DE19705775C1 - Flicker reduction method for image signal - Google Patents

Abstract

In order to reduce the flickering of a picture signal (FBAS), a high and deep signal separation (4, 5) is carried out followed by different signal treatment (7, 8). In the high channel (8), a first frame of a sequence of line-assembled frames with a double frame rate is produced by direct reception of a frame with an identical raster, on the input side. The remaining frames are produced by means of median filtering. During movement, which is detected by motion detection (9), pixels with equal numbers of identical and different rasters of input frames adjacent during the movement phase, as well as a constant value are sent to the median filters. If no movement is detected, pixels with identical rasters are weighed more highly.

Description

The invention relates to a method for reducing flicker egg nes image signal with interlaced fields, in which the Image signal into a high-frequency and a low-frequency Share with different signal processing is separated to an image signal with a doubled field to generate te. The invention also relates to a corre appropriate circuit arrangement.

Such a method is described in EP-A2-0 727 904 ben. After splitting the video signal into a treble and a depth signal component is measured using median fil techniques in the high-altitude canal are essentially flickering free, in the deep channel an essentially motion-rich conversion to a field sequence with doubled Field rate performed. In the high-altitude canal first field of an output sequence from line ver combed fields by direct takeover of a grid-like Chen received field on the input side. The pixels nes second field of the height channel are indicated by a me dian filtering generated, the input "0" and the pixels of two successive grid differences ner input side fields are supplied. Correspond The same applies to the generation of a fourth output side Field. To generate a third field, On gait pixels from two consecutive grid matches Fields and the intervening grid Field fed into the median filter. The input picture points are around the respective existing motion vector compensated.  

Since pixels from three are used to generate the third field successive fields on the input side solution, the given solution requires at least three Field memory. If according to a specified training to calculate the second output field of the Me dian filtering also pixels of another raster glide Chen input field are even supplied four field memories required.

The object of the invention is to begin with bene method to improve such that with appropriate Image quality reduced the storage effort for the height channel becomes.

This task is accomplished by a method according to the characteristics of claim 1 solved.

A circuit arrangement is specified in claim 8.

In the method according to the invention, the respective me dian filtering in the height channel only input values from two to successive fields supplied. This only requires two field memories. A movement dependency becomes there by taking into account that one from a motion detector controlled switching is provided so that when kei ne movement is present, such pixels with higher weight device are fed, compared to the generated Pixel have the same grid position, and that when Movement is detected, grid-like and grid-shifted whose pixels are fed with the same weighting and also a constant value. In the former case with little or no movement will dominate raster-like pixels, so that there is a high spatial resolution and a good still image playback results, while a detectable movement Implementation in the correct phase is carried out.  

As with EP 0 727 904 mentioned at the outset, the The input vector is set to the motion vector that was calculated for the pixel point to be generated. This Vector is in an input field, its movement phase before the movement phase to be generated, in a first Direction set in a field, its movement phase after the movement phase to be generated lies in the opposite opposite direction. They will expediently be present the motion vectors used to detect motion to determine if there is movement or Not. With respect to the deep channel, this is preferably done same processing as in the above European Patent application.

The invention based on the in the drawing illustrated figures explained in more detail. Show it:

Fig. 1 is a block diagram of a procedural procedure according to the invention or a circuit arrangement according to the invention and

Fig. 2 is a representation of the input and output side fields in the height channel, specifying the input values of the respective median filter.

The circuit of FIG. 1 is supplied to an input terminal 1 a video signal CVBS. The video signal FBAS contains interlaced fields A1, B1, A2, B2,. . . The fields A1, A2 contain the odd-numbered lines, the fields B1, B2 the even-numbered lines. In a field memory 2 , the fields on the input side are temporarily stored, so that the signal FBAS 'read out on the output side contains these fields with a doubled line frequency and field rate. While the fields are present on the input side at a rate of 50 or 60 Hz, the signal FBAS ′ has fields at a rate of 100 or 120 Hz. The signal FBAS 'is fed to a further field memory 3 , the output signal FBAS''is delayed by one field with respect to the signal FBAS'. In devices 4 , 5 , the fields are each separated into a height signal component H1 or H2 and a low signal component T1 or T2. In addition, a vector estimator 6 , to which the output signals of the memories are supplied, calculates the motion vectors present between the input side half images. Depending on these motion vectors, the depth signal components T1, T2 are converted into an output signal for the depth channel T12 in a device 7 . This implementation is preferably carried out according to the process steps described in EP-A2-0 727 904 in connection with FIGS . 5 to 7. Since input values of only immediately successive fields are supplied to the median filters provided for implementation, the two field memories 2 , 3 are also sufficient for signal processing in the deep channel.

