RU2444050C1 - Single-digit adder - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device comprises field transistors of P-type from the first to the ninth one, field transistors of N-type from the tenth to the eighteenth one, inputs of summands A and B, input of transfer C_in, supply outputs of high and low voltage levels, the first inverter, the output of which is the output of the transfer C_out signal, the second inverter, the output of which is the output of the summing result S, the third inverter and the double-input logical element EXCLUDING-OR.

EFFECT: increased reliability and reduction of adder dimensions.

1 dwg, 1 tbl

Description

The present invention relates to computer technology and can be used in the construction of multi-bit high-speed adders and ALU.

The well-known One-bit adder [Hubert Kaeslin, "Digital Integrated Circuit Design. From VLSI Architectures to CMOS Fabrication ”, Cambridge University Press, New York, 2008. p.408, Fig. 8.18 (c)] (in the text: Mirror adder (mirror adder)).

A disadvantage of the known single-bit adder is the low speed of the formation of the transfer signal. In the indicated single-digit adder, the transfer input C _{IN is} connected to the gates of three complementary pairs of transistors, which make the main contribution to the value of the parasitic input capacitance at this input. Since the input capacitance is a capacitive load for the transfer signal C _IN , its value directly affects the switching time of the transistors connected to the transfer input C _IN , and this ceteris paribus is directly proportional to the value of this capacitance and, therefore, the value the time of formation of the input and, accordingly, the output signal of the first inverter. Thus, the increased value of the parasitic input capacitance leads to an increase in the delay in the formation of the transfer signal at the output C _OUT .

In addition, it is known single-digit adder [Shubin V.V., patent for the invention of the Russian Federation No. 2380739, G06F 7/50, adder, FGU FIPS, bulletin No. 3, 01/27/2010], which is the prototype of the invention and containing field-effect transistors P -types from one to twelfth and N-type from thirteenth to twenty-fourth, the input of the term A connected to the gates of the first, fifth, sixth, tenth, fourteenth, sixteenth, nineteenth and twenty-fourth transistors, the input of the term B connected to the gates of the second, fourth, seventh, eleventh , Fifteenth, seventeenth, twentieth and twenty-third transistors, C _IN transfer input coupled to the gates of the third, twelfth, thirteenth and twenty-second transistors, the output of the high-level power voltage connected to the sources of the first, second, fourth, sixth, seventh, eighth and tenth of transistors, low voltage power output connected to the sources of the fourteenth, fifteenth, seventeenth, nineteenth, twentieth, twenty first and twenty fourth transistors, two-input loop logical AND-NOT element, the first and second inputs of which are connected to the inputs of the terms, respectively, A and B, and the output - with the gate of the eighth transistor and the two-input logic element OR-NOT, the first and second inputs of which are connected to the inputs of the terms, respectively, A and B, and the output is with the gate of the twenty-first transistor, and the drains of the first and second transistors are connected to the source of the third, the drain of the fourth to the source of the fifth, the drains of the sixth and seventh to the source of the ninth, the drain of the tenth to the source of the eleventh, the drains of the eighth and eleven atogo - with the source of the twelfth, drains of the fourteenth and fifteenth - with the source of the thirteenth, stock of the seventeenth - with the source of the sixteenth, drains of the nineteenth and twentieth - with the source of the eighteenth, stock twenty-fourth - with the source of twenty-third, drains of the twenty-first and twenty-third - with the source of twenty second, third drains, the fifth, thirteenth and sixteenth - the gate electrodes of the ninth and eighteenth transistors and the input of the first inverter, whose output is the output carry signal C _OUT and drains of the ninth, twelfth o, eighteenth and twenty-second transistors - to the input of the second inverter, whose output is the output of summing the result S.

A disadvantage of the known One-bit adder is that it contains a large number of elements and requires a large number of switching connections. Since the reliability of any physical object cannot be absolute and directly depends on the number of components in its composition and the number of connections connecting these components, the use of more components and connections between them when creating any device reduces the reliability of this device.

In addition, the use of a larger number of components and relationships when creating a device leads to an increase in its overall dimensions, in this case, a single-bit adder.

The objective of the invention is to increase the reliability of a single-digit adder and reduce its overall dimensions.

