SE418442B - Speech Encryption Procedure - Google Patents

Description

10 15 20 25 30 35 40 '78012 / 46-5 j 2 walk. When reading a new speech segment in a speech memory cell, at the same time the current content of this cell the modulator SM resp. the modulator RM (content change in a speech terminal fnescell) and is added to the encrypted signal VS resp. clear len K2. In this way, the ready signal K1 segments in the key mode are delayed. the dulator SM different integer multiples of the segment length T. If now one speech segments have been delayed the time p.'I 'in the key modulator SM, mourns the key sensor SG2 in order for this segment to undergo a further delay with time q.T in the remodulator (p and q are integers). Key- the signals S1 and S2 are then so correlated that the total delay which a segment undergoes in total in the modulator and remodulator latorn, just amounts to 2n ° T. In this case, n indicates the number of speech memory cells in the modulator resp. the remodulator; in the example shown is n = 8. For each number segment, the following applies: p + q = 2n, The clear signals K1 and K2 therefore differs only in that all segments in the signal K2 has undergone a delay of 2n-T compared to the segment ten in the signal K1. For the special case that a speech segment already in the modulator has_failed a delay of 2n ° T it is memory free the connection D to the receiving side is arranged.

By the Swiss patents 237 094, 232 786 and S18 658, speech encryption devices are known which operate according to the time-reversing procedure. Differences include in mode of action and in the structure of the key sensors SG1 and SG2. In the first two The said publications use key handlers, which by means of key signatures channel S1 designates the speech memory cells of the modulator SM in accordance with a fixed program in an ever-repeating sequence. An unauthorized outsider, who are aware of the operation of the device and who have access to it the encrypted signal, thereby possess good hold points for one decryption. 'I f An improvement is displayed terna. For generating the key signal S1, it is used in the key item $ G1 and pseudo-random number generator. The order in which in the third of the above-mentioned patent the speech memory cells are successively designated for a content change, becomes thereby essentially a random sequence, comparable to the sequence of 'dice results in dice games. Here, however, it can be encrypted the signal still contain plaintext-like places, for it is not excluded that the key sensor SG1 at a later time designates the same or a similar sequence of speech memory cells as in a previous one time. If an unauthorized third party has recognized such places, this facilitates the remaining decoding work related to 10 15 20 25 30 35 40 78012h6-5 worth for the person in question, since the number of returns of segments will be lower.

Through the published German patent application 2 H55 # 77 a key sensor is known which contains a code corrector, which test takes whether the contents of the speech memory cell of the key modulator SM, designated by the pseudo-random number generator for the next content hold change, together with the previously transmitted speech segments would result in plain text-like sequences. If the result of the testing is positive, the transmission of the the relevant speech segment and after a specific program, a nan cell. Then the testing is repeated with this cell. First when plain text-like sequences are excluded, a speech memory cell is released in the single-speed change modulator. This procedure is also fraught with imperfections. The has been shown to have certain delays in the speech segments - in particular the delay T and 2n-T - preferably occurs, such as in a dice, in which certain numbers occur particularly often.

In this way, an unauthorized reversal of speech segments is now made possible. in the encrypted signal with reasonable effort, if this throwing takes place through a systematic search for related speeches segment. "A".

The object of the invention is to provide a method for speech creep according to the time-reversing procedure by means of a pseudo- random number generator, which method significantly complicates a system tical reversal of speech segments in the encrypted signal.

The above object is achieved by the method according to the invention obtained the characteristics specified in claim 1. According to the invention is transmitted instead of the forbidden speech segment it segments, which have been delayed the longest in the transmitter's speech memory and not there is a plain text-like consequence with the segments already transferred.