In a device 8 , the high-frequency signal components H1, H2 are converted to an output signal H12, which includes the field at twice the field rate. For this purpose, the device 8 is supplied with the motion vectors determined by the vector estimator 6 . These are used in the same way as in the implementation in the device 7 for the deep channel for movement compensation by setting the motion vectors at the input values of median filters of the device 8 as described in the above-mentioned European patent application. In addition, a motion detector 9 is seen before, which expediently detects existing movement between the depth signal signals T1, T2 and, depending on this, controls the implementation in the device 8 . The downward converted signals T12 and H12 are additively superimposed in an adder 10 and provided as an output signal FBAS '''at an output terminal 11 .

Since the motion contained in the image signal is contained in the depth signal portions T1, T2, it is expedient to calculate the difference in the fields of the depth signal portion T1, T2 in the motion detector 9, if necessary after a raster interpolation to produce the same raster position. Subsequent amount formation, horizontal and vertical filtering and a threshold value comparison provide information at the output of device 9 as to whether or not there is movement between the half-frames that are currently being filtered in the median filters. Alternatively, the processing can Einrich 9 with the determined by the vector estimator 6 motion vectors are fed, wherein for hori zontal separated and vertical motion vector components, a threshold value comparison is carried out with subsequent horizonta ler and vertical filtering.

The mode of operation of the device 8 will now be explained with reference to FIG. 2, in which the fields A1, B2, A2 of the height channel at the input contained in the signal FBAS are shown with a field rate of 50 Hz and the fields α, β, γ, δ converted upwards Output image sequence H12, which are interlaced with 100 Hz field rate. The device 8 is expediently supplied with the fields on the input side already at the 100 Hz level, so that two input fields in the 100 Hz line grid are available for calculating an output field. The field α is obtained by taking over the pixels of the field A1 directly. Pixels of the other fields β, γ, δ are obtained by median filtering 20 , 21 and 22 , respectively.

To calculate a pixel 30 of the field β, the median filter 20 is supplied with the pixels 31 , 32 of the field A1 each with a single weighting and the pixel 33 of the field B1 with a multiple weighting. The pixel 33 is fed to the median filter 20 at least twice. A switch 26 , which is controlled by a movement detection 23 , ensures a switchover such that when no movement is detected, the pixel 33 is fed three times (shown in FIG. 2) and that when movement is detected is, the switch 26 switches into its other switch position and the constant value "0" is supplied instead of the pixel 33 . The motion detection 23 detects movement present between the fields A1, B1. It is realized in the device 9 ( FIG. 1) by processing either the depth signal components T1, T2 or the motion vectors calculated by the vector estimator 6 as described above. The pixels 31 , 32 are located at those points of the field A1 that are directly adjacent to the point corresponding to the pixel 30 in the field β. The pixel 33 lies at the point in the field B1 corresponding to the pixel 30 in the field β. As can be seen from FIG. 2, field A1 has a different grid position compared to field β, field B1 has the same grid position. The movement phase of the field β to be generated lies between the movement phases which represent the fields A1, B1, that is to say after the movement phase of the field A1 and before the movement phase of the field B1. For the sake of simplicity, ge provided by the device 6 motion vectors are not taken into account in FIG. 2. In fact, to give those points 31, 32 and 33 countries in the Halbbil A1, B1 in that 30 ent speaking location A to the image point 30 associated BEWE is set at the supply vector where the pixel. The movement vector with the same amount is applied in the fields A1, B1 in the opposite direction in each case.

