FI72241C - Encoding and decoding device for protecting the communications secret - Google Patents

Description

ADVERTISEMENT η · Ί O *, 1 ^ 11 UTLÄGGNINGSSKRIFT! • g «j <«> V.: vr;.; Vo: ui.,, ...? (51) Kv.lk .- / lm.a.- H 01 (K 1/06 SUOMI FINLAND (21) Patent application - Patentansökning 780649 (22) Application date - Ansökningsdag 27.02.78 (H) (23) Starting date - Giltighetsdag 27- 02.78 (41) Has become public - Blivit offentlig 26.11.78

National Board of Patents and Registration Date of publication and publication. -

Patent- och registrstyrelsen '' Ansökan utlagd och utl.skriften pufclicerad 31.12.86 (86) Kv. application - Int. ansökan (32) (33) (31) Privilege claimed — Begärd priority 25.0 3.77

Switzerland51-Switzerland (CH) 6 ^ 55/77 (71) Mineralweeding and -Handel Aktiengese11schaft, Egertastrasse 15,

Vaduz, Liechtenstein (LI) (72) Emilio Martelli, London, Eng 1 anti-Eng 1 and (GB) (74) Leitzinger Oy (54) Encryption and decoding 1 device for the protection of communications secrecy -Kodnings- och dekodningsanordning för skyddande avommunikations- heml igheten

The present invention relates to an apparatus for encoding and decoding electrical signals included in a preset frequency band for the protection of a communication secret, which device can be connected between said electrical signal generating and receiving means and the means used for exchanging said coded signals with at least one other encoding and decoding device. the apparatus comprises a transmission and coding circuit and a reception and decoding circuit of said signals, a switching means which commentarily enables the operation of the transmission and coding circuit and the reception and decoding circuit, said circuits comprising first members having a plurality of memory elements for successively received temporary means for storing electrical signal components, second means for enabling said first means for sequentially storing said signal parts in memory and so on; to send in a different order to one of said switching means and to the signal receiving means.

Devices are known which encode a transmitted signal and decode a received signal, respectively, which signal is generally in the audio band, whereby such devices protect the communication secret by either affecting the frequency band, changing or inverting the transmitted signal band or affecting the time domain 2 n: 2 2 4 1 by sampling and temporarily storing portions of the transmitted signal in memory and later transmitting said portions along the communication line in a random pseudo-order. More specifically, in this type of device, the audio signal after sampling is substantially converted from analog to digital and sent to different logic memory registers. From these registers, the signal is then withdrawn and transmitted on the communication line via a control function from a code generator which selects the registers according to a variable sequence having a remarkably large sequence repetition period compared to the short period of time associated with radio or telephone communication.

Although these types of devices greatly improve the secrecy of the communication system to which they are connected, they now have disadvantages that limit their performance. For example, said code generator cannot monitor or control the register selection sequence, and therefore the same register can be selected many times in succession, whereby the audio signal parts in the register are consequently transmitted in their natural order and thus the transmission may be uncoded for some short moments. In order to achieve the correct decoding of the transmitted signal, the code generator of the receiving device must be synchronized with the code generator of the transmitting device with which it is communicating. Said synchronization operation is repeated in known devices every time it is desired to change the direction of communication between users, and therefore in a transmission system with more than two devices connected simultaneously in different places, it is possible that failure to receive the synchronization signal causes one or more receiving devices to unable to perform reception.

Switching from the transmission of a clear, uncoded signal to the transmission of an encoded signal requires manual operations by all users to operate the devices, making the use of the device not particularly simple.

Finally, the price of such devices rises relatively high due to the number and price of individual electronic components used, which in turn limits the wider spread of the devices.

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It is an object of the present invention to provide a time-domain encoding and decoding device for protecting communication secrets, which device eliminates said disadvantages, is easy and quick to install and simple to use, and takes up less space and can be manufactured as a portable device. a considerable decrease compared to the devices currently on the market in a sauna when the device according to the invention is very secure and has good communication properties.

