NO146935B - Snood. - Google Patents

Description

Device for with an irregular sequence of steps to

move a group of incrementally moving key elements.

The present invention relates to a device with irregular

step order to move a group of incrementally moving key-

kel elements, where each element has a number of active and passive styles

lings corresponding to the value "one" resp. "zero", which number of style-

lings is preferably equal to a prime number, as no elements can assume their initial state again before a predetermined minimum number of step operations has been carried out, and as each element has a drive

device and a selector device in which a common drive mechanism directly drives the drive device for the first element, and through coupling means the drive devices for the following elements depending on the selected position of the preceding element.

Such a device is previously known as part of a "zero"-"one" generator for producing an irregular series of "ones"

and "zero".

Such an irregular sequence of "one" and "zero" is used for keying messages to keep them secret and for correlation measurements in distribution networks, for solving equations using electronic calculators and also where digital noise voltages are desired.

With this known device, the common drive device is connected to the drive device for an element when at least one element in front of the former is in an active coupling state.

An element that is in the active link state becomes

hereinafter referred to as active element.

In the known devices, an element in the group is thus always switched forward step by step when at least one of the previous elements is active or, in other words, a key element in a group can only have an influence on the step switching of a following element when none of the previous elements are active.

The last element then does not connect when none of the elements before the last in the group are active.

The influence that the state of an element in the group has on the forwarding of the following elements can thus be set off by the effect of one or more of the preceding active elements.

This disadvantage is eliminated by the present invention in that a key element is connected by means of the associated coupling device to the common drive mechanism in dependence on a control signal which is obtained by modulo-two addition of read positions (one-one^ for all preceding elements and from the control signal from a preceding key element in such a way that the element belonging to this coupling device is connected when the number of the elements which are in the "one" position and are in front of this element are either exclusively the same or exclusively different.

As switching on or off of an element is exclusively determined by the number of "ones" that are read in the preceding elements, namely whether this number is equal or different, in the present invention a read "zero" is as important as a read "one" ", as switching on or standstill for the element is always reversed

upon a change in the state of any preceding element.

There is previously known a device in which all states (both "one" and "zero") for at least one element in the group exert an influence on the interconnection of the elements in this group. With this device, however, an active state of the element always leads to a connection of a certain element (or certain elements) and a non-active state always leads to a connection of a certain other element (or certain other elements).

In the present invention, one has in the same way as

in the known device, the possibility to stretch the element group over a large number of elements and thereby the predetermined minimum number of connections by means of which all elements simultaneously obtain the initial state (that is, the so-called cycle) can be significantly increased.

This is explained in more detail in the following description of an embodiment of a device according to the invention.

However, it should already be noted here that the increase in the number of elements that is possible according to the invention is important because when the state of an element is changed from active to passive or vice versa, there will always be an inversion of the state of the following element.

The device according to the invention can be made both as an electrical device and as a mechanical device.

The invention is explained in more detail with reference to the drawing, where: Fig. 1 is a connection core for an embodiment of the invention with series-connected module-two circuits that control gate circuits. Fig. 2 shows in more detail an electronic element of the device according to fig. 1. Fig. 3 shows an embodiment where the elements are connected to the drive mechanism via a distributor, so the elements can be moved step by step, one after the other. Fig. 4 shows an embodiment which has two transmissions or lines with connections which can be controlled by the selectors at the elements.

In fig. 1 denotes 1, 2, 3 and 4 key elements which can be moved in steps and which can occupy a prime number of positions which are then either "zero" or "one". The devices 9, 10, 11 and 12 read or scan the positions of the elements 1, 2, 3 and 4.

The drive device 5 for the first key element 1 is connected directly to the drive mechanism 17 via the line 19.

The drive mechanism 17 is further directly connected to the "AND" portejie 38,

39 and 40, which ports are controlled by module-to-circuits 41, 42 and 43.

A control source 44 applies to the module-two circuit 41 a signal which can be a "one" or a "zero", for example in the form of a fixed potential. The outputs of the "0G" ports 38, 39 and 40 are connected to the drivers 6, 7 and 8 of the elements 2, 3 and 4.

