NO802740L - PROCEDURE AND DEVICE FOR CODED TRANSFER OF INFORMATION - Google Patents

Description

The present invention relates to a method

and a device for coded transmission of information as specified in the introductory part of claim 1 and claim 4 respectively.

With most known digitally working transmission methods, the pulse stream to be processed is structured, which means that packets are formed which are usually the same length, and thus comprise an equal number of pulses. The individual packets, which according to telegraphy terminology are called "signs" and according to computer terminology are called "words", can be separated from each other by means of timing signals which on the receiving side serve as reference signals for the synchronization control.

It is previously known that for coding the message to be transmitted, either the individual packets as a whole can be substituted, or rearranged (letter or block coding). or the individual character elements can be subjected to a coding (bit or character element coding).

The principle is frequently used in image transmission

for block rearrangement (block permutation) during the coding. In this connection, e.g. an image line divided into equally long blocks which rearrange themselves in between. Because an image information is structured more monotonously than e.g. a speech information and exhibits several similar paragraphs, e.g. very white (especially when transferring drawings or text), a permutation over several lines is usually necessary. In this connection, temporary limits are set at the transfer standards, because permutation is always associated with a delay.

Today's image transmission devices work as is well known

according to standardized methods. Within a certain time after the connection is established, the start of the transfer must take place. After a certain period of time that runs from then on, the recipient is no longer able to process further information. If a coding device is now connected in the transmission line, then the entire sequence should preferably not be changed. However, it means that a certain walking time delay cannot be exceeded. For this reason, it is therefore unrealistic e.g. to rearrange blocks from the last line of a picture telegram with blocks from the first line. You also get the same limitation^albeit in a different order of magnitude^in connection with speech coding, because be-

Agreed walking times cannot be exceeded here either, if intelligible speech is to be possible.

In the case of image transmission or -telegraphy, however-

time this limitation only follows that under the circumstances certain image structures can still be recognized, even after permutations. Thus, e.g. the digitized rendering of a document with a black, wide stripe due to the great redundancy which can be easily ascertained with the eye, permit inferences with respect to the original. Even if the exact picture structure appears blurred by the reproduction of the permuted information, there are still opportunities for cryptological break-ins by means of block-wise correlation.

If the information signals or information groups

are separated from each other by means of spaces without actual information content, then there is a danger that even after coding

however, these spaces give rise to inferences regarding the code regulations and the information that is transmitted. In order to avoid

to this end, it has already been proposed to fill in these spaces in whole or in part by means of filling signals which are again separated on the receiving side (FR-PS 2 233 768, DE-PS 855 876). In another solution, in these spaces there is a scfcedimentveriering of the characters according to a specific code regulation.

However, these known methods and devices are not suitable for preventing break-ins in the coding system in cases where not the spaces between the information signal blocks, but the information signal blocks themselves can give rise to such break-ins.

One is thus faced with the task of obtaining a method, resp. a device, of the nature indicated at the outset, which on the one hand determines the legality of the coding and on the other hand makes a conclusion with regard to the content of the information transmitted due to certain information signal blocks impossible or at least very difficult.

According to the invention, this task is solved by the features

which is stated in the characterizing part of claim 1 and claim 4, respectively.

The exchange made on the transmitter side of certain information signal blocks, e.g. blocks that consist entirely of make signals, with substitution signal blocks that are formed from signals of different types, now have the effect that only signal blocks with an inhomogeneous structure appear on the transmission path. An inference with regard to the content of the information that is transmitted, resp. an interpretation of the coding regulations is at least made very difficult, but not completely impossible. On the transmitter side, the original information content of the information being transmitted is re-acquired by replacing the substitution signal blocks with information signal blocks.

On the receiving side, one can substitute not only information signal blocks which are structurally of the same type, but also information signal blocks which in their structure belong to two or more different types.

In the following, an exemplary embodiment of the object of the invention will be described in more detail with reference to the drawing. Fig. 1 is a schematic block diagram of a device for transmitting coded information. Fig. 2 comprises various pulse/time diagrams which serve to explain the code and substitution processes.

