NO129227B - - Google Patents

Description

Device for the treatment of

the stand for element groups.

The present invention relates to a device for processing the binary state of a group of key elements, provided with a reading device for each element and provided with connections that can be controlled by the reading devices, and at whose outputs a "zero" or a "one" signal appears, depending on the state of the associated element and where the input of a switch is connected to a signal source capable of sending a "zero" or a "one" signal.

Such a device is known from the field of work

this is about and is used in encryption machines.

In the known machine, the signal that appears at the output of each of the connections is used as a key for coding and decoding.

The input to each of the connections is connected to the signal source and the signal that appears at the output of each connection,

is an indication of the states that the associated key element goes through when it moves step by step.

This can prove to be a disadvantage, because it can cause every single element to be recognized. Attempts have been made to eliminate this disadvantage by first directing the signals that appear at the outputs of the couplings to a commutator, so that the outputs from the couplings are changed before the signals are used as a key.

When this is done, the commutator can move incrementally in the same way as a key element or together with a key element.

A device that uses such a commutator is complicated and difficult to maintain. In addition to this, the successful result that can be achieved with the device will depend on the fact that the movement of the commutator cannot be recognized.

In the invention, no such commutator is used, and the above-mentioned disadvantage is eliminated in a way that is simple and easy to carry out, and the invention is characterized by the fact that the signal that appears at the output of the last connection is inverted by a state change in an arbitrary element.

This can be achieved in a simple way by summing the states of the two elements that are read by the module 2 devices.'

In this way, the influence of all the elements on the key will be the same, that is to say that each element is able to change its key, e.g. from "zero" to "one" by changing its state independently of the states of the other elements. The recognition of each separate element will therefore be practically impossible,

and the invention becomes simple and easy to keep in order.

The device has the further advantage, as is clear from the embodiments described below, that it can easily be expanded with the same type of elements without it becoming difficult to have the necessary overview.

An embodiment of the device according to the invention is characterized by the fact that the connections are connected in series, and that modular two circuits are preferably used as connections.

However, it is also possible to arrange the module two cretes

in some, different groups, so that you get a module-two circuit for this purpose controlled by two reading devices from two module-two circuits or by a module-two circuit and one reading device.

With this embodiment, the exposure time for the state in the key elements can be shorter than with a series connection.

The embodiment of the invention is characterized by the fact that the connections are switches that have bipolar inputs and bipolar outputs and that the input for the switch controlled by the first reading device is connected to the output from the signal source via a switch with a bipolar output and that the reading device can connect the input for each turns to its exit either crosswise or' straight through.

Yet another embodiment is characterized in that each reading device is connected to an input of one of a number of "AND" gate circuits which, in turn, are connected in series with respect to time by their other inputs being cyclically and in turn connected to the signal source

and whose outputs are connected together and to the input of a binary unit counter .which at its output is connected

to a device that triggers the signal after each cycle.

It is clear that the above-mentioned embodiments must not in any way be considered as limiting the scope of the invention.

In the following, the invention will be explained in more detail with reference to the drawings in which the above-mentioned embodiments are reproduced. schematically and where: Fig. 1 shows a device with module-two circuits connected in series,

fig. 2 shows a module two circuit used in fig. 1,

fig. 3 shows a device with module-two circuits which is controlled by two devices and two module-two circuits,

fig. 4 shows a symmetrical embodiment of the device shown in fig. 3,

fig. 5 shows a device which can be compared with fig. 1 for simultaneous encryption and decryption of all elements of a symbol from an alphabet, with five units,

fig. 6 shows an embodiment of the device with "turners" and

fig. 7 shows a device with "AND" gate circuits connected in series with respect to time.

In these figures, like reference numbers denote like components.

In fig. 1 denotes the numbers 1,2,3 and 4 key elements

which can be moved in steps in an irregular manner, and which can assume a different number of states, which states are either "zero" or "one".

The reading device 9,10,11 and 12 reads or scans the states of the elements 1,2,3 and 4.

The reading devices 9, 10, 11 and 12 control the connections 41, 42, 4 3 and 80, which are designed here as module two circuits.

The module-two circuit is connected to a signal source 44 by means of a switch 81...

The source 44, which in the embodiment shown is designated as a ground symbol, can in principle send a signal which is either a "zero" signal or a "one" signal.

In the module two circuits used here (see Fig. 2), a zero voltage or ground connected to the input 12 8 or A is regarded as a "one" signal, while a negative voltage or an open terminal at 128 or A is perceived by the modulo-two circuit as if a "zero" signal had been sent.

The module-two circuit 80 is connected to an output terminal 82.

