How does a CMOS NAND gate work?
Table of Contents
How does a CMOS NAND gate work?
CMOS NAND Gate It consists of two series NMOS transistors between Y and Ground and two parallel PMOS transistors between Y and VDD. If either input A or B is logic 0, at least one of the NMOS transistors will be OFF, breaking the path from Y to Ground.
Where is a NAND gate used?
NAND gates can also be used to produce any other type of logic gate function, and in practice the NAND gate forms the basis of most practical logic circuits. By connecting them together in various combinations the three basic gate types of AND, OR and NOT function can be formed using only NAND gates, for example.
How can a NAND gate be used as an inverter?
You can easily turn a NAND gate into a single-input inverter (that is, a NOT gate) by connecting the single input to both inputs of the NAND gate. This connection causes the two inputs to always be the same: Either both are HIGH, or both are LOW.
How would you implement NAND gate using CMOS?
The above drawn circuit is a 2-input CMOS NAND gate. Now let’s understand how this circuit will behave like a NAND gate. The circuit output should follow the same pattern as in the truth table for different input combinations. As VA and VB both are low, both the pMOS will be ON and both the nMOS will be OFF.
Why do we use NAND gates instead of AND gates?
In general, cells are designed to have similar drive strength of pull up and pull down structures to have comparable rise and fall time. NAND gate has better ratio of output high drive and output low drive as compared to NOR gate. Hence NAND gate is preferred over NOR.
What is the purpose of using CMOS over Gates?
A CMOS gate also draws much less current from a driving gate output than a TTL gate because MOSFETs are voltage-controlled, not current-controlled, devices. This means that one gate can drive many more CMOS inputs than TTL inputs. The measure of how many gate inputs a single gate output can drive is called fanout.