To achieve this object, the device according to the invention is characterized in that said second means comprise a logic memory storing a plurality of states, each corresponding to one memory element, evolving according to a coding sequence in said transmission and coding circuit and a decoding sequence in said receiving and decoding circuit, and the device comprises third means for continuously transmitting and receiving synchronization signals, the third means comprising a synchronization signal generator circuit and a detection circuit, the operation of which takes place in a complementary form.

For a better understanding of the invention, an embodiment thereof will be described in detail below by way of non-limiting example with reference to the accompanying drawing, which shows a block diagram of said embodiment.

The microphone not shown in the drawing terminates in the terminal 1 and is connected via an adjustable input impedance and a gain o-amplifier 2 to, for example, the first switching terminal 3 of the electronic switch 4 formed by the C / MOS component. The output of the receiver system shown in the terminal 6, e.g. and via a gain amplifier 7 and a second switching terminal 8 of the switch 4, the common terminal 9 being connected to the inputs of the synchronicity detection block 10 and to the band elimination filter 11. In particular, the filter 11 is provided with a very narrow band centered at 1600 Hz, and ---- - - · Γ ~ 4 7 2 2 41 is of the type with a plurality of capacitors, the first electrode plate of which is connected together to form a filter input, whereby the second plate can be alternately connected to the same filter output electronically. through the commutator. Such a filter is known as a "commutation filter" or an "N-way filter" ·

The signals arrive at the activation inputs 13 and 14 of the filter 11, respectively, from the outputs 15 and 16 of block 17, which represents the timing and is formed by a divider chain. A logic signal is received at the input 13 of the filter 11, which controls the speed of said electron switch, while a logic signal controlling the sensing direction of said communicator is received at the input 14.

The output of the filter 11 is connected via an electronic switch 20 to the signal input of an analog-to-digital converter 21, one output of the converter being connected to the signal inputs of logic memories 22, 23, 24 and 25, the memory activation inputs of which are connected to the outputs 26, 27, 28 and 29 of the decoding block. The outputs 22, 23, 24 and 25 are connected together and are connected via a digital-to-analog converter 33 to a low-pass filter 34, which preferably has a cut-off period of 3 KHz and whose output preferably reaches the common terminal 35 of the electronic switch 36 formed by the c / MOS component. In addition, the memories 23, 24 and 25 have respective clock inputs connected to the output 39 of the timer 17, one output 40 of the timer 17 coming to the clock inputs of the analog-to-digital and digital-to-analog converters 21 and 33, respectively.

The first switching terminal 44 of the electronic switch 36 is connected to the input of an amplifier 45, the output of which is connected to a terminal 46 which can be connected from the outside to a speaker (not shown). The second switching terminal 49 of the electronic switch 36 is connected to the input of an amplifier 50, in which the amplifier has an adjustable output impedance and a gain, and which can be connected to the input of a transmission system, for example a radiotelephone, via the connection terminal 51.

The first end of the resistor 54 is connected to the terminal 55 of the positive input terminal of the device and the second end is connected simultaneously to the terminal of a normally open type pushbutton terminal 56 having a second end of the pushbutton connected to ground and capable of transmitting or receiving said device. 5 intake; a resistor is connected to the control inputs 57 and 58 of switches 4 and 36, respectively; To the input of a NOT type logic gate 60; to the input of a delay block 61 with a grounded terminal; to the first input of the logic gates AND 62 and OR 63 with two inputs and to the input 64 of the read logic memory 65, which memory is of the externally programmable type (PROX).

The signal from the code selection block 70 and the clock signal from the output 71 of the timer 17 reach both respective inputs 68 and 69 of the memory 65.

