SU879804A1 - Device for monitoring multi-level pulse train generator - Google Patents

Description

(54) DEVICE FOR MONITORING THE GENERATOR OF MULTILEVEL SEQUENCE OF PULSES The invention relates to radio engineering, namely to communication systems in which information is transmitted using multilevel pseudo-random sequences of maximum duration, or multi-level M-sequences. A device for controlling a multilevel pulse train generator is known, which contains a clock pulse generator, a register and a series-connected pulse train generator and a comparison unit. However, the monitoring time in such a device is long. The purpose of the invention is to reduce the control time. The goal is achieved in that a device for controlling a generator of a multilevel pulse train containing a clock pulse generator, a register and a serially connected pulse train generator and a comparison unit are inserted in series a clock distributor, a switching unit, a multiplication unit, a first key block and a signal combining unit consecutive but connected clock key, accumulator and decoupling unit, serially connected first OR element, second key block, key management unit and second OR element, serially connected counter block and the third OR element and the second runner, with the output of the clock generator connected to the first input clock key n with the input of the clock distributor, the second output of which is connected to the second input of the clock key, the third input of which is combined with the second input of the decisive block and the first input of the second block and the keys, the second input of which is connected to the output of the third OR element and to the third input of the decision block, the fourth input of which through the second accumulator is connected to the second output of the second key block, the third input of which is connected to the output of the second OR element, the outputs of the signal combining unit are connected via a register with the signal inputs of the switching unit, the corresponding outputs of which are connected to the signal inputs of a pulse train generator, the clock input of which is connected to the output of the clock key, respectively The current inputs and outputs of the decomposition unit are combined with the corresponding inputs of the comparison unit, the outputs of which are connected to the corresponding inputs of the counter block of the first OR element, the first input of which is combined with the first input of the third OR element and the corresponding inputs of the key management block, the outputs of which are connected to corresponding control inputs of the first key block.

The drawing shows a structural electrical circuit of the device described. A device for monitoring a multilevel pulse generator comprises a sequence generator 1. pulses, clock generator 2, is a comparison unit 3, the first element OR 4, the second element OR 5, the signal combining unit 6, the third element OR 7, the first and second blocks 8 and 9 of the keys, the first and second drives 10 and 11, a register 12, a switching unit 13, a multiplication unit 14, a counter unit 15, a decisive unit 16, a 17 clock allocator, a clock key 18 and a key management unit 19.

The operation of the device can be divided into two stages. The first stage is to check the length of the block of the 25 / C-level M-sequence.

At the initial moment of switching on the device, the first drive. 10 and the second accumulator 11 are set to the zero state, all the keys of the first key block 8 and the clock key 18 are closed, all keys of the second block of 9 keys are open, and all switches of the switching block 13 are in the position shown in the drawing. Therefore, the initial code, previously entered into the register 12, is entered into the pulse train generator 1.

With the start of operation, the 2 clock pulse generator starts generating clock pulses arriving at the input of clock switch 18 and into the clock distributor 17, which with the arrival of the first clock pulse sends a signal to the control input of the switching unit 13, after which all its switches are transferred to the new working position, and with the arrival of the second clock pulse, opens the clock key 18. Due to the transfer of 45 switches of the switching unit 13 to the working position, the initial code from the register-. Pa. 12 is sent to Comparison Unit 3.1. Comparison Unit 3 and Multiplication Unit 14. At the same time, the 14.1 multiplication device adds the signals arriving at its inputs and thus increases the kO of the initial state by a factor of two; device 14.2. multiplying adds the initial state code to the resultant signal of the multiplier device 14.1 and thus increases the initial state code by 3. times, etc. Device 14 (/ (- 2) multiplying adds the initial count code to either the resultant the signal of the device M (K -Ch) is multiplied, and, thus, the uvs-shchpi stg code of the initial state in (KI) 1) and. A feature of all multipliers of multiplication unit 14 is that the absolute value of the resulting code does not exceed the base of the L -level.-Sequence, i.e., multiplication devices normalize the result but module K. All outputs of multiplication unit 14 are respectively connected to the inputs block 3 comparison.

The generator 1 of the pulse sequence with the arrival of each clock pulse generates the next symbol of the / C-level.-Sequence, in accordance with which it changes the initial code. The newly received code is sent to the other n inputs of the comparison unit 3. As soon as the code received from the generator I of the pulse sequence coincides with one of the codes entered B.; the comparison unit 3 from the register 12 or from the multiplication unit 14, the corresponding comparator of the comparison unit 3 produces a signal that is sent to the corresponding coincidence counter of the counter unit 15 or , if the coincidence of codes occurred in the comparison device 3.1, immediately to the third element OR 7. Signal From the comparison block 3 also goes to the second input of one of the triggers of the key management unit 19, if the coincidence of codes It did not occur in the device 3.1 of the comparison, and goes to the first element OR 4. With the arrival of such a signal, the first element OR 4 closes the clock key 18, blocking further operation of the generator 1 of the pulse sequence, sends a signal to the first control input of the decision block 16, to the second drive 11 through key 8.1 of the first key block 8 and, through key 8.2 of the first key block 8, to the first inputs of all the triggers of the key management unit 19. This completes the first stage of checking the number of characters in the block.

