JPH0244398B2 - - Google Patents

Description

[Detailed description of the invention] [Technical field of invention] The present invention relates to a nuclear medicine data processing device.

[Technical background of the invention and its problems]

Conventionally, nuclear medicine data processing equipment, such as RI diagnostic equipment, collects diagnostic data indicating the number and position of gamma rays from RI over time, while
When displaying images over time on a monitor, an operator has had to frequently manually adjust the gray level on the monitor screen. This is because in the early stages of diagnostic data collection, the number of gamma rays obtained is small, so the overall image on the CRT monitor becomes pale, and in the later stages of diagnostic data collection, the number of gamma rays obtained This is because as the number of images increases, the overall image on the CRT monitor becomes darker.

Therefore, conventional nuclear medicine data processing equipment
Adjusting the density level is extremely complicated, and
The images on the CRT monitor were difficult to see.

[Purpose of the invention]

This invention was made in view of the above circumstances, and while collecting diagnostic data over time,
The object of the present invention is to provide a nuclear medicine data processing device in which the gray level on the CRT monitor is automatically adjusted when displaying an image on the CRT monitor.

[Summary of the invention]

The outline of this invention for achieving the above object is as follows:
A memory for storing nuclear medicine diagnostic data collected over time by a scintillation camera, and a nuclear medicine data processing device for reading out the nuclear medicine diagnostic data from the memory and displaying an RI distribution image in a subject on a display means. and a level detecting means for reading nuclear medicine diagnostic data from the memory at predetermined time intervals and detecting the highest level of gradation data in the read nuclear medicine diagnostic data at predetermined time intervals; calculation means for determining a parameter to be converted to a predetermined gray level in the display on the display means according to the highest level; and nuclear medicine diagnostic data output from the memory based on the parameters determined over time by the calculation means. The present invention is characterized by comprising a level converting means for converting the gradation data in the gradation data into a predetermined gradation level.

[Embodiments of the invention]

An embodiment of the invention will be described with reference to the drawings.

As shown in FIG. 1, 1 is a scintillation camera that outputs an analog position signal containing the number and position of radiation, such as gamma rays, emitted from an RI (radioisotope) within the subject. 2 is a display memory, which stores pixel data collected in real time obtained by digitally converting the analog position signal output from the scintillation camera 1 using an A/D converter (not shown). be. The pixel data includes the RI distribution image of the subject detected by the scintillation camera 1, digital XY position data indicating the position of each pixel, and the number of gamma rays counted in that pixel, that is, digital gradation data. have Reference numeral 3 indicates a level detecting means, such as a high-speed memory controller, which reads the image data stored in the display memory 2 for each pixel at predetermined time intervals, and calculates the gradation data of the image data for each pixel read out. The highest level gradation data is detected by mutual comparison, and the highest level gradation data is output at every predetermined frame time. 4 is an arithmetic unit, which performs the calculations described below based on the highest level gradation data output by the high-speed memory controller 3.
The parameters for displaying the subject image on the screen of the CRT monitor 6 at the optimal gray level are calculated and determined. For example, as shown in FIG. 2, the arithmetic device 4 stores a large number of level conversion tables f(a) corresponding to the gradation levels, and selects a specific level conversion table from the highest level of input gradation data. Determine f(a) and output it. 5 is a level conversion means such as a display controller;
Image data is read out in pixel order for each frame from the display memory 2, and a specific level conversion table f(a), which is a parameter determined by the arithmetic unit 4, is input, and each pixel is Converts the gradation data into the gradation level of the CRT monitor 6. 6 indicates
This is a CRT monitor, and the brightness of each pixel is determined by the gray level converted by the display controller 5, and the image of the subject is displayed for each frame.

Next, the operation of the above configuration will be described.

The display memory 2 collects and stores digitally converted pixel data output from the scintillation camera 1 in real time. The high-speed memory controller 3 sequentially reads out the pixel data stored in the display memory 2, detects the highest level gradation data in the pixel, and outputs the highest level gradation data to the arithmetic unit 4. If the highest level of input gradation data is a ₁ as shown in FIG. 2, the arithmetic unit 4 selects a specific level conversion table f(a ₁ ) from among the many stored level conversion tables. decide,
f(a ₁ ) is output to the display controller 5. This level conversion table f(a ₁ ) is a parameter for displaying the subject image on the screen of the CRT monitor 6 at the optimum gray level when the highest level of gradation data is a ₁ . Next, when the highest level of the gradation data detected and output by the high-speed memory controller 3 is a ₂ , the arithmetic unit 4 converts a specific level conversion table f(a ₂ ) and changes the output table from the level conversion table f(a ₁ ) to the level conversion table f(a ₂ ). On the other hand, the display controller 5 receives pixel data sequentially from the display memory 2, converts the gradation data in the pixel data according to the level conversion table f(a ₁ ) input from the arithmetic unit 4, and then Arithmetic device 4
The gradation data in the image data is converted using the level conversion table f(a ₂ ) inputted from the image data, and the image of the subject is displayed on the screen of the CRT monitor 6 in real time at the optimum gray level.

In this way, the highest level of gradation data is detected in real time, the optimal gray level on the CRT monitor is automatically determined according to the highest level, and the image of the subject is displayed on the CRT monitor. An easy-to-see image can always be displayed from the initial stage of data collection to the latter stage, and the operator does not need to make any adjustments during this period.

Although one embodiment of the present invention has been described in detail above, the present invention is not limited to the above embodiment, and can be implemented with appropriate modifications within the scope of the gist of the invention. Needless to say.

〔Effect of the invention〕

According to this invention, when displaying a subject image while collecting diagnostic data indicating the number and position of radiation over time, tone data at a predetermined level in the diagnostic data collected in real time is detected. Then, based on the predetermined level of the gradation data, parameters for displaying the image at the optimal gray level are determined, and the gray level of the subject image is varied to the optimal value based on the parameters in real time. It is possible to provide a nuclear medicine data processing apparatus that can always display an easy-to-see image of a subject during the acquisition period and that does not require manual adjustment by an operator.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing one embodiment of the present invention, and FIG. 2 is an explanatory diagram showing a table for converting gradation data to an optimum gray level on a monitor. DESCRIPTION OF SYMBOLS 1...Scintillation camera, 2...Memory (display memory), 3...Level detection means (high speed memory controller), 4...Calculation means (calculation device), 5...Level conversion means (display controller), 6... ...Display means (CRT monitor).

Claims (1)

[Claims] 1. A memory for storing nuclear medicine diagnostic data collected over time with a scintillation camera, and nuclear medicine data processing for reading out the nuclear medicine diagnostic data in the memory and displaying an RI distribution image in the subject on a display means. In the apparatus, level detecting means reads nuclear medicine diagnostic data from the memory at predetermined time intervals and detects the highest level of gradation data in the read nuclear medicine diagnostic data at predetermined time intervals, and the level detecting means detects calculation means for determining a parameter to be converted to a predetermined gray level in the display on the display means according to the highest level determined by the calculation means; and a nuclear medicine diagnostic device output from the memory based on the parameters determined over time by the calculation means. 1. A nuclear medicine data processing apparatus comprising: level conversion means for converting gradation data in the data into a predetermined gray level.