The first end of the resistor 74 is connected to the terminal 75 of the positive terminal of the supply voltage and the other end is connected to the terminal of the switch 76, the second end of which is grounded and in particular allows the device in question to operate uncoded or coded, and said switch is connected to the input 77 of the decoding block 30. inputs 78 and 79 receive output signals 80 and 81 of memory 65, respectively. Input 84 of timer 17 is connected to the output of, for example, a vibrator circuit 85 comprising a crystal, while synchronization input 86 of timer 17 receives a signal from a second output of gate AND 62 and a second input of the same gate is connected to the output of the synchronicity detection block 10. The output 81 of the timer 17 is connected to the first input of an OR-type two input logic gate 90, the second input of the gate is connected to the output of the NOT gate 60 and the output of said gate 90 is connected to the control input of the electronic switch 20.

The output 16 of the timer 17 connected to the input 14 of the filter 11 is also connected to the first input of the EX-OR type two input logic gate 93, the second input of the gate receives a signal 94 from the timer 17. The output of the EX-OR logic gate 93 arrives at the second input of the OR logic gate 63 the output of the gate arrives at the input of the amplifier 50 via a sinusoidal synthesizer 97, which may be, for example, a digital-to-analog converter and which is capable of providing a synchronization signal at a frequency of 1600 Hz.

In the following, the operation of the device according to the invention in two possible forms of communication, which are uncoded and coded, will be considered.

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It is assumed that the connection between the two users starts when the communication is uncoded, in which case the communication is started by both the switch 7 6 to keep the input 77 of the decoder 30 grounded and the transmitting user holding the pushbutton 56 down.

In both transmitting and receiving devices, the grounded input 77 of decoder 30 keeps outputs 27, 28 and 29 at level "O" and output 26 of the same decoder at level "1", forcing memory 22 to operate through the latter, which in this case does not delay the input and output.

Due to the pushbutton 56, the inputs 57 and 58 of the electronic switches 4 and 36 in the transmitting device are connected to ground and, as a result, they determine the connection between the terminals 35 and 49 of the switch 36. The first input of the gate AND 62 also remains grounded and the output of this gate remains at the "0" level and does not allow the output signal to pass from the synchronism sensor 10 to the input 86 of the timer 17. In this case, the timer 17 is controlled only by the oscillator 85, leaving control signals at the inputs 13 and 14 through own outputs 15 and 16. For this reason, the filter 11 eliminates the audio signal entering its signal input, which still remains in the range of said band of about 1600 Hz.

Immediately when the change in the direction of rotation of the filter 11 occurs, the timer 17 transmits a signal in output "89" in the "0" level to the first input of the OR gate 90, but the output is always in the "1" level; in practice, the second input of the gate OR 90 remains in level "1" due to the output of the gate NOT 60, the input of the gate of which is grounded via the pushbutton 56. The control input of the electronic switch 20 therefore remains at "1" and keeps said switch permanently closed.

The timer 17 also sends clock signals to the converters 21 and 33, the memories 23, 24 and 25 and the logic memory 65, and in addition a signal is continuously sent to the input of the synthesizer 97 via the gate EX-OR 93 and the subsequent gate OR 63. The same synthesizer generates at its output said sinusoidal synchronization signal having a frequency of 1600 Hz, the phase of which changes periodically by 7 7 2 2 4 1 180 °, for example every second, due to the signal coming from the output 16 of the timer 17. Finally, the first period of operation of the memory 65 is provided by its own input 64, which is grounded by the pushbutton 56. Such an operation has no effect on the rest of the circuit, since the outputs 80 and 81 of the memory 65 arrive at the inputs 78 and 79 of the decoder 30, respectively, whose operation of the decoder is blocked by a signal entering its own input 77, as previously stated.

Therefore, the audio signal from the transmitter user's microphone, which microphone is connected to the terminal 1, enters the receiving device's user reception system of the amplifier 2, switch 4 terminals 3 and 9, filter 11, switch 20, analog-to-digital converter 21, memory 22, digital-to-analog converter 33, a low-pass filter 34, a terminal 36 and 49 of the switch 36, an amplifier 50 at the input of which it is connected to the synchronization signal from the synthesizer 97, and a terminal 51 connected to the radiotelephone, all of which together form a transmission circuit.

