DE1018453B - Facsimile receiver with a narrow 1 kHz band filter to eliminate the influence of the line background noise on the start impulses and with a device to prevent false starts caused by interference impulses - Google Patents

Description

The invention relates to a facsimile receiving device and seeks false starts of the receiving device as a result of line interference. In facsimile transmission systems it is necessary to that a start impulse is given by a sender who wants to transmit a message or a picture that starts the receiver. It has been found to be useful in facsimile systems that working over telephone lines, a suitable start impulse consists of a series of 1 kHz tones. Each impulse has a certain duration and between the successive tone impulses lies a certain time interval.

A narrow 1 kHz band filter is used so that the line background noises do not affect the start signal provided in the received signal circuit of the facsimile receiver. Unfortunately owns this filter has the property of switching noises occurring in 1 kHz pulses of approximately the same Reshape duration like the start impulses.

Since the receiving rectifier must respond to the real start impulses, it is not in the Able to recognize the wrong impulses resulting from the switching noises. Here you can false starts of the facsimile receiving machine result. The subject of the present invention is now that the receiving rectifier only when receiving real start pulses the start of the The recipient.

LTm a method of preventing false In order to be able to specify starts, the fact must first be recognized that the false impulses are from distinguish the real in principle by the fact that they arose during the screening or in any Periods take place, whereas the real ringing impulses are part of a regular sequence of a series of impulses and the same impulses always follow one another in a certain period of time. That's why each impulse can be determined as real or false by a test that is in a predetermined Time after its arrival is carried out to determine whether another impulse follows.

Since the identity of an impulse cannot be determined when it arrives, it must when it arrives and then a process begins that amounts to identity verification, the takes place in a certain time interval. If the test result indicates that the impulse was real, the facsimile receiver is activated. If the result shows that the impulse was wrong, will its storage is deleted.

Similar circuits are in anti-incidence circuits became known, d. H. in circuits in which a process is determined by several in Facsimile receiving machine

with a narrow 1 kHz band filter

to eliminate the influence

the background noises to the

Start impulses and with a facility

to prevent false starts

by glitches

Applicant:

Creed and Company Limited,
Croydon, Surrey (UK)

Representative: Dipl.-Ing. H. Ciaessen, patent attorney,
Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

Claimed priority:
Great Britain 4 May 1955

Frederick P. Mason, Croydon, Surrey (Great Britain), has been named as the inventor

Distance following impulses is triggered. The circuit arrangement according to the invention differs from these known circuits in that at a facsimile receiver, the first incoming start pulse is stored and time-delayed as a test pulse acts on a control grid of an electron tube in such a way that when they occur simultaneously of the second start impulse on the other control grid of this tube this conductive and thereby the facsimile receiver is turned on and that in the presence of z. B. a test pulse resulting from an interference pulse that does not occur in the rhythm of the start pulses, on one Control grid of this electron tube deleted the registration of the pulse and the facsimile receiver is not turned on.

It should of course be understood that this false start prevention method is not exhaustive can be, since it is possible that a wrong character by chance a first after the specified Interval can follow. For most commercial applications, however, this is the option so small that the percentage of false starts that can occur for this reason is so small that it can be neglected.

709 758/142

In the event that a higher degree of security is necessary, the same procedure can be used Way, like the first impulse by looking for a second, a second impulse in turn through Visiting a third can be checked and the storage of the first two is deleted if no third pulse was found. This principle can be extended to the likelihood false start has been reduced to the desired amount.

In order to be able to carry out a larger number of tests, it is suggested that the time for the Determining whether or not there is a pulse is as brief as practical.

The invention is described with reference to the drawing immediately after the tube 14 has become conductive. In the drawing the impulse receiver was placed, caused by its further growth, Shown according to the invention, the one that the current through the tube 14 approximately equal to facsimile receiver is used. increases moderately. The current through the winding 20

In the drawing, the start pulses are therefore also taken via one of the transformer 21 Message line 1 received and the input 20 evenly, with an approximately constant, einein Bandpass filter 2 supplied. This filter 2 is a potential in the winding 22 of the directional side matched that only those frequencies that are generated for the transformer 21 is generated. The direction of this The satisfactory transmission of the start pulses of the potential is such that the left connection of the are required to be transferred. The output of winding 22 is a positive change Filter 2 is identical to the input of a receiving 25 shows.

the current source 16 via a voltage conductor, consisting of the resistors 17, 18 and 19, positive are biased. Since the cathode of tube 15 is more strongly biased than the cathode of tube 14 a greater positive potential must be applied to the grid of this tube than to the grid of the tube 14 before these tubes become conductive.

