JP2010025958A - Image composing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image composing device in which a composition order conversion unit is greatly reducible in circuit scale. <P>SOLUTION: The image composing device operative to generate a desired display image by putting a plurality of images one over another is provided with an image determination means of determining whether or not video signal data of each iamge include image information, and changes the superposition order of the images on the basis of a determination result by the image determination means. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a screen composition device, and more particularly, to a circuit scale reduction of a composition order conversion unit in a device for composing a display screen by superimposing a plurality of screens.

  For example, in an electronic measuring instrument, a display screen is generated by superimposing a plurality of screens. FIG. 2 is an explanatory diagram of a screen synthesis example in a conventional waveform measuring instrument. In the example of FIG. 2, the menu screen shown in (A), the grid screen shown in (B), the foreground screen shown in (C), the measurement waveform screen shown in (D), and the cursor screen shown in (E) By rearranging in a predetermined order, the final display screen shown in (F) is generated.

  The display screen shown in (F) is from the back side to the front side, from the menu screen shown in (A) → the grid screen shown in (B) → the foreground screen shown in (C) → the measurement waveform screen shown in (D). → Overlapping in the order of the cursor screen shown in (E).

  The menu screen shown in (A) and the grid screen shown in (B) are generated as a background GUI screen by the GUI unit. The foreground screen shown in (C) includes a dialog menu and frequently rewritten elements, which are also generated by the GUI unit. In the measurement waveform screen shown in (D), video signal data is directly generated from waveform data stored in independent waveform memories for a plurality of measurement channels. The cursor screen shown in (E) is generated by the hardware mouse unit.

  FIG. 3 is a block diagram illustrating a configuration example for generating the display screen of FIG. Each of the screens shown in (A) to (E) is input to the synthesis order conversion unit 1 as, for example, a 16-bit video signal.

  Then, the composition order conversion unit 1 is set and inputted with the overlay order of each screen shown in (A) to (E) from the composition order setting unit 2. In the case of FIG. 3, as described above, from the back side to the front side, the menu screen shown in (A) → the grid screen shown in (B) → the foreground screen shown in (C) → (D). Setting input is made so that the measurement waveform screen is overlapped in the order of the cursor screen shown in (E).

  The composition order conversion unit 1 changes the composition order of each screen based on the composition order set by the composition order setting unit 2. When combining a plurality of n screens, the composition order conversion unit 1 is composed of n selectors each having 16 bits × n on the input side and 16 bits × 1 on the output side.

  The 16-bit × n video signal data rearranged in a predetermined superposition order by the composition order conversion unit 1 is input to the screen determination unit 3 and to the screen composition unit 4.

  The screen determination unit 3 determines whether the video signal data of each screen includes image information, and outputs 1-bit × n determination result data to the screen synthesis unit 4.

  Based on the determination result data of the screen determination unit 3, the screen synthesis unit 4 determines whether or not to output 16-bit × n video signal data as a 16-bit display screen in order from the screen with the highest synthesis order. Control. Specifically, if the determination result of the screen determination unit 3 includes image information, the video signal of the screen is output. If the determination result does not include image information, the next video signal is not output. Refer to the judgment result data of the screen with higher priority.

  Thereby, as shown in FIG. 2 (F), the screen including the image information is superimposed and displayed as the final display screen.

  In Patent Document 1, even when image data with different resolutions can be combined and the order of combining is determined in advance, a plurality of image data are set to a desired display priority order regardless of the order of combining. An image synthesizing apparatus that can be synthesized is disclosed.

Special table 2008-503795 gazette

  However, according to the configuration of FIG. 3, there is a problem that the circuit scale of the synthesis order conversion unit 1 increases. That is, when superimposing a plurality of n screens, the composition order converting unit 1 requires n selectors of video signal bit widths × n of the respective screens to be superimposed, and superimposes the bit widths of the video signals. The circuit scale increases in proportion to the number n of screens.