With reference to fig. 1, the construction of the facility will be described in the following. In this connection, the explanation of the structure and operation of known components will be omitted.

In fig. 1 shows a transmitting station 20 which is connected to a receiving station 21 via a transmission line 22.

The information transfer from the sending station 20 to the receiving station 21 can take place in a manner known per se, either via a line or wirelessly. The transmitting station 20 has an input stage 23 whose input is connected to an input line 24 for the information to be processed and transmitted. The input stage 23 is connected to a bearing 25 which consists of two bearing halves B1, B2 (fig. 2). Via an address line 26, the storage 25 at the entrance is connected to a key or code generator

27. The structure and operation of this code generator 27, which provides the code information for the coding, is known. On the output side, the bearing 25 is connected via a switch 28 to an output stage 29, to which the transmission line 22 is connected. A substitution signal generator (auxiliary code generator) 30 is connected to the other pole of the switch 28, which produces substitution signals as will be explained below. The substitution signal generator 30 is also of known construction. A detector 31 is further connected to the output of the input stage 23, which in turn is connected to a stock control link 32. A further input to the stock control link 32 is connected via an address line 26a to the output of the code generator 27. The stock control link 32 controls the switch 28 via a control line 33 For certain uses which will be explained in the following, the stock control link 32 is also connected via a further control line 34 to the substitution signal generator 30 in order to control it.

The receiving station 21 is provided with an input stage 35 which is connected on one side to the transmission line 22 and on the other side is connected to a bearing 36 with two bearing halves. The storage 36 corresponds in structure to the storage 25 in the sending station 20. The storage 36 is also via an address line 37 connected to a code generator 38 of known structure/which provides the necessary decoding information for the decoding. As is already known, the code generator 38 runs synchronously with the code generator 27 on the sending side. The output from the storage 36 is connected to one pole of a switch 39 which in turn is connected to an output stage 40. The output stage 40 is connected via a connection line 41 to data processing equipment. Two information signal generators 42, 43 of known structure are connected to further poles of the switch 39, which produce information signals in a manner that will be explained below. The output from the input stage 35 is also connected via a line 45 to the input of a correlator 44, whose other input via a connection line 46 is connected to a comparison signal generator (auxiliary code generator) 47. This comparison signal generator 47 is constructed in the same way as the substitution signal generator 30 on transmitter side, and runs synchronously with this. The comparison signal generator 47 thus generates the same sequence of signals as the substitution signal generator 30. A stock control link 48 is connected to the correlator 44, which is also connected on the input side to the output of the code generator 38 via an address line 37a. Via a control line 39, the bearing control coupling 4 8 controls the switch 39 in a way that will be explained later.

With reference to fig. 2, the operation of the device described above will now be explained in the following.

In fig. 2A shows a pulse current which is supplied from an information source not shown to the transmitting station 20 via the supply line 24. The pulse current is formed by means of equal length information signal blocks 1-12, which are separated from each other by means of separators not shown. Each information signal block 1-12 consists of five signals which are either "0" signals (light squares) or "L" signals (dark squares). The information signal blocks 1-12 that arrive in chronological order are transferred to the storage 25 via the input stage 23. As already mentioned, and as shown schematically in fig. 2, the bearing 25 consists of two bearing halves B1 and B2. The arriving signal blocks 1-12 are first stored in sequence in the first storage half Bl. It is assumed that each bearing half B1, B2 allows a storage of

ten information signal blocks. Thus, the first ten arriving information signal blocks 1 - 10 are stored in the storage half Bl. If the storage half Bl is full, then the storage of the information signal blocks 11 - 20 takes place in the other storage half B2. At the start of the insertion of the information signal block 11 in the storage half B2, the reading of the individual information signal blocks from the first storage half B1 now begins as indicated by C in fig. 2.