Elements 1,2,3 and 4 move in steps in an irregular manner when the device is in operation.

Here it can be assumed that the switch 81 closes the circuit at a certain time, and that the source 44 sends a "one" to the module-two circuit 41.

Furthermore, it is assumed that the device 9 reads a "zero" and sends this zero on to a module-two circuit 41. A "one" will then likewise appear at the output of the circuit 41, which "one" will then be passed on to the input for circuit 42.

If now the device 10 on the element 2 reads a further "zero", a "one" will appear at the output of the circuit 42.

If, however, the device 10 reads a "one", a "zero" will appear at the output of the circuit 42, which would also be the case if the device 9 had read a "one" and the device 10 had read a "zero".

In this way, one can continue, as the output from each modulo-two circuit always appears as a "zero" or a "one" depending on the state of the corresponding elements and the state of preceding elements.

By building in reversal devices, the state of a particular element or the states of one or more elements, if desired, can be reversed.

Each of the elements of the key S obtained at the output terminal 82 can now be combined with an element of a text K to form an element of a cryptotext C according to the formula:

The plain text K can be introduced in the circuit, e.g. as schematically shown by the switch 81 which can break and close the circuit for this purpose.

At each pulse from a pulse generator which is not shown and which controls the step-by-step movement of the key elements 1,2,3 and 4, it is then determined by the elements in the plaintext to be sent, whether the switch 81 is to be broken or closed.

Deciphering can be done according to the formula:

Now the element in the cryptotext determines whether the switch 81 should break or close the circuit. In this way, the device can imprint the state on the key elements to form a key, a cryptotext or a plaintext, as desired. The texts appear at the output terminal 82.

It is possible to expand the device simply by adding one or more kits each comprising a key element, a reader and a module-to-circuit. In the drawing, the sets 100, 101, 102 and 103 are shown framed with dashed lines for the sake of clarity.

Fig. 2 shows an embodiment of a module-two circuit. Input A is always connected to the previous module-two circuit, while output B is connected to the following circuit.

The output from the reading device 10 is also connected to a module two circuit.

If the input A and the output of the device 10 both show either a "one" or a "zero", a zero will appear at the output B. If, on the other hand, the input A does not show the same signal as the output of the device 10, a "one " appear at the output of the module-two circuit.

In fig. 3 shows a device with four key elements 1, 2, 3 and 4, and their states are scanned by four devices 9, 10, 11 and 12. The devices 10 and 11 control the module two circuit 125.

The module-two circuit 125 sums the state of element-

one 2 and 3.

The modulo-two circuit 126 is in turn controlled by the modulo-two circuits 124 and 125, and at the output 82 of the device the result of the modulo-two summed states for elements 1 to 4 is obtained.

Fig. 3 further shows a shift register 132. The input 130 of the shift register 132 is connected to the output 82 of the device, and the output 131 is connected to the input 128 of the device.

If by means of this device a clear symbol is introduced into the shift register in a known manner, the symbol can be encrypted into a crypto symbol which then appears above the shift register instead of the clear symbol.

To clarify the following explanation, it can be assumed

that all four key elements move in steps regularly and clockwise, and that a clear symbol (01001) has been entered into the shift register 132.

In practice, however, the key elements will not usually move regularly in step, nor will they all move in the same direction.

The right part of the clear symbol from the register, "one" is applied to the modulo-two circuit 124 along with the "zero" state of the first key element.

A "one" signal will then appear at the output of circuit 124. As a result of the "zero" state for element 2 and the "one" state of element 3, a "one" signal will also appear at the output of circuit 125.

The circuit 126 will then send a "zero" signal to the circuit 127, because the circuit 127 has been supplied with two "one" signals.

A "zero" signal then appears at the output terminal 82, which is fed back to the shift register and stored there in its left part.

The symbol in the shift register has now become (00100) ,. and as a result of the above-mentioned regular step-by-step movement forward, the states of all four key elements will be a "one".

The right part of this symbol is then encrypted with the states of the elements, and this again results in a "zero" signal at the output 82, so that the symbol in the register will now be (00010). At the time when all five elements in the actual text have been encrypted, the crypto symbol (00100) will have appeared in the shift register.

It should be clear that the symbol in the clear text can be converted from the crypto symbol in a similar way.

The arrangement with a shift register was chosen as a solution that is particularly suitable for encryption. However, the encryption can be performed with the device according to the invention in many other ways.

Fig. 4 shows a symmetrical embodiment of the device shown in fig. 3, and this embodiment is very simple and straight forward. It should be clear that the devices shown in the figures in connection with four key elements can always be expanded.

