SU849518A1 - Two-stage parallel-series regenerator - Google Patents

Description

The invention relates to communications and can be used in the equipment of data transmission systems.

A parallel-sequential $ regenerator is known, which contains the n-formers of the clock strobe pulses, the first outputs of which are connected to the output of the crystal oscillator and the input of the pulse generator, the output of which is connected through the series-connected add-subtract block and the divider to the first input register, a second input coupled to the second output of the divider, the third You are _{a) 5} turn coupled to a first input of a first AND gate whose output is connected to the input of the first flip-flop; the outputs of which are connected to the first inputs of the second and third elements, and AND, the outputs of which are connected to the corresponding inputs of the subtraction block, the second outputs η of the clock strobe drivers connected to the corresponding inputs of the register, as well as the second trigger

However, the known regenerator has a relatively low noise immunity.

The purpose of the invention is to increase noise immunity.

To do this: a time quantizer, a strobe pulse numbering device, an extreme strobe pulse extractor, a key block, a middle phase calculation unit, a grouping zone shaper, a counter and a fourth AND element are introduced into the well-known regenerator, and the third outputs η of the clock strobe shapers are connected to the time quantizer inputs, the corresponding input which is connected to the output of the pulse shaper, the output of which is through sequentially connected numbering of strobe pulses and an isolator of extreme strobe pulses ene to the first input key unit, and the second input through the key block and

8495 the fourth AND element, the counter and the second trigger with the second input of the first AND element, connected in series, the divider output through the shaper of the grouping zone is connected to the other _s inputs of the second trigger and the fourth AND element, the output of the pulse former through the connected block of keys and the middle phase calculation unit is connected with the second inputs of the second and third elements And, and the second output of the divider is connected to another input of the numbering of strobe pulses.

The drawing shows a structural electrical diagram of the proposed 15 regenerator.

A two-stage parallel-serial regenerator contains η shapers 1 clock strobe pulses, register 2, time quantizer 20, a crystal oscillator 4, a pulse shaper 5, a block of 6 keys, a block 7 of addition - subtraction, four elements And 8-11, a shaper 12 of the zone grouping, enumerator 13 25 strobe pulses, separator 14 extreme strobe pulses, block 15 calculates the middle phase, divider 16, counter 17 and two triggers 18 and 19.

The regenerator operates as follows 30.

The inputs η of the shapers 1 receive synchronous sequences. In each shaper 1, a clock frequency of strobe pulses f _T is allocated, which provides for each shaper 1 registration of discrete information arriving at it.

The reference reference oscillator is a quartz oscillator 4. In the driver 5, n phases of frequency k ^ are formed to quantize the phase of the strobe pulses of all η drivers 1 independently of each other on the time quantizer 3. In addition, the driver (5 +1) forms the frequency phase through block 7 is fed to the divider 16 to obtain the sampling frequency fj- _c . The frequency phase ^ provides an optimal record in register 2 of all η signals from the output η. formers 1.

The search for the optimal phase is performed according to two criteria. According to the first criterion, the average phase position between the most behind the clock cycle strobe pulses of all η formers G. is calculated for this. 4 targets, all strobe pulses are quantized by high-frequency pulses distributed over time and in accordance with the number of η channels. At the output of the time of quantizer 3 there are ή sequences of high-frequency pulses, where each channel has its own phase of quantization pulses kf _T.

In the numerator 13, the phase distribution of the strobe pulses is performed depending on their phase shift with respect to the strobe pulse, the phase position of which is conventionally taken as the initial position. The convention of numbering of strobe pulses at the first moment is determined by the arbitrariness of the phase position. the divider 16, the clock frequency of which is the installation of the numbering 13 in the initial position.

In the isolator 14, the first and last phase of the strobe is determined with the condition that the extreme positions of these strobe pulses may not correspond to the actual position of the phase extreme strobe of parallel channels in one clock cycle of the transformed signal.

In block 6, the time interval between the phase-extreme strobe pulses is filled with the frequency from the shaper 5. In block 15, the average phase between the extreme strobe is determined, and this phase average of one clock cycle goes to the second and third elements 9 and 10, where it is compared with phase ^f TC. Through block 7, the phase of the divider 16 is adjusted until the phase _{ί Ύε} from the output of the divider 16 coincides with the phase of the average value per cycle determined by block 15.

To correctly determine the boundaries of one clock interval, a second criterion for determining the phase position of the channel grouping criterion is introduced. Using a divider 16, the shaper 12 forms a time interval in which the grouping of strobe pulses is analyzed. The grouping zone from the shaper I2 and the strobe pulses from the output of the time-quantizer 3 arrive at the fourth element · And 11 and, if there are a sufficient number of strobe pulses in the interval of the grouping zone to decide on the presence of grouping, an impulse appears at the output of the counter 17, which translates the second trigger 19 to zero

849518 6 position, with the first trigger 18 working in the usual way. If the pulse does not appear from the output of the counter 17, then the second trigger 19, thrown to the single position by the front j of the zone pulse, will remain in the single position, the first element And 8 will close, and the first trigger 18 will remain in the same position and will constantly output pulses to ki by the divider 16. As a result, the phase of the divider 16 is rapidly shifted until the grouping effect is detected. After that, the frequency t5 is adjusted to the average phase value coming from the output of block 15.

The proposed regenerator allows you to build a multi-span data transmission path with speed transformation and signal regeneration along parallel subchannels. .

