DE1295593B - Method and circuit arrangement for digital message transmission with synchronization by level, frequency or phase changes and additional synchronous pulses - Google Patents

Description

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The invention relates to a method and a before, over longer periods of time, for. B. over several bit circuitry for digital message transmission over periods or entire character periods with synchronization by level and frequency feed, whether monotony and thus danger for the or there is a phase change and additional synchronization. In both cases will be impulses which are inserted at the sending end if 5 consecutive bits or bit groups do not have in the case of monotonous sequences of transmitted equivalents, changes in bit value are counted and when they are reached In terms of bits, the receiver's synchronization with a critical count value does not lead to the insertion of security can be sustained. additional synchronous pulses with changing bit

Initiated during synchronization by level and frequency values.

or phase change, the synchronism between io It has emerged in communication systems, transmitters and receivers through the level, frequency and the synchronization under consideration through bit or phase changes, which each work peri change, that the danger for which take place odically at certain times in the course of synchronous operation between sender and receiver in the case of transmitted messages. The timer for missing bit changes increases continuously. If the receiver occurs, a period with frequent changes then occurs again, essentially independently, from the transmitter's timer, but is always proportional to the level, frequency or phase change of the frequency of changes that occur with each received level, frequency or phase change again improved with the time of such. It is therefore compared to the better utilization of the change and geared towards this. In the case of message channels used, it may be useful to use an association transmission in which the use of all 20 drives, in which bits or coded combinations in any character sequence are not limited to bit groups without a change and are counted as permissible, it can result that be used for long mono criterion, but continuous dubbing sequences of only zero or one bits of the ratio of the number of characters transmitted to the number of synchronism between transmitter and receiver not the synchronizing bit change is guaranteed to be more secure. It is therefore advisable to avoid excessively long monotonous sequences and to use additional synchronous pulses as a criterion for inserting
without diminishing the freedom of coding. This object is achieved according to the invention

According to the known prior art, at least one additional synchronous pulse is solved Such synchronization difficulties will be inserted by forcibly on the transmit side when the ratio of the Periodic insertion of synchronization characters 30 Number of characters transmitted to the number of level, Fixed. This is known, for example, from a predetermined frequency or phase change German patents 1199314, 1202310, which exceeds the critical value.

British patent specification 738 587 as well as the German The advantages achieved with the invention exist

Auslegeschriften 1193 086, 1212146, 1214 727. in particular that instead of a periodic What they all have in common is that with a compulsory fade-in of synchronous pulses or a single-period inserted sync characters a phrase after a predetermined number of bits Considerable time requirement within the entire trailing or character without level, frequency or phase direction transmission occupied, so the Ubertra- change the synchronization impulse insertion only then efficiency is reduced. occurs when the ratio of the number of transmitted

According to the German patent specification 1190504, 4 ° NEN characters for the number of changes are a predetermined one exceeds the critical value in the idle interval between two messages. This means, Transmit clock signals. According to the German expressed reciprocally, if the ratio of the In patent specification 1192 239, filler characters are constantly changing per sum of the characters a critical one transmitted which falls below the actual post-value.

Directional transmission in each case by information or 45 Thus, the method according to the invention allows Check bits are to be replaced. Both of these methods involve a higher throughput of messages in common that with long, monotonous signal the bits and characters in the time unit, i. h., the follow within one and the same message as- transmission efficiency is compared to the after Therefore synchronization difficulties can occur. other fade-in through-holes known in the prior art the German Auslegeschrift 1173 932 it is 50 training procedures increased.

known, simultaneously with the phase-modulated circuit arrangement for the detection of

Message signal sequence through additional amplitude synchronization promoting bit change signals as well modulation to transmit clock signals. For high their use in one of the invention Transmission speeds is the circuit arrangement corresponding to the amplitude method modulation, however, is hardly applicable. Another 55 ongoing monitoring of the ratio of the number Procedure is the Austrian patent specification of the characters transferred to the number of level, Fre-250 444 can be found. In the case of monotonous frequency or phase changes, this is followed by a few more Sequences of zero or one characters in an embodiment are specified in the subclaims. Recoding in alternating characters proposed, An embodiment of the invention is in the

which is represented in the receiver by a corresponding drawing and is explained in more detail below Recoding is reversed. This should be described.

