WO2002042727A1 - System for displaying mtf measured value of crt monitor and its method - Google Patents

Abstract

A system for displaying an MTF measured value of a CRT monitor, having diagnostic image information captured by imaging a subject, a workstation where the diagnostic image information is stored, and a display for displaying the diagnostic image information, comprises a display capable of displaying a captured pattern image for MTF measurement, a light-receiving sensor additionally provided in front of the display so as to capture the pattern image, extracting means connected to the light-receiving sensor and built in the workstation so as to extract a maximum point and a minimum point of the pattern image, means adapted for calculating an MTF from the information about extraction of a maximum and a minimum point of the pattern image, connected to the extracting means, and built in the workstation, and a memory provided within the display connected to the calculating means so as to store therein performance parameters including the MTF.

Description

 Specification

System and method for displaying MTF measurement values on a CRT monitor

 The present invention relates to a diagnostic image information obtained by imaging a patient, a workstation for storing the diagnostic image information, and an MTF measurement value display of a display device for displaying the diagnostic image information. Background art

 In recent years, CRT diagnostic imaging using CRT monitors has been active in the United States and Europe. As of 2000, the penetration rate in the world market is about 5 to 8%, and it is said that it will reach about 70% in the next 8 years. As CRT (or any display) diagnostic imaging replaces traditional diagnostic X-ray film with an electronically-displayed display system, electronically-diagnosed diagnostic display monitors can be compared to X-ray films. Since the image quality deteriorates at a very high speed, the monitor performance parameters (brightness, gamma characteristics, MTF, etc.) can be easily maintained and quantitatively, taking into account the security of the diagnosing doctor and the assurance of the patient being diagnosed. Being able to measure is important. This is because the deterioration of the image quality due to the change over time may cause an erroneous diagnosis.

 Therefore, at present, the maintenance of the monitor is performed periodically. It is especially important to quantitatively measure the MTF (Modulation Transfer Function). The MTF is the level of brightness (range of brightness values) that can be displayed on a monitor, and is entirely white (DC). Using the brightness A in Fig. 3 (a) as the 100% reference, other frequencies f (Fig. 3 (b) or (c) Assuming that the brightness of the white part of the stripe pattern displayed by) is b (f), the MTF (f) at this f is expressed by (Equation 1).

 MTF (f) = (b (f) / A) * 100 (Equation 1) '

Fig. 3 (b) shows the image at low frequency f1 and the change in luminance at the bottom. That is, The black part and the white part are alternately continuous stripes, but the width of the white part and the black part is not thin. In this case, since the brightness change amplitude is b (f 1), the MTF is (b (f 1) / A) * 100.

 Figure 3 (c) shows the image at the high frequency (f h) at the top and the change in brightness at the bottom. In other words, the black portion and the white portion are alternately and continuously striped, but the width of the white portion and the black portion is small. In this case, since the amplitude of the luminance change is b (f h), the MTF is

(b (fh) / A) * 100.

 Fig. 3 (d) is a graph showing the relationship between MTF and frequency. In general, the higher the frequency, the lower the MTF. Also, the longer the CRT is used, the lower the MTF value. '

 However, in the past, MTF measurement was actually performed by humans who maintain the CRT, and there is no quantitative measurement data. It is difficult to compare accurate MTF values because human visual observations are not objective and rigorous data because individual differences always occur.

 Conventional MTF measuring instruments, which are large-scale at the laboratory level, are expensive, take a long time to measure, and can be used for experimental measurements, but are difficult to maintain.

 Therefore, an object of the present invention is to provide an MTF measurement system capable of easily measuring and recording a target CRT diagnostic image in a short time and recording a change with time. Disclosure of the invention

An MTF measurement value display system for a CRT monitor according to the present invention displays a diagnostic image information of a patient and a workstation for storing the diagnostic image information and a display device for displaying the diagnostic image information. A display device that can be attached to the display device, and a capture pattern for MTF measurement of the display device attached to the front of the display device. A light-receiving sensor that captures an image, a means connected to the light-receiving sensor, built-in to the workstation, and configured to extract maximum and minimum points of the MTF measurement captured pattern image, and a means for performing the extraction processing A means for calculating the MTF from the extraction processing information of the maximum point and the minimum point of the captured pattern image for MTF measurement built in the workstation, and a display device connected to the means for calculating the MTF. And a memory for storing performance parameters including MTF.

