SU993437A1 - Pulse repetition frequency multiplier - Google Patents

Description

(54) MULTIPLE OF FREQUENCY FOLLOWING PULSES

t. - -The invention relates to a pulse-on technique, namely, devices to multiply the frequency and monitor changes in the input frequency, and can be used in various radio engineering devices.

A pulse multiplying frequency multiplier is known, the sequentially connected dosed pulse shaper, the ipy filter, the meter, the controller, the phase meter, the fine filter, the frequency divider, and the coincidence circuit. .

The disadvantage of this multiplier is that in the presence of precipitations in the input pulse sequence, the speed of the phase channel is limited by the number of outgoing pulses at the input.

The closest to the technical point of the pre-agamvu is a frequency multiplier with a sampling pulse, containing an OR element, the output of which is connected to the first input of the phase meter, the output of which is connected to the first input of the matching element and the input of the first filter, the output of which is connected with the first 4 input totalizer. ra, whose syringe is connected to the entrance

controlled pulse generator, the output of which is connected to the second input of the coincidence element, the output of which is connected to the input of the first frequency divider, the output of which is connected to the second input of the Phasometer, shaper metered and 4pl, whose output is connected to the input of the second filter, the output of which is connected to the second the input of the adder, and the second frequency divider I.

A disadvantage of the known device is the multiply precision of multiplication and low speed.

15

The purpose of the invention is to increase the accuracy of multiplication while improving the speed of the device.

This goal is achieved by the fact that, in the following frequency multiplier

20 pulses containing an element OR, the output of which is connected to the first input of the phase meter, the output of which is connected to the pair input of the matching element and the input of the first filter, output

25 which is connected to the first input of the adder, the output of which through a controlled pulse generator, is connected to the second input of the coincidence element, the output of which through the first de-

Claims (2)

