Chapter 6: Difference between revisions

Latest revision as of 23:00, 24 March 2010

Digital Logic Gates

Boolean Algebra
A	B	NAND ${\overline {AB}}$	NOR ${\overline {A+B}}$	XOR $A\oplus B$
0	0	1	1	0
0	1	1	0	1
1	0	1	0	1
1	1	0	0	0

De Morgan Laws & NAND Equivalent Gates

"If the variables in a logic expression are replaced by their inverses, and if the AND operation is replaced by OR, the OR operation is replaced by AND, and the expression is inverted, the resulting logic expression yields the same values as before the changes."<ref>Electronics p.353</ref>
It is possible to create any combinatorial logic function with solely NAND (or NOR) gates

Gate	Symbol	NAND equivalent
Inverter	${\overline {A}}$	${\overline {AA}}$
AND	$AB$	${\overline {({\overline {A}}+{\overline {B}})}}$
OR	$A+B$	${\overline {({\overline {A}}\,{\overline {B}})}}$

CMOS Inverter

Zero static power consumption
$KP_{p}={\frac {1}{2}}KP_{n}$ , thus ${\frac {W}{L}}_{p}=2{\frac {W}{L}}_{n}$ to maintain symmetric transfer characteristics.

Questions

p.365: Why even have R_on?
p.377: What problems are there with the NMOS pull-up?
p.382: For CMOS, are the transistors in Triode or Saturation when they're in the "ON" state? How can we tell?

References

@@ Line 1: / Line 1: @@
-===Digital Logic===
+===Digital Logic Gates===
 {| class="wikitable" border="1" style="text-align:center"
 |+Boolean Algebra
@@ Line 13: / Line 13: @@
 |}
-*'''NAND Equivalent Gates'''
+===De Morgan Laws & NAND Equivalent Gates===
+*"If the variables in a logic expression are replaced by their inverses, and if the AND operation is replaced by OR, the OR operation is replaced by AND, and the expression is inverted, the resulting logic expression yields the same values as before the changes."<ref>Electronics p.353</ref>
-:*Inv: <math>\overline{AA}=\overline{A}</math>, Nand with the inputs tied together
+*It is possible to create any combinatorial logic function with solely NAND (or NOR) gates
-:*AND: <math>\overline{(\overline{AB})}</math>, NAND followed by and Inv
+{| class="wikitable" border="1" style="text-align:center"
-:*OR: <math>\overline{(\overline{A} \, \overline{B})}=A+B</math>
+!Gate!!Symbol!!NAND equivalent
-*De Morgan Laws
+|-
-:*
+|Inverter||<math>\overline{A}</math>||<math>\overline{AA}</math>
-:*
+|-
+|AND||<math>AB</math>||<math>\overline{(\overline{A}+\overline{B})}</math>
+|-
+|OR||<math>A+B</math>||<math>\overline{(\overline{A} \, \overline{B})}</math>
+|}
+===CMOS Inverter===
+*Zero static power consumption
+*<math>KP_p=\frac{1}{2}KP_n</math>, thus <math>\frac{W}{L}_p=2\frac{W}{L}_n</math> to maintain symmetric transfer characteristics.
+===Questions===
+*p.365: Why even have R_on?
+*p.377: What problems are there with the NMOS pull-up?
+*p.382: For CMOS, are the transistors in Triode or Saturation when they're in the "ON" state? How can we tell?
+===References===
+<references/>

Chapter 6: Difference between revisions

Latest revision as of 23:00, 24 March 2010

Contents

Digital Logic Gates

De Morgan Laws & NAND Equivalent Gates

CMOS Inverter

Questions

References

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Chapter 6: Difference between revisions

Latest revision as of 23:00, 24 March 2010

Digital Logic Gates

De Morgan Laws & NAND Equivalent Gates

CMOS Inverter

Questions

References

Navigation menu

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