 The manufacturing information, performance information, or environmental information of the display device is linked and recorded in a memory for storing the performance parameters including the MTF.

 This environment information is characterized by comprising luminance and gamma characteristics.

 A memory for storing performance parameters including the MTF is built in the workstation.

 It is characterized in that the captured pattern image for MTF measurement simultaneously includes a DC component pattern as a reference value at the time of calculating the MTF value and an AC component pattern of the MTF value to be obtained.

 The method of displaying the MTF measurement value of the CRT monitor is as follows: the diagnostic image information of the patient, the workstation that stores the diagnostic image information, and the display method that displays the diagnostic image information. A display step, a light receiving sensor attached to the front of the display device, a step of taking in an MTF measurement capture pattern image of the display device, and a means for extracting and processing a maximum point and a minimum point are connected to the light receiving sensor.工程 The process of extracting the maximum and minimum points from the captured pattern image data for MTF measurement built in the 1st station, and the maximum of the captured pattern image for MTF measurement from the information extracted by the means for calculating the MTF. The process of calculating the MTF from the extraction processing information of the points and the minimum points, and the process of storing the calculated MTF information in the memory that stores the performance parameters including the MTF Li Cheng.

The manufacturing information, performance information, or environmental information of the display device is recorded in a memory storing the performance parameters including the MTF in a linked manner. This environment information is characterized by comprising luminance and gamma characteristics.

 A memory for storing the performance parameters including the MTF is built in the workstation.

 It is characterized in that the captured image for MTF measurement includes simultaneously a DC component pattern which is a reference value at the time of calculating the MTF value and an AC component pattern of the MTF value to be obtained. BRIEF DESCRIPTION OF THE FIGURES

 FIG. 1 is a block diagram of an embodiment of an MTF measurement value display system for a CRT monitor according to the present invention,

 FIG. 2 is a configuration diagram showing an embodiment of an MTF measurement value display system for a CRT monitor according to the present invention.

 Fig. 3 (a) is a schematic diagram showing the brightness and its image in the case of DC, (b) is a schematic diagram showing the brightness in the case of low frequency (f1), and (c) is a high diagram. The luminance and the schematic diagram at the frequency (ih) are shown, and (d) is a graph showing the relationship between MTF and frequency.

 FIG. 4 is a captured image pattern diagram displayed in a monitor in the MTF measured value display system of the CRT monitor according to the present invention.

 FIG. 5 is a block diagram showing a method of displaying an MTF measurement value of the CRT monitor according to the present invention. BEST MODE FOR CARRYING OUT THE INVENTION

The present invention will be described in more detail with reference to the accompanying drawings. FIG. 1 is a block diagram of an embodiment of an MTF measurement value display system for a CRT monitor according to the present invention. MTF measurement value display system, CRT monitor 2, workstation 4 connected to CRT monitor 2, and workstation 4 And a CCD sensor 6.

 The CRT monitor 2 is a monitor of the workstation 4 and displays medical images. The image device is not limited to the CRT, but may be any device capable of displaying images of a liquid crystal display device, a plasma display device, and a computer such as a workstation such as an EL display. good.

 The CRT monitor 2 has a memory 12 for recording its manufacturing date, serial number, manufacturing information including a manufacturing location, and performance information such as luminance, gamma characteristics, and MTF including temporal changes. '

 The CRT monitor 2 also has a function of displaying a captured image pattern (FIG. 4) for measuring MTF.

 The workstation 4 includes a maximum and minimum point extraction processing software 8 connected to the CCD sensor 6 and an MTF calculation software 10 connected to the maximum and minimum point extraction software 8.

 The maximum / minimum point extraction processing software 8 receives data obtained by capturing the captured image for measuring the MTF displayed on the entire CRT monitor 2 by the CCD sensor 6. The maximum / minimum point extraction processing software 8 finds and captures the maximum and minimum points of luminance for each frequency from the captured image pattern for measuring the received MTF.

