DE1487078C - Method and circuit arrangement for increasing the efficiency of the message flow in telegraphy transmission systems - Google Patents

Description

3 4

Test time lying symmetrically in the middle of the step by means of current steps. If this ratio is met, then a step edge evaluates these steps, the code check evaluates the character as correct, is blocked when the code checking device on The new method is also suitable for reconciliation of the redundancy of the transmission system ARK). With these systems, codes that have occurred step falsifications are either recognized as incorrect characters and that when a certain level is exceeded they are either structured or as a "smear character" combination from the ideal step center symmetrically located test printed. The reconstruction and the missed character time by means of a step edge, the evaluation of this imprint depend on the Hamming distance d of the use step is released when the code checking devices depend on codes. With a code distance d = 2 , due to the redundancy of the used io one would do without a reconstruction of the disturbed characters, codes the step corruptions that have occurred, ie characters that do not recognize the code conditions, and dispense with odd numbers. Step-

The basic idea behind the solution is that faults print a "smear mark". In the case of a controlled step check on the reception of a code distance of d = 3, the single start page of those error messages are avoided. That is why the code check will identify the entity. The type of transmission system codes with the starting step test marks so only the time d = 4 applied. In the case of such a code, the number of distorted steps becomes characters in which a single step, if disturbed, could lead to undetectable errors. It is correct and signs in which three steps remain thus the step test is ineffective as long as disturbances are incorrectly reconstructed. If two steps one or more disturbed steps are disturbed by the code of a character, a »smear test will be recognized. This is used to print out the ARQ character combination. As a result, the efficiency of the message flow is expressed to systems, so that a reconstruction would improve, or if the transmitted message flow was not sufficiently reliable, the security against characters would result.

Falsifications by increasing the test time. The step test controlled according to the invention

increases. In the case of ARK systems, the imprint is incorrectly prevented to a large extent, the imprint is incorrectly recon-

reconstructed and forged characters largely structured and forged characters. The step test

prevented. 30 remains out of operation as long as the disturbed

According to the previously known method, each little is correctly reconstructed or as a "smear mark" Characters rated as disturbed if printed within the. All other malfunctions The step test addressed whether the step was within a character the code check recognizes this character as under review and causes a faulty character status correctly rated. 35 imprint. For an ARK system with a code

If the code conditions for a character whose code spacing is d = 4, a character

met, but the step test determines that the calculation in which three or more steps are distorted

Distortions of the steps occur, so are printed out with a certain combination of smear marks. Through

Probability of expecting fake characters. the controlled step test is reduced at

In this case, the step test is released. 40 ARQ systems run the risk of incorrectly reconstructed

With the help of the method according to the invention, characters can be received in a distorted manner,

every character can be evaluated, the code details of the invention are based on the

conditions is sufficient and in which so many steps are available. 1, 2 and 3, which are an advantageous embodiment

are distorted that it is explained by the redundancy of the code example show.

can still be identified as forged with certainty 45 F i g. 1 shows the principle of operation of a

can. Step test (element test);

In ARQ systems, with the aid of the invention F i g. 2 shows the block diagram of the controlled according to controlled step test only then a step test according to the invention, and repeating disturbed character if its steps F i g. 3 shows the controlled step test by hand received distorted, although the character is the 5 ° of a table in which the occurrence of an error code conditions Fulfills. In the case of a transmission message, depending on the number of the versystem with securing the characters by a dragged step of a character is entered. additional parity step is, for example, each Fig. 1 shows on the basis of a time diagram the odd number of disturbed steps within the basic mode of operation of the step check (eleeines Character recognized by the code check. 55 ment test). In Fig. Ib is the output of the The step check does not work here. All time receivers are shown. It is a low frequency one with an even number of disturbed steps telegraph signal and consists of seven steps, The code check would be correctly assessed as a separation stream step 1, a character stream. In this case the disturbance is caused by step 2, two separating current steps 3, 4 etc. In Step test determined and a repetition 60 F i g. 1c is the timeline, which is divided into a number of of the falsified character from the transmission memory on - time intervals equal to the duration of a step under-demanded, divides is shown. The beginning of every undistorted

When using an equivalent code, step coincides with a point in time i ₀ . The code check by monitoring the t of the steps is in the time interval between the ratio of the steps of one polarity and the times ^ ₁ and t.,. In Fig. La is effected by the steps of the other polarity, z. B. 7-hatched areas show a schematic picture of the We Code (CCIT No. 3) 3: 4 ratio, ie, each way of drawing the step test is shown. The width consists of three separating current and four characters and the position of the surfaces indicate the time intervals,

in which the step check is effective. To be safe Evaluation can be arranged at the same time as the step test, a threshold level circuit, see above that the step test only responds when the level of a telegraphic step crosses the threshold level. The height of the hatched areas in FIG. 1 a indicates a threshold level interval.