A considerable technical effort may be required. The message signals to be transmitted will be

and also, as indicated, in borderline cases one is fed to a delay circuit DEL. Occur on text falsification. Output N of the delay circuit DEL are available

The object of an older invention is to reduce the 65 message signals by approximately one bit period Length of critical, monotonous strings available from delayed. A signal TO is thereby the number of successive bits of the same value - used as a clock pulse, the delay function ability to be determined. Another invention suggests steering. The instant message signals from

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Input JV + 1 of the delay circuit DEL so this arrives at an input of an OR switch such as the delayed message signals from the output OO, which in turn emits a signal via its output line output JV to an input of an antivalence WZO indicating that the booth circuit EXO supplied. This gives in the cycle of one of the first counter WZ is not equal to zero. This bit-periodic clock signal T1 at each change of state depends on the number of bit changes during the bit value from zero to one or from one from the previous character string. Thereby after zero at their output W an alternating signal relieve characters with several alternations such in from. These alternating signals are transmitted over a gate whose course no change occurs.
Circuit AA and an OR circuit OW open . The output of the OR circuit OO is connected to the input of a first binary counter WZ io, an input of a gate circuit AB . The individual counting stages W1, W 2 and W 4, whose other input at the beginning of each 8-bit character of this first counter WZ, are by means of which a pulse is supplied via a line TBZ. AND circuits + Al and + Al by a time The on- signal Bitl ... Bit 8ITl is connected to the output of the gate circuit AB during the cycle times of the input of an interlocking circuit FL. Clock signal Tl is controlled adding and carry 15 This latch circuit FL is thus moderately connected to each other for all. Thus, this adds the characters switched on, 2ü the beginning of which the first first counter WZ contains all of the non-equivalence circuit counter WZ not equal to zero. The EXO output recognized change on. This addition is fed to the latch circuit FL , however, by means of a logic circuit L1, through a gate circuit Λ16. On the borders. Outputs of the counting stages Wl and W 4, 20 are the second input of this gate circuit A 16 are fed via lines 2 and 4 to the inputs of the AND via an OR circuit Ol during each switch-on A 6 of the logic circuit Ll . Two pulses each are supplied to individual bits, a first one. The AND circuit A 6 is connected directly to an inverter pulse at the bit cycle time Γ 3 via the bit 1 ... / 6 line. Thus, the logic circuit Ll Bit8 / T3 and a second at the bit clock time TA from an output signal for as long as the first 35 the line Bitl ... BitSJT4. The gate circuit A 16 counter WZ is not yet at 6. M = 16 pulses are transmitted via one, if at the beginning of the line 5 this output signal is fed to a character relating to the input, the reading of the first counter of the aforementioned gate circuit AA. work tool is not zero. The gate circuit AA thus allows alternating signals to the reset line TEZ of the interlocking switch from the output of the antivalence circuit EXO only 30 device FL, via which for each individual character long to add to the first counter WZ after the end of the 16th pulse in through the last, eighth bit, as this has not yet cleared the counter reading of the interlocking circuit FL , has reached "six". This gives the advantage that the M = 16 pulses are transmitted via the first input so that the first counter WZ can have a limited length of the OR circuit OV to the input of the second without an overflow and thus an additional counter VZ . This is to be expected from the unrelated difficulties. switched output of the interlock circuit FL

In the selected example, an 8-bit code was applied to the circuits -Bl, -Bl, -B4 ... Subtractive to be transferred via a gate circuit AN by means of the AND-bearing message characters. Controls during the first bit at clock time T4 , but only if its own counter is the additive control of the first counter WZ 40, recognized via a logic circuit L 2, suspended. In their place comes a non-zero subtractive. Below zero is no subtraction possible in the second control by means of the AND circuits —Al counter VZ , because with and —Al by a time signal bit VT 4. While counter reading zero, the gate circuit, 4JV is blocked, this subtractive control time is on the input At this point, the control of the first counter WZ above a pulse via the clock 45 called gate circuit AS is explained, which the line UIZ, the gate subtraction pulses to be described in more detail on the first counter WZ only circuit AS and the OR circuit OW allows an im to happen when the second counter VZ is not given a pulse. This pulse arrives once for every zero and also at the beginning of the relevant character on the input of the first counter WZ. Character the status of the first counter WZ itself. It reduces the added number of 50 which is not equal to zero. This condition is increased by one by the alternating signals (a maximum of six). As this gate circuit AB, the latch circuit FL is avoided subtraction below zero, and the gate circuit is ON formed and applied to the later-gate circuit when considering the AS control input of the gate circuit AS,
explained. Outputs from counting levels of the second counter