To calculate a pixel 40 in the field γ, the pixel filter 21 is supplied with a pixel 41 of the same-phase, raster-different field B1, and an image point 42 of the later-phase, raster-like field A2. Without taking into account the motion compensation by a motion vector assigned to the pixel 40 , the pixel 41 is adjacent to the point corresponding to the pixel 40 , the pixel 42 at the point corresponding to the pixel 40 . A movement detection 24 , which evaluates the movement between the fields B1, A2, controls a changeover switch 27 . If no movement festge is set, the switch 27 is in the position shown, whereby the pixel 42 with double weighting is fed to the median filter 21 . Otherwise, the pixel 42 is supplied only once and also the constant value "0".

By the median filter 22, a pixel 50 is generated δ in the field, the median filter 22 are input the picture points 42, 51 in bewegungsphasenspäteren, raster different field A2 fed in, and the pixel 33 in the bewegungspha senfrüheren, raster same field B1. Without taking into account a motion vector assigned to the pixel 50 , the pixel 33 lies at the point corresponding to the pixel 50 . The pixels 42 , 51 are located at the position corresponding to the pixel 50 in the field A2 in the line above and below. By means of a movement detection 25 , which detects the movement between the fields B1, A2, a changeover switch 28 is controlled, through which, if there is no movement, the pixel 33 is fed to the median filter 22 in triple weighting, and then, if there is movement, the pixel 33 is fed in double weighting and also the constant value "0".

The motion-controlled switch 26 , 27 , 28 ensures that when there is movement, the corresponding median filters 20 , 21 and 22 are fed a respective number of grid-different and grid-equal image points and the constant value "0". This leads to the fact that when moving motion-supported by the respective median filter that pixel is selected that best fits into the pixel environment of the motion phase of the field to be generated. Vector-based intermediate images are generated, which ensure relatively good detail resolution and avoid movement flickering. If there is no movement, the changeover switches 26 , 27 , 28 are set in such a way that the respective median filters are supplied with the same pixels with a higher weighting than the different pixels. The output field sequence then has the character of a repetition of the input fields in the sequence ABAB. This causes a high spatial resolution, which ensures a sharper still image reproduction, so that a good flicker reduction with high detail resolution is achieved.

Claims (8)

