DE2736522C2 - Circuit arrangement for transmitting data - Google Patents

Description

The invention relates to a circuit arrangement for transmitting data from a data transmitter via a symmetrical line to a Data receiver in which the data signals assigned to the data are on the one hand on a capacitor and on the other hand, they are applied to the primary winding of a transformer, to the secondary winding of which the data signals assigned double-current signals without a direct current component are output to the line.

Various methods for transmitting data with the aid of double-current signals which have no direct current component are already known. Such a method is, for example, the diphase or split-phase method. When such signals are transmitted over lines, such as symmetrical local cables, the frequency spectrum ^{M of} the signals to be transmitted must be limited in order not to generate any interference signals on neighboring local cables. To limit the frequency spectrum, it is already known to provide blocking elements in the data transmitter that block the transmission signals when their repetition frequency exceeds a predetermined limit value on the local cables is avoided. It is also already known to provide a transformer for galvanic separation of the transmission arrangement from the line, with which a balancing takes place at the same time during the adaptation to the line. Since separate circuit parts are used in the known circuit arrangements for limiting the frequency spectrum of the transmission signals and for galvanic isolation and balancing, these circuit arrangements require a relatively large amount of effort.

From DE-OS 23 06 681 a circuit arrangement for transmitting data is known in which im Data transmitter, a transmitter is provided via which data signals are output to a line. the Data signals are present on a capacitor, which prevents the occurrence of steep edges of the data signals The data signals of the primary winding of the transformer are prevented via a matching resistor The transformer has a rectangular hysteresis loop and it outputs on its secondary winding signals to the line which correspond to the differentiated data signals. To eliminate the The transformer contains a total of three windings for high-frequency components in the frequency spectrum. These Windings require a relatively large amount of effort. In addition, the differentiating effect of the transformer not desired due to the rectangular hysteresis loop

The invention is therefore based on the object of a Specify circuit arrangement in which the limitation of the frequency spectrum of the transmission signals that galvanic separation of the line from the transmitter arrangement and the balancing when adapting to the Management takes place with particularly little effort

According to the invention, the object is achieved in the circuit arrangement of the type mentioned at the beginning solved that a further capacitor is arranged parallel to the secondary winding of the transformer together with the leakage inductances of the transformer and with the first capacitor a transmission-side Forms low pass

The circuit arrangement according to the present invention has the advantage that both for Limitation of the frequency spectrum, only one for galvanic isolation and for balancing Circuit part is required to form the low-pass filter for limiting the frequency spectrum no additional coils required. The size of the leakage inductance depends on several parameters, such as the core material, the winding arrangement, the geometric shape, the size of the Transformer and the air gap. The leakage inductances can be determined by suitable selection of these parameters Manufactured with sufficient size and accuracy. The leakage inductances form together with the capacitance of the capacitors with a π-element Low-pass character, its cutoff frequency and impedance due to the 5 ": reinductivities and the capacitances is fixed

The transformer is controlled in a particularly simple way when the connections of the primary winding of the transformer are connected to the outputs of switching elements that depend on the binary values the data signals can be switched alternately.

To protect the data transmitter against interference voltages that are transmitted via the line to the data transmitter reach, it is beneficial if the connections of the primary winding of the transformer with diodes are connected to a point at which a reference point tial

In the following, an embodiment of the invention will be explained with reference to FIGS. 1 to 3 described.

It shows

F i g. I a block diagram of the circuit arrangement to transfer data,

F i g. 2 timing diagrams of signals at different Points of the circuit arrangement, F i g. 3 is a circuit diagram of a data transmitter.

In the circuit arrangement shown in FIG. 1 for transmitting data, a data source DQ emits data signals Di to a coding CD . The encoder CD generates data signals D 2 encoded by means of clock pulses 7 * generated in a clock generator TG , encodes the data signals Dl, for example, according to the diphase or split phase method, which is also known as "directional clock script" or "priase encoding" and outputs coded data signals D 2 to a data transmitter SF. In the case of the data signals D 2 encoded according to this method, the binary value changes after a period of time which is equal to the period of the clock pulses 7 * or after a period of time which is equal to half the period of the clock pulses T. For example, a data bit 0 is assigned a change from binary value 1 to binary value 0 and data bit 1 is assigned a change from binary value 0 to binary value 1. It follows that between two identical data bits, a change in binary values opposite to these data bits must occur. Coding according to this method has the advantage that if the transmission signals D 3 emitted by the data transmitter SE to a line LE are designed as double-current signals, they do not contain any direct current component to be recovered.

The transmission signals DZ are transmitted from the data transmitter SE via the line LE to a receiver EM . The receiver EM outputs data signals DA to a decoder DC, which decodes the data signals D 4 and data signals DS assigned to the data signals D1. and outputs clock pulses T2 assigned to the clock pulses Ti to a data sink DS .