With the help of the figures in the accompanying drawings comes the procedure according to the invention as well as the required aids to further described. upp _ _ ..r, f - ~ - As already mentioned, Fig. 1 shows a known speech encryption device transmitter and receiver side and Fig. 2 the principle diagram of a end modulator or re-modulator. Pig. 3a-Sd illustrate the invention and shows in different states a marker register that is included in the encoder of each encoder. Pig. H and E show with the marker register cooperating circuits required for implementation those of the method according to the invention. 780124695 The upper part of Fig. 3a schematically shows an example of a marker register M, which is included in each of the two key sensors SG1 and SG2. It is designed as a shift register and consists, for example 7 of sixteen in the following positions called cells P1 to P16. Over In each position, the associated address is indicated in Fig. 3a. For- ! in addition to the marker register, each key sensor also contains a " 'seudo-random number generator as an essential component. The processes, P as in the following description relates to the marker registers and The 3pseudo random number generators are the same on the transmitter and receiver side 10 s . and drains synchronously. The synchronization can, for example, be performed according to in the published German patent application 2 H55 H77 in the procedure. 7 "" After initial release of the devices, they are read in a numeric part a and an identification bit part b divided the addresses of the -15; for example, the 8 speech memory cells on the receiving side and 8 speech memory cells on the transmitter side, ie the speech memory addresses, in an agreed order into the marker registers. Addresses with identification-a bit O belongs to speech memory cells on the transmitter side and addresses with the identification bit 1 belongs to the speech memory cells on the receiving side. In the contents of a speech memory cell in the modulators, the nom a - here frame rate called - rate signal. The frame rates have a time distance of a segment length I. Between two frame rates more the key donors in one of several procedure steps cycle de _memory addresses, whose associated speech memory cell on the transmitter resp. § 25 the recipient side as the following comes into question for a content growth Eling. The determination of these speech memory addresses will first be šwritten without specifying the details of the marker changes in the state of the register. By permission is meant in this context šhang the order of the addresses stored in the marker registers. 30 S * Pig. 3a shows an initial state in a marker register a; M; this is the state in which the marker registers are located immediately before the occurrence of a frame rate. The initial condition is marked ßof obtaining a plain text sequence, if you merge the speech memory the contents of the cells in the same order in which they belong [The addresses read from position 16 to position 1 are in the marker Iregistren. A The lower part of Fig. 3a shows the contents of the respective : cell, _the address of which is in the above position. Clear- the text consists for the sake of simplicity of the alphabet, whereby a speech no. 'ment exactly includes a letter. 10 D15 20 25 30 35 HO 5 _ 7801246-5 . All speech memory cells in the speech memory of the transmitter and receiver the page is filled with one of the letters a to p. .stave is now added a to the ready signal K2. This letter constitutes the contents of the speech memory cell whose address is in position 16. for transmitting the key sensor SG2 on the behavior of the frame rate on the receiver side the address (%) of the remodulator, whereupon this makes the associated speech memory cell for a content change. Samti- selected after a later explained and by pseudo-random number operator-dependent selection procedure a speech memory address of the transmitter dan, e.g. the address (å) in position 8 and is transmitted from the sensor SG1 to the key modulator. This also releases the associated the speech memory cell for a content switch. Then the speaker receives memory cell with the address (g In a new number segment in the clear signal K1, namely the letter q, while its present content, i.e. the letter i, as a component of the encrypted signal sent to the recipient and stored in the voice memory cell with the address (%). The new conditions are shown in Fig. 3b.

For a further change of content in the speech memory cells : should be able to take place in the same way at the next frame rate, an additional change of position in the marking register M: The contents of positions 8 and 16 are shifted and then the entire contents of the marker register are shifted cyclically a position. Results are shown in Fig. 3c. It appears then that the new state is again an initial state in it the meaning defined above.

In order to avoid plain-text-like consequences in the crypto- the signal shall not be transmitted at the next frame rate, "which belongs to the letter in neighborhood, namely the letters h, j joch k. Therefore, positions 7, 8, 9 and 10 are marked as prohibited positions. As a result, the speech memory cells on the transmitter 'page, whose addresses are in these positions, at the next the frame rate is excluded from a content change. In Figs. 3c and 3d the forbidden positions are x-marked. Since the vulnerable the bids also remain active at the next next frame rate, one has provided that in the encrypted signal after the letter in at least a letter follows, which does not belong to the letter in the neighborhood, before or k is sent.

The initial state depicted in Fig. 3c represents a common case: A number segment - here the letter b - has already in the modulator SM has undergone the maximum permissible delay.

