RU211619U1 - Parallel binary-to-bipolar voltage converter with resistive matrix R-2R - Google Patents

Abstract

The utility model relates to computer technology. The technical result consists in providing the possibility of converting a binary code into a bipolar output voltage. Parallel converter of binary code to bipolar voltage with resistive matrix R-2R contains n RS flip-flops, reference voltage source, n on-off electronic switches, n-bit resistive matrix R-2R, voltage adder, analog inverter, first analog switch, second analog switch, analog adder and logic inverter. The conversion of a binary code into a bipolar voltage is achieved due to the fact that the converter has an analog inverter, which makes it possible to obtain both positive and negative output voltage of the converter. 1 ill.

Description

The utility model relates to computer technology and can be used in digital signal processing to convert a digital binary code into a bipolar voltage.

A parallel digital-to-analog converter code-voltage based on a resistive matrix on weight resistors is known (Gitis E.I., Piskunov E.A. Analog-to-digital converters. M .: Energoizdat, 1981. S. 210, Fig. 6.1, a).

The device is designed to convert a binary code into a unipolar voltage. The converter contains n R-S triggers, an n-bit resistive matrix on weight resistors, n two-position electronic switches, a reference current adder and a reference voltage source. The outputs of the R-S triggers are connected respectively to the control inputs of the on-off electronic switches; the reference voltage source is connected to the input of the reference voltage supply of the resistive matrix on weight resistors, the normally closed contacts of the two-position electronic switches are connected to the "ground", and the normally open contacts of the two-position electronic switches are connected to the input of the reference current adder, the inputs S of the triggers are used to supply the converted binary code .

The disadvantage of this device is the impossibility of obtaining a bipolar output voltage.

A serial converter of a binary code to a unipolar voltage is known (Gitis E.I., Piskunov E.A. Analog-to-digital converters. M .: Energoizdat, 1981. S. 214, Fig. 6.3, a).

The main elements of the device are R-S flip-flop, electronic key, analog adder, reference voltage source and analog storage device. The R-S trigger output is connected to the control input of the electronic key, the output of which is connected to the first input of the analog adder, the second input of the analog adder is connected to the output of an analog storage device, the input of which is connected to the output of the analog adder, the output of the reference voltage source is connected to the signal input of the electronic key, the setting the input S of the trigger is used for the sequential supply of the converted binary code.

The disadvantages of this device are low speed, the inability to obtain bipolar output voltage.

The closest in technical essence to the proposed utility model is a parallel converter of a binary code to a unipolar voltage (Gitis E.I., Piskunov E.A. Analog-to-digital converters. M .: Energoizdat, 1981. S. 210, Fig. 6.1, b ).

The device is designed to convert a binary code into a unipolar voltage. The converter contains n R-S flip-flops, a reference voltage source, n two-position electronic switches, an n-bit resistive matrix R-2R and a voltage adder, the outputs of n R-S flip-flops are connected respectively to the control inputs of n two-position electronic switches, the reference voltage source is connected to normally open contacts n two-position electronic keys, normally closed contacts of n two-position electronic keys are connected to the "ground", the outputs of n two-position electronic keys are connected to the inputs of the n-bit resistive matrix R-2R, the output of which is connected to the input of the voltage adder, the inputs S of the flip-flops are used to supply the converted binary code.

The disadvantages of this device is the impossibility of obtaining a bipolar output voltage.

The main task to be solved by the utility model is to create a parallel code-to-voltage converter.

The technical result achieved in the implementation of the claimed utility model is a bipolar output voltage.

