DE2937283C2 - - Google Patents

Description

The invention relates to a television standard converter with a digital afterglow arrangement. With such a television standard converter, which is known from DE-OS 27 46 285 is it is possible to transfer image information from one standard to another Norm, e.g. B. from the PAL system to the NTSC system.

To simulate movements, parts from several Fields are combined to give the viewer the effect a real motion interpolation. This will in a television standard converter with a digital afterglow arrangement using an image memory together with Coefficients that control afterglow in the standards converter a controlled afterglow performed. The coefficients determine the proportion of the previously saved image to the new image available from the incoming data stream, before it is saved again in the memory. The motion representation, where a digital afterglow is used the subjective effect brings the ideal case close.

In the known television standard converter with digital afterglow arrangement however, the digital afterglow within of a single memory.

The object underlying the invention is therefore therein, a television standard converter with a digital afterglow arrangement to create one that looks even more real Motion simulation can be done.

This object is achieved according to the invention through training solved in the characterizing part of claim 1 is specified.  

In the television standard converter according to the invention are thus two memory devices are provided, the output signals multiplied by two selected coefficients be added to the actual in an adder Image output signals to be added to an output image result with digital afterglow, making it possible is proportions of the two images recursively and non-recursively put together.

Particularly preferred further developments and refinements the television standard converter according to the invention are the subject of claims 2 to 8.

The following is a special based on the accompanying drawing preferred embodiment of the invention closer described. It shows

Fig. 1 shows a known television standards converter,

Fig. 2, the movement of an object in different fields,

Fig. 3 shows an arrangement for carrying out a cyclic afterglow,

Fig. 4 shows the embodiment of the television standard converter according to the invention, and

FIGS. 5 and 6 alternative embodiments of a portion of the embodiment of the television standards converter according to the invention shown in Fig. 4.

Incoming video data are applied to an input processor 20 . The incoming video data have a digital form after they have been converted from the analog form, if necessary. The input processor 20 carries out the synthesis of the pixels of adjacent pixel information from at least one field. The number of pixels synthesized can be controlled to be larger or smaller than the original number of pixels for a particular field or frame, thereby causing expansion or compression. For example, converting from PAL to NTSC requires accepting an incoming line standard of 625 lines per frame and converting it to an outgoing standard of 525 lines per frame. The number of lines is thus reduced and is comparable to a fixed compression amount. The manner in which the pixels are synthesized in the processor 20 is described in more detail in the aforementioned patent applications.

The data from processor 20 is received by modifier 210 , which modifies the data with a coefficient K 11 before it is received by adder 211 . This data is added to previously stored data, which was first modified in the modifier 212 with the coefficient K 12 . The output of adder 211 passes through the modifier 213 , which modifies the data with the coefficient K 13 before it is stored in the memory 22 .

The reasons for this modification are explained below will.

In addition to changing the number of lines for an image field, the number of fields per second also changes. In the European PAL standard, the field frequency is 50 fields / sec. and for the NTSC standard used in the USA, it is 60 fields / sec. The number of lines is reduced by the input processor, as already mentioned, and the field frequency can be increased due to the asynchronous nature of the image memory, which allows different write-in and read-out frequencies. Part of the data from the old image field is combined with part of the new image field using the "outflowing" integration system, ie the coefficients K 11 , 12 and 13 , in order to produce a smooth movement (motion interpolation) with different image frequencies.

In the digital standards converter, the coefficients K 11 , K 12 and K 13 must be modified on a cyclic basis. The effect of using a cyclic variation can be used for "motion interpolation". The requirement placed on the digital standards converter changes depending on the type of scene that is being tested. The motion interpolation reduces distortion due to motion, since the standard conversion requires a conversion from, for example, 525 lines - 60 fields per second (NTSC) to 625 lines - 50 fields per second (PAL).

When an incoming picture with an incoming field frequency a moving picture of 60 fields per second, then successive images provide a general increment of the image that is left to right on the screen emotional. The outgoing images that deal with the outgoing ones Fields deal with a sequence of 50 per second. In an ideal motion interpolator would need an image of the moving Object that is provided on the outgoing image be provided in a position that is not on the incoming Fields is shown.

Such a moving object is shown in FIG. 2. Images at a field frequency of 60 Hz are shown at (a), (b), (c) and (d) and at a field frequency of 50 Hz are images at (e), (f) and (g). In this example it was chosen that field (a) coincides with (e) and (d) with (g), and in this time field the circular object moved completely over the field of view (FOV); thus it moved at (g) to (c) 1/3 or 2/3 of the field of view, but the object must have moved 1/2 field of view in the 50 Hz system. It is clear that there is no object with a 1/2 field of view movement in (a), (b), (c) or (d).

Appropriate simulation of motion interpolation can be done by the use of components from multiple fields to different Proportions are realized to make the viewer artificial to get him to believe a real motion interpolation to see.