When the device is in operation, the drive mechanism sends 17 control pulses which, with respect to time, are evenly distributed so that the first element as a result of the direct operation is advanced one step under the control of each of the produced pulses.

The device 9 reads the selected state of the element 1, which state consists of either a "one" or a "zero", which e.g. in the form of a pulse, the module-two circuit 41 is applied. Either a "one" or a "zero" will then appear at the output of the module-two circuit 41 which is connected to the gate circuit 38 and to the module-two circuit 42 depending on whether the device 9 reads a "one" or a "zero".

If an "one" appears at the output of control circuit 44

and a "zero" at the output of the device 9, then a "one" will appear at the output of the module-two circuit 41. A "one" will also appear at the output of the modulo-two circuit 41 if the source 44 is set to a "zero" and the device 9 to a "one". In all other cases, a "zero" will appear at the output of the module-two circuit 41.

The "AND" gate 38 will open itself only if a "one" appears at the output of the circuit 41, and the drive mechanism 17 is then connected to the drive device 6 for the element 2. The stepwise movement of the element "3 is in turn controlled by module -two circuit 42, etc.

The subsequent table I for the device according to fig. 1 shows that an element following the first can only be advanced stepwise, if the number of elements preceding said element that are in the "one" state is exclusively equal or exclusively unequal. Here it is assumed that the source 1 applies a "zero" to the circuit 41, and that the device 10 controls the circuit 42 via an inverter 45 and that the device 11 controls the circuit 43 via an inverter 46.

If source 44 applies a "one" to modulo-two circuit 41, element 2 moves to a selected "zero" state for the first element.

In the following table II, this is shown for a circuit without inverters.

If it is required, then of course the inverter too.

can be placed elsewhere in the circuit, for example in the wires which connect the ports with the module two circuits.

In fig. 1, the element 2 which can be set in stepwise movement, together with the associated gate 38, the drive mechanism 6, the reading device 10 and the module-to-circuit 42, is framed by dashed lines. The device can be composed of a majority of these framed circuit elements and it can also always be expanded with one such circuit element at a time.

Fig. 2 shows a more detailed design of one of these framed circuit elements.

The drive mechanism 17, i.e. the pulse generator, is connected to

an "AND" gate 38 comprising the rectifiers 47 and 48 and the resistors 49

and 50. The port 38 can be connected to the drive device 6 of the key element 2 either directly or via an inverter 55, which can also be an amplifier. The inverter comprises a transistor 54 in a grounded emitter connection. The collector is connected to negative potential via a rectifier 51 and the base is the common point for the resistors 52 and 53,

of which one is connected to a positive potential and the other to the gate 38.

The input A for the step movement (see also fig. 1) is connected to the gate 38 and also to the module-two circuit which comprises the resistors 56, 57, 59 and 60 and the transistors 62 and 63. This circuit is further connected to the device 10 which reads the selected condition,

"zero" or "one" in key element 2. The module-two circuit ensures that a "zero" or a "one" appears at B, i.e. at the output of the stage, which may take place across an amplifier 64 which simultaneously acts as an inverter, and depending on whether the device 10 or the pulse generator 17 or both sends a "one".

Fig. 3 shows a distributor 70 driven by the drive mechanism 17 which is directly connected to the drive device 5 for the element 1. When the arm 71 connects the device 5 with the source 44, the element 1 advances one step. The device 9 reads the state of the element 1 and at the same time controls the "AND" gate 65 which is further controlled by the distributor 70 when. the arm 71 connects the source 44 to the gate 65. If, therefore, for example, as a result of an active selector device, both the source 44 and the device 9 send "one", then the "AND" gate 65 will push, the binary unit counter 69 a "one".

In all other cases, the "AND" gate will send a "zero".

Either a "one" or a "zero" appears each time at the output of the binary unit counter. If a "one" appears at the input of counter 69, while the output showed a "zero", then the "zero" at the output changes to a "one". If a "zero" later appears at the input then a "one" remains at the output. If, on the other hand, a "one" appears at the input, then the "one" at the output will again change to a "zero", etc.

