WO2000019714A1

WO2000019714A1 - Circuit system for image-in-image representation

Info

Publication number: WO2000019714A1
Application number: PCT/DE1999/002917
Authority: WO
Inventors: Xiaoning Nie
Original assignee: Infineon Technologies Ag
Priority date: 1998-09-30
Filing date: 1999-09-14
Publication date: 2000-04-06

Abstract

A miniature image processing stage (30) on its input side comprises a demultiplexer (31) for connecting at least two different video signal sources (Video2, Video3). In a storage unit (34) miniature images are stored which are assigned to each of the at least two video signal sources (Video2, Video3). An output stage (35) calls up the stored miniature images at the desired time.

Description

description

Circuit arrangement for picture-in-picture display

Such a circuit arrangement is already known from DE 43 13 228 AI of the applicant. As an essential component, this arrangement has a picture-in-picture processor which enables a reduced picture to be superimposed on a larger main picture. The video signal sources for the main picture and the small picture to be superimposed on the main picture can be selected completely independently with regard to television standard and synchronization. The picture-in-picture processor takes over the image reduction, the intermediate storage of the reduced image in an integrated image memory and the output of the image data for this reduced image via a digital-analog

Conversion stage so that the image signal for the reduced image is available in analog form at the output of the picture-in-picture processor.

The image processing stage for the main image provides image signals from a second video signal source. This main image processing stage can basically be constructed in analog or digital form. The structure and mode of operation of such a main image processing stage has long been known. At the output of this image processing stage, for example, analog image signals can be tapped. A switching device, that is to say a so-called RGB processor, finally ensures timely switching between the image signals for the reduced picture and the main picture, so that a small picture shown in a main picture is visible on the screen of the television set.

Integrated circuits for picture-in-picture display are now sufficiently available. Examples of the above-mentioned picture-in-picture processors are the integrated ones

Circuits SDA9188 and SDA9189 from the applicant. An example the integrated circuit is TDA 4685 or TDA 9080 for an RGB processor.

Common to these known circuit arrangements for picture-in-picture fading in is that the small picture to be faded in always comes from the signals of a single video signal source. This means that only one moving small picture can be faded into the main picture or several still pictures which are made available by switching the frequency of the one video signal source.

In order to be able to fade in several moving pictures, for example two moving pictures, into one main picture, it has so far only been possible to provide two small picture processing stages connected in parallel and to provide these decimated video signals provided at the output of these two small picture processing steps for fading into the main picture.

The problem with this solution is the high technical outlay required by the two parallel image signal processing stages connected in parallel. Separate image decimation stages and a downstream memory device are therefore required between two input-side demultiplexers for the two video signal sources in each signal branch. In addition, due to the parallel connection of the

35 mm signal processing stages also require UV interpolation stages and subsequent framing / blanking stages in each signal branch.

The aim of the present invention is to provide a circuit arrangement with which a plurality of moving small images can be superimposed on a main image, the circuit complexity required being reduced to a minimum compared to the previously known solutions. This goal is achieved by a circuit arrangement for picture-in-picture fade-in, as specified in claim 1.

Developments of this circuit arrangement are the subject of the dependent claims.

The circuit arrangement according to the invention is therefore essentially based on the fact that the small picture processing stage has a demultiplexer for the input connection of at least two video signal sources, and that small pictures associated with each of the at least two video signal sources can be stored, and that these small pictures from an output stage the 35 mm image processing level.

The principle on which the present invention is based is therefore based on the multiple use of the functional blocks (demultiplexer, decimation stage, memory device, filter device, etc.) connected in series in a single 35 mm processing stage. This means that at least the signals from two different video signal sources alternately pass through the same circuit blocks of the 35 mm signal processing stage. It is only necessary that the clock frequency for signal processing is increased accordingly. If, for example, two video signal sources are processed by the 35 mm signal processing stage, the clock frequency of the individual stages is selected to be twice as high as if only a single video signal is to be processed by the 35 mm signal processing stage.

In order to achieve the same quality as with a single PIP overlay, the clock frequency for processing two video signal sources, which represent moving images, is selected twice as high. In addition, each memory register in the memory device of the single PIP Chips added another register. This means that the storage capacity of the storage device when processing video signals from two video signal sources is to be selected twice as large as in a single-PIP device. The number of necessary adder and multiplexer stages, however, remains the same as with the single PIP. However, each adder works at double or multiple speeds as with the single PIP. Each multiplexer switches at exactly the same frequency as with the single PIP. The additional effort is therefore limited to the doubled number of memory registers. As a result, the costs of an ASIC implementation in a circuit arrangement for inserting, for example, two moving images into a main image will be significantly less than the effort of two small image signal processing stages connected in parallel.

In principle, the circuit arrangement according to the invention can also be applied to a color decoding stage and luma separation stage that may be present. For example, the number of multipliers will remain at two and the SINUS-ROM will remain the same. Advantageously, an integrated color decoder can also be implemented in a double PIP, the costs of which will be significantly lower than the costs of two separate single PIPs.

