SU661773A1 - Code to frequency converter - Google Patents

Description

conversion, for example, in the form of a ratio of two codes, which does not allow to get an additional VALUE in performance due to the combination of the operations being implemented, as well as the ratio of the two codes in absolute value1 to one unit.5.

The purpose of the invention is to improve the accuracy of the transformation.

This goal is achieved by the fact that the device for converting codes to frequency / containing the first counter of 10 pulses, the first outputs of which are connected via serially connected first MN1-OUTCUT matching element and the delay element. To the first input of the OR element, the second input j5 of which is connected to the generator output pulses, and the output is to the counting input of the first pulse counter,

the second. pulse counter, outputs

Secondly, they are connected to the outputs of the second „multi-input coincidence element, and iiv.impulse adder, the first one, the input of the first of which is connected to the output of the OR element, the second input of the first impulse adder is connected to the output of an additional multi-input coincidence element impulses, avy-. the stroke of the first adder is connected to the input of the second adder, the second 30 of the KOTOpotu internal control unit is connected to the output of the second multi-address unit. , prim. The input of the second total is connected to the counting input. The second pulse counter. 35

The structural electrical diagram of the device is shown in the drawing. The device contains binary, account. CHIK11 1 and 2; .- yogbvovye eyomynty: 3-5; Element B OR, Pulse Sum-. 40 motors 7 and .8, delay element 9 / generator 10 pulses, bus 11-13 input factors and bus 14 output.

The outputs of the meter 1 are connected to the xy of the elements. 3 .and 4. bjodane n -. Shevy-1kh6dy; elements 3 are connected to. ..; idamyonta. 9 delayed, the output of which is connected to the first input of the .6 element, whose second input is connected to the output of the generator 10 IMPRESS. Element b output OR connect SO to the input of counter 1 and 6 with the first 7, the second input is connected to the combined output of element 4, the output to the first input of the second adder 8, the second input 55 ko.TOporo connected to you;} Od element 5, and the output - with the input of the counter 2 and the output 14 of the device. The tires and the input of the first factor are connected to the second inputs of element 60, the tires 12 of the second factor Iko enter the second inputs of element 4, and the tires 14 the water of the third factor to the second inputs of element 5.

The device works as follows.

661773

in the general case, the device implements a coefficient for converting codes to a pulse repetition rate of the form Kf, N.J Nj / Nj, where the N-f factor code is fed to inputs 11, the Ng-Ha factor code 12 inputs,. and the N factor factor code — to inputs 13,

Depending on the actual; the state of the control codes at the inputs 11-13, the device realizes the partial coefficients of converting the codes into a repetition frequency of pulses.

When applying the pulses of the generator 10 to one of the inputs of the element b OR its output, the frequency F is set. Pulses F are gene 3

where Fg is the frequency of the pulses arriving at the second input of the element b OR through the delay element 9 with the combined well inputs of the element 3 is equal to NX,

but

-I 2

N is the code of the first factor; hence the frequency of ifiasKa.

 L. I.ALJ l - and /

(2

- {gene from where,.

top

gene

F.

N-i.

12 The frequency F is fed to the first input of the adder 7, the second input of the second that receives the frequency from the combined outputs of the element 4 is equal to

k - N2. . B4 - 2 The frequency Fg, coming from the output of the adder 7, is equal to

,.,. ,, „(Hyi

 It is clear from the last expression that the first partial K-transformation factor of the device is equal to

  IMJ /. greater than one and can be indicated in ID 1 (1 A, and the second partial conversion factor Kfig is equal to

. . - 2 + N2

2

greater than one and can be denoted as K „B (1 + Nj, 2), H. F, j arrives at the first input of the sum of .tor 8 operating in the mode you-. reading, the second input of which receives the frequency Fg of the combined outputs of element 5, and from the output of the pulse adder 8, the output bus 14 of the device receives the frequency equal to

YOU

out2 from where

. -. -with .

out fx jfrqjjj

where (Nj) is the third partial conversion factor. To, which can be written in the form of C K? | and / 1 + Nj-2 The frequency at the output of the device is thus equal to p (N2) 2 g (). 2P (2 + Ng) Let us consider in more detail the mode of converting the ratio of two N 3 codes to the pulse frequency .. Jk. OUT Nj Code, the number N is set equal to zero, and since the second partial conversion factor Kd h varies from 1 (with N 0) (with Ng 2 - 1), it is obviously a fractional conversion coefficient, the whole part of which is 1 , and fractional equals N, 2 — is set as a code on the input buses 12 of the device. The third partial conversion factor K, changes pt 1 (at NJ 0) to 2 (at) and is a fractional conversion factor, the whole part of which is 1, and fractional; equals N ,, 2 and is specified as a code on input tires 13 devices. It is obvious that the ratio of the codes of numbers N Nj — the ratio of the second and third partial conversion coefficients, respectively — is a fractional conversion coefficient varying from - (with and) to 2 (with N2 and N 0) with a discrete step, are equal, where n is the resolution of counters 1 and 2, i.e., the step of discreteness of changing the device conversion ratio in the mode of the ratio of two codes of the change tue unit, and can be set with the required and acceptable practice accuracy, and the value of the conversion coefficient Two consecutive choices set the optimal frequency of the generator 10. The output frequency of the device in this mode is equal to -F () 2 RIBS gene (,, V2. If necessary, decrease the discrete step of changing the output frequency, the code of the number Ng is set to zero and the conversion factor is determined by the code the N numbers, whose entailment per unit causes a larger discreteness of the change in the first partial coefficient by the number code Nj. The frequency on the unit and the output of the device is equal to 2 hals with (2lN, In the conversion mode of two, the device code works as follows way.,. The multiplier code Nj is set to zero, and the frequency at the output of the device is determined by the relation 2 (,,) (, 1 2 and, if necessary, can be further scaled downwards by supplying the appropriate code of the number Y "to the input buses 13. -. . With additional requirements and output frequency ripple, the element; 9 delays can be made controlled (analog, digital, or combined) depending on the code of the number N. The proposed device implements conversion factors with a small change step, This is determined by the required accuracy of the conversion factor, up to the actual digit level Ng and NJ, which allows the device to be used in digital frequency synthesizers, digital processing devices for information signals and in other cases where high accuracy is required. The frequencies start from the moment the codes are supplied to the control inputs of the device, which ensures a higher speed, operation. . In addition, the device requires the implementation of lower hardware costs, which increases the efficiency of use of equipment. Formula of the Invention A device for converting codes into a frequency containing a first pulse counter, the first outputs of which are connected via a serially connected first multiple input match element and. the delay element to the first input of the OR element, the second input of which is connected to the output of the pulse generator, and the output to the counting input of the first pulse counter, the second pulse counter, the outputs of which are connected to the outputs of the second mrgovhodovogo coincidence element, in order to increase the accuracy of the conversion, a multi-input coincidence element and two pulse adders are entered into it, the first input, the first of which is connected to the output of the OR element, the second input of the pulse adder is connected to the output to complementary multi-input element of coincidence, the inputs of which are connected to the second outputs of the first pulse counter, and the first input of the first adder is connected to the first input

the second adder, the second input of which is connected to the output of the second multiple head element of coincidence, and the output of the second adder is connected to the counting input of the second pulse counter.

Sources of information taken into account in the examination

1, USSR author's certificate

No. 418857, Cl, C 06 R 7/39, 4.06.1974.

2. USSR author's certificate

 371681, cl. H 03 K 13/02, 4.08.1973,

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