The problem is achieved in that in a single-bit adder containing P-type field-effect transistors from the first to the ninth and N-type from the tenth to the eighteenth, the input of the term A connected to the gates of the first, fifth, eleventh and thirteenth transistors, the input of the term B connected the gate electrodes of the second, fourth, twelfth and fourteenth transistors, C _IN transfer input coupled to the gates of the third, ninth, tenth and seventeenth transistors, the output of the high-level power voltage connected to the sources of n, of the second, fourth, eighth and eighth transistors, a low voltage power output connected to the sources of the eleventh, twelfth, fourteenth and eighteenth transistors, the drains of the first and second transistors connected to the source of the third, the drain of the fourth to the source of the fifth, the drain of the sixth to the source seventh, runoff of the eighth with the source of the ninth, runoff of the eleventh and twelfth with the source of the tenth, runoff of the fourteenth with the source of the thirteenth, runoff of the sixteenth with the source of the fifteenth, runoff of the eighteenth with the source of eye of the seventeenth, the drains of the third, fifth, tenth and thirteenth with the gates of the seventh and fifteenth transistors and the input of the first inverter, the output of which is the output of the transfer signal C _OUT , and the drains of the seventh, ninth, fifteenth and seventeenth with the input of the second inverter, the output of which is the output of the result of addition S, a third inverter is introduced, the output of which is connected to the source of the sixteenth and gates of the sixth and eighteenth transistors and a two-input logic element EXCLUSIVE-OR, the first and second inputs of which the second are connected to the inputs of the terms A and B, respectively, and the output is connected to the source of the sixth and the gates of the eighth and sixteenth transistors and the input of the third inverter.

Thus, in the proposed One-bit adder, in comparison with the prototype, there are no transistors: the seventh, tenth, eleventh, twentieth, twenty-third and twenty-fourth, and therefore all the connections that were used to connect the terminals of these transistors, which improves the reliability of the Single-bit adder and to reduce its overall dimensions, while maintaining the speed achieved by the prototype.

The drawing shows a diagram of the proposed single-digit adder.

The proposed single-digit adder contains: P-type field-effect transistors from the first 1 to 9th 9 and N-type transistors from the tenth 10 to the eighteenth 18, the input of the term A, connected to the gates of the first 1, fifth 5, the eleventh 11 and the thirteenth 13 transistors, the input of the term B connected to the gates of the second 2, fourth 4, twelfth 12 and fourteenth 14 transistors, a transfer input C _IN connected to the gates of the third 3, ninth 9, tenth 10 and seventeenth 17 transistors, a high voltage level power output 19, connected to the sources of the first 1 , of the second, fourth, fourth, and eighth 8 transistors, a low voltage supply terminal 20 connected to the sources of the eleventh 11th, twelfth 12th, fourteenth 14th and eighteenth 18th transistors, and the drains of the first 1 and second 2 transistors are connected to the source of the third 3, the drain of the fourth 4 - with a source of the fifth 5, a drain of the sixth 6 - with a source of the seventh 7, a drain of the eighth 8 - with a source of the ninth 9, sinks of the eleventh 11 and twelfth 12 - with a source of the tenth 10, a drain of the fourteenth 14 - with a source of the thirteenth 13, a stock of the sixteenth 16 - with the source of the fifteenth 15, current eighteenth 18 - with a source of the seventeenth 17, the third three effluents fifth 5, tenth 10 and the thirteenth 13 - the gate electrodes of the seventh 7 and fifteenth 15 transistors and the input of the first inverter 21, whose output is the output carry signal C _OUT, and the drains of the seventh 7, ninth 9, fifteenth 15 and seventeenth 17 - with the input of the second inverter 22, the output of which is the output of the result of addition S, the third inverter 23, the output of which is connected to the source of the sixteenth 16 and the gates of the sixth 6 and eighteenth 18 transistors and a two-input logic element EXCLUSIVE-OR 24, the first and second inputs of which are connected to the inputs of the terms A and B, respectively, and the output is connected to the source of the sixth 6 and the gates of the eighth 8 and sixteenth 16 transistors and the input of the third inverter 23.

Arbitrary execution of logic elements of the first, second and third inverters and two-input logic element EXCLUSIVE-OR, which implement the corresponding function, is allowed.

The proposed single-digit adder is a logical combination circuit type and works as follows.

The inputs of the terms A and B receive the values of signals requiring addition, and the transfer signal C _IN receives the value of the transfer signal.

