JPH0827608B2 - Image display controller - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application] The present invention relates to, for example, an image display control device for controlling display of an ultrasonic image and blood flow information of a subject on the same screen. It is a thing.

(Prior Art) An ultrasonic blood flow imaging device as a device for visualizing blood flow information of a subject based on a reflected wave from the subject of an ultrasonic wave transmitted toward a subject (living body) and providing it for diagnosis There is.

This device uses ultrasonic echo (reflected component) from the subject.
Is subjected to frequency shift due to blood flow to obtain blood flow information of the subject, and after converting this into a predetermined color corresponding to changes in direction and average velocity of blood flow, ultrasonic wave B of the subject is obtained. The image is superimposed and displayed on the mode image or the M mode image (black and white image).

In such a device, a CRT for color display is used as a display device (monitor) and an RGB system is adopted.
In the RGB system, the input voltage to the RGB color monitor
When V _R , V _G , and V _B are set, the luminance Y is expressed as Y = 0.3V _R + 0.59V _G + 0.11V _B within the dynamic range where the white balance of the monitor is maintained. Where V _R
A white color is obtained when = V _G = V _B.

By the way, in the conventional blood flow information display, there is a problem that the blood flow information (color image) superimposed and displayed on the ultrasonic image (black and white image) of the subject is difficult to see as compared with the black and white image. . This is considered to be based on the following reasons.

FIG. 6 is an explanatory diagram of a Cartesian coordinate system of V _R , V _G , and V _B , and FIG. 7 is an explanatory diagram of display colors.

As shown in FIG. 6, assuming that each input maximum voltage of the RGB color monitor is Vmax, points having chromaticity and brightness that can be displayed on the RGB color monitor exist on the surface and inside of a cube having one side Vmax. The planes indicated by 1, 2, 3, and 4 in the figure are the coordinates (Vma
It shows an equal-luminance plane for each 0.2 step when the white luminance of (x, Vmax, Vmax) is 1 and the origin O (0, 0, 0) is 0. The gradation of the monochrome image (ultrasonic B-mode image or M-mode image) moves on the diagonal line 5 connecting the origin O and the point of maximum brightness.

On the other hand, the maximum luminance of the highly saturated chromatic color in the shaded area (to which blue and red belong, etc.) in FIG. 7 is lower than that of white, which is an achromatic color. When used for the gradation of (blood flow image), the color image becomes difficult to see due to the brightness imbalance with the black and white image.

The above is the case of displaying blood flow information in the ultrasonic blood flow imaging apparatus, but such a problem can be said in all display systems in which a color image is superimposed and displayed on a monochrome image.

(Problems to be Solved by the Invention) As described above, when a color image is superimposed and displayed on a black-and-white image, the conventional display system has a problem that the color image is more difficult to see than a black-and-white image. ing.

The present invention has been made in view of such circumstances, and an object thereof is to easily display a color image when displaying a monochrome image and a color image on the same screen of an RGB color monitor. An object of the present invention is to provide an image display control device capable of performing the same.

[Structure of the Invention] (Means for Solving Problems) The present invention takes in the first data for color display and the second data for black and white display, and converts them into the first and second data. In an image display control device for controlling the display of RGB converted images of corresponding gradations on the same screen of an RGB color monitor, the maximum luminance of color display colors is the maximum luminance of black and white, and the coefficient α is 0 <α <1. At this time, the color conversion processing means for performing the color conversion processing of the gradation corresponding to the first data with α + (1−α) as the maximum gradation of the color display is provided.

(Operation) FIG. 3 is an explanatory diagram showing the relationship between the equi-intensity plane and .alpha. + (1-.alpha.) With respect to the hatched plane in FIG. In the same figure, if the angles formed by the isoluminance plane 0 and α + (1 + α) are θc, θw, and θ, respectively, there is a relationship of θc <θ <θw <90 °.

The brightness dynamic range of a monochrome image is || sin θw, and the brightness dynamic range of a display color with high saturation but low brightness is || sin θc. Further, the luminance dynamic range of the display color when the saturation is lowered and the luminance is raised is α · || sin θw + (1−α) · || sin θc.

And the relationship between these luminance dynamic ranges is || s
inθc <α ・ |｜ ・ sin θw + (1-α) ・ || sin
θc <|| sin θw. Here, when the coefficient α is set to 0 <α <1, the dynamic range of display colors is widened. Therefore, α + (1+
By performing color conversion processing with α) as the maximum gradation of color display, it is possible to display a color image in an easy-to-see manner.

(Examples) Hereinafter, the present invention will be specifically described with reference to Examples.

FIG. 1 is a block diagram of an image display control device according to an embodiment of the present invention, and here is shown a case where it is applied to an ultrasonic blood flow imaging device.

The image display control device 10 includes a color conversion means 12, a switching means 13, a B / W (black / white) gain attenuator 15, a synthesizing processing means 16, and a selecting means 17.

The color conversion means 12 takes in blood flow data (first data for color display) output from the DSC (digital scan converter) 11, converts it into color RGB, and outputs it, for example, for color conversion. Data (RG
It consists of a ROM (Read Only Memory) that stores B) as a function in advance. Specifically, the color conversion means 12 sets the maximum luminance of the display color to the maximum luminance of black and white, and when the coefficient α is 0 <α <1, α + (1 + α) is the maximum gradation of the color display. The color conversion processing of blood flow data is performed. The processing result is output to the switching means 13 and the synthesizing processing means 16 arranged in the subsequent stage.