The second stage is checking the number of blocks in the period of the / C-level M-sequence.

Claims (1)

The trigger of the key management unit 19, on both inputs of which signals were received, opens the corresponding key of the first key block 8, and sends it to the second element OR 5. With the arrival of this signal, the second element OR 5 closes the key 8.2 of the first key block 8, excluding the possibility of in the future, some of the triggers of the key management unit 19. Through the opened key of the second key block 9 and the block 6 of the C: IKL-IOB block, the code 12 is sent to the register 12 from that ii. block 14 multiplication, from which D) s.1 look at block 3 comparison code, coBfiniunnii with ios.andnim, received there and; rciifpaioiia I with a sequence of pulses kodpm Mchimy t; iii 4oiiHMH code 12 goes into register 12: the switching unit L to the multiplication unit 14, and from the same output of the multiplication unit 14 along the same circuit, another code is sent to the register 12, which, in turn, enters block 14 multiplication and so. Each time after the next signal arrives at the input of the multiplication unit 14, the codes obtained by multiplying the input code by 2.3 ..., (/ C-1) are received from the outputs of the comparison unit 3, the result of multiplying normalized by flo to the K-module. Each of these codes is compared in block 3 of the comparison with the last one obtained in the pulse sequence code generator 1. If these codes are matched, the corresponding comparator of the comparator unit 3 sends the signal to the corresponding coincidence counter of the counter block 15 and to the first element OR 4, which then sends a signal to the second drive AND through the key 8.1 of the first key block 8. As soon as a second signal arrives at any of the coincidence counters of the 15 counter block, this coincidence counter will send a signal to the third element OR 7, which, when a signal arrives at any of its inputs, sends it immediately to the second control input of the decision block 16. In The decisive block 16 by this time includes 11 numbers from the first accumulator 10 and the second accumulator, equal to the number of signals received by each accumulator. The number of signals received in the first drive 10 is equal to the number of symbols in the block of the checked sequence, and the number of signals received in the second drive 11 is the number of blocks in its period. With the arrival of the signal at the second control input of the decision block 16, the second multiplier of the first accumulator, 10 and the second accumulator 11, is multiplied. If the result is equal to the number of symbols in the period of the K-level-sequence for given values of / ( and n, the sequence, the first block of which formed the generator of the pulse train, has a maximum period. Otherwise, the sequence being checked is a sequence that is not maximal. The substance of the detected device is that it allows the duration of the generated C-level.-sequence to be checked, and the monitoring is carried out in a relatively short period of time. This advantage will be useful when using the device in modern information transfer systems, especially those that use / (as the information carrier) —level M-sequences, and the time savings increase with an increase in the number of sequence levels. An apparatus for controlling a generator of a multilevel pulse train, comprising a clock pulse generator, a register and a serially connected pulse trainer geerator and a comparison unit, characterized in that, in order to reduce the monitoring time, the serially connected clock distributor, switching unit, multiplier, first are introduced a key block and a signal combiner, a serially connected clock key, a first accumulator and a decision block, sequentially the united first element OR, the second key block, the key management block and the second OR block, the meter block connected in series and the third OR block and the second drive, with the output of the clock pulses generator connected to the per clock input and the clock distributor input, The second output is cohortly connected to the second input of the clock key, the third input of which is combined with the second input of the decision block and the first input of the second key block, the second input of which is connected to the output of the third element OR to the third The input of the decision block, the fourth input of which is connected to the second output of the second key block via the second drive, the third input of which is connected to the output of the second OR element, the outputs of the signal combiner are connected via a register to the signal inputs of the switching unit, the corresponding outputs of which are connected. with the signal inputs of the pulse sequence generator, the clock input of which is connected to the output of the clock key, the corresponding inputs and outputs of the multiplication unit are combined with the corresponding inputs of the comparison unit, the outputs of which are connected to the corresponding inputs of the counter unit of the first OR element, the first input of which is combined with the first input of the third element OR, and with the corresponding inputs of the key management unit, the outputs of which are connected to the corresponding control inputs of the first key block. Sources of information taken into account during the examination 1. USSR author's certificate No. 552723, cl. H 04 L 11/08, 1975 (prototype).