  The present invention has been made in view of such problems, and an object of the present invention is to realize a screen composition apparatus capable of greatly reducing the circuit scale of the composition order conversion unit.

  In order to solve such a problem, the invention according to claim 1 is a screen composition device configured to generate a desired display screen by superimposing a plurality of screens, and the video signal data of each screen is an image. A screen determining means for determining whether or not information is included is provided, and the overlapping order of the screens is converted based on the determination result of the screen determining means.

The invention according to claim 2 is a composition order setting unit for setting the order of each screen to be superimposed;
A screen composition unit that receives video signal data of each screen to be superimposed and sequentially outputs video signal data of the screen to be superimposed, and a screen determination that determines whether or not the video signal data of each screen includes image information A combination order conversion unit that changes the order of output data of the screen determination unit based on the setting order of the combination order setting unit, and a setting order of the combination order setting unit and an output data of the combination order conversion unit And a screen selection signal output unit that outputs a selection signal for selecting a screen to be combined to the screen synthesis unit.

  According to a third aspect of the present invention, in the screen composition device according to the second aspect, the screen selection signal output unit is configured so that the combination order set by the composition order setting unit and the composition order conversion are sequentially performed from the screen having the highest composition order. If the output data of the combining order conversion unit includes image information, a selection signal for selecting the screen is output to the screen combining unit and does not include image information. If there is, the determination result data of the screen with the next highest priority is referred to without outputting the selection signal for that screen.

  As a result, the circuit scale of the synthesis order conversion unit can be greatly reduced.

  The present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an example of the configuration of a screen composition apparatus according to the present invention, and the same reference numerals are given to portions common to FIG. In FIG. 1, the video signal data of each screen to be superimposed is directly input to the screen composition unit 5 and is also input to the screen determination unit 3. The output data of the screen determination unit 3 is input to the combining order conversion unit 6, the output data of the combining order conversion unit 6 is input to the screen selection signal output unit 7, and the output data of the screen selection signal output unit 7 is the screen combining unit 5. Has been entered. Note that the composition order conversion unit 6 and the screen selection signal output unit 7 are set and inputted with the composition order of the respective images to be superimposed from the composition order setting unit 2.

  The screen determination unit 3 determines whether or not the video signal data of each screen includes image information, and outputs determination result data of 1 bit × n to the synthesis order conversion unit 6.

  The combining order conversion unit 6 changes the order of the output data of the screen determination unit 3 based on the overlapping order set by the combining order setting unit 2. When combining a plurality of n screens, the composition order conversion unit 6 includes n selectors each having 1 bit × n on the input side and 1 bit × 1 on the output side.

  The screen selection signal output unit 7 refers to the overlay order set by the composition order setting unit 2 and the output data of the composition order conversion unit 6 in order from the screen with the highest composition order, and the output data of the composition order conversion unit 6 is If the image information is included, a selection signal for selecting the screen is output to the screen composition unit 5, and if the image information is not included, the next priority order is output without outputting the selection signal for the screen. Refer to the judgment result data of the high screen.

As the screen selection signal output unit 7, for example, a decoder having a bit width of “log ₂ n” can be used. This decoder has a bit width of “2” when n = 4 and a bit width of “3” when n = 8.

  The screen synthesis unit 5 sequentially outputs corresponding screens based on the selection signal input from the screen selection signal output unit 7. Thereby, as shown in FIG. 2 (F), the screen including the image information is superimposed and displayed as the final display screen.

  That is, the screen selection signal output unit 7 finally outputs a selection signal for selecting one of the screens 1 to n. For example, assuming that the screen 1 includes image data having the highest priority, the screen selection signal output unit 7 outputs a selection signal for selecting the screen 1, and the screen synthesis unit 5 outputs the screen 1.