As a result of the action of the signals supplied to the inputs of the single-bit adder C _IN , A and B, the values of the signals corresponding to the truth table below should appear on its outputs C _OUT and S.

Table the truth of a single bit adder. Combination number C _IN A AT C _OUT S one 0 0 0 0 0 2 0 0 one 0 one 3 0 one 0 0 one four 0 one one one 0 5 one 0 0 0 one 6 one 0 one one 0 7 one one 0 one 0 8 one one one one one

In combinations No. 1-4, a low-level voltage is supplied to the transfer input C _IN and to the gates of the transistors 3, 9, 10, and 17 connected to it, which corresponds to the value “0” of the adder truth table. Therefore, transistors P-type 3 and 9 open, and N-type 10 and 17 - closes.

If, at the same time, low-level voltage is supplied to the inputs of the terms A and B, then P-type transistors 1, 2, 4, and 5 connected by these gates to these inputs open and N-types 11-14 close and the two-input output of the logic element EXCLUSIVE-OR 24, in accordance with the function performed by it, a low level voltage is formed - “0”, which is supplied to the gates of transistors 8 and 16 and the source of the transistor 6 and the input of the third inverter 23. Since the voltage is supplied to the input of the third inverter 23 low level - "0", then on its output after the inverse and a high level voltage is generated corresponding to the value “1” of the adder truth table, which is fed to the gates of transistors 6 and 18 and the source of transistor 16. Therefore, transistors of P-type 6 and N-type 16 are closed, and P-type 8 and N-type 18 - open. Through open transistors 1-5 and 8-9 from the high voltage level power supply output 19, the gates of the first 21 and second 22 inverters receive a high level voltage “1”, which closes the P-type 7 transistor and opens N-type transistor 15. Since the high level voltage is “1” at the inputs of the first 21 and second 22 inverters, after inversion, their outputs, respectively, C _OUT and S, form low-level voltages - “0”. At the same time, the inputs of the first 21 and second 22 inverters remain isolated from low-level voltage by closed N-type transistors 10-14 and 17 and P-type 6 and 7. Thus, combination No. 1 of the truth table of the Single-bit adder is implemented.

If the input of the term A (B) receives the low level voltage - “0”, and the input of the term B (A) high - “1”, then the P-type transistors 1 (2), 5 (4) and N-type 12 (11), 14 (13), connected by their gates to these inputs - open, P-type 2 (1), 4 (5) and N-type 11 (12), 13 (14) - close, and on the output of the two-input logic element EXCLUSIVE-OR 24, in accordance with the function it performs, a high-level voltage is generated - “1”, which is supplied to the gates of transistors 8 and 16 and the source of the transistor 6 and the input of the third inverter 23. Since the input to the third inverter and 23, a high level voltage “1” is supplied, then a low level voltage “0” is generated at its output after inversion, which is supplied to the gates of transistors 6 and 18 and the source of transistor 16. Therefore, P-type 6 and N-type transistors 16 - open, and P-type 8 and N-type 18 - close. Through open transistors 1 (2) and 3 from the output of the power supply of a high voltage level 19, the gates of the transistors 7 and 15 and the input of the first inverter 21 receives a high level voltage - "1". Therefore, the P-type transistor 7 closes, the N-type transistor 15 opens. Since at the input of the first inverter 21 the high level voltage is “1”, then after inversion at its output C _OUT , a low level voltage “0” is formed. At the same time, from the output of the third inverter 23 through open N-type transistors 15 and 16, the input of the second inverter 22 receives a low level voltage - "0", which is inverted at its output S to a high level voltage - "1". In this case, the input of the first inverter 21 remains isolated from the low level voltage by closed N-type transistors 10 and 13 (14), and the input of the second 22 from the high level voltage by closed P-type transistors 7 and 8. Thus, the combination No. 2 ( No. 3) truth tables of the One-bit adder.