If the transmission signals D 3 are transmitted from the transmitter SE to the receiver EM via symmetrical local cables, it must be ensured that these transmission signals D 3 do not interfere with other signals on local cables, such as PCM signals and audio broadcast signals. For this purpose it is necessary to provide required in the transmitter SE a low pass filter that limits the frequency spectrum of the transmitted signals D 3 In order to achieve an electrical isolation of the line LE from the transmission-side devices, it is further desirable to provide a transformer in the data transmitter SE. With the help of this transformer, a balancing of the adaptation to the line LE is achieved if the transformer is dimensioned in such a way that its leakage inductances assume predetermined values. The transformer then forms, together with the capacitors, a jr element with a low-pass filter, the cut-off frequency and impedance of which can be set by the leakage inductance and the capacitance of the capacitors. With the help of the transformer and the capacitors, a limitation of the frequency spectrum of the transmission signals D3. reaches a galvanic separation of b. ~> line LE from the transmission side and a balancing means to adapt to the line

With the in F i g. In the time diagrams shown in FIG. 2, the time t is shown in the abscissa direction and the moment values of the signals are shown in the ordinate direction

The clock pulses Ti emitted by the clock generator 7TG are applied to a first input of the encoder CD . The data signals D1 output by the data source DQ , which have the binary value 0 or 1 at predetermined sampling times, if the data bits 0 or 1 are represented, are present at a second input. The predetermined sampling times are determined by the decaying edges of the clock pulse Tt. The encoder CD emits the encoded data signals D 2 at its output. If the data signal D1 has the binary value 0 at a sampling time, the coded data signal D 2 changes its binary value from 1 to 0. Correspondingly, the coded data signal D 2 changes its binary value from 0 to 1 if the data signal D1 has the binary value 1 at the sampling time If two identical data bits follow one another, each of which is assigned a change in the binary values in the same direction, a change in the opposite direction must take place between these changes. This means that the intervals between the changes are equal to the period 7 * of the clock pulses 7 * 1 or equal to half the period T / 2 of the clock pulses Ti 3 delivers to the line LE. As a result of the low-pass filter provided in the data transmitter DS , the frequency spectrum of the transmission signals D 3 is limited and, instead of digital signals, the data transmitter SE emits analog signals as transmission signals D 3.

The data receiver EM amplifies and limits the transmission signals DS and outputs data signals D 4 to the decoder DC , which on the one hand recovers the clock pulses T2 assigned to the clock pulses 7 "1 and on the other hand recovers the data signals D 5 assigned to the data signals Dl from the data signals D4 and sends them to the data sink DS

The in F i g. Data transmitter SE illustrated 3 includes a switching amplifier formed from two switching elements G 1 and G 2 with associated resistors R 1 and R 2, and einpm inverter N SV, a transmitter UE, two capacitors Cl and C2 and two diodes D 1 and D. 2 The encoded data signal D 2 is fed to the switching amplifier SV, which can also be designed as a differential amplifier. When the data signal D 2 assumes the binary value 1, the switching element G 3 assumes the binary value 0 at its output. If the switching element G 1 is provided with an open collector and the resistor R 1 represents the collector resistance of the output transistor, an output transistor provided in the switching element G 1 is turned on and a voltage of approximately 0 V is applied to the output of the switching element D 1. If the switching element G 2 is also provided with an output transistor with an open collector and the resistor R 2 represents the collector resistance, the output transistor is blocked as a result of the inverter N and the output of the switching element G 2 is a voltage that is equal to the positive supply voltage UB. In a corresponding manner, the output transistor in switching element G 1 is blocked and the output transistor in switching element G 2 is turned on when the encoded data signal D 2 assumes the binary value 0

According to the changes in the coded data

signals D 2 is produced at the outputs of the switching elements G 1 and G 2, an alternating voltage. This alternating voltage is applied to the primary winding of the transformer UE , to which a capacitor C I is connected in parallel. A capacitor C2 is also connected in parallel to the secondary winding of the transformer t / f and the line LE is also connected to the connection points of the capacitor Cl , to which the The data transmitter Sf emits the transmit signals D 3 assigned to the coded data signals D 2.

The transformer UE is represented by an equivalent circuit diagram which contains a mutual inductance M arranged in the shunt branch and two leakage inductances L 15 and L 2S arranged in the series branches. Assuming that the mutual inductance M is very large and thus has little effect, the capacitors CX and C2 and stray inductances LiS and L filters 25, a π-base member with a low-pass. The inductance of this low-pass filter is the sum of the stray inductances L ISund L 25 formed

By choosing the leakage inductances L 15 and L 25 and the capacities of the capacitors C 1 and C2 , the cut-off frequency and the impedance of the low-pass filter are determined.The leakage inductances L 15 and L 25 depend on several parameters, such as core material, winding arrangement, geometric shape, size of the transformer, air gap, etc. A suitable selection of these parameters can be defined with sufficient size and accuracy

Set leakage inductances L 15 and L2S so that, together with the capacities of the capacitors Cl and C2, the desired cut-off frequency and the desired impedance are achieved.

To protect the switching amplifier SV against glitches

To be able to protect, which are coupled on the line Lf and are switched forward via the transformer i / f, it is advantageous if the diodes D 1 and D 2 are provided, which limit the amplitudes of the interference peaks.

1 sheet of drawings

Claims (3)

Patent claims: 1.Circuit arrangement for transmitting data from a data transmitter via a symmetrical line to a data receiver, in which the data signals assigned to the data are applied on the one hand to a capacitor and on the other hand to the primary winding of a transformer, on whose secondary winding the double-current signals assigned to the data signals are output to the line without a direct current component are, characterized in that a further capacitor (C2) is arranged parallel to the secondary winding of the transformer (UE) , which together with the Streuindukti- is (LiS, L2S) of the transformer (UE) and with the first capacitor (Cl) a Forms low-pass filter on the transmission side 2. Circuit arrangement according to claim i, characterized in that the connections of the primary winding of the transformer (UE) are connected to the outputs of switching elements (Cl, G 2) which, depending on the binary values ("0", "1") of the Data signals (D 2) can be switched alternately. 3. Circuit arrangement according to claim 1 or claim 2, characterized in that the connections of the primary winding of the transformer (UE) are connected via diodes (Dl, D2) to a point at which a reference potential (0 V) is applied *>