A specific example will be described.
When n = 16, the bit width of the selection signal is 4 bits (log ₂ 16 = 4).
Here, the output of the screen selection signal output unit 7 is determined as follows.
Select screen 1 → Output binary number “0000” as selection signal Select screen 2 → Output binary number “0001” as selection signal Select screen 3 → Output binary number “0010” as selection signal Select screen 4 → Output binary number “0011” as a selection signal
・
Select screen 16 → Output binary number “1111” as selection signal

At that time, the output of the screen composition unit 5 is determined as follows.
Selection signal is binary number “0000” → Screen 1 is output Selection signal is binary number “0001” → Outputs screen 2 Selection signal is binary number “0010” → Outputs screen 3 Selection signal is binary number “0011” → Screen 4 Output
・
Select signal is binary number “1111” → screen 16 is output

  When the screen 1 includes image data having the highest priority, the screen selection signal output unit 7 outputs a binary number “0000” as a selection signal in order to select the screen 1. Then, the screen composition unit 5 outputs the screen 1 when “0000” is input as a binary number.

  With the configuration as shown in FIG. 1, the circuit scale of the synthesis order conversion unit 6 can be significantly reduced compared to the circuit scale of the synthesis order conversion unit 1 of FIG. That is, in order to configure the composition order conversion unit 1 of FIG. 3, n selectors of video signal bit widths × n of the respective screens to be superimposed are required, but the composition order conversion unit 6 of FIG. It can be configured by using n number of × n selectors. More specifically, when the video signal input is 48 bits wide and 20 planes, compared with the number of use of a look-up table (LUT) which is a basic block of a commercially available FPGA (Field Programmable Gate Array), For example, when using Stratix 2 manufactured by ALTERA, the composition order conversion unit 1 in FIG. 3 must use 1008 LUTs, but the composition order conversion unit 6 in FIG. 1 can be composed of 21 LUTs. The circuit scale can be reduced to about 1/20.

  In the above-described embodiment, the example of the overlay display screen in the waveform measuring instrument has been described. However, the present invention is not limited to this, and can be applied to the display screens of various measuring instruments.

  As described above, according to the present invention, it is possible to realize a screen composition device that can greatly reduce the circuit scale of the composition order conversion unit, which is suitable as a display screen composition device for a waveform measuring instrument, for example.

It is a block diagram which shows the structural example of the screen composition apparatus by this invention. It is explanatory drawing of the example of a screen synthesis | combination in the conventional waveform measuring device. It is a block diagram which shows the example of a conventional structure for producing | generating the display screen of FIG.

Explanation of symbols

2 Composition order setting part 3 Screen determination part 5 Screen composition part 6 Composition order conversion part 7 Screen selection signal output part

Claims (3)

In a screen composition device configured to generate a desired display screen by superimposing a plurality of screens,
A screen composition apparatus, comprising: a screen determination unit that determines whether or not the video signal data of each screen includes image information, and converts the overlapping order of the screens based on a determination result of the screen determination unit. A composition order setting unit for setting the order of each screen to be superimposed;
A screen compositing unit that receives video signal data of each screen to be superimposed and sequentially outputs video signal data of the screen to be superimposed;
A screen determination unit that determines whether the video signal data of each screen includes image information;
A combination order conversion unit for switching the order of output data of the screen determination unit based on the setting order of the combination order setting unit;
A screen selection signal output unit that outputs a selection signal for selecting a screen to be superimposed based on the setting order of the composition order setting unit and output data of the composition order conversion unit, to the screen composition unit;
A screen compositing device characterized by comprising:   The screen selection signal output unit refers to the overlay order set by the composition order setting unit and the output data of the composition order conversion unit in order from the screen with the highest composition order, and the output data of the composition order conversion unit is the image If information is included, a selection signal for selecting the screen is output to the screen composition unit, and if it does not include image information, the next highest priority is output without outputting the selection signal for the screen. 3. The screen composition apparatus according to claim 2, wherein the screen determination result data is referred to.

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