DE2552751C2 - Process for digital run length coding with redundancy reduction for the transmission of binary coded image information - Google Patents

Description

The invention relates to a method for digital length coding with redundancy reduction for the ) Transmission of binary coded image information, short code yorte for frequently occurring run lengths and seldom run lengths long code words can be assigned and from a predetermined "5 .auflänge the run lengths a prefix word to distinguish between code words of the shorter run lengths md are assigned a code word following the prefix word, which defines the respective run lengths as Indicating binary number.

When transmitting binary coded image information, efforts are made to save transmission time and To save bandwidth, to use a coding, with the help of the redundancy provided by the scanner supplied image information is stuck, is reduced. The so-called run length coding is already used for this purpose has been specified in which the information of each pixel is not transmitted individually, but continuous runs of the same information (runs) are called length-coded digital lines transferred (US-PS 29 22 840).

This run length coding has in the meantime been improved by H u f f m a η η to the effect that the coding of the run lengths takes place with code words of different lengths. The most common Run length is used with the shortest code words and the less frequently occurring run length with longer code words, depending on the probability with which they appear in the picture happen. One can find an optimal code with this type of coding, but the electronic one The effort involved in encoding and decoding long code words, which are rare but still occur not justifiable.

As an improvement, a so-called aborted Huffman code has been described in "IEE International Convention Record" by PD D o dd and FB W o d, 1963, pages 60 to 93, in which Huffman coding is carried out up to an acceptable run length will. For longer run lengths, a prefix word followed by a code word of constant length with η bits is introduced, which specifies the real run length as a binary number. This code has also been given by WS M iche 1, WO F1 ecke η stei η and ER Kretzschmer in "Wescon Convention Record", 1957, Part 2, Vol. 1, pages 84 to 93. A good redundancy reduction can be achieved in this way, but the code is very susceptible to interference, and a minimally occurring interference is dragged along from line to line because the decoder does not recognize it.

The object of the present invention is to improve such a code so that the influence of Disturbances in the bit flow in which the transmission is reduced to a minimum, errors on the receiving side do not propagate over several lines and pages and the transmission quality is improved.

The invention achieves this through the features specified in claim 1.

Advantageous further developments of the invention are specified in subclaims 2 to 6.

The invention is illustrated below with reference to FIGS. 1 to 4 explained in more detail; it shows

F i g. 1 a table for an improved Huffman code for black and white run lengths,

F i g. 2 an example of an encoder,

F i g. 3 shows, as an example, part of a code tree for decoding the black run lengths 1 to 10 of FIG Fig.l,

F i g. 4 shows an example of a decoder.

In Fig. 1 is an example of one in the form of a table Encoding schemes according to the invention given for white and black run lengths. One to be transferred Template has been examined for its statistical distribution and depending on the black and white run lengths the frequency of occurrence of the individual run lengths are, as with Morse code, the frequently occurring

• short code words have been assigned to lengths. ^len Y _n black run lengths in the example the -11 was the termination at> 10 and at the white

^{Let fläneen} bei> 30 made.

P ", · ₂ larger run lengths are used for white value combinations

, can of the prefix and Π Π; iner thereto h ießenden binary constant Langen which the ^"1 Wp auflänge indicating formed, for Schwarzwer- ^E by a prefix word 11111111 and a binary number also ^te flowing.
^on , contrary to the known codes have been used for

ι he black and white run lengths different r itewords chosen and the interruption point corresponds

determined differently according to the probability

^leg 'j _{recognize the beginning of the line from} the transmitted bit flow, a line beginning word is sent. this

Tt resemblance to the so-called "margin", i.e.

oJndworl of known codes, but different Literally from this. The well-known edge word will though

Ü, rh is sent anew for each line, but - like the

ι fläneen - assigned a code word whose

ι nU between the other code words according to ZIr occurring probability. this

T has the disadvantage for a disrupted data transmission,

SÜr the code combination in the event that the bit synchro-

n? «tion is disturbed, can occur in the data flow, and was from parts of various other code words or

Directly composed of other code words. This is explained in the following using an example.

The marginal word is

The word for the run length 8

The word for the run length 4

If the run lengths 8 and 4 are transmitted one after the other, the following bit combination can occur:

30th

IUO 11 111 HO

11!

If word synchronization works, the words are recognized separately, but this is indicated by a Error by one place to the left out of clock, the bordered combination is recognized as a border word and the 4s The following image transmission is irreparably disturbed, as the error continues over the rest of the transmission to the end propagates. Instead of this margin word, however, a line beginning word is now transmitted at the beginning of each line, which is chosen so that it exists in the possible combinations of the successive run-length codes or parts of these run-length codes do not occur. In the one shown in FIG. 1 code was the Word 0000000000000001 selected. As an example, a possible accumulation of zeros is examined, e.g. B.

black barrel lengths over 30: Π1.0 000000000 and black run length 5: 00001. If these two follow one another, the result is: Ul 0000000000.00001.

If the word synchronization is disturbed, this combination, as it only contains fourteen zeros, cannot can be recognized as the beginning of a line containing 15 zeros.

In addition, the beginning of the line can have another one, shown in FIG. 1 in brackets with "x" have the specified bit that starts the black or white line as "0" or "1" or vice versa signals. In the subsequent run-length transfer, the states "black" and "white" then change off each other.