In the case of telegraphy step 6, both the level monitoring and the step monitoring in the time interval I ₁ to i ₂ respond. Because a certain distortion value has been exceeded, a repetition of the last characters is requested from the sender in ARQ systems, while in ARK systems this character is not reconstructed but printed out as a "smear" combination.

2 shows the arrangement according to the invention for controlling the step test in a block diagram. The bistable trigger circuit K3 and the gate circuits G3, GA, GS are required to carry out the method according to the invention. With the bistable flip-flop Kl , the time segment t _t to i _{2 is} formed, which lies in the symmetrical to the ideal center of the telegraphy steps. The flip-flops Kl to K3 have two stable positions and are overturned when a bias voltage and a control pulse are present at the same time. The control pulses are applied to the lines marked with an arrow, which lead to the control inputs of the multivibrator. The mixing gates Gl and GI get from the clock supply TV pulses which are applied to the flip-flop Kl at the two bias inputs. The clock supply TV generates the clock and distributor pulses required to carry out the transmission, for which purpose the oscillator frequency of a vibration generator is divided with frequency dividers. At the control input ST of the flip-flop there are pulses that are also derived from the clock supply TV . The flip-flop Kl remains in the stable position I for the period from J ₁ to t ₂ (FIG. 1 a) and outputs a bias voltage to the flip-flop K2 for this period of time. The flip-flop circuit K2 flips into the rest position I at the end of a character. This is achieved by the end-of-character pulse ZE , which is applied to the control input for position I and, after the end of each character, which consists of several steps, flips the flip-flop K2 back into the initial position I. ; the end-of-character pulse is derived from the distribution cycle. The edges of the telegraphy steps TS are at the control input for the stable position II of the toggle switch Kl. If a tendril of a telegraphic step falls in the period in which the flip-flop Kl issues a bias voltage to the flip-flop Kl , the stage Kl flips into working position II and remains in this position until the end of a telegraphic character. Only at the end of the character is it reset by the end-of-character pulse ZE. At the same time, an error signal is emitted from working position II at the output of the flip-flop, which signals the distortion that has occurred. This last-described operational case occurs in telegraphy step 6 in FIG. 1 on.

However, the method according to the invention controls the output of this error signal, specifically with the aid of the toggle switch K 3. The step check is controlled as a function of the code conditions. If, for example, in a transmission system, each character is secured by an additional parity step, then every odd number of disrupted steps within a character is recognized by the code check. According to the invention, the step check should not come into action here. All telegraph characters with an even number of disturbed steps, on the other hand, would pass the code check undetected. In this case, the malfunction should be detected and signaled by the step test. This task is solved by the K3 flip-flop, the three

ίο has control inputs. In the idle state, the flip-flop is in position I, which is forced at the end of a telegraphic character by the end-of-character pulse ZE. Via gates G 3 and G 4, the two bias inputs of flip-flop obtain a preparation voltage of the flip-flop Kl. During the period of I ₁ to f ₂ (Fig. 1) receives the flip-flop Kl bias, so that each step edge which in this period falls, the toggle switch tips over. While the flip-flop Kl only flips over when the first edge of a distorted step occurs, the flip-flop K 3 is toggled back and forth in time with the incoming distorted step flanks. Since the flip-flop K3 acts as a divider, a voltage can be taken from one output if the number of distorted telegraphy steps is even and at the other output if the number of distorted telegraphy steps is odd. If the flip-flop K1 is in position II and the flip-flop K 3 is in position I, the gate G 5 emits an output pulse to the error display device FA . At the end of the telegraphic character, both flip-flops Kl and K 3 are returned to the rest position by the end-of-character pulse ZE.

The in F i g. The circuit arrangement described 2 is also suitable for transmission with a balanced code, e.g. B. 7 code with the 3: 4 condition of the individual characters that are monitored by the code check.

F i g. 3 shows the mode of operation of the method according to the invention on the basis of the output signals at the components according to FIG. 2. The first column on the left contains the number of distorted steps (TS) within a telegraph character. Column 2 contains the output voltage of the flip-flop Kl at the output II. If a voltage occurs at the output II of the flip-flop Kl , this corresponds to the binary state "1", while the absence of the voltage at the output II is due to the binary symbol

so "0" is shown. Column 3 shows the output voltage of the multivibrator K 3 at output I as a function of the number of distorted steps of a character. Column 4 shows the voltage output by the gate G 5, which is created by the logical combination of the two outputs of the flip-flop circuits K1 and K3 . The gate G 3 supplies this voltage to the error display device FA, which emits an error signal F (column 5) and thus identifies the incorrect character. As shown in FIG. 3 can be seen, with the code used here, an error signal F is emitted whenever two, four or six steps of a character have exceeded a certain adjustable distortion.

