SU748898A1 - Phototelegraph system monitoring apparatus - Google Patents

Description

The invention relates to a television.izi-7 technology. .

A device for monitoring a photo telegraph system is known, comprising a 5 storage device in which ’. A photo telegraph signal is recorded, a buffer unit, a control unit / length parameters of a deployable line that measures the length of the scan | q and identifies a length error of £ 1].

However, this device is complex.

Closest to the technical essence 15 to the invention is a control device of a phototelegraph system containing a reference pulse generator, consisting of series-connected first waiting G) multivibrator, element And and additional waiting multivibrators, the corresponding outputs of which are connected to the corresponding inputs _ of the OR element, the second input element * 5 is connected to the input of the fill pulse generator, the output of which is connected to the input of the error indicator. through the second element And and the counter [2] connected in series. thirty

However, this device does not provide sufficient measurement accuracy.

The aim of the invention is to improve the accuracy of measurements.

To this end, a control device for a phototelegraph system * containing a reference pulse generator, consisting of a series-connected first waiting multivibrator, an element And additional waiting multivibrators, the corresponding outputs of which are connected to the corresponding inputs of the OR element, and the second input of the element And is connected to the input of the fill pulse generator whose output is connected to the input of the error indicator. through the second element AND counter, connected in series, two prohibition elements and an additional OR element are introduced, the inputs of which are connected to the outputs of the prohibition elements, and the output of the AND element is connected to the second input of the second AND element, and the first inputs of the prohibition elements are connected to the outputs of the OR element.

The drawing shows a structural electrical diagram of the described device 3 - '’device control phototelegraph system.

The described device comprises a reference signal generator 1, consisting of waiting multivibrators 2-6, logic element AND 7 and logic element OR 8, logic elements 5 prohibition 9 and 10, logic element LI 11, logic element I 12, generator 13 pulses of filling, counter 14 and error indicator 15. · \

The phase pulses are applied to the bus 16, and the test pulses are fed to the input bus 17.

The device operates as follows.

The phase pulse of the receiver (not shown in FIG. 15) of the photo telegraph system ~ ^: '™ ^: ' same ^t ' ^, ' come on 'go' go in? ^ 7yYU1; 7 in vibrator 2 of the generator 1 of the reference signal, the output pulse of this multivibrator ' arrives as an impulse 20 of the discharge to the element And 7, to the other Input of which a pulse arrives ........ of the leading edge of the first pulse of the pulse, the signal is received on the input bus 17 with the generatrix, .. ........ p _aiopa test signal of the transmitter (not shown in the drawing).

From the output of the And 7 element, the impulse of the forward frame starts sequentially connected waiting multivibrators 3-6, generating a set of reference impulses (30 with certain intervals between them), strictly analogous to that transmitted from the transmitter. The number of generated test and reference pulses is determined by the requirements for accuracy in monitoring the operation of the photo telegraph system and does not exceed five to seven. ....

The inputs of two elements of the ban and 10 receive test ampul-40 sys from the input bus 17 and the reference pulses from the output of the circuit element OR 8 of the reference pulse generator. To control the reference pulses of expansion and shorten the duration of the test pulses formed in the receiver, which corresponds to positive and negative deformation of the strokes, the elements are used ап ап Έ 9, 1 b ’, з ап apraking _ signal at the input of one is a signal at the input of the other. ' As a result, at the output of the elements of prohibition 9 and 10, pulses are formed, the duration of which is equal to the difference in the durations of the corresponding pulses of the supporting signal and the test signal.

To increase the accuracy of measuring the duration of the output pulses of the elements ban 9 and 10 and the element OR 11, the filling method is used.

(filling; measured pulses with a high-frequency signal, followed by counting the number of filling pulses. To this end, the filling pulse generator 13 is triggered by the leading edges of the input pulses; the signal from the generator output is sent to element 12 and then to counter 14.