The output of the binary unity counter 69 is connected to the "AND" gates 38,39 and 40. If the arm 71 of the distributor 70 connects the source 44 to the gate 38, and both the source 44 and the binary unity counter 69 send "one" then the element 2 move one step forward. The device 10 now reads the state of element 2 again, regardless of whether this element has advanced a step or not.

If the "AND" gate 66 outputs a "one" a "zero" will appear at the output of the binary unity counter 69, because this displayed a "one".

In that case, the element 3 cannot be advanced, because the "AND" gate 39 remains closed.

If the device 11 then reads a "one" again, the binary unit counter 69 is again switched from a "zero" to a "one", and the element 4 can move if the "AND" gate 40 is opened.

In the one in fig. 3 shown circuit arrangement, the elements can thus only be advanced one step at a time one after the other.

According to this design, the circuit has a particular advantage if the selected states of the elements cannot simply be read, either mechanically or electrically, by means of the selectors, which e.g. is the case if magnetic elements are used.

Each time the arm 71 of the distributor 70 has been connected to the last element of the group, a new cycle is started for step advancement of any elements in successive rows.

In fig. 4 denotes 1, 2, 3 and 4 key wheels which are divided into a prime number of divisions and whose circumferences are equipped with pin rings whose pins can be placed in a "one" position (31) or in a "zero" position (32) in such a way that each wheel gets the required irregular distribution of states. The pins are located in accordance with the division of each wheel.

The drive device 5 of the first wheel 1 is connected via a line 19 directly to the drive mechanism 17. This is further connected via a line 18 to a turner 13 which divides the line 18 into two individual lines 20 and 21, which at the turner 14 can be passed straight through or crosswise to wires 22 and 23. These wires can then be led straight through or crosswise to wires 24 and 25 with the help of the turner 15.

Each of the wheels 1, 2, 3 and 4 is equipped with a drive device 5, 6, 7 and 8, as well as with a device 9, 10, 11 and 12 for reading the condition of the individual wheels.

If the wheel 1 of a pin 31 is given a "one" state, the reading device 9 will control the turner 13, so that the drive mechanism 17 via the wires 18, 21 and 33 is connected to the drive device 6 for the wheel 2.

If the wheel 2 of a pin 32 is given a "zero" state, the wires 20 and 21 are cross-connected with the wires 22 and 23

by means of the turner 14 which is controlled by the device 10. In this case, the drive device 7 is not connected to the drive device 17.

If the state of the wheel 3 is also "zero", the turner 15 will connect the wires 22 and 2 3 in a cross with the wires 24 and 25 so that the drive device 8 is connected to the drive mechanism 17. When the device is in operation, the drive mechanism 17 preferably sends control pulses which are evenly distributed with respect to time, so that - as a result of the direct operation under the control of each of the generated pulses -

the first wheel 1 is moved one step and the following wheels 2, 3 and 4 are moved in the same way, if the number of preceding wheels, showing the selected "one" state, is either exclusively equal or exclusively unequal.

This is evident from the following table III. The wheel 2 moves under the control of the selected state for wheel 1. The wheel 3 moves exclusively at an equal number of selected "one" states, whereby "zero" -r "zero" = an equal number of selected "one" states.

The wheel 4 moves exclusively at an unequal number of selected "one" states.

It is of course possible to make, for example, the wheel 2 move only in selected "zero" states. It is also possible to

for example, make the wheel 3 move exclusively on a different number of selected "one" states.

It will appear from the following that the extension of the rows by

increasing the number of wheels or elements in accordance with the invention here is more appropriate and effective than in the known devices, because the influence of all the wheels on the stepwise movement of the following wheels or elements is constant.

It is assumed that in an arbitrary double inverter W, in the device according to the invention, an unequal number of pulses N v and an equal number of pulses N^ are received from the drive mechanism and over the line.

The sum N, + = N, i.e. the total number of pulses sent from the drive mechanism 17.

The control pulses Nk on the transmission or line with different numbers will then move the associated wheel w, n states, where n is the prime number for the number of states for the wheel w^.

The wheel w, has p pins and the selected state of each of these is "one".

A different number of pulses are then applied to the wire connected to the inverter W, and the number of these pulses amounts to:

The number of pulses applied to the wire with the inverter Wk forbundrié which has an equal number, amounts to:

These equations show, among other things, that if a certain wheel, for example the K th, is moved very rarely during a certain operating period by the drive mechanism 17, then the (k+1) th wheel will receive a considerably larger number of control pulses.