The charging time of the capacitor 13 is approximately constant and is dimensioned so that a sufficiently large positive potential, which makes the tube 14 conductive, arises after a time which is equal to the interval between the successive pulses of the start signal. The positive potential associated with the Grid of the tube 14 over the capacitor 13 and

connected judge, which is represented by the block 3. At the output of this receiving rectifier appears a series of unidirectional positive pulses resulting from the start tone signals.

Shortly after the tube 14 becomes conductive, the potential at the grids of the tubes 14 and 15 becomes positive enough across the capacitance 13 that the tube 15 also becomes conductive. This is how a

The receiving rectifier output is connected to the current, which increases in strength evenly, in the control electrode of a gas-filled tube 4. Winding 23 of the transformer 21. This current continues to the grid 5 of an electron tube 6 with
four electrodes. The gas-filled tube 4 is provided

to save an incoming start impulse, and

induces in the winding 22 of the transformer 21 an opposite potential of substantially the same size as the potential created by the

is on standby. The electron tube 6 35 current was previously induced in the winding 20.

is normally non-conductive and only becomes conductive when its two grids 5 and 7 become positive at the same time. The arrival of a first positive start pulse from the receiving rectifier ionizes the

The resulting effect of these two potentials, induced in winding 22, applies the potential the left connection of the winding 22 to its previous value. This connection can be used as a power

gas-filled tube 4 and makes it conductive. The tube 6 40 source of a positive-going pulse from behing is not yet conductive, as no positive amplitude, duration and appearance are seen yet

will. This pulse serves as a test pulse to determine whether the receiver rectifier first received impulse was a real start impulse or

tive potential appears at its grid 7 at this time.

If the tube 4 has become conductive, then it sinks

Voltage at the anode 8, and these voltage changes 45 do not.

tion affects the grid 9 of the electron tube After the test pulses have been generated,

10 off. The electron tube 10 is normally conductive, the potentials of the grid of the tubes 14 and 15 have

Current flows from the current source 11 via the resistor - a change going into the negative through a

stood 12 and tube 10 to earth. But the negative circuit on which will be described later and this one

potential at their grid 9, causing 5 ° tubes are blocked again.

As the voltage at the anode 8 becomes low, the test pulse in the winding 22 is transmitted to the

the tube 4, it is sufficient that the current flow is interrupted grid 7 of an electron tube 6 and continues to the

will. As long as the tube 10 was highly conductive, the grid of an electron tube 33 was placed. If the

Capacitor 13 in parallel with the tube 10 at a first received by the receiving rectifier

relatively small positive potential. But as soon as the 55 impulse was a start impulse, it would be different

Tube 10 is no longer conductive ■ - this happens every start pulse that is sent to the output of the

times when receiving a start pulse of 1 kHz via the receiving rectifier -, the capacitor 13 charged by the power source 11 via the resistor 12. This is where the capacitor more positively charged. A test pulse is generated during the charging period. This time is equal to the interval between two consecutive pulses of the start signal.

modulator 3 would appear at the same time as the test pulse in the winding 22 of the transformer 21 was generated. Here, the grids 5 and 7 of the tube 6 are simultaneously positive, and the tube 6 becomes conductive, causes the relay 24 to respond, which then turns itself on via its contact 25 holds. The relay 24 switches on the facsimile receiver connected to it, which then

When the capacitor 13 is charged, an awake 65 receives a message via devices that are in send positive potential to the control grid of the drawing are not shown. Electron tubes 14 and 15 placed. In the ready- When the first through the receiving rectifier Shaft position when the capacitor 13 only receives a pulse, accidentally reduced by interference Has positive potential, the tubes 14 are causing it to be wrong, then follow it (with a large and 15 blocked because their cathodes considerably by 70 degrees of probability) no further pulse,

which corresponds to the test pulse via the winding 22. In this case, only the grid 7 is the Tube 6 positive, and this alone is not enough for tube 6 to become conductive. The relay 24 will not attracted and the facsimile receiver will not start.

As already mentioned, the test pulse is still applied to the grid of the electron tube 33, and the Tube 33 then becomes conductive for the duration of the test pulse. The current flow from the positive Current source 26 via resistor 27 and tube 33 to earth leaves the anode voltage at anode 28 of the tube 33 fluctuate briefly. This fluctuation is transmitted to the anode 8 via the capacitor 29 the tube 4 transferred. Since the tube 4 is a gas-filled tube, it causes the voltage fluctuation its anode 8 that the ionization in the tube is interrupted, the tube can then again controlled by their grid.

