced overall image P0'. A moving means (for example, a pointing device such as a mouse) for moving in the reduced whole image P0 'is further provided, and inside the ROI frame of the same-size local region images R1 "and R2" displayed simultaneously with the reduced whole image P0'. The local regions R1 ', R1 in the reduced ROI frame being moved by the moving means in the reduced overall image P0'
Local areas R1 "and R2" corresponding to 2 'and represented by the number of pixels of the original whole image P0 may be displayed as shown in FIG.

The image display system 1 of the above embodiment
0 indicates that the abnormal shadow candidate detection system 20 is a separate system, but as shown in FIG. 6, the abnormal shadow candidate detection system 20 ′ is added to the abnormal shadow candidate detection system 2.
By incorporating 0 as the abnormal shadow candidate detecting means 21 and further incorporating the image display system 10, the abnormal shadow candidate detecting system 20 'can be an embodiment of the abnormal shadow candidate detecting system of the present invention. .

By omitting the second pixel density conversion means 3, it is possible to provide an embodiment of the second image display system of the present invention.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of an embodiment of an image display system of the present invention.

FIG. 2 is a view showing an entire image to be displayed on the image display system shown in FIG. 1;

FIG. 3 is a view showing an image displayed by the image display system shown in FIG. 1;

FIG. 4 is a diagram showing another display layout mode.

FIG. 5 is a diagram illustrating a mode in which a partial region of the entire image is displayed in a scrollable manner with the same number of pixels as the local region.

FIG. 6 is a diagram showing a configuration of an embodiment of an abnormal shadow candidate detection system according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Image display means 2 1st pixel density conversion means 3 2nd pixel density conversion means 4 Layout setting means 10 Image display system 20, 20 'abnormal shadow candidate detection system 21 Abnormal shadow candidate detection means P0, P0' reduced whole image S0, S0 'Reduced whole image signal P1, P2 Abnormal shadow candidate S1, S2 Abnormal shadow candidate signal R1, R2 Local area SR1, SR2 Local area signal R1', R2 'Same-size local area SR1', SR2 'Same-size local area signal

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04N 1/387 101 A61B 6/00 350A 350D (72) Inventor Takeshi Takeshi Okubo 798 Miyadai, Kaisei-cho, Ashigagami-gun, Kanagawa Prefecture. Fuji Photo Film Co., Ltd. F-term (reference) 4C093 AA26 CA18 CA21 DA06 FF08 FF09 FF13 FF17 FF28 FF35 5B057 AA08 CA08 CA12 CA16 CB08 CB12 CB16 CC01 CC03 CD05 CE11 DA08 DB02 DB09 DC22 5C076 AA02 AA12 AA12 AA11 CA10 CB04

Claims (12)

[Claims] 1. An image display method for displaying an image on an image display device, comprising: displaying an entire image having a larger number of pixels than the number of displayable pixels of the image display device on the image display device; The whole image is displayed on the image display device by performing a pixel density conversion so that the number is equal to or less than the number of displayable pixels of the image display device, and the entire image is displayed based on the whole image before the pixel density conversion. The abnormal shadow candidate portion extracted from the inside is subjected to pixel density conversion so that the number of pixels is equal to or greater than the number of pixels of the corresponding portion in the whole image before the pixel density conversion, and the whole image after the pixel density conversion Separately, an image display method is displayed on the image display device. 2. An image display method for displaying an image on an image display device, comprising: displaying an entire image having a larger number of pixels than the number of displayable pixels of the image display device on the image display device; The whole image is subjected to pixel density conversion and displayed on the image display device so that the number is equal to or less than the number of displayable pixels of the image display device, and an abnormality extracted from the whole image before the pixel density conversion is performed. An image display method, wherein a shadow candidate portion is displayed on the image display device separately from the whole image after the pixel density conversion with the same number of pixels. 3. An abnormal shadow candidate portion displayed separately from the whole image is displayed in a display area of the image display device different from an area where the whole image is displayed. Or the image display method according to 2. 4. The apparatus according to claim 1, wherein a partial area of the whole image is displayed with the same number of pixels as an abnormal shadow candidate part displayed separately from the whole image. The image display method described in the section. 5. The abnormal shadow candidate portion displayed separately from the whole image is subjected to gradation processing and / or frequency processing. Image display method. 6. An image display system comprising an image display means for displaying an image, wherein an entire image having a larger number of pixels than a displayable pixel number of the image display means is set to be equal to or less than a number of displayable pixels of the image display means. First pixel density conversion means for performing pixel density conversion on the entire image, and an abnormal shadow candidate portion extracted from the entire image based on the entire image before the pixel density conversion, A second pixel density conversion unit that performs pixel density conversion so that the number of pixels is equal to or greater than the number of pixels of a corresponding portion in the entire image before the density conversion, and a pixel density conversion obtained by the first pixel density conversion unit. The whole image after the pixel density conversion and the abnormal image candidate portion obtained by performing the pixel density conversion by the second pixel density conversion means are displayed on the image display means separately. A display layout setting unit configured to set a display layout of the abnormal shadow candidate portion. 7. An image display system comprising image display means for displaying an image, wherein an entire image having a larger number of pixels than the number of displayable pixels of the image display means is set to be equal to or less than the number of displayable pixels of the image display means. Pixel density conversion means for performing pixel density conversion on the entire image, and the image display means using the number of pixels after the pixel density conversion of the entire image obtained by performing the pixel density conversion by the pixel density conversion means. In addition, the abnormal shadow candidate extracted from the whole image before the pixel density conversion is displayed in the image display means separately from the whole image after the pixel density conversion, with the number of pixels as it is, An image display system comprising: a display layout setting unit configured to set a display layout of the whole image after the pixel density conversion and the abnormal shadow candidate portion. 8. The display layout setting means displays the abnormal shadow candidate part after the pixel density conversion in a display area of the image display means different from an area where the whole image after the pixel density conversion is displayed. The image display system according to claim 5, wherein the display layout is set so as to perform the display layout. 9. A pixel density conversion is performed on the partial region so that the partial region of the entire image is displayed with the same number of pixels as the abnormal shadow candidate portion displayed separately from the whole image. 9. The image display system according to claim 6, further comprising another pixel density conversion unit. 10. The image display system according to claim 9, wherein said second pixel density conversion means also functions as said another pixel density conversion means. 11. The image processing apparatus according to claim 6, further comprising image processing means for performing a gradation process and / or a frequency process on an abnormal shadow candidate portion displayed separately from the whole image. An image display system according to any one of the preceding claims. 12. The abnormal shadow candidate detecting means for extracting the abnormal shadow candidate portion from the entire image based on the entire image before the pixel density conversion, and the abnormal shadow candidate detecting unit according to any one of claims 6 to 11. An abnormal shadow candidate detection system, comprising: an image display system.