But it should be despite this choice of the beginning of the line the addition of the run lengths carried out at the end of the line, which is used to check the line length if, caused by a fault, is wrong, this line can be omitted and through the previous one must be replaced, which is very easy with these codes, since they are cached is being worked on. Omitting the line is better than recording a broken line because the information will be hardly differ from line to line. The repetition is advantageously carried out from the beginning of the line the previous line. The same line can also be sent again.

If a completely white line occurs once, only the beginning of the line is sent, whereby a considerable redundancy reduction is achieved.

A further improvement can be made by transmitting an end word at the end of the transmission, that according to the same criteria as the line beginning word is selected, must deviate from this and also not occur through a combination of the line start word with other values in the bit flow

can.

This has the advantage that the transmission from both sides may be triggered by a response from the recipient can be terminated and no more line costs

attack.

In Fig. 2 is in principle an encoder for the ones shown in FIG.

given coding shown.

In the case of the aborted Huffman code, it is not possible to use a calculation algorithm from the run length derive the corresponding code word. The code word can only be found by searching in a Determine the code table in which all occurring code words must be stored.

The memory for the code table can advantageously be implemented with a memory of the ROM (Read Only 40 Memory) type. The run length contained in the REG register is entered as the address in the memory R0M \. The associated code word then appears at the output of the memory ROM ₁ , which is entered in the shift register SR? is enrolled. Since the code words have different lengths, the length of the code word also appears at the output of the memory ROM \ as a binary number that is written into the down counter Z. The code word can now be shifted out serially from the shift register SRi, e.g. B. on the transmission channel. At the same time, the down counter counts the bits output. If the counter has reached "zero", the code word is

over.

The run lengths not contained in the terminated Huffman code are represented by a prefix and a remainder with a constant code word length, which contains the binary number of the run length. If such a run length occurs, only the prefix that is written into da: shift register SRi appears at the output of the memory: ROMi as a code word. The run length is then written into the shift register SR \ and the sum of the length of the prefix and the length of the remainder is entered as the code word length in the counter Z. This means that the complete code, consisting of prefix and run length, can be extracted from the two shift registers connected in series.

be pushed.

F i g. 3 shows a code tree for the decoding df

Code words for the black run lengths 1 to 10. At each node, the direction in which the Decoding to go ahead is decided.

During decoding, the end of the code word and the associated code word should be taken from the serially incoming data Run length can be determined. The decoding is carried out in such a way that the code tree through which the every Huffman code is uniquely determined, iterating from node to node until one reaches the end of the Code word (see picture). At every node that you go through, the junction is indicated by the the respective bit of the code word (0 or L) determines the implementation of the Huffman code forms this code tree according to, whereby a number is assigned to each node. Is the knot known to which you are currently working is located and the next code word bit is also known, these two pieces of information carry unambiguously to the next knot.

FIG. 4 shows a decoder which works according to this principle. The decoding process can also be implemented with a memory of the ROM type, which is constructed similarly to a microprogram control. The number assigned to the node is located in a register REG 1. In addition, the next code word bit that appears at the data input »E« is written into the register. Both pieces of information, which must clearly lead to the next node, that is to say to the next number, are given as addresses on the memory ROM ₂ . This number appears at the output of the memory ROM2 , which is now again written into the register REG \ , together with the next code word bit, etc. In this way, you run through the code tree until you have reached the end of the code word. The end of the code word is displayed at the output CW of the memory ROM ₂ . At this moment, it is not the next node that is stored in the memory ROM ₂ , but the decoded run length which is written into the register REG ₂ . The register REGt is then returned to its initial state. If the prefix has been decoded as a code word, this is indicated at output P. In this case, the next data bits do not represent a Huffman code word, but the run length as a π bit binary number.

Therefore, the next π bits are serially entered into register REG ₂ . After each decoding, the register REG _{2 contains} the run length from which the corresponding number of white or black pixels is generated by counting down to zero.

For this purpose 4 sheets of drawings

Claims (6)

Patent claims: 1. Method for digital run length coding with redundancy reduction for the transmission ϊ ^; när s: odated image information, in which
Coming run lengths short code work md rare run lengths long code words are assigned and in the case of which from a given run length the run lengths are assigned a prefix word to differentiate between code words of the shorter run lengths and a code word following the prefix word, which assigns the respective run lengths as a binary number indicates, characterized in that the black and white run lengths, which are transmitted with a code word, are assigned different code words depending on their frequency, that for black and white run lengths the predetermined run length from which the coding is carried out with a prefix word is different , and that a single code word is transmitted at the beginning of the line, which differs from the code words for the individual run lengths, as well as from the word combinations resulting from the prefix word and the subsequent code words and in the transmitted data flow as a bit combination of several words or Te üwort does not occur. 2. The method according to claim 1, characterized in that the individual code word at the beginning of the line has an additional bit for the color of the first run length at the beginning of the line. 3. The method according to claim 1 or 2, characterized in that for the transmission of a Leerzei-Ie the individual code word transmitted at the beginning of the line is sent. 4. The method according to any one of claims 1 to 3, characterized in that at the end of one side or an image, an end word is transmitted, which is different from the code words for the individual Run lengths, as well as those resulting from the prefix word and the subsequent code words Word combinations and the code word transmitted at the beginning of the line and in the The transmitted data flow as a bit combination of several words or partial words does not occur. 5. The method according to claim 4, characterized in that the end word at the recipient a Triggers feedback to the transmitter. 6. The method according to any one of claims 1 to 5, characterized in that in one in one Line errors that have occurred this line is omitted and replaced by the previous line of their Line start word is replaced.