VLSI design Lecture 1: MOS Transistor Theory. CMOS VLSI Design3: CMOS Transistor TheorySlide 2 Outline  Introduction  MOS Capacitor  nMOS I-V Characteristics.

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Presentation transcript:

VLSI design Lecture 1: MOS Transistor Theory

CMOS VLSI Design3: CMOS Transistor TheorySlide 2 Outline  Introduction  MOS Capacitor  nMOS I-V Characteristics  pMOS I-V Characteristics

CMOS VLSI Design3: CMOS Transistor TheorySlide 3 Introduction  Treatment of transistors as something beyond ideal switches  An ON transistor passes a finite amount of current –Depends on terminal voltages –Derive current-voltage (I-V) relationships  Transistor gate, source, drain all have capacitance –I = C (  V/  t) ->  t = (C/I)  V –Capacitance and current determine speed

CMOS VLSI Design3: CMOS Transistor TheorySlide 4 MOS Capacitor  Gate and body form MOS capacitor  Operating modes –Accumulation –Depletion –Inversion

CMOS VLSI Design3: CMOS Transistor TheorySlide 5 Terminal Voltages  Mode of operation depends on V g, V d, V s –V gs = V g – V s –V gd = V g – V d –V ds = V d – V s = V gs - V gd  Source and drain are symmetric diffusion terminals –By convention, source is terminal at lower voltage –Hence V ds  0  nMOS body is grounded. First assume source is 0 too.  Three regions of operation –Cutoff –Linear –Saturation

CMOS VLSI Design3: CMOS Transistor TheorySlide 6 nMOS Cutoff  No channel  I ds = 0

CMOS VLSI Design3: CMOS Transistor TheorySlide 7 nMOS Linear  Channel forms  Current flows from d to s –e - from s to d  I ds increases with V ds  Similar to linear resistor

CMOS VLSI Design3: CMOS Transistor TheorySlide 8 nMOS Saturation  Channel pinches off  I ds independent of V ds  We say current saturates  Similar to current source

CMOS VLSI Design3: CMOS Transistor TheorySlide 9 I-V Characteristics  In Linear region, I ds depends on –How much charge is in the channel? –How fast is the charge moving?

CMOS VLSI Design3: CMOS Transistor TheorySlide 10 Channel Charge  MOS structure looks like parallel plate capacitor while operating in inversion –Gate – oxide – channel  Q channel =

CMOS VLSI Design3: CMOS Transistor TheorySlide 11 Channel Charge  MOS structure looks like parallel plate capacitor while operating in inversion –Gate – oxide – channel  Q channel = CV  C =

CMOS VLSI Design3: CMOS Transistor TheorySlide 12 Channel Charge  MOS structure looks like parallel plate capacitor while operating in inversion –Gate – oxide – channel  Q channel = CV  C = C g =  ox WL/t ox = C ox WL  V = C ox =  ox / t ox

CMOS VLSI Design3: CMOS Transistor TheorySlide 13 Channel Charge  MOS structure looks like parallel plate capacitor while operating in inversion –Gate – oxide – channel  Q channel = CV  C = C g =  ox WL/t ox = C ox WL  V = V gc – V t = (V gs – V ds /2) – V t C ox =  ox / t ox

CMOS VLSI Design3: CMOS Transistor TheorySlide 14 Carrier velocity  Charge is carried by e-  Carrier velocity v proportional to lateral E-field between source and drain  v =

CMOS VLSI Design3: CMOS Transistor TheorySlide 15 Carrier velocity  Charge is carried by e-  Carrier velocity v proportional to lateral E-field between source and drain  v =  E  called mobility  E =

CMOS VLSI Design3: CMOS Transistor TheorySlide 16 Carrier velocity  Charge is carried by e-  Carrier velocity v proportional to lateral E-field between source and drain  v =  E  called mobility  E = V ds /L  Time for carrier to cross channel: –t =

CMOS VLSI Design3: CMOS Transistor TheorySlide 17 Carrier velocity  Charge is carried by e-  Carrier velocity v proportional to lateral E-field between source and drain  v =  E  called mobility  E = V ds /L  Time for carrier to cross channel: –t = L / v

CMOS VLSI Design3: CMOS Transistor TheorySlide 18 nMOS Linear I-V  Now we know –How much charge Q channel is in the channel –How much time t each carrier takes to cross

CMOS VLSI Design3: CMOS Transistor TheorySlide 19 nMOS Linear I-V  Now we know –How much charge Q channel is in the channel –How much time t each carrier takes to cross

CMOS VLSI Design3: CMOS Transistor TheorySlide 20 nMOS Linear I-V  Now we know –How much charge Q channel is in the channel –How much time t each carrier takes to cross

CMOS VLSI Design3: CMOS Transistor TheorySlide 21 nMOS Saturation I-V  If V gd < V t, channel pinches off near drain –When V ds > V dsat = V gs – V t  Now drain voltage no longer increases current

CMOS VLSI Design3: CMOS Transistor TheorySlide 22 nMOS Saturation I-V  If V gd < V t, channel pinches off near drain –When V ds > V dsat = V gs – V t  Now drain voltage no longer increases current

CMOS VLSI Design3: CMOS Transistor TheorySlide 23 nMOS Saturation I-V  If V gd < V t, channel pinches off near drain –When V ds > V dsat = V gs – V t  Now drain voltage no longer increases current

CMOS VLSI Design3: CMOS Transistor TheorySlide 24 nMOS I-V Summary  Shockley 1 st order transistor models

CMOS VLSI Design3: CMOS Transistor TheorySlide 25 Example  0.6  m process (Example) –From AMI Semiconductor –t ox = 100 Å –  = 350 cm 2 /V*s –V t = 0.7 V  Plot I ds vs. V ds –V gs = 0, 1, 2, 3, 4, 5 –Use W/L = 4/2

CMOS VLSI Design3: CMOS Transistor TheorySlide 26 pMOS I-V  All dopings and voltages are inverted for pMOS  Mobility  p is determined by holes –Typically 2-3x lower than that of electrons  n –120 cm 2 /V*s in AMI 0.6  m process  Thus pMOS must be wider to provide same current –In this class, assume  n /  p = 2

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