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<font size="4">'''[[ECE_270_SLecture_Table_of_Contents|The Brown-Meyer Lectures on Digital Systems]]''' </font>  
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<font size="4">'''[[ECE_270_Digital_System_Design_Slecture_Wayner_Table_of_Contents|The Meyer Lectures on Digital Systems]]''' </font>  
  
 
'''Module 1: Boolean Algebra &amp; CMOS logic structures'''
 
'''Module 1: Boolean Algebra &amp; CMOS logic structures'''
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[[slectures|Slectures]] by [[User:Rwayner|Robert Wayner]]  
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1.2 Making Logic Gates from MOSFETs
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[https://www.projectrhea.org/learning/slectures.php Slectures] by [[User:Rwayner|Robert Wayner]]  
  
 
© 2013  
 
© 2013  
 
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= 1.2 Making Logic Gates from MOSFETs =
 
 
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== Introduction ==
 
== Introduction ==
Voltage controlled MOSFETs make the most fundamental logic gates. It is important to know basic configurations of MOSFETs to be able to resemble logic gatee, mainly to assemble them on real circuit boards. Many circuits nowadays use transistors to make logic gate configurations.
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Voltage controlled MOSFETs make the most fundamental logic gates. It is important to know basic configurations of MOSFETs to be able to resemble logic gates, mainly to assemble them on circuit boards. Many circuits nowadays use basic transistors to make logic gate configurations.
 
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The video below will show how they work and how to make a basic inverter using them.
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The video below will show how N-channel and P-channel MOSFETs work and how to make a basic inverter using them.
  
 
<youtube>2qTc6l-W-rU</youtube>
 
<youtube>2qTc6l-W-rU</youtube>
  
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In addition to the theory of MOSFETS as shown above, the video below will demonstrate ways to configure MOSFETs into logic gates.
  
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<youtube>shgxUhFPn2c</youtube>
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Lastly to make AND & OR gates using MOSFETS, simply attach an inverter (shown in first video) to the end of a NAND/NOR MOSFET configuration (shown in second video).
  
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=Relevant Links=
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*[[Media:ECE_270_Slecture_1.2_Notes.pdf|Accompanying lecture notes by Prof. Meyer]]
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*[[2013 Fall ECE 270 Brown|ECE 270 Homepage]]
 
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[[ECE_270_SLecture_Table_of_Contents|Back to table of content for "The Brown-Meyer Lectures on Digital Systems Design"]]
 
[[ECE_270_SLecture_Table_of_Contents|Back to table of content for "The Brown-Meyer Lectures on Digital Systems Design"]]
 
[[2013 Fall ECE 270 Brown|Back to ECE 270 Homepage]]
 

Latest revision as of 06:32, 26 February 2014


The Meyer Lectures on Digital Systems

Module 1: Boolean Algebra & CMOS logic structures

1.2 Making Logic Gates from MOSFETs

Slectures by Robert Wayner

© 2013


Introduction

Voltage controlled MOSFETs make the most fundamental logic gates. It is important to know basic configurations of MOSFETs to be able to resemble logic gates, mainly to assemble them on circuit boards. Many circuits nowadays use basic transistors to make logic gate configurations.


The video below will show how N-channel and P-channel MOSFETs work and how to make a basic inverter using them.

In addition to the theory of MOSFETS as shown above, the video below will demonstrate ways to configure MOSFETs into logic gates.

Lastly to make AND & OR gates using MOSFETS, simply attach an inverter (shown in first video) to the end of a NAND/NOR MOSFET configuration (shown in second video).


Relevant Links


Back to table of content for "The Brown-Meyer Lectures on Digital Systems Design"

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