1. Method for flicker reduction of an image signal, in which an input image signal (FBAS) is supplied, which contains interlaced fields (A1, B1, A2) with a predetermined field rate, in which the image signal is in a high frequency (H1, H2) and a low-frequency signal component (T1, T2) is separated and in which a different signal processing ( 7 , 8 ) is applied to the high-frequency and the low-frequency signal component by converting the input-side fields of the high-frequency and the low-frequency signal component into line-intermeshed output-side fields with a doubled field rate be, in which the output-side fields of the signal components are combined to form an output image signal (FBAS '''), in which, in the signal processing of the high-frequency signal, in part a first output-side field (α) is derived from an input-side field (A1) of the same grid position and the other fields (β, γ, δ) on the output side by means of median filtering ( 23 , 24 , 25 ) of image points from two successive fields on the input side with different raster positions are generated by the median filtering (e.g. B. 20 ) a pixel (z. B. 33 ) is supplied, the point at one of the point of the image to be generated (z. B. 30 ) after a shift by an assignable motion vector corresponding position in a grid (z B1) of the fields on the input side, and at least one pixel (e.g. 31 , 32 ) located at a position adjacent to the location of the pixel to be generated (e.g. 30 ) after a shift by an assignable motion vector (e.g. 31 , 32 ) lies in a grid-different one of the input-side fields (e.g. A1), and in that when the movement is detected, the latter pixel is fed with a higher weighting to the median filtering than when the movement is not detected. 2. The method according to claim 1,  characterized in that if no movement is detected, the median filter tion a constant value ("0") is supplied and that instead of when the motion is detected, the former pixel (e.g. 33) is fed. 3. The method according to any one of claims 1 or 2, characterized in that the first (α) and a second (β), a third (γ) and a fourth (δ) field are generated on the output side for the high-frequency signal component that to generate the second field (β) of the median filtering ( 20 ) from the raster-different input field (A1) preceding the phase of the movement, two such picture elements ( 31 , 32 ) are supplied, which are used to generate the picture element ( 30 ) after one Shift adjacent to an assignable motion vector, as well as that pixel ( 33 ) from the movement-phase-following frame-like input field (B1) which corresponds to the position at the location of the pixel ( 30 ) to be generated after a shift by an assignable motion vector ( 33 ) is triple weighted if no movement is detected and double weighted if Movement is detected, and a constant value ("0") is also supplied. 4. The method according to claim 3, characterized in that for generating the third field (γ) of the median filtering ( 21 ) from the same phase in terms of movement phases raster different nen input side field (B1) one of those pixels te ( 41 ) is supplied, which to the place of Pixels ( 40 ) to be generated are adjacent after a shift by an assignable motion vector, and that pixel ( 42 ) from the raster-smooth input field (A2) that follows in terms of the movement phase is located at the location of the pixel ( 40 ) to be generated after a shift by an assignable motion vector corresponding location ( 42 ), in double weighting if no movement is detected, and in single weighting if movement is detected, and a constant value ("0") is also supplied. 5. The method according to any one of claims 3 or 4 or 3 and 4, characterized in that for generating the fourth field ( 8 ) of the median filtering ( 22 ) from the subsequent rasterver in terms of movement phase different input-side field (A2) two such image points ( 42 , 51 ) are supplied, which are adjacent to the location of the image point to be generated ( 50 ) after a shift by an assignable motion vector, and that image point ( 33 ) from the motion phase precedes the grid-like input-side field (B1) which is at the location of the pixel to be generated ( 50 ) after a shift by an assignable movement vector corresponds to the location ( 33 ), in triple weighting if no movement is detected, and in double weighting if movement is detected, and a constant value is also supplied becomes. 6. The method according to any one of claims 1 to 5, characterized in that to determine movement a difference between successive fields of the low frequency Signal portion is performed. 7. The method according to any one of claims 1 to 6, characterized in that the motion compensation of the fed into the median filter most pixels by means of the values assignable to the pixels tion vectors by means of between the fields of the input Motion signal determined image signal is performed and that from the vectors after a threshold comparison  Signal is generated which indicates the presence of motion gives. 8. Circuit arrangement for flicker reduction of an image signal with a connection for supplying an input image signal (FBAS), which contains line-interlaced fields (A1, B1, A2) with a predetermined field rate, to memory means ( 2 , 3 ) for storing two fields, filter means ( 4 , 5 ), by means of which the input image signal can be separated into a high-frequency signal component (H1, H2) and a low-frequency signal component (T1, T2), means for signal processing ( 7 , 8 ) to which fields of the high-frequency and low-frequency signal components can be fed on the input side and by the output-interlaced output-side fields with doubled field rate by different signal processing for the high and low signal components can be generated, and means ( 10 ) by which the output-side fields of the signal components can be combined to form an output image signal (FBAS ′ ′ ′), the means for signal processing itung ( 8 ) with respect to the high-frequency signal are partially designed such that a first output-side field (α) can be derived from an input-side field of the same raster position (A1) and that further output-side fields (β, γ, δ) by median filtering ( 20 , 21 , 22 ) of pixels from two successive input-side fields with different grid positions can be generated by the median filtering (e.g. B. 20 ) a pixel can be fed, which at a location of the pixel to be generated (z. B. 30 ) after a shift by an assignable Be motion vector corresponding location (z. B. 33 ) in rasterglei Chen of the input fields (z B1), and at least one pixel (e.g. 31 , 32 ) which is located at a position adjacent to the position of the pixel to be generated (e.g. 30 ) after a shift by an assignable motion vector (e.g. B. 31 , 32 ) in a raster different one of the input-side fields (for example A1), and by depending on a motion detector (for example 23 ) when motion is detected the first pixel (for example 30 ) with higher Weighting of the median filtering (e.g. 20 ) can be supplied as if the movement was not detected.