DE1301358B - Method and circuit arrangement for transmitting direct current telegraphic characters - Google Patents

Description

The invention relates to a method and a circuit arrangement for the transmission of direct current telegraph characters with double current via galvanic switched lines.

Such methods are known because of the symmetrical current flow especially used for longer connecting lines (S c h i w e c k, teletype technology, 1962, p.61.7) in order to avoid large one-sided telegraphic distortions. Known is also the method of pulse telegraphy (S c h i w e c k, telex technology, 1962, p.622), which is characterized by its great insensitivity to derivative fluctuations and afterimage defects.

Telegraph characters are now becoming more limited when they are transmitted over lines Bandwidth - be it in general or using the procedures mentioned - known to be deformed. This deformation affects the evaluation of the received Telegraph characters do not exist as long as the telegraphic distortion has certain limits does not exceed. A low telegraphic distortion arises only if the settling time of the transmission system is shorter than the step duration. at a polarity jump at the input of the line must be the voltage at the output of the transmission system have reached the DC voltage value during a step duration. The transmission speed is therefore due to the settling time and the maximum permissible telegraphic distortion set a limit.

Now to the transmission speed, which with binary transmission and binary evaluation could not be exceeded so far, with the same To increase bandwidth, multi-level modulation types have already been used been; however, these processes are very complex.

The object of the invention is therefore the transmission speed in the transmission of direct current telegraph characters by simple means raise.

The method for solving this problem is according to the invention thereby characterized in that with each step change the information of the following Drawing step corresponding transmission voltage is placed on the line and after the half the step time is switched off again.

With every step change in the transmission location circle, the current is at the output of the line rise to a value that depends on the settling time of the line as well of the recipient and the duration of the step. The transmission speed is only limited by the fact that the current exceeds the response threshold of the receiving circuit must exceed. As long as the swing-out device of the transmission system if the transient process lasts, the current at the output of the line decreases during the second half of the step duration falls back to zero. Every step envelope finds therefore the same initial state on the line, and an overlay of Swinging in and out is avoided. This is despite the high telegraph speed ensures a transmission with little telegraphic distortion.

The circuit arrangement for carrying out the method according to the invention is characterized in that the transmitting device receives a direct current from the telegraph the Sendeortskreises controlled timing element is assigned, which the key circuit only switches to send status for half a step.

This timing element can be implemented by several different circuit arrangements will be realized. The use of an RC element is particularly simple Capacitor is reloaded with each step change on the subscriber line. The time constant of this RC element is dimensioned so that the one controlling the key circuit Charging current only flows during half the step duration.

A more precise control of the pushbutton circuit can be achieved through two monostable multivibrators, whose inputs to the subscriber line and whose outputs are connected to the push button circuit. One of these tilt stages is the transition from start to stop polarity and the other the change from stop polarity assigned according to start polarity.

These circuit arrangements can still be improved in that the output resistance of the transmitting device and the input resistance of the receiving device are chosen to be significantly smaller than the line resistance. By the per se known Mismatch on the sending and receiving side results in a reduction in the time constant the conduction path, which results from the resistance of the conduction path, the two terminating resistors and the line capacitance, and thus also a reduction in the settling time achieved.

In this case, if the telegraph voltage remains the same, the slope becomes the increase in current at the line output is greater. The decrease in the steepness as it goes down the telegraph voltage can therefore be compensated for by reducing the settling time so that the telegraph distortion caused by interference voltages, the increase with decreasing slope, remain about the same size. By a reduction the telegraph voltage can now be known to cause crosstalk interference in neighboring Telephone channels, which increase with increasing telegraph speed, to allowable Values are reduced. If the telegraph speed is chosen so high that the fundamental frequency of the signal outside the frequency band of the telephone channels the telegraph voltage can be increased again. The insensitivity as a result, it becomes even greater in relation to interference voltages.

It is advantageous to the key circuit of the receiving device upstream bistable multivibrator whose control inputs are connected to the line and the outputs of which are connected via a common resistor, which in the input circuit of the pushbutton circuit is switched. The tilt stage remains during a step duration in the set position and at the same time amplifies the received small telegraph voltage, so that also less sensitive receiving key circuits can be used.