 The MTF calculation software 10 obtains b (f) from the difference between the maximum point and the minimum point of the luminance obtained by the maximum / minimum point extraction processing software 8.

 On the other hand, A in Equation 1 is obtained from the difference between the luminance of the white part and the luminance of the black part, which is DC. The MTF is obtained from b (f) and A.

The CCD sensor 6 has a function of capturing a captured image pattern for measuring the MTF displayed on the entire CRT monitor 2. As a feature, the CRT monitor 2 may be scanned, but it is more preferable to collectively capture all images. This is because the imaging time is shortened and the subsequent processing time is shortened by setting the imaging data to the necessary minimum amount of data. In addition, the imaging device is not limited to a CCD sensor, but may be a CMO. An S imaging device or other devices may be used. Preferably, the use of a CCD sensor reduces the manufacturing cost, so that it can be reproduced at a lower price compared to conventional devices.

 FIG. 2 is a configuration diagram showing an embodiment of an MTF measurement value display system for a CRT monitor according to the present invention. The MTF measurement value display system consists of a CRT monitor 2, a workstation 4 connected to the CRT monitor 2, a keyboard and mouse 16 connected to the workstation 4, and a CCD sensor 6 connected to the workstation 4. Be composed.

 FIG. 4 is a captured image pattern diagram displayed in a monitor in the MTF measured value display system of the CRT monitor according to the present invention.

 The image pattern diagram shows an example of six image patterns for measuring the MTF of each frequency in the horizontal direction of the CRT monitor and the MTF of each frequency in the vertical direction of the CRT monitor. FIG. 4 (a) shows a combination pattern of a low frequency and a limit frequency in the horizontal direction, and FIG. 4 (b) shows a combination pattern of a low frequency and the limit frequency in the vertical direction. c) is a combination pattern of a plurality of different frequencies in the horizontal direction, FIG. 4 (d) is a combination pattern of a plurality of different frequencies in the vertical direction, and FIG. 4 (e) is a combination pattern of the horizontal and vertical frequencies. Fig. 4 (パ タ ー ン) shows a combination pattern of a plurality of different frequencies in the horizontal and vertical directions.

 In addition, as a combination of patterns, a DC component without a frequency component, that is, a pattern including only white and black, and a pattern including an AC component for measuring MTF and simultaneously including a low frequency, a limit frequency, and a plurality of other frequencies are used. May be prepared. Using this pattern has the advantage of simultaneously measuring both 数 値 and b (f) in Equation 1, which is the reference value.

 Furthermore, these patterns are only examples and need not be displayed at all. The patterns shown are not limited to the patterns shown here.

FIG. 5 is a block diagram showing a method of displaying the measured MTF value of the CRT monitor according to the present invention. First, start (A2) CRT monitor 2 displays the captured image pattern for measuring MTF on its screen (A4). This is to measure MTF.

 The CCD sensor 6 captures a captured image pattern for measuring MTF on the screen of the CRT monitor 2 (A6). At this time, it is possible to perform imaging by the vertical and horizontal scanning methods, but it is more preferable to perform batch imaging.

 The maximum / minimum point extraction processing software 8 receives data obtained by the CCD sensor 6 capturing a captured image pattern for measuring the MTF displayed on the entire CRT monitor 2. The local maximum / minimum point extraction processing software 8 finds and captures the maximum and minimum points of luminance for each frequency from the captured image pattern for measuring the received MTF (A8).

 At this time, the validity of the data such as the absence of a maximum point or a minimum point is determined. If the data is invalid, the process returns to the maximum / minimum point extraction process. If the data is valid, the process proceeds to the next step (A10).

 The MTF calculation software 10 obtains b (f) from the difference between the maximum point and the minimum point of the luminance obtained by the maximum / minimum point extraction processing software 8.

 On the other hand, A in Equation 1 is obtained from the difference between the luminance of the white part and the luminance of the black part which is DC. The MTF is obtained from b (f) and A (A12).

 At this time, the validity of the data whose MTF is 0 or the like is determined. If the data is invalid, the process returns to the maximum / minimum point extraction process, and if the data is valid, the process proceeds to the next step (A14).