Depending on the problems solved by the indicator 15 of the error, it is possible to measure (count) the number of pulses in the counter, or just fix the fact that the error in reproducing the duration (size of strokes) exceeds the permissible value. Test signals can be switched on in the transmitter at any point in the path from the output of the photoconverter to the input of the modulator. Such switching of test signals can be foreseen programmatically and switched line by line during transmission of the edge of the strip. Thus, a faulty system link is uniquely determined. If, at the same time, a sufficient time shift of the test signals is provided with respect to the phase pulse of the transmitter, then the test signals from various links of the system path will be recorded on photocopies, which makes it possible to document the system state.

Claims (1)

Controls of the phototelegraph system. . , . --... . The described device contains the generator 1 of the reference signal, consisting of waiting multivibrators 2-6, logic element AND 7, and locking element OR 8, logical prohibition elements 9 and 10, logical element LI 11, logic element AND 12, generator 13 pulses auto-locking the score is 14 and the error indicator 15 ,. Phase pulses are applied to bus 16, and test pulses are fed to input bus 17. The device works in the following way,. . The phase pulse of the receiver (not shown in the figure) of the phototelegraphic system Tüja 1 is delivered to the Adu Kyo Pyudav area and the vibrator 2 of the generator 1 of the reference skal. The output impulse of this multi-type device for the impedance of an impulse to an element of And 7, on the other input of which impulses the front impulse r $ $; 5n 1-WepWor urMny ° ШЙ1ТГ Gey 1Tigent 6 sigala, entering the input chin of the seam, entering the input chin of the sigma, entering the input chin of the sigma, entering the input plane of the seam of the head of the body. piafra test: transponder signal (not shown in the drawing). G output element And 7 impulse of the front-run startbright. There are sequentially included wait-and-wait multivibrators B-6, generating a set of reference pulses (with definite intervals between them), strictly analogous to that transmitted from the transmitter. The number of generated test and yoX IMyuls supports is determined by the accuracy requirements for controlling the phototelegraph system and practically does not exceed five to seven, ..., Two elements 9 and 10 ban from the input bushes 17 and reference pulses c the output element of the circuit OR generator reference pulses. For oozybzhsheeti control of oyoryym impu itself expansion and contraction dlytolnosti formed in priemni1se the testing & Tel'nykh impulso that sboagvetst exists a positive and negative ™ deformation strokes used elements monty of apret 9 and 16, apira1otdy is the signal at the input of one is a sig nal at the input On the other hand, B-result, at the output of the prohibition elements 9- and 10, impulses are formed, the duration of which is equal to the difference of the durations of the corresponding opar signals and the test signals. To increase the accuracy of measuring the duration of the output pulses of the elements, the prohibition of 9 and 10 and element or 11 uses the filling method (filling; measured pulses with a high-frequency signal followed by counting the number of filling pulses. To this end, the filling pulse generator 13 is triggered by the front edges of the input pulses; signal from the output of the generator goes to the element And 12 and further to the counter 14. Depending on the tasks solved by the error indicator 15, it is possible to measure (count-) the number of pulses in the counter, or t It is possible to fix the fact that the reproduction error of the duration (dimensions of the plumes) exceeds the permissible value Test signals can be switched on by the 8 transmitter at any point of the path from the photovoltage converter output to the modulator input. Such switching of the test signals can be foreseen programmatically and switched by lines during transmission edge of the strip. This will unambiguously identify the faulty link in the system, if at the same time ensure a sufficient time shift of the test signals with respect to the phase and the transmitter pulse, then the test signals from different parts of the system path will be recorded on photocopies, which makes it possible to document the system state. A device for controlling a photo-telegraphic system comprising a reference pulse generator consisting of a series-connected first standby multivibrator, AND element and additional stand-by multivibrators, the corresponding outputs of which are connected to the corresponding inputs of the OR element, and the second input of the AND element is connected to the input of the filling pulse generator , the output of which is connected to the input of the error indicator through the second element AND and the counter, sequentially connected, and that, that, in order to improve the measurement accuracy, two prohibition elements and an additional EL orMONT element are introduced, whose inputs are connected to the outputs of prohibition elements, and the output of the AND element is connected to the second input of the second element AND, the first inputs of the prohibition elements are connected to the outputs of the OR element. Sources of information taken into account in examination 1, Japanese Application W46-20313, class 97/3/171, 1971. 2, Patent; Germany No. 1227069, class, 21 a-36/22, 1966 (prototype).