The specified technical result is achieved by the fact that a parallel converter of a binary code to a bipolar voltage with a resistive matrix R-2R, including n RS flip-flops, a reference voltage source, n two-position electronic switches, an n-bit resistive matrix R-2R and a voltage adder, outputs n RS triggers are connected respectively to the control inputs of n two-position electronic switches, the reference voltage source is connected to the normally open contacts of n two-position electronic switches, the normally closed contacts of n two-position electronic switches are connected to the "ground", the outputs of n two-position electronic switches are connected to the inputs of the n-bit resistive matrix R-2R, the output of which is connected to the input of the voltage adder, additionally contains an analog inverter, the first analog switch, the second analog switch, an analog adder and a logic inverter, the output of the voltage adder is connected simultaneously with the input of the analog inverter and signal th input of the second analog switch, the output of which is connected to the second input of the analog adder, the output of the logical inverter is connected to the control input of the first analog switch, the output of which is connected to the first input of the analog adder, the input d _sign sign bit is simultaneously connected to the control input of the second analog switch and the input logic inverter, the inputs of the converter d ₁ ,..., d _n are the inputs for supplying the converted binary code, the input d _sign serves to supply a sign bit, the output of the analog adder is the output of the converter.

The set technical result is achieved through the introduction of additional blocks and connections between them, which makes it possible to obtain both positive and negative output voltage of the converter.

The analysis of the prior art carried out by the applicant has established that the analogs do not have a set of features identical to the features of the claimed device "Parallel converter of a binary code to a bipolar voltage with a resistive matrix R-2R". Therefore, the claimed device meets the condition of "novelty".

The results of the search for known technical solutions in this and related fields of technology in order to identify features that match the distinctive features of the prototype of the proposed device showed that they do not follow explicitly from the prior art.

The essence of the utility model is illustrated by the drawing shown in Fig. one.

Parallel converter of binary code to bipolar voltage with resistive matrix R-2R includes n RS flip-flops 1-1,…,1-n, reference voltage source 2, n two-position electronic switches 3-1,…,3-n, n-bit resistive matrix R-2R 4-1,…,4-(2n+1), voltage adder 5, analog inverter 6, first analog switch 7, logic inverter 8, second analog switch 9, analog adder 10; outputs Q ₁ ,…, Q _n RS flip-flops 1-1,…,1-n are connected respectively to the control inputs of n on-off electronic keys 3-1,…, 3-n; normally open contacts 1 and 2 n of on-off electronic switches 3-1,…, 3-n are connected to the reference voltage source 2, normally-closed contacts 1 and 3 n of on-off electronic switches 3-1,…, 3-n are connected to ground , contacts 1 n of on-off electronic switches 3-1,…, 3-n are connected respectively with resistors 4-1,…, 4-n of n-bit resistive matrix R-2R 4-1,…,4-(2n+1) , the output of the n-bit resistive matrix R-2R 4-1,…,4-(2n+1) is connected to the input of the voltage adder 5, the output of which is simultaneously connected to the input of the analog inverter 6 and the signal input of the second analog switch 9, the output of which is connected with the second input of the analog adder 10, the output of the analog inverter 6 is connected to the signal input of the first analog switch 7, the output of the analog switch 7 is connected to the first input of the analog adder 10, the sign bit input d _zn is simultaneously connected to the control input of the second analog switch 9 and the input of the logical inverter 8, whose output connected to the control input of the first analog switch 7, the inputs of the converter d ₁ ,..., d _n are the inputs of the binary code to be converted, the output of the analog adder 10 is the output of the converter.

The K555TR2 microcircuit is used as R-S-triggers, the K140UD7 microcircuit is used as an analog inverter, the K561KT3 microcircuit is used as logical keys, the K140UD7 microcircuit is used as an analog adder, the K140UD7 microcircuit is used as a reference current adder, and the K155LN1 microcircuit is used as a logical inverter [ 12].

A parallel converter of a binary code to a bipolar voltage with a resistive matrix R-2R operates as follows.

In the initial state, before the start of the conversion process, the positive voltage of the reference voltage source 2 is supplied to normally open contacts 1 and 2 n of two-position electronic switches 3-1, ..., 3-n, and through normally closed contacts 1 and 3 n of two-position electronic switches 3-1 ,…, 3-n resistors 4-1,…, 4-n of the n-bit resistive matrix R-2R 4-1,…,4-(2n+1) receive zero voltage from the ground.