The method according to the invention can be used wherever telegraphic signs be transmitted in coded form, with a step check being carried out on the receiving side, which is a code check is downstream.

1 sheet of drawings

Claims (8)

1 2. Transmission systems with code security of the patent claims: carried message characters and receiving side 1. Procedure for increasing the impact assessment of the middle position of the telegraphy steps. degree of message flow in the case of telegraphic On disturbed transmission paths (e.g. short transmission systems with code protection of the 5 wave radio links) become teletype transmissions Message characters and reception 'carry either systems with error detection and lateral evaluation of the middle position of the part repetition of the disturbed characters through autograph steps, characterized by automatic inquiry (ARQ systems or Wiederdaß when exceeding a certain for recovery procedure) or systems with automatic ideal mid-step symmetrically lying test- io reconstruction of the forged characters at the reception time by means of a step edge, the evaluation at the starting point (ARK systems or reconstruction methods Steps is blocked if the code checks are used. While the ARQ systems for the facility due to the redundancy of the for automatic query a permanently available If the codes used in the transmission require a four-wire connection, the ARK step corruption occurs recognizes and that in the case of 15 devices with a two-wire connection from and exceeding a certain to the ideal are therefore on one-sided connection-step center symmetrically lying test time used by gene. In order to obtain the correct one on the transmission path Step edge recognizing or reconstructing the evaluation of these steps disturbed characters is released when the code checking device can, as is well known, the codes used have a redundancy due to the redundancy of the code 20 used. That means codes for the transmitted telegraphic characters that must be used, for which a character step falsifications not recognized. by changing only one drawing element 2. The method according to claim 1, characterized in that it cannot change into another character. This indicates that a counter must change the number of the number of character elements that counts at least step envelopes of a telegraphic character, 25 if a code character in which the symmetrical to the ideal step center is to transition to another, is called code distance d or short test time exceed. Hamming distance. For the secure telex 3. The method according to claim 2, characterized in transmission, the Hamming distance must at least indicate that an odd (even) number d = 2 or greater. Every received character, from steps of a telegraphic character that does not meet the code requirements, is incorrectly recognized as certain symmetrical to the ideal step center and can, depending on the system, exceed the test time, cause an error display or reconstruction of the disturbed character (FA) . to lead. So z. B. in ARQ systems with the same 4. The method according to claim 3, characterized by weighty 7-digit code (CCIT. No. 3) each disturbed Indicates that an error display has a how- 35 3: 4 ratio to the repetition of the wrong recuperation of the disturbed character triggers. caught character while each code with easier 5. The method according to claim 3, characterized in that parity protection denotes forged characters, that an error display recognizes the violation of the parity conditions. printing of an error sign, in particular one However, the steps of a sign are »Combination of smear marks causes. 40 fakes that. the code evaluation of the respective 6. The circuit arrangement for implementing the system cannot recognize the fault, the method according to claims 1 to 5, thereby outputting a wrong character from the receiver. Since it indicates that for the duration of the test time which is ideal for this incorrect character the code conditions are satisfied, a bias voltage lying in the middle of the step, it cannot be recognized as an error and corrected at the inputs (G3, G4) of the flip-flop 45. Such disturbances mostly occur with ver. (K 3) is that the distorted received characters on two control inputs. For this reason, the edges of the telegraphy steps (TS) are present and in addition to the code check to ensure that after the end of each telegraphic character, a step test (ZE) over a third ("element-test") to prevent falsification of characters. This test device control input the flip-flop (K3) in the 50 evaluates the quality of the steps of a character and rest position (I) flips. reports every step that is beyond a specified level 7. Circuit arrangement according to claim 6, in which it is distorted. Since the step test each characterized by the fact that one of the outputs step reversal during a test period as a precautionary measure of one flip-flop (K 3) and one of the outputs of the other flip-flop circuit (K 2) as a disturbance of the character just received knows via a 55, this is not done evaluated, although due to the coincidence gate (G 5) the error display device of the code conditions controls the character correctly (FA) . can be rated. It follows that at 8. The circuit arrangement as claimed in claim 7, since the repetition process is often unnecessary characterized in that a counting device started fetches and in the case of reconstruction processes counts the steps that are ideally printed at the mid-step 60 "smear marks", although one Exceed the existing test time, and that with a correct impression or a reconstruction of the drawing certain counter reading an error signal would have been possible. the error display device (FA) controls. The object of the invention is to provide a method to show that allows telegraphy transmissions 65 transmission systems to increase the efficiency of the message object of the invention is a method and flow. a circuit arrangement for increasing the efficiency The solution according to the invention is that The degree of efficiency of the message flow in the case of telegraphy when a certain value is exceeded to the ideal