 If the data is valid, the MTF calculation software 10 records the MTF measurement results in the memory 12 for recording performance information such as luminance, gamma characteristics, and MTF including temporal changes in the CRT monitor 2 (A16 ) And finish (A18). By recording luminance, gamma characteristics, and MTF including temporal changes, environmental information at the time of image diagnosis is recorded in medical diagnosis, so that it is easy to measure and record whether the diagnosis is always performed in the optimal environment. It can be used as important evidence information in medical trials. Industrial applicability

As described above, the CTF monitor MTF measurement value display system according to the present invention According to the conventional image diagnosis monitor using a CRT display, only the luminance (low, high) and gamma correction curves are periodically displayed. On the other hand, by adding the MTF measurement according to the present invention, the CRT diagnosis monitor can be used. All of the important parameters will be aligned, and diagnostic accuracy can be quantitatively maintained.

 In addition, quantitative information on MTF can be obtained, monitor performance can be objectively confirmed, and can be combined as monitor performance data during diagnosis. This makes it possible to prove that the diagnosing doctor made the diagnosis in such an environment.

 Furthermore, it takes less time to capture the image of one pattern to measure the MTF value.

 In addition, since the MTF measurement is performed with a simple CCD sensor, it can be realized with an extremely simple and inexpensive system.

Claims

The scope of the claims

1. a diagnostic image information of a patient and a workstation for storing the diagnostic image information and a display device for displaying the diagnostic image information,

 A display device capable of displaying a captured pattern image for MTF measurement, a light receiving sensor attached to the front of the display device for capturing the captured pattern image for MTF measurement of the display device, and the workstation connected to the light receiving sensor Means for extracting the maximum point and the minimum point of the MTF measurement capture pattern image that is built in the MTF measurement capture pattern image, and the maximum points of the MTF measurement capture pattern image built in the workstation connected to the extraction processing means. Extraction of the minimum point Calculation of MTF from processing information, MTF measurement value of CRT monitor composed of memory that stores performance parameters including MTF that exists in display connected to means for calculating MTF Display system.

2. The MTF of the CRT monitor according to claim 1, wherein the manufacturing information or the performance information or the environment information of the display device is recorded in a memory storing the performance parameter including the MTF in a linked manner. Measurement display system.

 3. The system according to claim 2, wherein the environmental information includes luminance and gamma characteristics.

 4. The MTF measurement value display system for a CRT monitor according to claim 1, wherein a memory for storing the performance parameter including the MTF is built in the workstation.

 5. The method according to any one of claims 1 to 4, wherein the captured pattern image for MTF measurement includes a DC component pattern as a reference value at the time of calculating the MTF value and an AC component pattern of the MTF value to be obtained at the same time. MTF measurement value display system for CRT monitor described in.

6. A diagnostic image information obtained by capturing a patient and a workstation for storing the diagnostic image information and a display method for displaying the diagnostic image information, A step of displaying the MTF measurement capture pattern image on the display device; a step of capturing the MTF measurement capture pattern image of the display device attached to the front of the display device; Is connected to the light receiving sensor and is built into the workstation to extract the maximum point and the minimum point from the MTF measurement captured pattern image data, and for the MTF measurement based on the information extracted by the MTF calculation means. Extracting the maximum and minimum points of the captured pattern image.Calculating the MTF from the processing information and storing the calculated MTF information in the memory that stores the performance parameters including the MTF. .

7. The CRT monitor according to claim 6, wherein manufacturing information or performance information or environmental information of the display device is recorded in a memory for storing performance parameters including the MTF in a linked manner. MTF measurement value display method.

 8. The method according to claim 7, wherein the environmental information includes luminance and gamma characteristics.

 9. The method for displaying an MTF measurement value of a CRT monitor according to claim 6, wherein a memory for storing performance parameters including the MTF is built in the workstation.

10. The captured pattern image for MTF measurement, wherein the DC component pattern which is a reference value at the time of calculating the MTF value and the AC component pattern of the MTF value to be obtained are simultaneously included. How to display the measured MTF value of the CRT monitor described.