This case is recognized by a speech memory address for the transmitter side h is sent and at least two letters, before j V5 10 15 2.0 '25 30 35 RO 7801246-s - in Fig. 3c the address (å) - has reached position 16g in the marker gistret. The speech memory cell belonging to the address (%) is read out In now unconditionally, because otherwise a correct insertion of the letter b in the ready signal K2 is no longer possible; For the same reason happens on in the recipient side nor any extra delay. The remodulator selects - controlled by the identification bit 0 - the memory-free throughput D and adds the transmitted letter b directly to the The signal K2. With the reading of the letter b on the transmitter side inlä-lmv a new segment is read at the same time, namely the letter r. To the next An initial state must be obtained needs the marker register content now only shifts cyclically one position; The result is displayed ' A fig. sa. a _ a '_ ll When it is the case that in position 16 a speech memory address lfor the receiver side is present (cf. eg fig. 3a), it is determined in which position the_talk memory address of the transmitter side exists, which has generated by the pseudo-random number generator. About the specific position šicke-is forbidden, all the following steps take place on the one already described jsättet. If, on the other hand, the determined position is marked as gden, the speech memory address of the transmitter side, which is stored in is not a forbidden position and whose associated speech memory cell contains contains the longest delayed speech segment. This speech memory address can be found by going through the marker registers at the beginning f state from position 15 to position 1 and asks for it first non-prohibited position, which contains a speech memory address _for the transmitter side. According to Fig. 3a it would be, for example, position 15 with, the address (% 1). Once the requested position has been determined, the again all the following steps in the manner already described.

The described operation for selecting a voice memory address for sending on the other hand, the fact that the pseudo-random number generator the entered address is stored in a forbidden position, resulting in an fair equal distribution of the relative incidence rates for all any delays in speech segments in the key modulator. Comparable the division results in a considerable complication of the decryption for an unauthorized outsider, who now no longer - as in the case of procedures - can rely on dominant prevalence rates for the shortest and longest delays. j Pig. 4 and 5 illustrate technical details and additional components required for the implementation of the above-described faringsstegen. The realization of it lying between two frames the process cycle takes place in .32 working beats with a beat frequency of tÄex.

VT! 10 15 20 25 30 35 v 78012116-5 750 Hz. The 32 work strokes are divided into two main sections, of which the first comprises 17 and the second 15 working beats.

In the first main section are linked after the appearance of a frame rate all 16 positions in the marker register (cf. fig. 4) annular..With each work rate, the contents of the marker register are shifted hold a position cyclically. Consequently, at the end of it is brought. take the main section the speech memory address, which originally existed in oposition Sat, in position 1. The content of position 1 is written in one auxiliary memory Y and in a read-out memory X (not shownï.

In the case of annular circulation of the contents of the marker register, it takes place at the same time the search for a speech memory address for the transmitter side, the hearing cell is suitable for the next content change. Pig. H they show components involved in the search, namely a pseudo-random number êgenerator PZG, a comparator VGL, a NOR gate G1, a OR gate ÉG2, an AND gate G3, an S-bit counter Z, a flip-flop FF1 and a 1H- : and a 16-bit shift register SR1H resp. SR16. The two shift registers 'ren serves to set up and test bans. If a cell in the two shift registers contain a "1", so it applies above that standing position in the marker register as a forbidden position (cf. Fig. H). Additional details regarding the lineup IN šav ban follows below. "_ 'During the first main section, the output c remains on the shift Register SR14 connected to the input on register SR16. The exits Éc and d on the shift register SR1H resp. SR16 as well as identification The bit output b on the marker register M is connected to the NOR branch ídens G1 three inputs. The number output a on the marker register M is ßconnected with the comparator VGL. When performing a frame rate, the flip-flop PF1 descends in the zeroed state and the counter Z should jar with the calculation of the work rates. It receives an extinguishing pulse and flip-flop FF1 simultaneously a solidification pulse, if the following two the cows together are fulfilled: 1. At each of the three inputs b, c and d appear a binary "D". According to the above, this means that position 16 contains a speech memory address for the transmitter side, which at the beginning The condition was stored in a non-prohibited position. The flip-flop FF1 is in the reset state or comparator VGL determines the conformity between the the numerical output of the driver register a and the from the pseudo-random number generator PZG output figure. p? so12Aß-s L "\ 10 15 20 25 iso ' 35- H0 8 'i Within the first main section comprising 17 bars is deleted ¿At least one, but not more than two extinguishing pulses to the counter Z and the same number one-position pulses to Vippan FF1. i D As follows from the conditions for the triggering of an extinguishing pulse, occurs at the last extinguishing pulse in position 16 either the non- offered speech memory address for the transmitter side, which was generated using the pseudo-random number generator, or the address, associated with ars cell the longest delayed and also not forbidden speech segment is located. This address is later taken over by the read-out memory X '(not shown).