The same pulse via the 55 VZ shown twice, in the selected example the outputs of the number line UlZ, the for each transmitted character, such as levels V 32 and V 64, are already mentioned by means of the inputs 32, subtractively once the first count and 64 of the AND circuit AX summarized, work WZ is supplied, passes via an OR. As soon as the critical counter circuit OV in the second counter VZ reaches the input of a second count 32 + 64 = 96, the AND works VZ, which at this time by means of the AND 60 circuit AX via its output X = 96 a signal circuits + Bl, + Bl, + B 4 ... through the same. This is the signal that is additively controlled the insertion of impulses via the line UlZ. Additional synchronous impulses not shown here. On the other hand, the input of this second posed way in the train of the post-counter VZ to be transmitted, but depending on the status of the directional sign, is initiated. This signal from the first counter WZ is also influenced. As long as 65 is used by the output of the AND circuit AX to contain the first counter WZ not equal to zero and a reset pulse via the reset line R thus at least one of the counting stages Wl, Wl, W 4 is switched on for all stages of the second counter VZ , their output emits a signal. win.

Finally, the functional conditions of the circuit arrangement are summarized again:

Every change in the serial message flow recognized by the exclusive circuit EXO is added up in the first counter WZ , but only up to a counter reading of a maximum of six.

For each character transmitted, at the beginning of which the reading of the first counter WZ is not zero, a one is also subtracted from the reading of the first counter WZ , provided, however, that the second counter VZ is not at zero either.

In the second counter VZ , a one is added for each character.

In the second counter VZ , on the other hand, a sixteen is subtracted if the status of the first counter WZ is not equal to zero at the beginning of the relevant character, but only until the second counter VZ possibly reaches zero.

When the second counter VZ reaches the predetermined critical level during counting, the signal to insert the additional synchronous pulses is given and at the same time the entire second counter FZ is deleted.

In the example chosen, this critical state is given by 96 characters without a bit change, whereby it is assumed that a bit change ensures synchronization for a maximum of 16 characters.

Claims (8)

Patent claims: 1. Method for digital message transmission with synchronization by level, frequency or phase changes and additional synchronous pulses, which are inserted at the transmitting end if the synchronism of the Recipient cannot be maintained with certainty, characterized in that that at least one additional synchronous pulse is inserted at the transmitting end if the ratio the number of characters transmitted to the number of level, frequency or phase changes exceeds a predetermined critical value. 2. Circuit arrangement for performing the method according spoke 1, characterized in that a delay circuit (DEL) is provided, the input (N + 1) and the output (N) are each connected to an input of an exclusive OR circuit (EXO) , which always then emits a change signal at its output (W) if a change occurs in the course of the transmitted bits. 3. A circuit arrangement for carrying out the method according to claim 1, characterized in that a first counter (WZ) is provided for counting the changes, the input of which on the one hand an alternating signal is added additively for each change and the input of which a pulse is fed subtractively on the other hand, if, due to the existing bit change, the content of a second counter (VZ) is correspondingly reduced so that the second counter (VZ) is provided to determine the ratio of characters to changes, the input of which is supplied with an additive pulse on the one hand for each character transmitted and on the other hand the input of this second counter (VZ) is fed a predetermined number of pulses subtractively for each character if the counter reading of the first counter (WZ) is greater than zero at the beginning of the respective character. 4. Circuit arrangement according to claim 3, characterized in that in front of the input of the first counter (WZ) a gate circuit (AA) is inserted which is controlled via its second input of at least one output of the first counter (WZ) in such a way that it only lets through signals to be added when the count of the first counter (WZ) is below a predetermined limit value. 5. Circuit arrangement according to claim 3 or 4, characterized in that in front of the control input of the second counter (VZ) for subtraction . tion control a gate circuit (AN) is provided, which is controlled via its second input by the outputs of the counting stages (Vl, Vl, V4 ... F 64) of the second counter (VZ) in such a way that a subtraction in the second counter ( VZ) only takes place if its counter reading is greater than zero, thus avoiding a reduction in the counter reading below zero. 6. Circuit arrangement according to one of claims 3 to 5, characterized in that the pulse supplied to the first counter (WZ) subtractively for each character transmitted is passed via a gate circuit (AS) which is only open when the counts of both Counters (WZ and VZ) is greater than zero. 7. Circuit arrangement according to one of claims 3 to 6, characterized in that an output or, combined via an AND circuit (AX) , several outputs of the second counter (VZ) is used to issue a control command to insert at least one additional synchronous pulse / will. 8. Circuit arrangement according to claim 7, characterized in that a reset pulse for the second counter (VZ) is derived from the control command for inserting at least one additional synchronous pulse. 1 sheet of drawings