The B / W gain attenuator 15 captures the echo data (second data for monochrome display) output from the DSC14,
This data is subjected to RGB conversion with the same weight as RGB, and its output is taken in by the switching means 13 and the synthesis processing means 16. The synthesis processing means 16 synthesizes the output of the color conversion means 12 and the output of the B / W gain attenuator 15 and outputs the synthesized result. The selection means 17 is the DS
Comparing the output states of C11 and C14, the switching means 13 operates according to the comparison result, and the color conversion means
One of the 12 outputs, the output of the synthesis processing means 16 and the output of the B / W gain attenuator 15 is selected, and the D /
It is transmitted to the A (digital / analog) conversion means 18. The output (analog signal) of the D / A conversion means 18 is applied to the cathodes K _R , K _G , and K _B of the RGB color monitor 21 via the cathode drive amplifier 19 arranged in the subsequent stage. Reference numeral 20 is a contrast adjusting means for adjusting the contrast of the entire screen of the RGB color monitor 21 by adjusting the gain of the cathode drive amplifier 19.

An object (not shown) in the apparatus of the above configuration
Blood flow data of is written in DSC11, echo data (B
The mode image data or M mode image data) is written in the DSC 14. These data are read at the timing of the display system, the blood flow data is color-RGB converted by the color conversion means 12, and the echo data is RGB-converted by the B / W gain attenuator 15. These converted outputs are directly or after being combined by the combining processing means 16.
The D / A converter 18 is converted into an analog signal, the cathode K _R of RGB color monitor 21 via the cathode drive amplifier 19, K _G, is applied to the K _B. This RGB color monitor 21
Usually, the blood flow information of the subject is superimposed and displayed as a color image on the B-mode or M-mode black and white two-dimensional image of the subject.

FIGS. 4 (a) and 4 (b) are for explaining an example of color RGB conversion contents in the apparatus of this embodiment in relation to the conventional apparatus. RGB color monitor 21 cathodes K _R , K _G , K _B
Let V _R , V _G , and V _B be input voltages respectively, and let S be one independent variable in the blood flow data. When expressing the magnitude of this independent variable S by the gradation of the display color magenta, According to this, as shown in FIG. 4A, the conversion content has high saturation but low luminance. On the other hand, when color RGB conversion is performed under the conditions already described in the apparatus of the present embodiment, FIG.
As shown in, V _G at Smax is 0.5 Vmax (meaning a decrease in saturation). Lines a and b in FIG. 5 show changes in luminance corresponding to FIGS. 4 (a) and 4 (b), respectively, and a luminance of 1.0 can be displayed on the RGB color monitor 21.
The maximum brightness is V _R = V _G = V _B = V max. In line a, the independent variable S is 0.41 when Smax, while in line b it is 0.41.
This is 0.705, and the degree of brightness improvement of the display color is remarkable.

As described above, in the apparatus of this embodiment, the maximum brightness of the display color is set to the maximum brightness of black and white, and the coefficient α is set to 0 <α.
When <1, the color conversion means 12 for performing color RGB conversion of the blood flow data with α + (1-α) as the maximum gradation of color display is provided, and the saturation of the color display color is reduced to obtain a color image. The RGB color monitor 21
On the display screen, the luminance balance with the black-and-white image is obtained, and the blood flow information is displayed in an easy-to-see manner.

Although one embodiment of the present invention has been described above, it is needless to say that the present invention is not limited to the above embodiment and various modifications can be made. In particular, in the above-mentioned embodiment, the case where the invention is applied to the ultrasonic blood flow imaging apparatus has been described, but the image display control apparatus according to the present invention is applicable to various apparatuses in which a color image needs to be superimposed and displayed on a monochrome image. You can

[Effects of the Invention] As described in detail above, according to the present invention, when a monochrome image and a color image are displayed on the same screen of an RGB color monitor, a color image can be displayed in an easy-to-see manner. Can be provided.

[Brief description of drawings]

FIG. 1 is a block diagram showing a case where an image display control device according to an embodiment of the present invention is applied to an ultrasonic blood flow imaging device, and FIGS. 2 and 3 are explanatory views of the principle of improving the luminance dynamic range. 4A and 4B are characteristic diagrams for explaining an example of color RGB conversion contents in the apparatus of this embodiment,
FIG. 5 is a characteristic diagram showing a luminance change corresponding to FIGS. 4 (a) and 4 (b), and FIG. 6 is an explanatory diagram of a Cartesian coordinate system of V _R , V _G , and V _B ,
FIG. 7 is an explanatory diagram of display colors. 10 ... Image display control device, 12 ... Color conversion means, 21 ... RGB
Color monitor.

Claims (1)

[Claims] 1. A first data for color display and a second data for black and white display are fetched, and RGB converted images of gradations corresponding to the first and second data are the same on an RGB color monitor. In the image display control device for controlling the display on the screen, when the maximum brightness of the color display color is the maximum brightness of black and white and the coefficient α is 0 <α <1, α + (1-α) is the maximum of the color display. An image display control device comprising a color conversion processing unit that performs color conversion processing of gradation corresponding to the first data as gradation.