The invention is based on an embodiment shown in the figures explained in more detail. It shows F i g. 1 shows the course of the telegraphing currents in the known Transmission method, FIG. 2 the course of the telegraph currents during the procedure according to the invention and FIG. 3 the circuit arrangement for carrying out the method. F. i g. 1. shows the current in the transmitting location circle 11, the current at the output of the line 12 and the current in the receiving location circuit 13 in the conventional transmission method for Double stream telegraph characters. The current at the output of the line 12 oscillates during a step duration to the direct current value. The broken lines Ts and Zs characterize the response threshold of the receiving device.

F i g. 2 shows the current at the output of the line 12 in the case of the invention Procedure. With a step change from character stream Z to separating = stream T at the input the line increases the current at the output of the line from zero during the first Half of the step duration to a value that is above the threshold value Ts of the receiving device lies. During the second half of the step duration, the current then drops again Zero off. There is no voltage at the line input during this second half. The following step reversal leads to a current increase from zero to a value which is above the response threshold Zs. Line 13 of FIG. 2 shows that of the bistable receiving device delivered to the receiving location circuit.

The circuit arrangement for performing the method is shown in FIG. 3 from the transmitting device S, the ground-balanced line L and the receiving device E. The transmitting location circuit is formed by the wires a, b coming from the subscriber and the resistor R 1. The a-wire is connected via the capacitor C, the b-wire directly to the control inputs of an electronic relay with galvanic isolation between the transmitting location circuit and the line circuit. The RC element made up of resistor R 1 and capacitor C serves as a timing element.

The electronic relay is known per se and will therefore only be described briefly here. The alternating voltage generated by a square wave generator G with a frequency of 50 kHz, for example, is fed via the transformer U 1 to two modulators which are alternately blocked and opened by a transistor Ts or Ts2. The base electrode of the transistor is connected via the capacitor C to the a-wire and that of the transistor Ts 2 to the b-wire of the transmitting location circuit. Depending on the polarity of the telegraph voltage, only one of the two transistors is opened. The auxiliary alternating current passed on via one of the two transformers Ü 2 or Ü 3 is rectified by the diodes D 3, D 4 or D 1, D 2. One wire of the line is now connected via the resistor R 3 to the diodes D 3, D 4 and to a center tap of the transformer Ü 3 and to the other wire of the line L via the resistor R 2. The latter is connected in a corresponding manner via the resistor R 4 to the diodes D 1, D 2 and the center tap of the transformer U 2. The telegraph voltage to be transmitted, which can be in the order of magnitude of ± 1 V, for example, arises at the resistor R 2. The resistors R 3, R 4 and R 2 also contribute to the mismatching of the transmitting device S to the line L.

The line L controls a bistable multivibrator with the transistors Ts 3 and Ts 4, the base electrodes of which are each connected to a wire via a resistor. The outputs of the multivibrator, ie the collectors of the transistors Ts 3 and Ts 4, are connected to the series circuit of the resistors R 8 and R 7 via a resistor R 9 and R 11, respectively. The electronic relay of the receiving device is controlled via a resistor R 10 connected in parallel with this series circuit. A floating DC voltage source U is connected on the one hand to the common point of the resistors R 7, R 8 and on the other hand via a resistor network to the base and emitter electrodes of the transistors. The resistor R 10 is in the input circuit of the electronic relay with galvanic isolation between the input and output circuit. -TB or + TB is switched to the outgoing line via the transistors Ts5 and Ts6.

The mode of operation of this circuit arrangement can be seen from the following: The a-wire is initially positive compared to the b-wire (stop polarity). The direct current from the data transmitter flows through the resistor R 1. The capacitor C is charged to the voltage across the resistor R 1. Since the base electrodes of the transistors Tsl and Ts2 are negative with respect to the emitter electrodes, the transistors are blocked. The square-wave alternating voltage generated by the generator G is therefore not transmitted to the transformers U 2 and V 3, so that no current flows through the input resistor R 2 and the line L either. The bistable multivibrator of the receiving device E was previously set by a transmitted pulse with stop polarity so that the transistor Ts3 conducts. This state is maintained even when the line is de-energized. A current then flows in the following circuit: + U, R 8, R 9, collector-emitter path of the transistor Ts 3, R 6, R 5, - U.