For the purpose of coding, however, the reading from the storage 25 does not take place in order, but according to a regulation which is determined with the help of the code information obtained from the code generator 27. In fig. 2D shows a possible sequence of information signal blocks as these may appear at the output from the storage 25. From fig. 2D, it is also readily apparent that the ten information signal blocks 1-10 appear in a permuted order in relation to the original order according to fig. 2A.

If the second storage half B2 is filled, then the first storage half B1 is emptied and ready to receive new information signal blocks. Below, a reading of the individual information signal blocks from the storage half B2 takes place in a similar manner in a changed order given by the code information. The permuted sequence of information signal blocks obtained in the above-mentioned manner in the sending station 20 is transferred to the receiving station 21. The input stage 35 on the receiving side now ensures a block-by-block storage of the received information signal groups in the storage 36. As the storage 25 on the sending side, this shows two storage halves which in the same way as described in connection with the storage on the sending side, is alternately filled and read. However, the storage of the received information signal blocks does not take place in the chronologically received order, but in the chronological order that was originally used at the input stage 23 in the transmitting station 20, as shown in fig. 2A. The storage in the original order is provided by the code generator 38 which, as already mentioned, runs synchronously with the code generator 27 on the sending side. This means that in the first storage half of the storage 36, the information signal blocks 1-10 are stored in the manner shown at D1 in fig. 2. Due to this storage of the information signal blocks in the original order, under the influence of the code generator 38, a decoding is achieved. Via the output stage 40, the information signal blocks are supplied to an information processing unit via the connection line 41.

In order to now avoid or at least to greatly complicate cryptological intrusions into the system, on the sending side information signal blocks exhibiting a given information content are/replaced by means of substitution signal blocks. In the embodiment example shown, it is now assumed that all information signal blocks that consist entirely of make signals, e.g. "0" signals are substituted. This means that in the block sequence shown in fig. 2A, the information signal blocks 4, 6 and 10 must be replaced.

For recognition of the information signal blocks to be exchanged, the detector 31 serves on the transmitting side. This recognizes each of the information signal blocks 4, 6, 10 which consist of make signals. The detector 31 transmits the information about which blocks are to be substituted to the storage control link 32, which via the address line 26a also receives the information about where in the storage 25 these blocks are stored. From this storage control link 32, the status of each information signal block stored in the storage 25 can now be queried ("to be replaced", or "not to be replaced").

When emptying the individual storage halves Bl, B2, the code generator 27 will now, as has already been discussed, interrogate the signal blocks from the various storage locations according to the code information that the generator has provided. They interrogated informa-. sion signal blocks are supplied to the output stage 29 via the switch 28 which would normally be connected to the output from the storage 25. However, if a storage space containing a block to be replaced is now queried (i.e. storage spaces 4, 6 and 10 in the storage half Bl), then the storage control link provides 32 which is indeed controlled from the code generator 27 via the address line 26a, a control signal which via the control line 33 causes a switching of the switch 28 to the output of the substitution signal generator 30. During the time course for the information signal block to be replaced, the output of the substitution signal generator 30 is now connected to the output stage 29 , so that instead of the block 10, 6, 4, which consists of make signals, a substitution signal block 10', 6V, 4' is transmitted to the receiver side 21. The substitution signal generator 30 has a higher rate than the code generator 27, since the latter only has to deliver one new piece of information for each information signal block, while the substitution signal generator 30 within a block has to deliver a quasi-random signal which possibly corresponds to the pulse rate. In fig. 2E shows a possible pulse sequence which is produced by means of the substitution signal generator 30. This quasi-random pulse sequence consists of substitution signal blocks which are formed by five "0" or "L" signals. As already mentioned, the information signal blocks 10, 6 and 4 are replaced by substitution signal blocks 10', 6<1> and 4'. In fig. 2F shows the sequence of signal blocks that are transmitted to the receiving station 21 via the transmission line 22. The transmitted train of signal blocks thus no longer contains blocks that exclusively

are formed by similar signals.