Pig. 5 shows the components required for the second ¿15-stroke main section of a bicycle. Between the components shown * and those required only for the first main episode, ¿There is no longer any connection. In addition, markerre-_f position 1 of the register M via the switch S separated from the remaining ones the positions, which in turn are linked to a ring formation. , migt shift register. “The following processes depend on whether now in : position 1, ie at the beginning of the first main section in position Ä16, it says a speech memory address for the transmitter side or not. Thanks. .submit the connection of the identification bit output from position 1 via inverter I to the counter Z, it immediately receives an external more extinguishing pulse§ if in position 1 there is an address for the transmitter ídan. In this case, the counter Z can no longer operate for the next 15 beats reach the count 16. This causes the switch S to remain in the highlighted position until the end of the second main section, why the contents of positions 2-16 are only shifted around to 'until the original starting position has been restored. Thus have one - taking into account the processes in the first main section 4 at the end of the second main section has reached a cyclic sliding the entire contents of the marker register by one position. At at this time, the contents of position 1fav readout memory are taken over s in » l 2 in 1 net X (not shown). in 7 In the case that in position 1 there is a speech memory address for the receiving side immediately disconnects the connection of position 1 with the Z. The mower then advances again and reaches the position a 15, when the speech memory address of the transmitter side, as in the first The 17-stroke main episode triggered the last extinguishing pulse, again standing in position 16. Depending on the position 16 of the counter Z is triggered the following process: The flip-flop FF2 emits four binary ones to the shift register register SR14 and switch S are adjusted for a working rate. The one- g1 10 15 25 30 35 H0 the rapid changeover of the switch S means that the contents of the position tion 16, namely the address of the one intended for a content exchange the voice memory cell on the transmitter side, is transferred to position 1, while the content in position 1, namely the address of that of a content switching speech memory cell on the receiving side, is transferred to the At the end of the second main section, therefore, the position contents 2-16 contain the same position as in the initial state with , the difference that the position, which at the initial state was occupied by the address of the number of speeches intended for a content exchange nescellen on the transmitter side, now contains the corresponding address for , the recipient side. If one again considers it from the first main section, ftet due to the cyclic shift of the marker register total Content, at the end of the second main section the new content is the state of favor. In this case, too, the content of the position is taken over. tion 1 of the read-out memory X. 1 _ The four binary ones, which the flip-flop FF2 at the occurrence of The position 16 exits to the shift register SR14, is shifted all the way to the fifteenth bar to the right parallel to the contents of the marker register hold in such a way that a binary one unlocks the address of it memory cell (eg the address (%) in Fig. 3b), as on the receiving side is intended for the next content exchange, a binary one stands in the middle said address and two additional binary ones trailing said address. Each address, as in the first main section of the next kel appears at the output of the marker register at the same time as a one on the registers' SR14 and SR16 outputs, applies as a prohibited address.

The ones act as prohibitions in that they prevent the release of ien quench pulse to the counter Z. Because in the first main section the shift registers SR1H and SR16 are connected one after the other, an set binary one operates in two consecutive cycles; 'the first time on output c and the second time on output d. The ones leaving the shift register SR16 are lost. On this In this way, the cancellations of the imposed bans are extinguished.

In the above description, the identically descending the races on the transmitter and on the receiver side have been clarified. Of these clarifications It appears that at the end of the second main section memory X contains the address of it for a content change intended speech memory cell on the transmitter side, while the auxiliary memory Y at this time either contains a corresponding speech memory address 'for the receiver side or the address of the cell on the transmitter side, whose content has undergone the maximum allowable delay in the modulator. ~ “Isoi2Ã6-sad 10 ? šö124aïš " If the device operating according to the described procedure is used ~ as a transmitter, the identification bit of the memory X first stored the speech memory address from "0" to "1", * nan the address is passed on to the modulator. For triggered by identification : bit "O" is selected in the modulators a memory-free throughput, Which d, however, may only become effective hes the recipient. On the receiving side Ä, the contents of the memory Y can be transferred either directly to the module d tower or after an intermediate storage i_ütläsníngsmínnet X.