Claims (1)

the fourth element AND, the counter and the second trigger with the second input of the first element I are connected in series, the output of the divider is connected to the other inputs of the second trigger and the fourth element I through the shaper of the grouping unit and the middle key is connected to the second element inputs of the second and third elements, And, the second output of the divider is connected to another input of the strobe pulse numerator. The drawing shows a structural electrical circuit of the proposed regenerator. The two-stage parallel-serial regenerator contains n clock drivers 1 clock strobes, register 2, time quantizer 3, crystal oscillator 4, pulse shaper 5, key block 6, subtraction addition block 7, four elements AND 8-11, grouping zone shaper 12, numerator 13 strobe pulses, selector 14 extreme strobe pulses, block I5 for calculating the average phase, divider 16, counter 17 and two triggers 18 and 19. The regenerator works as follows. At the inputs of the n drivers 1 receive synchronous sequence. In each driver 1, the clock frequency of strobe pulses f is allocated, which provides for each feed analyzer 1 registration of discrete information arriving at it. The reference oscillator is the quartz oscillator 4. In Former 5, n phases of the quantization frequency of the strobe pulses of all n formers 1 are formed independent of each other on time quantizer 3. In addition, a (n + 1) phase kf is formed in the Former 5. which, through block 7, feeds to divider 16 to obtain a frequency of strobing. The phase of frequency f ensures the optimal recording of all n signals from the output of the shaper 1 in the Eg. 2 reg. 1. The optimal phase is searched for by two criteria. The first criterion calculates the average phase position between the most lagging clock pulses of all the n drivers. D. For this purpose, all strobe pulses are quantized by high-frequency pulses distributed over time and in accordance with the number n of channels. At the time exit-. There are n sequences of high frequency pulses, where each phase corresponds to its own phase of quantization pulses kf. In the J 3 numerator, the phase distribution of the strobe pulses is performed depending on their phase shift with respect to the strobe pulse, whose phase position is conventionally taken as the initial position. The convention of the numbering of strobe pulses at the first moment is determined by the arbitrariness of the phase position, the divider 16, the clock frequency of which f- sets the numerator 13 to the initial position. In the selector 14, the first and last phase of the pulse is determined, with the condition that the extreme positions of these strobe pulses may not correspond to the actual position of the extreme phase strobe pulses of the parallel channels in one clock of the transformed signal. In block 6, the time interval between the extreme in phase strobes of the frequency generator 5 is filled. In block 15, the average phase between the extreme strobes is determined, and this average per phase enters the second and third elements of AND 9 And 10, where it is compared with phase. Through block 7, the phase divider 16 is adjusted until the f-rc phase from the divider 16 output coincides with the average phase per step determined by block 15. Correct determination of the boundaries of one clock interval is entered by the second channel phase criterion . With the help of the divider 16, the former 12 forms a time interval on which the grouping of strobe pulses is analyzed. The grouping zone from the imaging unit 12 and the strobrtxn .f ialgla f 1 1xhlgll1altOpet U m pulses from the output - temporary quantum body 3 arrive at the fourth element I 11 and, if there is a sufficient number of strobes in the grouping zone to decide whether there is a grouping, then at the output of counter 17, an impulse appears that drives the second trigger 19 to the zero position, with the first trigger 18 triggered in the usual way. If the pulse from the output of counter 17 does not appear, the second trigger 19, transferred to the unit position by the leading edge of the zone pulse, will remain in the unit position, the first element of AND 8 will close, and the first trigger 18 will remain in the same position and will continuously generate pulses adjusting the divider 16. As a result, there is a rapid phase shift of the division of bodies 16 until it detects. with grouping effect. After that, the frequency f is adjusted to the phase Average value coming from the output of block 15. The proposed regenerator allows building a multi-span data transmission path with speed transformation and signal regeneration along parallel subchannels. Claims of the Invention A two-stage parallel-serial regenerator, containing p clock pulse drivers, the first outputs of which are connected to the output of the crystal oscillator and the input of the pulse former, the output of the counter through the serially connected addition and subtraction unit, and the divider connected to the first register input, the second input of which is connected to the second input the output of the divider, the third output of which is connected to the first input of the first element I, the output of which is connected to the input of the first trigger, the outputs otorrhea connected to first inputs of the second and third elements 8 8 whose outputs are respectively connected to inputs of the addition block stvukschimi -. subtracting, wherein the second outputs n clock pulses, frr tors, are connected to respective hodami register, and the second trigger of tlichayuschiys in that, in order to increase the noise immunity ,, introduced temporary quantizer numerator of pulses, vmdeJShtel extreme of pulses, the key block, calculating an average the phases, the grouping zone shaper, the counter and the fourth element I, the third outputs and the clock stroby formers are connected to the inputs of the time quantizer, the corresponding input which is connected to the output of the pulse generator, the output of which through serially connected numerator strobe pulses and the extreme pulse generator is connected to the first input of the key block, as well as the second input of the key block and sequentially connected fourth element I, the counter and the second trigger with the STOpim input of the first element And, the output of the unit through the shaper zone, grouping is connected to other inputs of the second trigger and the fourth element, And, the output of the pulse shaper through the series connection The key block and the middle phase calculator are connected to the second inputs of the second and third elements AND, the second output of the divider is connected to another input of the strobe pulse numerator. Sources of information taken into account in the examination I. USSR Author's Certificate in Application No. 2620501, cl. H 04 L .7 / 02, positive decision 28. (proto-: type).