The frequency converter is connected to the second input of the phase meter, the shaper pulse generator, the output through which the second filter is connected to the summers of the adder's input, and the second frequency divider, the pulse sequence analyzer is entered, the first input of which is connected to the input bus, the second input to the first output of the second the frequency divider, the first input of which is connected to the output of the controlled pulse generator, the first input with the second input of the second frequency divider, and the second and third outputs corresponding to the first and second inputs and the OR element, the output of which is connected to the input of the metered pulse generator, wherein the pulse sequence analyzer is designed as a pulse distributor, whose input is the first input of the pulse sequence analyzer, and the first, second and third outputs are connected to the inputs of the corresponding channels of which includes in series connected pulse expander pulse shaper, element I, the second input of which is connected to the output of the expander and myc analog and trigger, the second input of which is connected to the pulse generator of the subsequent channel and in the third channel the second inputs of the element AND and the trigger are connected respectively to the outputs of the expander and pulse former of the first channel, npH these outputs of the pulse formers of all channels are connected to the inputs of the first element OR, and the outputs three / ger of all channels are with the inputs of the second OR element, the output of which is connected directly to the first input of the first coincidence element, the second input of which is connected to the output of the first The OR and the inverter are with the first input of the second coincidence element, the second input of which is the second input of the pulse sequence analyzer, while the output of the first coincidence element is connected to the input of the short pulse shaping input, the output of which is the first output of anantiated pulse of the pulse sequence the second output of which is connected to and to the course of the first element of the match, and the third output to the output of the second elvmatment of the match. The drawing shows the structural scheme of the device. It contains shaper 1 pulse pulse generator, fine filter 2: settings, coarse filter 3, dividers 4 and 5 frequencies, element b OR phase meter 7, adder 8, controlled generator of 9 pulses, element 10 coincidence, analyzer 11 of a pulse sequence pulse distributor 12, pulse spreaders 13-15, pulse formers 16-18, elements 19-21 AND, triggers 22-24, elements 25 and 26 OR, inverter 27, elements 28 and 29 coincidence, driver 30 short pulses. The frequency multiplier of the pulses operates as follows (Fig. 2). The input pulse sequence arrives at the input of the analyzer 11 through distributor 12. Distributor 12 can be filled in the form of a three-bit ring-recorder that shifts the unit. Thus, at the outputs of the distributor 12, in the presence of an input pulse sequence, there are pulses, the frequency of which is three times lower than the frequency of the pulses of the input sequence, and at the outputs of the expanders 13-15 which can be made as one-shot, there are pulses with the same frequency, but the duration of the pulses corresponds to a double period of the following average frequency of the input pulse sequence (,), Forchiators 16-18 on the falling edge of the pulses from the outputs of the expanders 13-15 form ru short impulses. Elements 19-21 produce f f f from the output of pulses in the input pulse sequence, taking into account the possible detonation of the input pulses up to 100%. In the case of impulses generated by the formers 16-18 in the respective zones of the pulses received at the outputs of the expanders 14, 15 and 13, the triggers 22-24 are switched, and they are reset by the pulses formed by the formers 17, 18 and 16 Therefore, at the output of element 26, the Potential will be allowed to allow the passage of pulses formed by the former 16-18 from the output of element 25 through element 28 to element 6 and the Forgliater 30 input. (1pulses formed by the former 30 are produced under synchronization of pulses produced by & ix by a divider 5. In the event of a single pulse falling out in the input nm: the pulse sequence through one of the elements 19, 20 or 21 will not pass the pulse, formed by 4, 17 or 18, which means and not, one of the triggers 22-24 switches. At the output of the element 26. A potential prohibits the passage of a signal from the output of element 25 through element 28 to the input of the element & Alternately, the signal from inverter 27 will allow the passage of pulses from the output of divider 5 to the input element 6 6 Thus, in the absence of "occurrences in the input pulse sequence from the output; yes, element 6 is the same as the pulse output sequence with a delay of n. 2. When the impulses are input, the pulse input sequence from element 6 removes the pulses obtained by dividing and dividing the EC by multiplying the partial wavelength, which is followed by the presence of pulses in the input: and pulsed sequence in the output region. From the output element b impulse n6 the sequence With the frequency of the sequence f is fed and the forkdater 1 code and to the approach of the Phase meter 7, From the output pho; The 4 inrpulys with a duration of t ' s tp are fed to a filter 3, from which voltage Btixoea is removed, which is proportional to the frequency of the input signal. Shaper 1 and filter 3 form an auto-tuning frequency circuit. The voltage from VN, the filter 3 running through the sumiator 8 is fed to the input of the generator 9 and changes the frequency of the generator and in accordance with the modulation characteristic (f dependence on the voltage control) of the generator. Thus, the configuration of the controlled geierator is carried out. . . From the generator 9 input, the pulses go to the input of the divider 5 with a division factor under which synchronization is performed by the pulses generated by the shaper 30 of 2T delayed (with an analyzer 11. In addition, from the output of the controlled generator 9, the pulses go to one of the inputs of element 10 whose output through a divider 4 with a division factor of / 2fgy is connected to the second input of the phase meter 7 The output of the phase meter 7 is connected to the second input of the element 10 and the filter 2. Thus, pulses are formed at the output of the phase meter which does not contain a constant component in the case, If K f to the frequency spectrum of the oscillation contains a constant component of one sign ...,. If f0j,., then the sign of the constant component of the frequency spectrum of the oscillation changes the opposite. 10, the divider 4, the phase meter 7 and the filter 2 enclose the phase-locked loop, the proposed multiplier provides tracking of the frequency of the input pulse sequence having a detonation of up to 95%, provides an increase in the accuracy of the multiplication with increasing speed. Claim 1. A pulse frequency multiplier comprising an OR element, the output is connected to the first input of the phase meter, the output of which is connected to the input of the matching element and the first filter, the output of which is connected to the first input of the adder, after which the controlled pulse generator is connected to the VTOM% zm input of the element coincidence, the output of which through the first frequency divider is connected to the second input of the phase meter, the shaper of the metered pulses, the output of which through the second filter is connected to the second input of the adder, and the second frequency divider, characterized in that, in order to increase the multiplication accuracy while simultaneously increasing the speed of the device, a pulse sequence analyzer is entered into it, the first input of which is connected to the input bus, the second input the input of which is connected to the output of the controlled pulse generator, the first output - with the second input of the second frequency divider, and the second and third outputs - respectively with the first and second inputs of the OR element, the output to The splices are connected to the inlet of the metered dose. pulses. 2. A pulse frequency multiplier according to claim 1, wherein the analyzer, of the pulse sequence is designed as a pulse distributor, whose input is the first input of the pulse sequence analyzer, and the first, second and the third outputs are connected to the inputs of the corresponding channels, each of which includes a pulse extender connected in series, a pulse shaper, an element AND the second input of which is connected to the output of the next channel pulse extender, and a trigger, the second input of which is connected to the output of the pulse generator of the subsequent channel, and in the third channel the second inputs of the element I and the trigger are connected respectively to the outputs of the extender and the driver of the pulses of the first channel, while the outputs of the drivers, pulses of all channels are connected to the inputs of the first element OR, and the outputs of the trigger - all channels - from the entrance