As mentioned, the signal blocks that arrive at the receiver station 21 are stored in the storage 36 under the influence of the decoding information provided by the code generator 38. At the same time, the signal blocks are supplied to the correlator 44 via the line 45. Via the connection line 46, the correlator 44 also receives comparison signals that are provided from the comparison signal generator 47. Because the comparison signal generator 47 is constructed in the same way as the substitution signal generator 30 on the sending side and runs synchronously with this, the comparison signal generator 47 produces the same pulse train as the substitution signal generator 30, i.e. also e.g. the signal train which is likewise shown in fig. 2E.

The correlator 44 now compares the signal blocks supplied via the line 45 with the comparison signal blocks obtained from the comparison signal generator 47. By means of this comparison, the substitution signal blocks added on the sending side are recognized as such by the correlator 44. The signal trains shown are compared on fig. 2E and 2F with each other, then one can easily see that in the time periods to which blocks 10, 6 and 4 are assigned, the signal train on the transmission section 22 (Fig. 2F) is identical to the signal train in the comparison signal (Fig. 2E ). It is also to be understood that non-substituted information signal blocks are only slightly correlated in relation to the comparison signal train (Fig. 2É), since their structure was not provided by means of the substitution signal generator 30. Possible correspondences between the non-substituted signal blocks and the comparison signal blocks, can however, lead to some wrong decisions. Biased investigations in connection with a picture telegraphy system have, however, given a probability of such wrong decisions in the order of 10 -4. In start-stop teletypewriter systems without special protective measures, such a probability of wrong decision will usually be accepted and is therefore classified as "good".

The correlator 44 now delivers information regarding status

("substitution signal block", or "information signal block")

for the signal block which has just been added to the storage 36, to storage

the control link 48. The storage control link is controlled in the same way as the storage 36 via the address line 37a from the code generator 38. When the signal blocks stored in the storage 36 are read out, the information signal blocks recognized as such are transferred to the output stage 40 via the switch 39 which is normally connected to the output from the storage 36. However, if a substitution signal block recognized as such is ready for reading, then the stock control link 48 via the control line 4 9 causes a switching of the switch 3 9 to close contact with the information signal generator 42. The information signal generator 42 is thus connected to the output stage during the duration of the substitution signal block to be replaced 40. The information signal generator 42 provides information signal groups corresponding to the information signal groups 4, 6 and 10 which were substituted on the sending side, i.e. those which in the present embodiment were formed by means of "0" signals. At the output of the output stage 40, a train of information signal blocks 1-12 thus appears, which in structure and in chronological order correspond to the information signal blocks that arrive on the transmitter side (fig. 2A).

Then there in the data stream which is transmitted according to fig. 2F, no signal blocks with homogeneous internal structure can be traced, attempts to draw conclusions from the original clear information using block-wise organized correlation tests are made difficult, provided that there is a certain relationship in the statistics for the substituted and non-substituted transmitted signal blocks. The described solution thus provides an increase in security against unauthorized decoding.

Until now, it is believed that only information signal blocks

4, 6, 10 consisting of the same type of signals, i.e. only "0" signals, are exchanged. However, it is possible to design the detector 31 so that it can recognize both information signal blocks which only consist of "0" signals, and signal blocks which only consist of "L" signals. In this case, the detector 31 transmits to the stock control link 32, in addition to the information "block to be substituted", also the information regarding the type of signals that form this block. Depending on the type of signal, will

then the stock control link 32 via the control line 34 affects the substitution signal generator 30, so that the latter for the corresponding block length produces a "normal" signal train according to fig. 2E or a signal train with reverse polarity compared to the "normal" signal train. This is shown in Figures 2G and 2H.

In fig. 2G two information signal blocks are shown to be substituted, one consisting of only "0" signals (a),

and the other by only "L" signals (b). In fig. 2H shows the two substitution signal blocks which are produced by means of the substitution signal generator 30. A comparison between fig.