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Claims (13)

11 7801246 s Patent claim A method of speech encryption by reversing speech segments of the same temporal length in a transmitter and retransmitting in a receiver, the retrieval taking place by reading the speech segments into a speech memory with n speech memory cells and different delayed readings, and the retransmission with a similar speech memory in such a way that a speech segment in this memory is further delayed until an equal total delay for all speech segments has been achieved, and wherein the reading of the segments from the speech memory in the transmitter is controlled by a pseudo-random number generator and in the receiver is dependent on a synchronous running pseudo-random number generator, and wherein in the transmitter the transmission of a speech segment specified by the pseudo-random number generator is prohibited, if this segment with the already transmitted segments results in a plain text-like sequence, characterized in that instead of the forbidden the speech segment is the segment that has been delayed the longest in the transmitter's speech memory and not b fires some plain text-like sequence with the segments already transmitted. _ Method according to claim 1 with a marker register similar in the transmitter and receiver, in whose 2n successively addressed memory cells, i.e. positions, the addresses separated by an identification bit, i.e. the speech memory addresses, to the n speech memory cells on the transmitter side and the, n speech memory cells on the receiver side is stored in a sequence determined at the beginning of the transmission, characterized by a cycle identical in the transmitter and receiver of the following steps: a) storing the speech memory address in position 2n in a read-out memory and an auxiliary memory; b) testing whether the stored address is a speech memory address of the transmitter side, i.e. identification bit 0, and if so continue with the procedure step h); c) determining the position k in which the speech memory address of the transmitter side stands, the associated speech memory cell of which the pseudo-random number generator is designated for the next content change; d) testing whether the determined position is marked as prohibited and, if so, determining the highest position, also denoted by k, which is not prohibited and contains a speech memory address for the transmitter side; e) storing the contents of the position k in the read-out memory determined according to step c) or d); 7801246-5 12 f) marking of positions k11, k and k ¥ 2 as prohibited; g) changing the contents of positions 2n and _k; h) cyclic displacement of the contents of the marker register by one position; f ii) switching off the positions in the penultimate cycle as prohibited marked positions; j) testing whether the utilized device is used as a receiver and, if so, transferring the contents of the auxiliary memory to the A read memory, and if not setting the identification bit of the address stored in the read memory to 1. Method according to claim 2, k 3 n n e t e c k n a t of said cycle being performed at Mn rates. i p H. A method according to claim 3, characterized in that the cycle comprising the Un bars is divided into two sections, the first of which comprises 2n + 1 and the second 2n-1 bars, and that different component groups are active under these two sections. 5¿ Procedure - according to claim 4, characterized by the cat marker register during the first 2n + 1 bars comprising the section annularly linked, whereby its contents are cyclically shifted by 2n + 1 bars. 6. A method according to claims 1-5, characterized in that two shift registers are arranged for marking and testing prohibitions, one of which comprises 2n-2 bits and the second 2n bits, and that the two the shift registers are connected in series during the first 2n + 1 bars comprising the section, whereby with each bar via a first flip a binary "0" is read in and the common contents of the shift registers are shifted by one position. 7 Method according to claim 6, characterized in that a counter is arranged, which at the beginning of the first 2n + 1 bars comprising the section stands at_0 and which with each beat progresses one step., I I 8. A method according to claim 7, characterized in that a logic circuit is arranged, which consists of a comparator, a second flip-flop and three gates and which emits to the counter a quenching pulse and to the second flip-flop a one-position pulse, if a ) at the output of the marker register a speech memory address for the transmitter side appears and g 'b) both outputs of the shift registers arranged for marking and testing of prohibition are set to "0", and 7 c) the said second flip-flop is in the reset 13 78012106- The state or comparator determines the identity between the address designated by the random number generator and the address appearing at the output of the marker register. Method according to claims 1-8, characterized in that throughout the second 2n-1 bars comprising the section the said logic circuit is separated from all other components and that the second 2n-bit shift register is separated from the first (2n-bit shift register). 2) -bit- -shift register and from the clock generator. Method according to claim 8, characterized in that at the beginning of the second 2n-1 bars comprising the section position 1 is separated from the remaining positions via a switch and that these remaining positions are linked to an annular register and remain connected to the clock generator. . 11. A method according to claim 10, characterized in that said counter at the beginning of the 2n-1 bar section receives a quench pulse from position 1, if this contains a speech memory address for the transmitter side. Method according to claim 11, characterized in that position_1 and the remaining positions are connected to each other via said switch at a rate, if the counter has reached position 2n, and that during this time all positions are annularly linked and that, likewise triggered by the position of the counter 2n, via the first flip-flop instead of zeros four ones are loaded into the (2n-2) -bit shift register. 13. A method according to claim 2, characterized in that the enumerated procedure steps are performed by means of a microcomputer. MENTIONED PUBLICATIONS: