HU192084B - Circuit arrangement for the transmission of digital informations through analog or digital channel of transmission - Google Patents

Abstract

The invention includes a transmitter and receiver circuit, a data source, a gated oscillator, a counter and a timer unit in the transmitter circuit having a counter and timer unit in the receiving circuit. The essence of the invention is that the output of the gated oscillator (1) on the transmitter circuit is connected to the clock input of the first counter (2), the output of the first counter (2) or one of its parallel outputs is connected to the input of the first timer unit (4), the output of which is connected to the input of the first counter (2) and to the gate input of the gated oscillator (I). The outputs of the data source (3) are connected to the parallel input of the first counter (2), the output of the gated oscillator (1) is connected to the input of the transmission channel (5), the output of which is to the input of the second counter (6) and the second timer unit (7). join. An output of this timer unit (7) is connected to the wiper input of the second counter (6), the parallel outputs of the second counter (6) are the data outputs of the receiver circuit, and the output of the second timer unit (7) is the "DATA VALID" output of the receiver circuit. -1-

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for transmitting digital information over an analog or digital transmission channel comprising a transmitter and receiver circuit, the transmitter circuit comprising a data source, a gate oscillator, a counting and timing unit, and a receiving circuit comprising a counting and timing unit.

There are many solutions or switches for transmitting digital information over an analog transmission channel.

Their functions are the conversion of the parallel digital signal into a serial one, since the signal can be transmitted on the analog channel, the modulation of a carrier frequency with the resulting serial signal and its adaptation to the transmission channel. On the receiving side, operation is reversed, that is, demodulation and then serial to parallel conversion. Reliable operation requires error protection, signaling, or correction codes to reduce interference on channel members.

The known solutions to this task generally aim at the rapid transmission of large amounts of data, but require a high quality transmission channel. Current equipment is microprocessor-based, and typical solutions, as well as principles and details, are described in Chapter 10 of the Texas Instruments Working Group: Introduction to Microprocessor Technology (1982 Technical Publisher). The description also shows that the system architecture is very complicated and cannot be used economically to transmit a very small number of control signals with high reliability over a noisy channel.

Since the basic issue of the transmission system is to reduce the likelihood of a faulty transmission, many solutions have been found. They operate in part on the analog portion of the sign, such as those described in I 169673. Hungarian Patent (Layout for Transmission of Coded Information), which, in the case of a variable level, seeks to ensure correct operation by controlling the level of comparison. For these reasons, these solutions only solve a partial task, do not protect against the receipt of false bits, and only prevent over-control.

Another part of the solutions relates to the coding process. Such as 2532915 C2. US Patent (Switching Arrangement for Interference Protection between Data Transmitter and Receiver) which achieves the desired effect by a complex logical relationship between the parity bit, error protection, and error correction bits added to the signal. 2942998 C2 Ins. In the case of the German Patent (Error Recognition and Repair Arrangement) solution, Haming code is used for data protection and this is supplemented with additional error protection bits.

The latter two solutions result in a complicated structure which is economical only when transferring large amounts of data, but cannot be flexibly applied to a given transmission channel.

Each solution also requires keeping the carrier frequency very accurate.

SUMMARY OF THE INVENTION It is an object of the present invention to eliminate the aforementioned disadvantages, i.e., to provide a transmission device capable of transmitting digital information which provides a significantly higher level of transmission noise protection compared to known switching arrangements. and at the same time its structure is simple.

The invention is based on the recognition that when information is assigned to certain binary local values of a pulse number of a transmitted pulse packet, it is very simple to encode and decode! method is used, the protection of individual bits increases with increasing local value and transmission and reception do not require high frequency stability.

The object of the present invention is that the output of the gate oscillator in the transmitter circuit according to the invention is connected to the input of the first counter clock, the output of the first counter transmission or one of its parallel output to the input of the first timer. connected to the gate input of the gated oscillator, the outputs of the data source are connected to the parallel input of the first counter, an output of the gated oscillator is connected to the input of the transmission channel whose output is connected to the input of the second counter and second timing unit the second counter wiper input is connected to the second counter parallel outputs, the receiver circuit data outputs, and the second timer unit output is the receiver circuit DATA output,

According to one embodiment of the invention, the parallel outputs of the second counter are connected to the data inputs of the rain storage, the output of the second timer unit is connected to the recording input of the first storage and the output of the first circuit is connected.

The circuit may also be configured so that the outputs of the first storage are connected to a second storage input, a digital comparator coupled between the output of the second storage and the output of the receiving circuit, the first storage input and outputs of said second storage unit; the output of the second timer unit is connected to the recording input of the second container. Another possibility for the circuit according to the invention is to connect the parallel outputs of the second counter to the counting input of the fourth counters and the output of the second timing unit to the clock input of the fourth counters.

The invention may also be implemented by connecting the output of the first counter transmission or one of its parallel outputs or the output of the first timer unit to the input of the third counter, one of the outputs of the third counter being connected to one of the gate inputs of the gated oscillator.

In another embodiment, the output of the data source is connected to a data input of the first counter via an encoding circuit and / or a decoding circuit is connected between the parallel outputs of the second counter and the output of the receiving circuit.

Advantageously, the circuit according to the invention can be designed such that between the output of the gate oscillator and the input of the transmission channel, an amplifier and / or

A shaping and / or filter and / or transformer is mounted.

In another preferred embodiment, a filter and / or signal generator and / or amplifier and / or transformer is coupled between the transmission channel output and the second counter input.

Some preferred embodiments of the circuit arrangement of the present invention will be described in detail with reference to the drawings, in which:

Figure 1 is a block diagram of an embodiment of the circuit arrangement according to the invention, a

192 084

Figure 2 shows a practical implementation of the receiver circuit, a

Figure 3 shows another practical implementation of the receiving circuit, a

Figure 4 illustrates a third practical implementation of the receiver circuit, i

Figure 5 illustrates a practical implementation of the tax circuit, a

Figure 6 shows a more detailed drawing of a circuit arrangement according to the invention in practice, a

Figure 7 illustrates another embodiment of the circuit arrangement according to the invention in more detail.

In the arrangement shown in Figure 1, the gate oscillator 1 provides a digital pulse sequence which is input to the first counter. Are the first 2 counters - preferably built from backward counters? - at the beginning of the counting, it contains the N binary number entered from the 3 data sources, whose binary local value bits represent the transmitted information. When N pulses from the gate oscillator 1 are received in the counter 2, they are set to 0 and signaled at the output of the transmission. This pulse initiates the first timing circuit 4 which stops the gate oscillator 1 for a set time T and re-writes the data source 3 into the first counter 2. After T, the process is hardened again.

According to the operation described above, packets containing N pulses are displayed on the output and carry the information. Through the transmission channel 5, the parallel information is restored as follows. The second counter 6 counts the incoming pulses, and the second timing circuit 7 monitors when the pulse stream stops. In this case, the output of the counter 6 just displays the n "binary number set on the transmitter side, and this is indicated by the appearance of a so-called DATA VALUE '' at the output point of the timing circuit 7, indicating that the counter 6 output is valid. In this case, the output lines contain input information from the 3 spinning data.

As the transmission channels 5 may be noisy and linear distortion may occur, information protection is needed. This solution can be done very simply and flexibly, such that the entered N number contains information only at higher binary local values, and contains lower bits of security bits, the change of which during transmission does not affect the actual information content, thus acting as an error correction code. .

FIG. 2 illustrates a possible embodiment of the receiving circuit. In this solution, the outputs of the second counter 6 are led to the first storage input 8, the input of which is a DATA valid output of the second timing circuit 7, such that, as described above, the transmitted information is written to the first storage 8 output can be found.

3, the digital comparator 18 compares the data at the inputs and outputs of the first storage 8 with the receiver circuit shown in FIG. Because the outputs contain data from the previous cycle, the inputs contain data from the running cycle, the comparator will only provide a signal if the same data has been received in two consecutive cycles. In this case, the commander 18 allows data to be written to the second storage 10 via the timing circuit 7.

In the embodiment of the receiver circuit shown in Fig. 4, the outputs of the second counter 6 are individually led to the fourth counters 9, which, depending on the state of the outputs of the second counter 6, are either counted or canceled by a pulse from the second timer 7. Data is output to each output of the fourth counter 9 only if the transmission was correct in at least K consecutive cycles corresponding to that output.

5, a third counter 12 is used, the input of which is the output signal of the first counter 2 or the first timer circuit 4. The third counter 12, depending on its configuration, gives an erase signal to the gated oscillator 1 after the 'η''incoming pulse, so that, by a control signal, it emits the same pulse packet of' ₉ . Figure 6 shows a detailed version of a circuit arrangement according to the invention. It operates as follows: A circuit arrangement consisting of a gate oscillator 1, a first counter 2, a data source 3, and a first timing circuit 4 operates as previously described. That]. The pulse packets produced from the gated oscillator according to the data source 3 are transmitted to the amplifier and signal generator 141, and then to the bandpass filter 142, whose center frequency corresponds to the frequency of the gated oscillator 1. From its output, the signal is transmitted to the isolating transformer 143, which transmits it to the transmission channel 5 (e.g., telephone line). On the receiving side, the signal packet is transmitted to the gate current 16 via the isolation transformer 143, a bandpass filter 142 '(which filters out unwanted interference, and information transmitted at different frequencies on the same channel) and an amplifier and signal former 141'. The function of this is to prevent further interference to the input signals at the beginning of the signal loss detected by the second timing circuit 7 during the period defined by the third timing circuit 17 '. The pass-through signal is counted by the second counter 6 so that, according to the operation described above, after the complete signal packet has been received, its parallel output has the signal of the data source 3. This is written to the first memory 8 by the input signal of the second timing circuit 7 and simultaneously the second counter 6 is cleared. The digital comparator 18 compares the output and input data of the first storage 8, which corresponds to the pulse number of the last two signal packets, and, if the two values are equal, detects the transmission to be flawless and enables the second timer 7 to enter data 10 containers connected to the output. It can thus be seen that in this circuit solution the signal arrives at the output if and only if the number of pulses transmitted is at least twice in succession. Another protection here is to extract very small bits of local value from the data transmission and thus allow a very high level of security by allowing the transmission rate.

An expanded version of the basic layout is also shown in Figure 7. Here's how it works differently than before.

Encoder 11 encodes the signal of the data source, thereby increasing transmission error protection. Preferably Apply-31

192-084 works for example on command transmissions where there is no arbitrary combination on the input (there can be ON and K1 commands at the same time) and encoding can take advantage of the ratio of transmitted bits to 'meaningful' combinations in g. The addition of the third counter 12 also serves to reliably transmit command information. The purpose of this is to ensure that the number of transmitted pulse packets is a preset value even when transmitting brief information. On the receiving side, however, by inserting the decoder 10 13, the original information can be restored and the counters 9 output only when the second timer 7, which gives a clock after each pulse packet has received a pulse corresponding to the preset number, while the information on their enabling input remains unchanged. If this changes: counter 9 is set to θ and counting begins live, so that the transmission of a command information is subject to providing the same decoded information from at least the number K of the pulse packets set on the third counter 12 at least on the fourth counters 9. This way the probability of issuing a false command is negligibly low, but it can only occur on a very noisy channel that information is not received. Because the values of n and K can be easily changed, the system flexibly adapts to different transmission channels.

The circuit arrangement of the present invention provides a very high degree of protection for transmitting digital information over a noisy analog channel. The simple encoding-decoding method 30 provides a simple structure, which at the same time flexibly adapts to the quality of the channel. Higher-priority signals provide greater protection and do not require high frequency stability.

Claims (8)

Claims A circuit arrangement for transmitting digital information on an analog or digital transmission channel comprising a transmitter and receiver circuit, the transmitter circuit comprising a data source, a gated oscillator, a counting and timing unit, the receiving circuit comprising a counting and timing unit. the output of the gate oscillator (1) is connected to the clock input of a first counter (2), the transmission output of one of the first counter (2) or one of its parallel outputs is connected to the input of the first timer unit (4). connected to the gateway input of the gated oscillator (1), the outputs of the data source (3) are connected to the parallel input of the first counter (2), one output of the gated oscillator (1) is connected to the input of the transmission channel (5). to the input of the second counter (6) and the second timing unit (7) cs an output of this timing unit (7) is coupled to the wipe input of the second counter (6), the parallel outputs of the second counter (6) are the data outputs of the receiver circuit and the output of the second timer unit (7) is the VALUE output of the receiver circuit. Circuit arrangement according to claim 1, characterized in that the parallel outputs of the second counter (6) are connected to the data inputs of the first storage (8), the output of the second timing unit (7) being connected to the recording input of the first storage (8). the output of the first storage (8) is the output of the receiver circuit. The switching arrangement according to claim 2, characterized in that the outputs of the first storage (8) are connected to a second storage (10) input, the output of the second storage (10) between the output of the receiving circuit, the input and outputs of the first storage (8). a digital comparator (18) connected, the output of the comparator (18) being connected to the gate input of the second timer unit (7), the output of the second timer unit (7) being connected to the recording input of the second storage unit (10). Circuit arrangement according to claim 1, characterized in that the parallel outputs of the second counter (6) are connected to the count enable input of the fourth counters (9) and the output of the second timer unit (7) is connected to the clock input of the fourth counters (9). . 5. Circuit arrangement according to any one of claims 1 to 3, characterized in that the transmission output of the first counter (2) or the output of the first timing unit (4) is connected to the input of the third counter (12), one of the outputs of the third counter (12) (1) is connected to one of the gate inputs. 6. Circuit arrangement according to any one of claims 1 to 4, characterized in that the output of the data source (3) is connected via a coding circuit (11) to the data input of the first counter (2) and between the parallel outputs of the second counter (6) and the output on. 7. A circuit arrangement according to any one of claims 1 to 3, characterized in that an amplifier and signal generator (141) and a bandpass filter (142) and a separator transformer (143) are connected between the output of the gated oscillator (1) and the input of the transmission channel (5). 8. A circuit arrangement according to any one of claims 1 to 3, characterized in that a bandpass filter (142 ') and an amplifier and signal generator (14Γ) and a separator transformer (143') are coupled between the output of the transmission channel (5) and the input of the second counter (6).