2H and fig. 2E shows that the first substitution signal block in FIG. H is the mate of the first signal block in fig. 2E, while the second signal block in fig. 2H, which has replaced the information block consisting exclusively of "L" signals, has the opposite polarity in relation to the second substitution signal block in fig. 2E. The correlator 44 in the receiver station 21 will now be able to determine the polarity of a substitution signal block recognized as such. The internal structure of this signal block is, with the exception of the polarity, the same as the signal train that was produced by the comparison signal generator 47. The correlator 44 will therefore via the stock control link 48 ensure that during the course of time for the substitution signal block which is to be replaced at any time according to the determined polarity, the switch 39 connected either to the output of the first information signal generator 42 or to the output of the second information signal generator 43. As already mentioned, the information signal generator 42 provides information signal blocks consisting exclusively of "0" signals, while the information signal generator 43 provides signal groups formed only of "L" -signals.

It is also possible to design the detector 31 so that it not only reacts to information signal blocks that consist exclusively of "0" or "L" signals, but also to information signal blocks that, for example, over their full extent contain the sequence 0L0L0L... or L0L0L0 In this case, the substitution signal generator is influenced via the stock control link 32 so that it produces another pulse train which differs greatly from the structure of the first pulse train. However, it is also possible to provide this second pulse train to arrange a further substitution signal generator which runs parallel to the first substitution signal generator 30. The bearing control coupling 32 as well as the switch 28 must then be constructed in a corresponding manner.

On the receiver side 21, the correlator 44 must of course be constructed in such a way that it reacts to the different types of substitution signal blocks. The correlator 44 constructed in this way will act on the switch 39 via the bearing control link 48,

so that this is connected to the output of a further information signal generator which is not shown in fig. 1, and which, during the course of the signal blocks to be replaced, generates signal blocks of the type replaced on the transmitter side 20, i.e. e.g. the signal train 0L0L0L... resp. L0L0L0...

Thus, within the framework of the above-mentioned embodiments, information signal blocks of the following type can be substituted: 000.00... for substitution signal blocks of the first type LLLLL... for substitution signal blocks of the first type with opposite polarity

0L0L0... in the case of substitution signal blocks of a different kind L0L0L... in the case of substitution signal blocks of a different kind with the opposite polarity

00LL0... for substitution signal blocks of the third kind

LL00L... at substitution signal blocks of the third kind with opposite polarity

etc.

In the latter cases, additional comparison signal generators are preferably arranged on the receiver side 21 in addition to the comparison signal generator 47, with all types of substitution signals being continuously supplied to the correlator 44, so that the necessary decoding (repermutation)

is possible without loss of time.

It is of course also conceivable to substitute other information signal blocks which, by their structure, are significant and thus cryptologically dangerous, e.g. by letterpress transfer of such blocks as e.g. shows a structure 0000L000L000L... where one can draw conclusions with regard to the period of writing-drawing a line. Depending on the substitution purpose, other configurations of signal blocks and other substitution methods than those proposed can also be used. Above, the idea behind the invention is explained in the light of binary pulse trains. However, it is possible to apply the method to systems with multi-valued digital or continuous analogue signal forms as well as organized information processing and transmission systems which are more complex than those mentioned.

It should be understood that some of the building elements shown in fig.l can be combined into building units, e.g. the code generators 27, 38 with the substitution signal generator 30 and the comparison generator 47, respectively.

Claims (10)