In the receiving device, the pushbutton 56 is open, whereby the inputs 57 and 58 of the switches 4 and 36 have a signal at "1" level, which is why a connection follows between the terminals 8 and 9 of the switch 4 and the terminals 35 and 44 of the switch 36, respectively. Said signal at level "1" allows the synchronization signal to pass from the output of the detector 10 to the input 86 of the timer 17 via the gate AND 62 and prevents the operation of the synthesizer 97 because the output of the gate 0R 63 remains at the level "1". The timer 17 of the receiving device, which is controlled by the oscillator 85 and synchronized by the transmitting device, sends control signals analogously to the transmitting device to the filter 11 and the electronic switch 20. The filter 11 operates analogously as described above, while the gate NOT 60 output at "0" allows the control signal to pass 89 to the control input of switch 20 through gate OR 90. Within a few thousandths of a second, after the rotation of the filter 11 is reversed, the control signal at level "0" opens the switch 20 after said short period. In this way, the momentary broadening of the synchronization signal spectrum during the phase change caused by the transmitter is substantially compensated. - 8 7 2 2 4 1 that due to the opening of the switch 20, for which reason a considerable attenuation of said signal at a frequency of 600 Hz is achieved as a whole. From the timer 17, the clock signals are further transmitted to the converters 21 and 33, the memories 23, 24 and 25 and the logic memory 65, where a second operating cycle is provided via its own level 64 input "1". As for the transmitting device, there are no consequences for the rest of the circuit either.

Therefore, the audio signal from the receiving system connected to the receiving device terminal 6 is transmitted through terminals 8 and 9 of switch 4, filter 11, switch 20, analog-to-digital converter 21, memory 22, digital-to-analog converter 33, low-pass filter 34, switch 36 terminals 35 and 44 and amplifier 45. , all of which together form a receiving circuit, after which the signal arrives at the terminal 46 connected to the speaker.

A change in the direction of communication between the two users is possible when the user of the transmitting device releases the push button 56 and the recipient presses the corresponding push button 56, whereby the functions shown on the two devices are completely exchanged. In particular, the "0" level obtained from the actuation of the pushbutton 56 is maintained for a few hundred thousandths of a second (e.g. 300 thousandths of a second) by a delay block 61 in the transmitting device to clear the contents of memories 23, 24 and 25, which are already free. Furthermore, since the period of the signal present at the output 16 of the timer 17 is 1 second and said signal determines the phase change of the sinusoid caused by the transmitting device synthesizer 97 and thus the period of the synchronizing signal at the output of the receiving device detector 10, the maximum time for two connected devices to synchronize within one second.

The change from uncoded to coded communication takes place by opening switch 76 in both devices. This start-up disconnects the outputs 26, 27, 28 and 29 of encoder 30, which then momentarily set to "1" when pairs of binary numbers 00 are present at inputs 78 and 79 of said decoder, respectively. 01, 10, 11 formed by the logic memory 65. The outputs 26, 27, 28 and 29 then start the operation of the respective memories 22, 23, 24 and 25 9 7 2 2 4 1, for which reason the line or speaker is transferred to the memory. part of the audio signal and the part of the audio signal coming from the microphone or the reception system is stored in the memory.

In particular, the memory 65 contains at least one pair of sequences, each comprising the same number of binary number pairs, for example 16 pairs, which are progressively and periodically generated at the outputs 80 and 81 of the memory 35 due to the control of the clock signal at the input 69 of the same memory. The use of each sequence is provided by a signal at level "O" or level "1", the level of which is determined by the closed or open position of pushbutton 56, present at input 64 of memory 65 and wherein the first sequence is used for transmitting device and second sequence for receiving device; furthermore, in the case where the memory 65 contains several sequence pairs, a certain pair can be selected externally via the code selection block 70.

The sequence associated with the transmission device, which at this stage is in a substantially random order, is constrained by three factors: The first is that the total delay of the audio signal portion in the transmitting and receiving device must not be greater than 6 steps of the clock signal at output 71 of the timer 17; that good coding of an audio signal requires that the parts of the signal successively stored in the memories of the transmitting device must not be retransmitted in sequential order and the third is because said sequence must be periodically reproducible, with pairs of numbers transmitted at the end of the sequence without interruptions in the receiving device.

