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ans. 3 nand gates resoon :- OR GATE :- x+y NAND GATE :- x'+y' LOGIC :-so the logic is is we apply NAND to the inputs x' and y' instead of xand y we would get x+y DESIGN PROCEDURE 1. for inverting the input x and y can be done by NAND gates , 2. take a NAND gate and pass both x in both the inputs it means x NAND x gives you x' 3. follow similar procedure for inverting y 4. and then all the outputs of those NAND gates as the inputs of another NAND gate
it's a little and basic integrated circuit that makes calculations regarding Boole's logic (true/false) they can make various operations instantly regarding as the type of logic gate based on the 2 inputs, giving the result as output. they can make the OR operand, And, Xor,Not and a combination of them (cheaper) Nor,Nand,XNor it's the base for digital computing.
Mostly Japanese prefer negative logic so you can face negative logic in Japanese equipment only
nor as well as nand gate are universal gates they both can be used as a complete set of logic gates
universal logic gate is a gate using which you can make all the logic gates there are two such gates NOR gate and NAND gate
A: two
A "Nand" gate is an "And" gate with an "Inverter" added to its output. To get a logic 1 output from a "Nand" gate, you need a logic 0 on both of its inputs. If I understand your question correctly, you have three "Nand" gates. Presumably the outputs of two of them are connected to the inputs of the third. Logic 1 at both inputs of the first two "Nand" gates will produce a logic 0 output from both of them. The two logic 0's are fed to the inputs of the third "Nand" gate producing a logic 0 output from the third "Nand" gate.
It means that C is the inverse of A. Implementing the equation C = !A in basic logic gates requires the use of an inverter. An inverter can be made from a dedicated inverter gate, if available, or from a NAND gate with n inputs, where all n inputs are connected to A.
AND, OR, XOR, BUFFERNAND, NOR, XNOR, NOT/INVERTERAny of these except the BUFFER and NOT/INVERTER can have 2 or more inputs.Any of these can have Schmitt Trigger inputs to reduce noise sensitivity.Any of these can have a tristate output driver that can be switched off by a control input.This results in a potentially unlimited number of variant logic gates.
ans. 3 nand gates resoon :- OR GATE :- x+y NAND GATE :- x'+y' LOGIC :-so the logic is is we apply NAND to the inputs x' and y' instead of xand y we would get x+y DESIGN PROCEDURE 1. for inverting the input x and y can be done by NAND gates , 2. take a NAND gate and pass both x in both the inputs it means x NAND x gives you x' 3. follow similar procedure for inverting y 4. and then all the outputs of those NAND gates as the inputs of another NAND gate
it's a little and basic integrated circuit that makes calculations regarding Boole's logic (true/false) they can make various operations instantly regarding as the type of logic gate based on the 2 inputs, giving the result as output. they can make the OR operand, And, Xor,Not and a combination of them (cheaper) Nor,Nand,XNor it's the base for digital computing.
limitations of logic gates
The reversible logic is different from the other logics because of the Toffoli gates are used.
types of optical logic gates
combinational circuit is depend only on inputs,like sequential circuits its not depend on previous outputs.
Mostly Japanese prefer negative logic so you can face negative logic in Japanese equipment only
Logic gates can be classified in a variety of ways.AND GATEOR GATENAND GATENOR GATENOT GATEXOR GATEXNOR GATEOR they can be classified according to the manufacturing type. i. e.RTLDTLTTLIILCMOSNMOSPMOS