Procedure for the coded transmission of information which is formed by equally long, chronologically consecutive information signal blocks, where the individual information signal blocks on the transmitter side are rearranged in relation to their original time order by a code information in the time axis, and the original time order of the received information signal blocks is restored on the receiver side by means of a decoding information, characterized in that on the transmitter side (20) the information signal blocks (10, 6, 4) for a given information content are exchanged with differently structured substitution signal blocks (10', 6', 4') and on the receiver side (21) instead of the substitution signal blocks (10', 6', 4'), information signal blocks are again inserted which, with regard to information content, correspond to the information signal blocks (10, 6, 4) that were replaced on the transmitter side. 2. Method as stated in claim 1, characterized in that the substitution signal blocks (10', 6', 4') are obtained in at least one substitution signal generator (30) whose output signals (10', 6', 4') when determining information signal blocks (10, 6, 4) for the given information content is transferred to the receiving side (21). 3. Method as stated in claim 1 or 2, characterized in that on the receiver side (21) the received signal blocks (7, 1, 3, 10*...) are compared with comparison signal blocks and the received signal blocks that agree with the comparison signal blocks, is replaced by information signal blocks which, with regard to information content, correspond to the information signal blocks (10, 6, 4) which were replaced on the transmitter side. 4. Device for the coded transmission of information which is formed by equally long, chronologically consecutive information signal blocks, with a coding device on the transmitter side which, by means of code information in the time axis, causes a rearrangement of the individual information signal blocks in relation to their original time sequence, and with a decoding device on the receiving side by means of which a reconstruction of the original time sequence of the received information signal blocks takes place with the help of a decoding information, characterized in that there is arranged on the receiving side (20) at least one substitution signal generator (30) which provides ;substitution signal blocks (10', 6', 4') and a detector (31) which examines the information signal blocks (1 - 12) with regard to their information content, and which by determining the information content given to the individual information signal blocks (10, 6, 4) causes an exploitation of these with respective substitution signal blocks (10 <1> , 6' . ...), and by means of which, upon recognition of the respective substitution signal blocks (10', 6', 4'), an exchange of these takes place with respective information signal blocks which have been obtained by means of an information signal generator (42, 43). 5. Device as stated in claim 4, characterized in that the recognition device (44,47) has at least one comparison generator (47) which runs synchronously with the substitution signal generator (30) on the transmitter side, and which provides comparison signal blocks corresponding to the substitution signal blocks (10', 6', 4') provided on the transmitter side, and which is connected to a correlator (44) which compares the comparison signal blocks with the received signal blocks (7, 1, 3, 10'...) and, in case of agreement, causes an exchange of established substitution signal blocks ( 10', 6', 4') with information signal blocks. 6. Device as stated in claim 4 or 5, characterized in that the coding device (25, 27) has a storage (25) for supplied information signal blocks (1 - 12), which is connected to a code generator (27) for producing the code information and can be queried about the stored information signal blocks (1 - .12) in the time order determined by the code information, and that a switch (28) controllable from the detector (31) is arranged which, depending on the information content of the information blocks (1 - 12), connects either the output from the warehouse (25) or the output from the substitution signal generator (30) with the output (29) from the transmitter station (20). 7. Device as stated in claim 6, characterized in that between the detector (31) and the switch (28) a storage control link (32) is arranged which controls the switch (28) and stores the information obtained from the detector (31) with regard to the information signal blocks (10, 6, 4) which are to be replaced, the connection (32) at the input being connected to the code generator (27) and upon polling an information signal block (10, 6, 4) which is stored in the storage (25) and to be replaced, switches the switch (28) from the output of the bearing (25) to the output of the substitution signal generator (30). 8. Device as stated in one of claims 4-7, characterized in that the coding device (36, 38) has a storage (36) for the received signal blocks (7, 1, 3, 10'...), which are connected with a code generator for the provision of decoding information, and in which due the decoding information the received signal blocks (7, 1, 3, 10'...) can be stored in their original time order, and that a switch (39) is arranged which can be controlled from the recognition device (44, 47), and which according to the determined type of the received signal blocks (7, 1, 3, 10') connect either the output from the storage (36) or the output from the information signal generator (42, 43) with the output (40) from the receiving station (21). 9. Device as stated in claim 8, characterized in that between the recognition device (44, 47) and the switch (39) there is arranged a storage control link (48) which controls the switch (39) and stores it information with regard to the type of received signal blocks ( 7, 1, 3, 10'...) which is obtained from the recognition device (44, 47), and which is also connected on the receiving side to the code generator (38) and when polling a signal block (10', 6', 4 <1 > ) which is stored in the storage (36) and is to be replaced, disconnects the switch (39) from the output of the information signal generator (42, 43). 10. Device as stated in one of claims 4-9, characterized in that several substitution signal generators (30) are arranged on the transmitter side (20) and/or several information signal generators (42, 43) are arranged on the receiver side (21).