Because of the voltage drop across resistor R 8, a current also flows through resistor R 10 and the input circuit of the electronic relay. The transistor Ts 5 is switched to the conductive state by this current. This transistor switches + TB into the receiving location circuit.

If the data transmitter sends out a character step with start polarity, the direction of the current is reversed in the sending location circle with a steep edge (a-wire negative compared to b-wire). The capacitor C therefore charges through the base-emitter resistor of the transistor Tsl and the base-emitter resistor of the transistor T92 or its base-emitter path and the resistor R 1, so that the transistor Ts2 becomes conductive. The length of time within which the transistor is in the conductive state depends essentially on the dimensioning of the resistor R 1 and the capacitor C. These components are dimensioned so that the opening time of the transistors is equal to half the step duration at the highest telegraph speed required. While the transistor Ts 2 is open, the square-wave alternating voltage generated by the generator G is transmitted via the transformers Ü 1 and ü 3. After rectification by the diodes D 1 and D 2, a direct current flows through the resistors R 4 and R 2, which due to the voltage drop across the resistor R 2, a pulse that rises according to the time constant of the entire line circuit on the receiving side and then falls back to zero Starting polarity. The receiving flip-flop is now reversed so that the transistor Ts 4 conducts while the transistor Ts 3 is blocked. The direction of current in resistor R 10 and in the input circuit of the electronic relay is reversed. The transistor Ts6 is switched to the conductive state, while the transistor Ts5 is switched to the blocked state. The conductive transistor switches -TB into the receiving location circuit.

The described double current pulse direct current telegraphy enables error-free digital transmission with high transmission speeds small telegraphic distortion. For example, when transmitting via unpupinized Twisted wires of city cables up to about 10 km in length Telegraph speeds of 40 kBd reachable. With appropriate training of the transmitting and receiving circuits even higher speeds can be achieved. The circuit arrangement for implementation The method is characterized by -the mismatching of the transmitting and receiving devices to the line, the short settling time achieved by the line circuit and because of the use of a balanced line due to insensitivity against strong interference voltages, for example from neighboring telephone lines with high-level call and high-level selection or high-level direct current telegraph lines be generated. The invention therefore uses simple means to provide a system that is immune to interference Subscriber line technology created, the advantages of which are particularly important for broadband connections, as required, for example, for high-speed data, facsimile and image transmission will come into their own. The proposed technique is of course included Advantage can also be used in a multi-channel time division multiplex transmission system.

Claims (7)

Claims: 1. Method for transmitting direct current telegraph characters with double current via galvanically connected lines, d u rc h marked, that with each step reversal the information of the following character step corresponding transmission voltage is applied to the line and after half the step duration is switched off again. 2. Circuit arrangement for carrying out the method according to claim 1, characterized in that the transmitting device (S) receives a direct current from the telegraph of the Sendeortskreises (I1) controlled timer is assigned, which the key circuit only switches to send status for half a step. 3. Circuit arrangement according to claim 2, characterized in that an RC element (R 1, C) is used, the capacitor of which is reloaded with each step reversal. 4th Circuit arrangement according to Claim 2, characterized in that the timing element is off two monostable multivibrators is built, the inputs of which to the subscriber line and whose outputs are connected to the pushbutton circuit. 5. Circuit arrangement according to claim 2, characterized in that the output resistance of the transmitting device (S) and the input resistance of the receiving device (E) are chosen to be much smaller are than the line resistance and that the line (L) is balanced to earth. 6. Circuit arrangement according to claim 2, characterized in that the key circuit of the receiving device (E) is preceded by a bistable multivibrator, the control inputs of which are connected to the line (L) and the outputs of which are connected via a common resistor (R 10) which is in the input circuit of the pushbutton circuit is switched. 7. Circuit arrangement according to claim 2 or 6, characterized in that an electronic relay with electrical isolation between input and and output circuit is used.