DD254095A1 - VIDEO STORE ADDRESS CIRCUIT - Google Patents

Abstract

The invention relates to the field of digital television signal storage on read-only memories, which are used primarily for image processing and as a buffer for the transition to other storage media. The better utilization of the individual memory is done without waiving pixel and row address by reformatting the addresses in such a way that in each case the lines are three quarters of a memory line of 1 K and partial lines are in the sequence memory. The arrangement consists of a simple arithmetic unit in two of the pixel and nine of the row address lines, which are reduced to a total of ten. Fig. 1

Description

For this 2 pages drawings

Field of application of the invention

The invention relates to the address control of memory circuits for use in digital image signal processing. It is applicable in digital image memories, where address manipulations are necessary to achieve image effects.

Characteristic of the known state of the art

For video memories which operate at the 13.5 MHz clock frequency envisaged for the studio, CCIR (Rec. 601, Geneva 1982) and OIRT (Rec. No. 106 of the TK OIRT) recommend 720 samples for one line and to save a field of 288 lines. In order to manage with as little storage space as possible, it is generally known to use 768 memory locations for one line in synchronizers. This is a three quarters K, where K is the number 1024. For a field memory, therefore, 768 x 288 = 221184 memory locations are required. Conventional synchronizers are therefore equipped with 256K bytes of memory. This space is minimal.

The address counters for these synchronizers usually consist of counter circuits, which are disabled after 768 sampling points by another Zählschaitung for the time of digital blanking {96 sampling points). After this digital blanking, the counter continues to count for the next 768 sample points. The disadvantage of this address control is that line and pixel addresses are not separated. For image memory, which should be suitable for digital effects, a separation of pixel and row address is required for the computer control.

A simple known way of separating these addresses is to oversize the memory by using 1K memory locations for one line and 512 memory lines for the 288 TV lines. The shortcomings of this solution consist in the larger space requirements, the larger power consumption and the smaller reliability for such oversized memory arrangements.

In the patent DE HO4N 5/76 3510539 a method for reducing the storage space requirement is also specified. The feature is a conversion and summary depending on content and data. However, this method is unsuitable for video memory, since the fixed assignment of the sampling point on the screen to the corresponding memory space is lost.

A known image storage device (DLS 6001 Fa. Quantel) therefore uses a conversion of the addresses, wherein

ASp = AZ (1), ASp = memory address; AZ = line address and with η = integer

8th "

AZ '

- with K = 1 024. In this conversion, no enumeration of the Η gap is required. The disadvantage of this solution is that at K

256 K byte field memories only 262144/896 = 292.6 lines can be stored in one field, so the total V gap is not detected and that for permanent storage on the hard disk memory a larger storage space or a new conversion is required.

Object of the invention

The aim of the invention is to avoid the mentioned disadvantages with minimal effort.

Explanation of the essence of the invention

An analysis of the technical causes of defects shows that the separation of the line and pixel address with losses in storage capacity is purchased, or unusable capacity of the hard disk memory are claimed. In contrast, the object of the invention is to achieve the separated line and pixel addresses with minimal storage space without loss of usable storage capacity.

Assuming a video memory address circuit with blanked pixel addresses and line addresses as inputs, an arithmetic unit and memory addresses as outputs, this object is achieved in that the zeroth to seventh pixel address line directly to the corresponding memory address lines and the eighth and ninth pixel address line and the tenth to eighteenth line address line on the Are connected to the eighth to seventeenth memory address line and the nineteenth row address line is connected directly to the eighteenth memory address line.

The invention is based on the finding that the losses are based on the fact that the comparison solution does not omit the storage space for the Η-gap in the conversion of the addresses and therefore must reduce the V-gap, whereas the invention proceeds from an optimal staggering of the output-side memory addresses , The effect of the invention is therefore that at least all lines of the V-gap in the video memory are einspeicherbar and yet space is saved on the hard disk space. In the lines of the V-gap also computer data can be entered, which are then available both in the video memory and on the hard disk space. Furthermore, due to the reduced storage space requirement, a faster transfer of data between hard disk storage and video storage is possible. The invention is based on the fact that the calculator converts the addresses according to the formula

ASp = AZ (I - ^ -)

allowed.

Here, ASp = memory addresses; AZ = counter addresses; η = integer from AZ / customer K the number 1 024.

embodiment

The invention and its mode of action are explained in more detail in the following embodiment. In the accompanying drawings show the

1 shows a block diagram of the arrangement according to the invention,

Fig. 2: the principle of the division of the memory space and

Fig. 3: an embodiment with an arithmetic unit of ALU circuits.

In Fig. 1, the block diagram of the inventive arrangement is shown. On the input side, the address lines A0 to A19, which have been blanked out with a blanking counter or a corresponding horizontal blanking pulse, are available which are separated according to picture elements and line addresses. The address lines A8 to A18 are connected to an arithmetic unit. As an arithmetic unit ALU circuits come into question. On the output side, the memory addresses A8 to A17 are present. The effect of the arithmetic unit is that for all addresses of the first line, the memory address coincides with the pixel counter address. This is from 0-767. For the time of the digital blanking interval, ie 96 sample point, the pixel counter is stopped. Thereafter, the line counter is switched from 0 to 1 and the pixel counter is set to 0. The 1 of the input-side row address causes in the arithmetic unit that is deducted for all the following sampling points of the second line ¹ AK. For the 3rd line ² AK are subtracted from the input address. This conversion is also feasible by complementation and addition. · ·

With this conversion, it is possible to manage with input-side separation of pixel and line address not only with minimal storage space. The avoided storage of the redundant digital H blanking interval makes it possible to store the entire V gap in the video memory and to save space for the hard disk memory. Figure 2 shows the principle of the division of the memory space. The first line ranges from 0 to ³ AK. Between the individual lines only a small part of the H-blanking interval (48 sampling points) is stored. This part is drawn hatched in Fig. 2. For the greater part of the Η-blanking, ie for 96 sampling points, no storage space is needed. The 2nd line is stored in the video memory between ³ AK and 1.5 K.

Figure 3 shows an embodiment with an arithmetic unit of ALU circuits. The circuit IP4, for the z. B. the circuit S182 to K551 IP4 is suitable forms the transfer unit ÜE. The ALU circuits (K531 IP3) are switched as subtractors. They allow the conversion according to the formula given above. By using Schottky circuits for this conversion, the time for a conversion is less than one sampling interval.

Claims (4)

Claim: 1. Video memory address circuit with blanked pixel addresses and line addresses as inputs, an arithmetic unit and memory addresses as outputs, characterized in that the zeroth to seventh pixel address line directly to the corresponding memory address lines and the eighth and ninth pixel address line and the tenth to eighteenth line address line via the arithmetic unit with the eighth to seventeenth memory address lines are connected and the nineteenth row address line is connected directly to the eighteenth memory address line. 2. Video memory address circuit according to claim 1, characterized in that the arithmetic unit consists of arithmetic logic circuits (ALU). 3. Video memory address circuit according to claim 1, characterized in that the arithmetic unit consists of negators and full adders. 4. Video memory address circuit according to claim 1, characterized in that the arithmetic unit consists of ROM circuits.