The circuit arrangement according to the invention is explained in more detail below in connection with several figures. Show it:

1 shows the basic block diagram of a picture-in-picture processing device,

Fig. 2 is the block diagram of the 35mm processing stage of Fig. 1 according to the prior art, and

Fig. 3 is a block diagram of a 35mm processing stage of FIG. 1 according to the present invention. The block diagram shown in FIG. 1 of a circuit arrangement for image-m-image insertion shows a main image processing stage 20, to which a signal from a first video signal source Videol is fed on the input side, and RGB signals Rl, Gl, Bl of the main image channel at its output are tapped. These RGB signals R1, Gl and B1 are fed to an RGB processor 40, that is to say a switchover device. The signal from a second video signal source Vιdeo2 reaches a terminal image processing stage 30, on the output side of which the RGB signals R2, G2 and B2 of the terminal image can be tapped. The terminal image processing stage is synchronized via a so-called VSP (Vertical Synchronous Parent) signal.

For example, the integrated circuit SDA9188-3X from Applicant can be used as an integrated circuit for the terminal image processing stage. The RGB processor can be implemented, for example, by the integrated circuit TDA 9080. RGB signals R1, R2, Gl, G2, Bl, B2 of an image-image signal can be tapped at the output of the RGB processor. If these RGB signals Rl, R2, Gl, G2, Bl, B2 are made available to a video output stage of a television set, a main picture with a superimposed terminal picture appears on the screen.

FIG. 2 shows the block diagram of a conventional terminal image processing stage. The signal from a video signal source Vιdeo2, which is to be displayed as a terminal image on the screen, is fed to a demultiplexer 31, at the output of which the series circuit of a filter stage 32, a decimation stage 33, a memory 34 and a digital-to-analog converter stage 35, ie one Output stage, is supplied. The demultiplexer 31 and the other circuit components are supplied by a clock generator 60 with the clock frequency T1 for signal processing. The demultiplexer 31 ensures that, for example, the YS and UVS signals made available via ten lines alternately terstufe 32 are supplied. The decimation stage arranged at the output of the filter stage 32 ensures that the image signal is reduced. The signals for the reduced image are then buffered in the memory device 34 in order to finally be fed back to the digital-to-analog converter stage 35.

FIG. 3 shows the block diagram of the small picture signal processing stage 30 according to the present invention. The series connection of demultiplexer 31, filter stage 32, decimation stage 33, downstream storage device 34 and ultimately provided digital-to-analog converter stage 35 is again present. However, the demultiplexer 31 is now intended to alternately switch the signals from at least two separate video signal sources Video2, Video3 to the filter stage 32. For this purpose, the demultiplexer 31 is of course to be provided with at least twice as many input terminals as the demultiplexer 31 of FIG. 2. Furthermore, the demultiplexer 31 is switched with a clock signal T2 from a clock generator 60, which is twice as high when processing two moving small images that come from two separate video signal sources Video2, Video3.

The signals provided by the demultiplexer 31 at the output pass through the filter stage 32 and the decimation stage 33 in order finally to be temporarily stored in the memory 34. So that the memory 34 can temporarily store the video signals provided for the two small images to be faded in, the memory capacity of this memory 34 is twice as large as the memory capacity of the memory 34 from FIG. 2. On the output side, the circuit arrangement from FIG. 3 again has a D / A converter 35.

Claims

claims

1. Circuit arrangement for picture-in-picture display, in which in a main image processing stage (20) a main image and in a small image processing stage (30) a decimated small image to be superimposed on the main image can be generated and in each case an RGB processor (40), which Provides picture-in-picture signal on the output side, can be supplied, characterized in that the small picture processing stage (30) has a demultiplexer (31) for the connection of at least two video signal sources (Video2, Video3) on the input side, and that in a memory device ( 34) small images assigned to each of the at least two video signal sources (Video2, Video3) can be stored, and that these small images can be called up from the storage device (34) by an output stage (35) of the small image processing stage (30).

2. Circuit arrangement according to claim 1, so that the demultiplexer (31) is connected in series with a filter stage (32), an image decimation stage (33) and the memory device (34).

3. Circuit arrangement according to claim 2, so that the demultiplexer (31) is connected upstream of the filter stage (32).

4. Circuit arrangement according to one of claims 1 to 3, d a d u r c h g e k e n n z e i c h n e t that a clock generator (60) is provided, which provides the demultiplexer (31) a double high clock frequency (T2) compared to a single pip device.

5. Circuit arrangement according to one of claims 1 to 4, since you rchgek characterized in that the small images superimposed in the main image of the small image processing. Processing stage (30) feedable video signal sources (Video2, Video3) provide moving images.

6. Circuit arrangement according to one of claims 1 to 5, so that the video signal sources (Video2, Video3) which can be connected to the 35 mm image processing stage (30) are provided by separate tuners.

7. Circuit arrangement according to one of claims 1 to 6, d a d u r c h g e k e n n z e i c h n e t that the 35 mm image processing stage (30) is designed as an integrated circuit.

8. Circuit arrangement according to one of claims 1 to 7, so that the video signal sources (Video2, Video3) that can be fed to the 35 mm processing stage (30) are Y-U-V signal components in 4: 2: 2 or 4: 1: 1 format.