DE569789C - Device for automatic control of the efficiency of transmission systems - Google Patents

Description

GERMAN EMPIRE

ISSUED ON
FEBRUARY 8, 1933

REICH PATENT OFFICE

PATENT LETTERING

JVi 569789 CLASS 21a ¹ GROUP 33 si

S / 9P74 VIIIa \ 2iQ> Date of publication of the patent grant: January 19th

Siemens & Halske Akt.-Ges. in Berlin-Siemensstadt *)

Addition to patent 540

Patented in the German Empire on May 29, 1927 The main patent started on April 22 , 1927.

In the main patent a device for the automatic regulation of the efficiency is included of transmission systems described in which a auxiliary stream with an outside of the Useful current frequency band Hegenden frequency is used to control the reception strength.

The invention relates to a further embodiment of this device, through the one low inertia of the control process is achieved. This makes the facility suitable especially for wireless high-speed transmission of image streams that are usually The reception strength is adversely affected by fadings and similar interferences will.

An essential feature of the invention is that the on the receiving station located, set by the control currents relay device in a three-electrode tube, in whose a circuit, preferably in the anode circuits, as it is, for. B. in the so-called Echo cancellers and amplitude limiters is known to have an impedance located (preferably in connection with smoothing agents), which at the same time in the grid circles Another electrode tube through which the useful currents flow. Depending on the The reception strength of the control currents is the grid bias of the useful circuits displaced lying tube and thereby the transmission capacity of the utility circuit changed in such a way that it decreases as the reception strength of the control current increases will, and vice versa.

The regulation of the transmission capability can either be done at one point the receiving circuit where only the useful currents flow, i.e. behind the Selective means sifting out the useful streams, or at a point where the image streams and control currents flow, i.e. in the direction of transmission before the point at which Separate useful and control currents from one another.

On the transmission side, the control current is constant amplitude in the same or in a similar way, as shown in the main patent, at the same time with the useful flows Imposed carrier currents.

Fig. Ι shows an embodiment of the invention, specifically for the case of image transmission.

The vibrations picked up by the antenna, i. H. the carrier currents that are modulated in the rhythm of the image streams and the control streams are via a

*) The patent seeker stated as the inventor:

Dr. Frans Tucsek in Berlin-Charlottenburg.

Transmitter ä is fed to the grid circuit of a tube g acting as a rectifier. In the anode circuit of this tube, the carrier frequency flows through a capacitor k; the useful frequencies resulting from the rectification and the auxiliary frequency via a "resistor w, from where the currents branch: The filter c, e.g. a capacitor chain, only lets through the useful frequencies that are fed to an amplifier tube". The amplification This tube should be changed according to the absorbed energy! The filter $, e.g. a coil chain, only allows the auxiliary frequency to pass. This is rectified in a tube h . The alternating current component passes through the capacitor /, the direct current component via the resistor r The voltage drop that arises at / * and which is greater the greater the energy of the control current absorbed by the antenna, now serves as a bias voltage for the tube «.

The greater the voltage drop at r , the more the grid bias is shifted from η to the negative, so the lower the degree of transmission of the tube «. By a suitable choice of the resistance / · it can be achieved that the useful current drawn off behind the tube is always proportional to the modulating useful current on the transmitter side, regardless of the fluctuations in the transmission rate between transmitter and receiver.

The resistance / · can also be in the grid circle of a tube which is located in front of the branch point for the useful and control currents, e.g. B. in the grid circles of the rectifier tube g or an upstream further amplifier tube.

In this case there is a linear relationship between the amplitudes of the control currents and the changes in the transmission capability of the receiving circuit not necessarily necessary.

You can therefore make the control device so that it is only exceeded when responds to a certain threshold value and then carries out the regulation until the amplitude of the auxiliary frequency and thus also the amplitude of the useful current, which is also changed at the same time, theirs has reached or almost reached the old value. The response of the control device at A certain limit is expediently achieved by using a grid current an electron tube.

Fig. 2 shows an embodiment of this arrangement. The currents coming from the antenna β via the transmitter into the receiver flow first through an amplifier tube v, on which the degree of transmission of the receiving circuit is regulated. A rectifying discharge tube g is connected to the tube ν , in the output circuit of which there is a capacitor k and a resistor w . The carrier currents flow through the capacitor k , while the useful and control currents flow through the resistor w. The two types of current are separated behind the resistor. The fiI-ter c, e.g. B. a capacitor chain, only transmits the useful currents, while the filter, such as a coil chain, only transmits the control currents. These are fed to a resistor / · which is located in the grid circle of an auxiliary tube, the grid bias of this tube being selected so that a grid current begins in the tube h from a certain amplitude of the control currents coming from s to the resistor / ·. This grid current generates a voltage drop in the connected grid circuit of the amplifier tube ν , which shifts the grid voltage from ν to the negative and which is greater, the greater the amplitude of the control current acting on the grid circuit of h. This degrades the transmission capability of the receiving circuit. In the connection between the grid circles of the amplifier tube ν and go of the auxiliary tube, electrical selective means are expediently switched on, which prevent the control frequency itself from getting into the grid circle of the amplifier tube, where it could be superimposed on the useful currents.

The lattice circle of the tube ν can be connected to the anode circles instead of the lattice circle of the auxiliary tube «. In this case, the voltage drop for shifting the grid potential of ν is not generated directly by the grid current of «, but by the associated change in the anode current.

The grid current of tube A or its anode current, which is dependent on the grid current, can also act differently on the transmission line than by shifting the grid potential, z. B. with the help of a relay o Transmission line is switched, which has the no amplitude of the received currents, ie also the control currents, again down to below the response limit of the relay or the like. This resistance can expediently be increased from the moment it is switched on be e.g. B. with the help of a potentiometer moved by a motor, as described in the main patent.

If the invention is applied to image transmission systems, so it is advantageous to use the control currents as synchronization currents at the same time.

Claims (9)

Patent claims: ι. Device for automatic control of the efficiency of transmission systems according to patent 540615, in particular for image telegraphy, thereby marked; that the control current screened out in the receiver by selective means acts on a three-electrode tube through which the amplitude of the useful currents is regulated. 2. Device according to claim 1, characterized in that the relay device only affects the branch in which the useful currents that have been screened out by selective means flow. 3. Device according to claim 1, characterized in that the relay device influences the part of the receiving circuit in which, in addition to the useful currents, the auxiliary current and possibly the carrier current also flows. 4. Device according to claim 1, 2 or 3, characterized in that the anode circles or lattice circles of the electron tube forming the relay device has an impedance which is simultaneously im Lattice circles of a three-electrode tube located in the current branch to be regulated lies. 5. Device according to claim 1 and 3, characterized in that the control tube only reaches a certain limit amplitude from causes a damping of the transmission path. 6. Device according to claim 5, characterized in that the response limit the starting point of a grid current is used by the control tube. 7. Device according to claim 5 and 6, characterized in that the grid current or the anode current of the control tube influenced by it a voltage drop generated at an impedance, which is located at the same time in the grid circles in the current path to be regulated Three-electrode tube lies. 8. Device according to claim 5 and 6, characterized in that on insertion a grid current in the control tube, expediently by means of a relay, a resistor in the current path to be regulated is switched on, the amplitude of the control currents back to below the response limit of the control device belittles. 9. Device according to one of claims ι to 8, characterized in that ^s when working with synchronizing currents transmission systems, for. B. in image telegraphy, the synchronizing currents serve as control currents. 1 sheet of drawings