If e.g. Nk = 0 then Nk+1 = . Here, Nk is not equal to "zero", but equal to the number of pulses that have been sent during the previously assumed operation of the device.

n and p are also never equal.

If the wheel in question is equipped with pins in a number p = -^(n-rl), then this wheel will move with an average speed approximately equal to half the speed of the first wheel.

In the device according to the invention, no progressive acceleration is thus caused by advancing the successive wheels. Such an acceleration would result in a very rapid movement of the wheels in the row. In that case, during a period of time, these wheels would rarely be in the state of rest in which they should contribute to being recognized by the symbols produced by the device.

During very short periods of time, a wheel can move at the same speed as the first wheel or be at rest.

In the embodiments of the device according to the invention, it is only a matter of whether elements perform step movement or not. With these designs, it is possible to convert this in a known manner to, for example, one or two steps, which e.g. can be achieved by causing all the elements to perform an additional specific step between every other possible step.

The designs shown in the figures can be improved with a fairly simple reading device, which possibly only includes a reading point on each wheel or element.

The continuous moving element 1 is preferably not equipped with any reading point. In these embodiments, it is therefore preferred to use 6 elements to excite a series of symbols with 5 information wheels.

Claims (4)

1. Device for moving a group of incrementally movable key elements in an irregular step sequence, where each element has a number of active and passive positions corresponding to the value "one" or "zero", which number of positions is preferably equal to a prime number, since no elements can assume their initial state again before a predetermined minimum number of step operations has been performed and since each element has a drive device and a selector device where a common drive mechanism directly drives the drive device for the first element and through coupling means the drive devices for the following elements depending on the selected position of the preceding element, characterized in that a key element (e.g. 3) by means of the associated coupling means (e.g. 39) is connected to the common drive mechanism (17) in dependence on a control signal obtained by modulo-two addition of read positions (one-one) for all preceding elements (1 and 2) and from the control signal (44) from a preceding key element (1) in such a way that the element (3) belonging to this coupling device (39) is connected when the number of the elements that are in the "one" position and lie in front of this element (3) are either exclusively equal or exclusively different. 2. Device as stated in claim 1, where each element is equipped with drive devices (5-8), characterized in that the drive device for the first element (1) is connected directly to a drive mechanism with a module-two circuit (41- 43) which on the one hand is connected in series with a control signal source (44) and which can otherwise be controlled by the selector device belonging to the element, as well as by the fact that each element following the first element is equipped with a drive device (6-8) which is connected to the output of an "AND" gate circuit (38, 40) which can connect the drive device to the drive mechanism (17) under the control of the preceding module-two circuit. 3. Device as stated in claim 1 or 2, where each element is equipped with a drive device which is connected to the drive mechanism by means of a distributor (70) characterized in that the drive device (5) for the first element is directly connected to the distributor which is connected to the drive device (6-8) for each of the subsequent elements by means of an "AND" gate circuit (38-40) which can be controlled by the drive mechanism (17) and at the same time by a binary unit counter (69) connected to the circuit, and by an extra "AND" gate circuit (66-68) has been added to each element which can be controlled by the selector device belonging to the element in question, and which is also connected to the drive mechanism via the distributor and at the same time controlled by it, as well as by the outputs for "extra " gate circuit is connected to the input of the binary unit counter. 4. Device as stated in claim 1 or 2, comprising a drive device for the first element directly connected to a drive mechanism, a drive device belonging to the second element which can be connected to the drive mechanism via a coupling, which coupling can be controlled by that of the first element belonging to the selector device, as well as to the following elements belonging to drive devices which can be connected to the drive mechanism via two wires or transmissions using selector devices via couplings, characterized in that the couplings comprise a switch or switch via which the drive mechanism can be connected to one or the other of the wires which is provided with a double inverter belonging to each element which is controlled by the element's selector device, and which can further connect the wires either straight through or in a cross, over which the drive mechanism is connected to a subsequent double inverter and can be connected to the drive device for the element that belongs to this inverter.