In the case when a high level voltage “1” is applied to inputs A and B, P-type transistors 1, 2, 4, 5, connected by their gates to these inputs, are closed, N-types 11-14 are opened, and on the output of the two-input logic element EXCLUSIVE-OR 24 in accordance with the function it performs, a low-level voltage is generated, which is supplied to the gates of the transistors 8 and 16 and the source of the transistor 6 and the input of the third inverter 23. Since the low level voltage is applied to the input of the third inverter 23 - "0", then at its output after inversion is formed I have a high-level voltage - “1”, which goes to the gates of transistors 6 and 18 and the source of transistor 16. Therefore, transistors P-type 8 and N-type 18 - open, and P-type 6 and N-type 16 - close. Through the open transistors 13 and 14 from the output of the low voltage level 20 voltage, the gates of the transistors 7 and 15 and the input of the first inverter 21 receive a low level voltage - "0". Therefore, the P-type 7 transistor opens, and the N-type 15 transistor closes. Since the low level voltage is “0” at the input of the first inverter 21, then after inversion, a high level voltage “1” is formed at its output C _OUT . Simultaneously with the output of the power supply of a high voltage level 19, through the open transistors of P-type 8 and 9, a high level voltage “1” is supplied to the input of the second inverter 22. Therefore, at the output S of this inverter, an inverse with respect to the input voltage of a low level is formed - "0". In this case, the input of the first inverter 21 remains isolated from the high level voltage by closed P-type transistors 1, 2, 4, 5 and the second inverter 22 - from the low level voltage by the closed N-type transistors 15-17. Thus, combination No. 4 of the truth table of the Single Bit Adder is implemented.

In combinations No. 5-8, the high-level voltage “1” is applied to the transfer input C _IN and to the gates of the transistors 3, 9, 10, and 17 connected to it. Therefore, P-type transistors 3 and 9 are closed, and N-types 10 and 17 are opened.

If, at the same time, low-level voltage is supplied to the inputs of the terms A and B, then P-type transistors 1, 2, 4, and 5 connected by these gates to these inputs open and N-types 11-14 close and the two-input output of the logic element EXCLUSIVE-OR 24, in accordance with the function performed by it, a low level voltage is formed - “0”, which is supplied to the gates of transistors 8 and 16 and the source of the transistor 6 and the input of the third inverter 23. Since the voltage is supplied to the input of the third inverter 23 low level - "0", then on its output after the inverse and a high level voltage is formed - “1”, which is supplied to the gates of transistors 6 and 18 and the source of transistor 16. Therefore, transistors of P-type 6 and N-type 16 are closed, and P-type 8 and N-type 18 are opened. Through the open transistors 4, 5 from the high voltage level power supply output 19, the gates of the transistors 7, 15 and the input of the first inverter 21 receive a high level voltage - "1", which closes the P-type transistor 7 and opens the N-type transistor 15. So as at the input of the first inverter 21 the high level voltage is "1", then after inversion at its output C _OUT a low level voltage "0" is formed. At the same time, through open transistors 17 and 18 from the output of the low-voltage supply voltage 20, a low-level voltage “0” is supplied to the input of the second inverter 22. Therefore, at the output S of this inverter, an inverse voltage of a high level, “1”, is generated. In this case, the input of the first inverter 21 remains isolated from the low level voltage by closed N-type transistors 11, 12, 13 and 14, and the input of the second inverter 22 is isolated from the high voltage by closed P-type transistors 6 and 9. Thus, the combination No. 5 truth tables of the One-bit adder.

If the input of the term A (B) receives the low level voltage - “0”, and the input of the term B (A) high - “1”, then the P-type transistors 1 (2), 5 (4) and N-type 12 (11), 14 (13), connected by their gates to these inputs - open, P-type 2 (1), 4 (5) and N-type 11 (12), 13 (14) - close, and on the output of the two-input logic element EXCLUSIVE-OR 24, in accordance with the function it performs, a high-level voltage is generated - “1”, which is supplied to the gates of transistors 8 and 16 and the source of the transistor 6 and the input of the third inverter 23. Since the input to the third inverter and 23, a high level voltage “1” is supplied, then a low level voltage is generated at its output after inversion, which is supplied to the gates of transistors 6 and 18 and the source of transistor 16. Therefore, transistors P-type 6 and N-type 16 open, and P -type 8 and N-type 18 - are closed. Through the open transistors 10 and 12 (11) from the output of the low-voltage power supply 20 to the gates of the transistors 7 and 15 and to the input of the first inverter 21, the low-level voltage - "0". Therefore, the P-type transistor 7 opens, the N-type transistor 15 closes. Since the low level voltage is “0” at the input of the first inverter 21, then after inversion, a high level voltage “1” is formed at its output C _OUT . Simultaneously with the output of the two-input logic element EXCLUSIVE-OR 24 through the open transistors of P-type 6 and 7, the input of the second inverter 22 receives a high level voltage - "1", which is inverted at its output S to a low level voltage - "0". In this case, the input of the first inverter 21 remains isolated from the high level voltage by closed P-type transistors 3 and 4 (5), and the input of the second 22 from the low level voltage by the closed transistors N-type 15 and 18. Thus, the combination No. 6 ( No. 7) truth tables of the One-bit adder.