Claims of amendment

 [May 28, 2001 (28.05.01) Accepted by the International Bureau: Claims at the time of filing

 1, 2, 6 have been amended; other claims remain unchanged, (2 pages)]

1. (After correction) In a workstation that stores diagnostic image information and diagnostic image information obtained by capturing a patient and a display device that displays diagnostic image information,

 A display device capable of displaying a captured pattern image for MTF measurement, a light-receiving sensor attached to the front of the display device for capturing the MTF measurement capture pattern image of the display device, and connected to the light-receiving sensor Means for extracting a maximum point and a minimum point based on the data obtained by measuring the luminance from the MTF measurement captured pattern image built in the workstation, and the workstation connected to the extraction processing means. The means for calculating the MTF from the information on the extraction processing of the maximum and minimum points of the brightness of the MTF measurement captured pattern image built into the MTF, and the MTF that exists in the display device connected to the MTF calculation means The CTF monitor's MTF measurement value display system, which consists of a memory that stores performance parameters in sequence and records changes over time.

 2. (After correction) The manufacturing information, performance information, or environmental information of the display device is linked and recorded in a memory for sequentially storing the performance parameters including the MTF and recording a change with time. The CTF monitor MTF measurement value display system according to claim 1.

 3. The system according to claim 2, wherein the environmental information includes luminance and gamma characteristics.

 4. The MTF measurement value display system for a CRT monitor according to claim 1, wherein a memory for storing a performance parameter including the MTF is built in the workstation.

 5. The captured pattern image for MTF measurement, wherein the DCF component pattern which is a reference value at the time of calculating the MTF value and the AC component pattern of the MTF value to be obtained are simultaneously included. 4. The CRT monitor MTF measurement value display system according to any one of the above items.

Amended paper (Article of the Convention)

6. (After correction) In the workstation for storing the diagnostic image information and the diagnostic image information obtained by imaging the patient and the display method for displaying the diagnostic image information,

 A step of displaying an MTF measurement capture pattern image on the display device; a light receiving sensor attached in front of the display device; a process of capturing the MTF measurement capture pattern image of the display device; extracting a maximum point and a minimum point Means for processing is connected to the light receiving sensor and is incorporated in the workstation to extract maximum and minimum points from the MTF measurement captured pattern image data, and information extracted and processed by the means for calculating MTF. A CRT monitor consisting of the steps of extracting the maximum and minimum points of the captured pattern image for MTF measurement, calculating the MTF from the processing information, and storing the calculated MTF information in the memory that stores the performance parameters including the MTF MTF measurement value display method.

 7. The CRT monitor according to claim 6, wherein the manufacturing information or the performance information or the environment information of the display device is recorded in a memory for storing the performance parameters including the MTF in a linked manner. MTF measurement value display method.

 8. The method according to claim 7, wherein the environmental information includes luminance and gamma characteristics.

 9. The method according to claim 6, wherein a memory for storing the performance parameters including the MTF is built in the workstation.

 10. The captured pattern image for MTF measurement, wherein the DC component pattern which is a reference value at the time of calculating the MTF value and the AC component pattern of the MTF value to be obtained are simultaneously included. 9 Display method of MTF measured value of CRT monitor described in any of the above.

GCorrected; g (Article 鹩 ^ Convention) Description based on Article 19 (1) of the Treaty Japanese Patent Application Laid-Open No. 2000-28772, which is considered to be particularly relevant to the present invention, is used for performing a temporary MTF measurement. There is.

 On the other hand, the present invention has a memory that sequentially stores measurement data and records changes over time.

 Also, in the present invention, the maximum point and the minimum point are extracted based on data obtained by measuring the luminance from the pattern image. not.

 Therefore, in order to clarify the features of the present invention, an amendment was limited to Claim 1 in terms of “including time-dependent changes” described on page 7, line 19 of the specification. Here, the “performance parameters” are sequentially stored, and if they change over time based on a comprehensive understanding of the data, those skilled in the art can read them uniquely.

 In addition, a correction was made in Claim 1 to limit the search and retrieval of the maximum and minimum points of brightness from the image pattern for each frequency described in page 5, line 17 of the specification. This correction can be clearly read by those skilled in the art by extracting the maximum point and the minimum point from the pattern image shown in Fig. 3 based on the "data obtained by measuring the luminance".

 Claim 2 has been amended in the same way as for claim 1. Claim 3 clarified the subject by adding the particle “ga”.