The drop in voltage at the anode 28 of the tube 33 together with the deionization of the tube 4 lets the voltage at the anode 8 of the tube 4 quickly become positive until its anode voltage becomes the Voltage of the power source 30 approaches again. The control grid 9 of the tube 10 thus becomes so positive that the tube 10 becomes conductive again. The capacitor 13 discharges through the tube 10, and the potential at the grids of the tubes 14 and 15 falls so rapidly that the tubes 14 and 15 are blocked again.

If the first pulse received by the receiving rectifier was a real ringing pulse, then the relay 24 is actuated. This relay is provided to receive a signal through devices not shown are to be sent to the sender. No more test pulses are received in response to this signal. The receive rectifier circuit is no longer actuated until the end of a message after the relay 24 has picked up.

If the first pulse received by the receiving rectifier was a false pulse then is the state of the receiving rectifier after the tube 4 has been blocked is identical to the state that passed before the pulse was received. The receiving rectification system is for this reason ready again to respond to the next impulse to be received.

If a higher degree of false start safety is desired, the circuit can do so be designed that when a second pulse is found, a third pulse is sought and the Facsimile receiver is put into operation when a third pulse has been found. In this In this case, the relay 24 and its contact 25 will not be arranged in the anode circuit of the tube 6, but in the anode circuit of a tube similar to tube 6 in another tube stage in the circuit.

In a device capable of testing a third pulse, the tube 6 would be a variable one Represent resistance in their anode circuit so that if a second pulse is found and the Tube 6 has become conductive, as described above, a negative pulse at the anode of tube 6 appears. This negative pulse would be inverted and result in a positive pulse which is on the control grid of a gas-filled tube, e.g. B. to the control grid of the tube 4 is placed. the Sequence of what goes on in the circuit and above as a result of receiving a first pulse are described, were via corresponding switching means in a further stage in the Circuit repeated to generate a second test pulse, which is sent to the grid of an electron tube with four electrodes similar to the tube 6 would be placed. The other grid of this tetrode would be connected to demodulator 3, and if three pulses had been received at the correct intervals of the start pulses, this would Tetrode are conductive to pull the relay 24, and the facsimile receiver in motion set.

Even higher levels of security can be achieved by further increasing the number of pulses. which must be found at clean intervals before the facsimile receiver is started.

The principles of the present invention have been described in connection with specific details and individual modifications are indicated. But it goes without saying that the present Description illustrates only one embodiment of the invention that can implement the invention in no way restricts.

Claims (5)

Claims 1. Facsimile receiver with a narrow 1 kHz band filter to eliminate the influence the line background noise on the start impulses and with a device to prevent False starts due to interference pulses, characterized in that the first incoming start pulse registered and time-delayed as a test pulse on the one control grid of an electron tube in this way acts that when the second start pulse occurs at the same time at the other control grid this tube is conductive and thereby the facsimile receiver is switched on and that in the presence of z. B. a test pulse that is not in the rhythm of the start pulses occurring S tor impulse originates on the one control grid of this electron tube the registration of the pulse is canceled and the facsimile receiving machine is not turned on. 2. Facsimile receiving device according to claim 1, characterized in that the registration of the first incoming start pulse with a grid-controlled one that is non-conductive in the normal state Gas discharge tube (4) takes place when the first incoming start pulse hits the control grid of this tube becomes conductive. 3. Facsimile receiving device according to claim 1 and 2, characterized in that the test pulse by charging a capacitor (13) which occurs when the first start pulse is received positively charged in a certain time (equal to the interval between two start impulses) and that this test pulse charges the control grid of two triodes (14, 15) and that the cathode of the triode (15) is more positively biased than the cathode of the triode (14), that in the anode circuits of these triodes, the primary windings (20, 23) of a transformer (21) lie and that these primary windings with opposite potentials on a secondary winding (22) of the transformer (21) act when both triodes become conductive. 4. Facsimile receiving device according to claim 1 to 3, characterized in that the start of the Facsimile receiving machine with an electron tube (6), with two control grids (5, 7) and a relay (24) with switching contact (25) takes place, that closes its switching contact when both control grids (5, 7) of the electron tube (6) are positive Show potential. 5. facsimile receiving device according to claim 1 to 4, characterized in that the first of the grid-controlled gas discharge tube (4) registered the pulse with the help of an electron tube (33) is deleted in such a way that the test pulse is applied to the control grid of this tube and this creates a negative pulse at the tube output, which is sent to the anode side of the grid-controlled gas discharge tube (4) acts so that the gas discharge tube thereby becomes non-conductive. Considered publications:
Book: Fünfer and Neuert: "Counting tubes and scintillation counters", year 1953, Verlag G.Braun, Karlsruhe, pp. 229 and 231;
U.S. Patent No. 2,556,713. 1 sheet of drawings