In the process of conversion, the input binary code d ₁ ,…,d _n is fed to the corresponding installation inputs S n RS of flip-flops 1-1,…,1-n and is fixed in them. With a positive value of the converted number, a logical zero is set at the sign input d _zn of the converter, with a negative number - a logical unit. Signals from outputs Q1,…, Qn n RS triggers 1-1,…,1-n switch n two-position electronic switches 3-1,…, 3-n. With a logical unit at the RS output of the trigger, contacts 1 and 2 of the electronic key are closed and the voltage of the reference voltage source 2 is supplied to the corresponding input n by the bit resistive matrix R-2R 4-1, ..., 4-n. At a logical zero at the output of the RS trigger, contacts 1 and 2 of the corresponding electronic key open and contacts 1 and 3 close. In this case, the zero voltage of the "ground" is supplied to the corresponding input n by the bit resistive matrix R-2R 4-1, ..., 4-n. The resulting voltage from the output of the n-bit resistive matrix R-2R 4-1, ..., 4-n is fed to the input of the voltage adder 5, from the output of which it is simultaneously fed to the input of the logical inverter 6 and the signal input of the second analog switch 9. From the output of the analog inverter 6 the inverted output voltage is fed to the signal input of the first analog switch 7.

With a positive converted number, when d _zn =0, a high-level voltage is set at the output of the logical inverter 8, under the action of which the analog key 7 opens and from its output a positive output voltage is supplied through the analog adder 10 to the output of the converter. With a negative converted number, when d _zn =1, the output of the logical inverter 8 is set to a low voltage. As a result, the analog key 7 closes, the analog key 9 opens, and from its output, a negative voltage flows through the analog adder 10 to the output of the converter.

As a result, the proposed converter allows you to get both positive and negative output voltage compared to the prototype.

The conversion of a binary code into a bipolar voltage is achieved due to the fact that the converter has an analog inverter that allows you to generate both positive and negative output voltage of the converter.

Comparison of the parameters characterizing the claimed device and the prototype allows us to conclude that the claimed device provides the possibility of forming a bipolar voltage converter at the output.

The above information proves that the following conditions are met when implementing the claimed model:

- a tool that embodies the proposed device in its implementation, is intended for use in computing, namely in digital signal processing devices;

- for the claimed device in the form as it is described in the independent claim of the utility model, the possibility of its implementation using the means described before the filing date of the application is confirmed;

- a tool that embodies the claimed device in its implementation, capable of obtaining the specified technical result.

Therefore, the claimed device meets the condition of "industrial applicability".

Sources of information taken into account:

1. Ziatdinov S.I., Suetina T.A., Povarenkin N.V. Circuit engineering of telecommunication devices. Textbook. M: Academy, 2016.

2. Shilo V.L. Popular digital circuits. Moscow: Radio and communication, 1988.

Claims (1)

Parallel converter of binary code to bipolar voltage with resistive matrix R-2R, including n R-S flip-flops, reference voltage source, n two-position electronic switches, n-bit resistive matrix R-2R and voltage adder; the outputs of n R-S triggers are connected respectively to the control inputs of n two-position electronic switches, the reference voltage source is connected to the normally open contacts of n two-position electronic switches, the normally closed contacts of n two-position electronic switches are connected to ground, the outputs of n two-position electronic switches are connected to the inputs n- bit resistive matrix R-2R, the output of which is connected to the input of the voltage adder, characterized in that the device additionally contains an analog inverter, the first analog switch, the second analog switch, an analog adder and a logic inverter, the output of the voltage adder is connected simultaneously to the input of the analog inverter and the signal input of the second analog switch, the output of which is connected to the second input of the analog adder, the output of the logic inverter is connected to the control input the first analog switch, the output of which is connected to the first input of the analog adder, input d_znsign bit is simultaneously connected to the control input of the second analog key and the input of the logical inverter, the inputs of the converter d_one,…, d_nare the inputs of the binary code to be converted, input d_znis the sign bit input, the output of the analog adder is the output of the converter.

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