In the case when a high level voltage “1” is supplied to inputs A and B, P-type transistors 1, 2, 4, 5 connected by their gates to these inputs are closed, N-type 11-14 are opened, and at the output of a two-input of the logic element EXCLUSIVE-OR 24, in accordance with the function performed by it, a low level voltage is generated, which is supplied to the gates of transistors 8 and 16 and the source of the transistor 6 and the input of the third inverter 23. Since the low level voltage is supplied to the input of the third inverter 23 - 0 ", then at its output after inversion is formed high-level voltage - “1”, which is supplied to the gates of transistors 6 and 18 and the source of transistor 16. Therefore, transistors P-type 8 and N-type 18 are opened, and P-type 6 and N-type 16 are closed. Through the open transistors 10-14 from the output of the low-voltage power supply 20 to the gates of the transistors 7 and 15 and to the input of the first inverter 21, the low-level voltage - "0". Therefore, the transistor P-type 7 opens, N-type 15 - closes. Since the low level voltage is “0” at the input of the first inverter 21, then after inversion, a high level voltage “1” is formed at its output C _OUT . Simultaneously with the output of the low level voltage supply 20, through the open N-type transistors 17 and 18, the low level voltage “0” is supplied to the input of the second inverter 22. Therefore, at the output S of this inverter, an inverse voltage of a high level, “1”, is generated. In this case, the input of the first inverter 21 remains isolated from high-level voltage by closed P-type transistors 1-5 and the second inverter 22 from high-level voltage by closed P-type transistors 6 and 9. Thus, combination No. 8 of the truth table of the Single Bit Adder is implemented.

In the proposed single-digit adder circuit, a two-input EXCLUSIVE-OR logic element and a third inverter are introduced, which allows excluding P-type transistors of the seventh, tenth, eleventh, N-type twentieth, twenty-third and twenty-fourth and two-input I-NOT logic gates from the prototype circuit and OR NOT, as a result of which the total number of transistors used in the Single-Bit Adder circuit is reduced by six and all the connections that were previously used to connect the terminals of these transistors are eliminated, which allows t improve the reliability of one-bit adder and reduce its weight and overall dimensions, while maintaining the performance reached the prototype.

Thus, in the proposed single-digit adder by reducing the number of components used and the connections needed to connect them, the reliability is increased and the overall dimensions of the device are reduced. At the same time, the speed achieved by the prototype remains at the same level.

Claims (1)

A one-bit adder containing P-type field-effect transistors from the first to the ninth and N-type from the tenth to the eighteenth, the input of the term A connected to the gates of the first, fifth, eleventh and thirteenth transistors, the input of the term B connected to the gates of the second, fourth, twelfth and fourteenth transistors, C _IN transfer input coupled to the gates of the third, ninth, tenth and seventeenth transistors, the output of the high-level power voltage connected to the sources of the first, second, fourth and eighth tRANSIT stors, a low voltage level power output connected to the sources of the eleventh, twelfth, fourteenth and eighteenth transistors, the drains of the first and second transistors connected to the source of the third, the drain of the fourth to the source of the fifth, the drain of the sixth to the source of the seventh, the drain of the eighth to the source ninth, runoff of the eleventh and twelfth - with the source of the tenth, runoff of the fourteenth - with the source of the thirteenth, runoff of the sixteenth - with the source of the fifteenth, runoff of the eighteenth - with the source of the seventeenth, drains of the third, fifth, esyatogo and thirteenth - the gate electrodes of the seventh and fifteenth transistors and the input of the first inverter, whose output is the output carry signal C _OUT, and the drains of the seventh, ninth, fifteenth and seventeenth - to the input of the second inverter, whose output is the output of the addition result S, wherein that a third inverter is introduced into it, the output of which is connected to the source of the sixteenth and the gates of the sixth and eighteenth transistors and a two-input logic element EXCLUSIVE-OR, the first and second inputs of which are connected contain terms A and B respectively, and the output - to the source of the sixth and the eighth and sixteenth gate transistors and the input of the third inverter.