The motion interpolation system used in the above system makes use of three different methods of moving in in the most acceptable subjective way. The system is variable and adaptive. Methods have been developed that make it possible to make the adaptation system semi-automatic.

The three methods used are listed below:

• a) Field sequence exchange
• b) Digital afterglow
• c) Digital cyclic afterglow variation

The three methods are explained below.

One can assume that the incoming field sequence to a known time position with regard to the outgoing field sequence  begins. As the images arrive sequentially, increases the error that occurs in the outgoing field sequence over a period of twelve incoming fields and ten outgoing Fields in a converter that 60 fields in Convert 50 fields.

In the paragraph above it was assumed that the two are different Field types (odd field and even field) cannot be exchanged in the order. The resulting discontinuous movement is clear to the observer visible.

If the field sequence is changed so that an odd field is represented as a straight field, the amplitude of the discontinuity be reduced by a factor of two.

The input processor 20 with adaptive volume manipulation described in the above-mentioned patent applications is capable of converting an odd field into an even field or an even field into an odd field with accuracy without distortion of the fixed and moving image. In the case of such a standard converter, adaptive volume manipulation is used to carry out a field sequence variation and thus to reduce the amplitude of the visible movement discontinuities.

An improvement in the subjective effect of movement discontinuity is made possible by the use of digital afterglow. A normal television system has due to the impact of phosphorus decay a small amount of residual storage.  

By using the image memory together with coefficients that control the afterglow, a controlled afterglow is introduced in the standard converter. The coefficients K 11 , K 12 and K 13 thus dictate which portion of the previously stored image is added to the new image available from the incoming data stream before it is stored again in the memory. It is possible to arrange the system with only two channels, but it is more typical to use three channels. Channel 1 is an input channel that enables data to be entered into the image memory. Channel 2 is an output channel that can be considered to be synchronous with channel 1 and allows information to be extracted from memory. Channel 3 is an asynchronous output channel through which the input and output system can be operated at different speeds.

In the basic system for digital afterglow, the coefficients K 11 , K 12 and K 13 are fixed values. Typical values are listed below:

K 11 = 0.625
K 12 = 0.375
K 13 = 1.0.

The motion display, in which digital afterglow is used, brings the subjective effect closer to the ideal case. However, different viewers could choose different values for the coefficients that best suit them. The variation of K 11 ; K 12 and K 13 by means of a control function that can be accessible to the viewer would create a means of choosing such values.

The effect of movement in a norm converter leads to cyclical discontinuity. Greater improvements in the subjective effect can be achieved if the digital afterglow is varied in a similar cyclical sequence. A typical cycle for K 11 is shown below:

Field K 11 10.5 20.625 30.75 40.875 51.0

The cycle repeats every 5 fields at the output. Again, subjective viewers can choose different K values that meet their own viewing needs, and it can be provided that the K value be changed after the viewer controls.

In Fig. 3 is a way how the cycle can be carried out is shown. A cyclic afterglow controller 220 , having address counters, receives incoming field pulses and outgoing field pulses and provides an address as a result of the comparison. The address provided is used to look up K 11 , K 12 and K 13 in a read only memory (ROM) 221 . A number of coefficients are stored in the read-only memory, to which access is possible through the address. In addition, the read-only memory has an input for varying the afterglow control. The afterglow control variation input drives a group of coefficients stored in the read-only memory. If a single read-only memory is not large enough to accommodate all of the required coefficients, a number of read-only memories can be addressed and controlled simultaneously by the afterglow control variation input. The operation and control of a read-only memory for digital processing are well known.

The coefficients for K 11 , K 12 and K 13 controlled at the read-only memory are received by the modifiers 210, 212 and 213 . The multiplier function of the modifier can be performed using a random access memory, for example.

One or more could improve the flexibility of the system suitable programmed digital microprocessors for calculation of the required coefficients can be used.

They can also be used to store the data stored in the memory To determine address places and the interaction of the Controls for compression or expansion, for digital afterglow and for other processing functions with the memory locations and to compute the hardware coefficient lookup tables.

In the above description, the digital afterglow and the digital cyclic afterglow were performed within a single memory, for example using the system within block 100 of FIG. 1.

According to the invention, an improved system for converting standards created, which will be described below.  

In the system according to the invention, an alternative form of afterglow characteristics can be achieved in that more than a memory is used. To make it easier to understand the method using memory as recursive Filters are called. In the method according to the invention, where more than one memory is used are recursive and non-recursive screening combined, and it turns out that improved results are achieved.

When the coefficient K 11 is set to 0.5, the lag causes an undesirable optical effect on the movement.

The fact that two identical systems are connected in series makes it possible to combine parts of the two images in a non-recursive method, as is shown in the embodiment in FIG. 4.