Therefore, the audio signal portions from the microphone of the transmitting device each rest in one memory 22, 23, 24 or 25 for a different time than the previous portion, but this time difference is not greater than the time period determined by said six steps of the clock signal, and then transmitted from said memories to the line 1600. With a Hz synchronization signal.

The sequence associated with the receiving device should instead contain one set of binary number pairs suitable for initiating the operation of each memory 22, 23, 24 and 25 so that each audio signal portion, 7 2 2 4 1 10 transmitted with a zero to five clock step delay, is arranged to remain in the receiving device. a number of clock steps that complements the number of delays in the transmitting device to six steps.

For this reason, the audio signal arrives from the transmitting microphone to the loudspeaker of the receiving device, so that the total delay is essentially said six clock steps plus the propagation time along the transmission line.

The binary number pairs associated with these two sequences and satisfying said limitations are formed separately, for example by means of a computer, and when the sequence associated with the transmitting device is periodic, it can be started from any pair of binary numbers contained in the device. As a result, a sequence having N number of binary number pairs and satisfying the three conditions mentioned provides N number of different code formats of the transmitted audio signal which are independent of each other and which can be selected by the user, for example via block 70.

In order for the encoding and decoding to work properly, the sequences associated with the transmitting and receiving device must operate synchronously. This is achieved by transmitting a 1600 Hz synchronization signal from the transmitting device, as determined in connection with uncoded communication. The operation of the filter 11, the electronic switch 20 and the delay block 61 takes place analogously, which, as shown, clears the memories 23, 24, 25 after the transmitter user has released the push button 56 before the signal from the transmitting device arrives at said memories.

It is clear from the presented features how the device according to the invention solves the coding of the audio signal in the time domain reliably and with the smallest possible number of components. In particular, when a periodic type coding sequence is used, only one set of appropriately selected N-binary number pairs yields N number of different coding systems, thereby occupying as little space as possible in the memory 65. Such memories are abundant and inexpensive, and can also be replaced by an analog memory containing different sequences of binary number pairs, whereby any unfavorable expression of the coding system can be overridden simply by changing the memory 65. In addition, access to memory 65 is generally shown in Figure 7 taken with the code selection block 70, can be provided by selectors, punch or magnetic cards, or other methods to better protect a particular pair of coding and decoding sequences used.

In the communication system shown, synchronization signals are transmitted to the time period of each receiving device substantially every second. This periodicity always allows complete alignment between the sequences provided by the memories 65 and, in addition, allows any user to communicate with and synchronize with other users already in communication with each other for a maximum of 2 seconds after the moment the device is connected. This special feature greatly increases the usability of the device compared to known types of encoders, in which the transmitting device transmits the synchronization signal only once at the beginning of the sequence formed by the associated code generator, making it impossible for users of other devices wishing to listen thereafter. In addition, the 1600 Hz synchronization signal is associated with an audio signal with which it is continuously transmitted along a communication line, thus increasing the compactness of the communication system, since said synchronization signal produces a masking sound.

The filter 11 is used in a particularly important way: In practice, it is controlled by a timer 17, the stability of which is proportional to the stability of the oscillator 25 and is not affected by possible transitions of the synchronization signal generated by the transmitter synthesizer 97 in the receiving device, since the same synchronizing signal also arrives at the same receiving device. . In addition, reversing the commutation direction of the filter 11 and using the electronic switch 20 as a whole provides a significant improvement in the performance of said filter.

The presented time division coding system does not substantially expand the band of the transmitted audio signal, which is why it is possible to use any type of radio channel or telephone channel.

Finally, the possible adjustment of the input impedance and gain of amplifiers 2 and 7 and amplifier 50 allows the device according to the invention to be arranged in its entirety in connection with any type of microphone and radiotelephone, thus increasing the possibilities of using such devices.