In fig. 5 shows a device which is suitable for the simultaneous introduction of the symbol parts in an alphabet with five units. In this figure, each key element is provided with a series of devices so that the coded or decoded symbols from the quintuple alphabet appear at once at the end terminals 82^........ to 82^.

The figure needs no further explanation.

A "one" in the symbol as in fig. 5 causes the switch 81 to break, can also be reshaped so that it will cause the switch 81 to close the associated circuit. In principle, a converter device can be installed at any point in the circuit.

Fig. 6 shows a device that works with turners. The device 9,10,11 and 12 controls the inverters in such a way that the input terminals are connected to the output terminals either in a cross or straight through.

You will then receive signals at output terminals 62 or 82<1>

which is received on the two clamps.

Fig. 7 shows a device where the states of the key elements are scanned in turn and released at the output after module-to-summing.

The device again has four key elements 1,2,3 and 4, med

a "zero"-"one" part.

The devices 9,10,11 and 12 lead the states of the key elements 1,2,3 and 4 to the "AND" gate circuits 65,66,67 and 68. The source 44 will, depending on how it is set, send a signal which either can be a "zero" or a "one" and is connected to the gate circuits 65,66,67 and 68 via a driven dividing device 70.

The gate circuits 65,66,67 and 68 are connected in series with respect to time, being cyclically connected one after the other, to the signal source 44. Now if the signal source sends a "one" and the reading device 9 reads a "one" in the first element 1, then the gate circuit 65 will break and at the output of this gate circuit 65 you will get a "one" signal.

In all other cases, a "zero" signal will appear at the output of the "AND" gate circuit, that is, in all those cases where one of the two, either the key element or the source or both sends a "zero".

The output of the "AND" gate circuit 65 is connected to the input of a binary unity counter 69.

If the binary unity counter 69 indicated that a "zero" and a "one" appeared at the input, a "one" would appear at the output of the counter. If, on the other hand, the binary unit counter 69 had a "one" and a "one" at its input, a "zero" would appear at the output/ If a "zero" appeared at the input, the binary unit counter 69 would remain in that state it has.

As will be seen, the "AND" gate circuit 65,66,67 and 68 are cyclically coupled, one after the other, to the source 44, and in doing so, depending on the condition of the elements, the binary unit counter 69 will change, or it will remain to replace.

The binary unit counter 69 will thus sum the output signals from the "AND" gate circuits together according to the modulo-two principle.

The binary unit counter 69 is connected to the trigger circuit

110 which after a cycle is finished and before a new cycle starts,

is supplied with a pulse at C which causes the state of the binary unit counter to be passed on to the output terminal 82 of the device.

The state that is passed on will always be a "zero" signal or a "one" signal. It represents the sum of the modulo-two addition of the states of elements 1,2,3 and 4.

The cryptotext or the plaintext can be supplied to the "AND" gate circuit 83 at 81 in the form of one signal "one" or "zero". The arm 71 in the dividing device 70 always connects the gate circuit 83 to the source

44 before the end of a cycle. If the signal sent by the text part and the signal sent by the source are both "one", the gate circuit 83 will open and will send a "one" to the binary unit counter 69. The parts of the text will here affect the binary unit counter 69

in the same way as the key elements 1,2,3 bg 4 by means of the above-mentioned gate circuits 65,66,67 and 68.

Claims (4)

1. Device for processing the binary state ("zero" or "one") of a group of key elements (1-4), provided with a reading device (9-12) for each element and provided with connectors (41-43, 80 ) which can be controlled by the reading devices, and at whose outputs a "zero" or a "one" signal appears, depending on the state of the associated element and where the input of a coupling is connected to a signal source (44, 81) which is able to send a "zero" or a "one" signal, characterized in that the device is connected so that the signal that appears at the output (82) of the last connection (80) is inverted by a change in the state of an arbitrary element. 2. Device as stated in claim 1, characterized by the fact that each of the connections are module-two circuits and are controlled by two reading devices (10, 11), by two module-two circuits (124, 125) or by a module-two circuit and a reading device (fig. 3). 3. Device as specified in claims 1 or 2, characterized in that the connections are switches with bipolar inputs and bipolar outputs, and that the input for the switch controlled by the first reading device is connected to the output from the signal source via a switch with a bipolar output and that the reading devices can connect the input of each face to its output either crosswise or straight through. 4. Device as stated in claim 1, characterized in that each of the reading devices is connected to an input of one of a number of "AND" gate circuits (65-68) which are connected in series with respect to time in that their other inputs are cyclic and in turn is connected to the signal source, and the outputs of which are connected together and to the input of a binary unit counter (69) which at the sLn output is connected to a device which triggers the signal after each cycle.