The system includes two memories 22 , each provided with the associated components for digital afterglow 210, 211, 212 and 213 . Thus, double systems, each corresponding to that of block 100 of FIG. 1, are provided. In addition, the output of channel 3 of memory P is received by coefficient unit 300 for coefficient KP and the output of memory Q is received by unit 302 for coefficient KQ . Their outputs are added in digital adder 301 to provide the video data system output. The function of the KP and KQ coefficients can be performed using the multipliers and the lookup system previously described.

The systems shown in Fig. 4 are usually set so that K 11 is 0.875. The two images are added in an adder 301 , which is designed such that it takes a portion KP and KQ from the two memories. KP and KQ are then varied cyclically to simulate the effect of motion interpolation. Below are typical KP and KQ values for a conversion from 60 to 50.

Two identical systems are shown in series for easier explanation. The demands on memory Q are not as high as for memory P , which has to work asynchronously between its input and output. Furthermore, it is not necessary to use the recursive filter elements around the memory Q , which only has to work as a simple delay memory.

By adding stored images over non-recursive Filter becomes a method for noise suppression in television signals created. If not the main task of the above non-recursive System of the norm converter, so this suppression takes place but instead of and is to be regarded as a useful feature.

If the standard converter has to change the number of lines per image field, a processor in the sense of block 20 is required, but this does not directly affect the digital afterglow.

In addition to the cyclic variation in the various coefficients as described in connection with Fig. 4, the coefficients can also be varied so that the degree of afterglow is controlled depending on the degree of motion detected by including a motion detector , which can additionally control the coefficient selected, for example, from the read-only memory and which is described in British Patent 15 94 341.

Although FIGS. 1 and 4 memory with associated elements for the coefficients K 11, K show 12 and K 13, these coefficients arrangements could also be modified so that only a variable coefficient (K 11) is provided, as in the systems of Figures . 5 and 6 is shown. Here, a subtractor 230 is additionally provided and, as shown in Fig. 5, the processed data is received by the subtractor along with the output from channel 2 of the memory. This output also goes to adder 211 . In the arrangement of FIG. 6, the memory output from channel 2 only runs directly to the subtractor. The incoming video data are received here directly by the adder 211 .

In practice, the system could be further simplified with reduced flexibility, so that it has the units 300 (KP) and 302 (KQ) and the adder 301 assigned to them, as well as the memories P and Q. As an alternative to such a simplified system, it would be possible to provide only one coefficient unit for the return line according to FIG. 5 or 6 for only one of the memories P and Q , as has already been proposed with reference to FIG. 4.

Although the system described separate storage and Having processing elements, the facility could also be in sectors be set up, to which processing would be assigned, making a distributed system like that in the United States patents 41 63 249 and 43 39 803.

Claims (8)

1. TV standards converter with a digital afterglow arrangement, characterized by a first memory device ( 22 ) for storing image signals, a second memory device ( 22 ) for storing image signals, a first coefficient device ( 300 ), the output signals of the first memory device ( 22 ) with a multiplies the first selected coefficient (KP) , a second coefficient device ( 302 ) which multiplies the output signals of the second storage device ( 22 ) by a second selected coefficient (KQ) , and an adder device ( 301 ) which outputs the output signals of the first and the second coefficient device ( 300, 302 ) added to image output signals which result in an output image with digital afterglow. 2. TV standards converter according to claim 1, characterized by a third coefficient device ( 210-213 ) which is connected between the output and the input of the first storage device ( 22 ) and a portion of the signals stored in the first storage device ( 22 ) the input image signals for the first storage device ( 22 ) is added and the resulting signals are stored in the first storage device ( 22 ). 3. TV standards converter according to claim 2, characterized by a fourth coefficient device ( 210-213 ) which is connected between the output and the input of the second memory device ( 22 ) and a portion of the signals stored in the second memory device ( 22 ) the input image signals for the second storage device ( 22 ) is added and the resulting signals are stored in the second storage device ( 22 ). 4. TV standards converter according to claim 2, characterized in that the third coefficient device ( 210-213 ) has an adder ( 211 ) and at least one multiplier ( 210 ). 5. TV standards converter according to claim 3, characterized in that the fourth coefficient device ( 210-213 ) has an adder ( 211 ) and at least one multiplier ( 210 ). 6. TV standards converter according to claim 4 or 5, characterized by a to the multiplier ( 210 ) connected subtractor ( 230 ). 7. TV standards converter according to one of claims 1 to 6, characterized in that the signals for a plurality of fields form a cycle and a device ( 220, 221 ) is provided which selects the coefficients depending on the position of the respective field in the cycle . 8. TV standards converter according to one of the claims 1 to 7, characterized by a motion detector device, that for a coefficient device or several coefficient devices selected Coefficients as a function of a detected Image movement controls.