Although the invention has been specifically elucidated with reference to this embodiment, it will be apparent to those skilled in the art that various modifications and changes may be made to this embodiment of the invention without departing from the scope of the invention.

In particular, it is possible to replace the logic memories 22, 23, 24 and 25 and the analog-to-digital 21 and digital-to-analog 33 converters with analog-type memories when the cost of the latter proves to be advantageous without substantially changing the circuit shown.

Claims (15)

7 2 2 4 1 13 An apparatus for encoding and decoding electrical signals included in a preset frequency band for the protection of a communication secret, which apparatus may be connected between said electrical signal development and reception means and, on the other hand, means for exchanging said coded signals with at least one other encoding and decoding device, comprising apparatus for transmitting and encoding said signals and a receiving and decoding circuit, a switching means which, in addition, enables the operation of the transmitting and encoding circuit and the receiving and decoding circuit, said circuits comprising first members having a plurality of memory elements in succession temporarily storing the received electrical signal portions, second means for enabling said first means to sequentially store said signal portions in memory and transmit them in a different order; one of said switching means and signal receiving means, characterized in that said second means comprise a logic memory (65) storing a plurality of states, each corresponding to one memory element (22, 23, 24, 25) and evolving according to a coding sequence in said transmitting and encoding circuit and according to the decoding sequence in said receiving and decoding circuit, and that the device comprises third means for continuously transmitting and receiving synchronization signals, the third means comprising synchronizing signal generator circuitry (97) and a detection circuit in complementary or detecting mode. Device according to Claim 1, characterized in that the electronic switching means comprise analog gates (4, 36) with logic control. Device according to claim 1, characterized in that said memory elements (22, 23, 24, 25) are of the logic type and in that the device is further provided with an analog-to-digital converter (21) and a digital-to-analog converter (33) sequentially placed on the back of said memory elements. 7 2 2 4 1 14 Device according to claim 1, characterized in that the coding and decoding sequences are repeated periodically due to the control of the clock signal and are transmitted in complementary form via the manual control element (56). Device according to claim 4, characterized in that said electronic switching means are actuated via said manual control element (56). Device according to claim 4, characterized in that it comprises a selection means (70) which can be actuated from the outside and which sets the initial starting state in said periodic sequences. Device according to claim 6, characterized in that the selection element (70) comprises selectors and / or perforated cards and / or magnetic cards. Device according to claim 1, characterized in that a signal is received from the manually controlled element (76) in the circuit (30) decoding the output signals of the logic memory (65), which may or may not force the element (22) of said memory elements to operate, said element (22) transmission of electrical signal components in the same reception order. Device according to claim 1, characterized in that the synchronization signal generating circuit comprises a sinusoidal signal synthesizer (97), in which the sinusoidal signal changes periodically by 180 °. Device according to claim 9, characterized in that the synthesizer is formed by a digital-to-analog converter and that said phase change is effected by supplying to said synthesizer a clock logic signal from the output of an EX-OR logic gate (93), the clock signal arriving at the first input A logic signal of O "or" 1 ", which alternates a period equal to the phase change period, arrives at the second input. 15 7 2 2 41 Device according to claim 1, characterized in that it comprises a band elimination filter (11) located in front of said memory elements (22, 23, 24, 25). Device according to claim 11, characterized in that the filter (11) attenuates said synchronization signals and electrical signals having a frequency close to the frequency of the synchronization signals. Device according to claim 11, characterized in that the filter (11) is of the type comprising a plurality of capacitors, the first plate of which is firmly connected to the inlet of said filter and the second plate is physically connected to the output of the filter via an electronic switch; wherein said filter is further provided with a control input (14) to allow a change of the periodic connection. Device according to claim 13, characterized in that it comprises an analog switch (20) with logic control, located at the output of said filter (1) and actuated during the receiving phase and simultaneously with the change of direction of the periodic connection. Device according to claim 1, characterized in that it comprises a delay circuit (61) which, during the passage from the transmission phase to the reception phase, enables the transmission of the signal parts in the memory elements (22, 23, 24, 25). 7 2 2 4 1 16