nmos fundamentals

71
MOS-SLIDES-AKM 1 MOS DEVICE FUNDAMENTALS Professor A. K. Majumdar Computer Science and Engineering Department Indian Institute of Technology, Kharagpur

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Page 1: NMOS Fundamentals

MOS-SLIDES-AKM 1

MOS DEVICE FUNDAMENTALS

Professor A. K. MajumdarComputer Science and Engineering

Department Indian Institute of Technology, Kharagpur

Page 2: NMOS Fundamentals

MOS-SLIDES-AKM 2

Metal-Oxide Semiconductor (MOS) Field Effect Transistors

NMOS enhancement mode transistor

Page 3: NMOS Fundamentals

MOS-SLIDES-AKM 3

Induced Channel in NMOS Transistor

Enhancement mode NMOS transistor with VGS>0 showing induced channel

Page 4: NMOS Fundamentals

MOS-SLIDES-AKM 4

Current – Voltage characteristics of NMOS transistors

Page 5: NMOS Fundamentals

MOS-SLIDES-AKM 5

NMOS Transistor Analysis

• Induced Channel Charge / Unit AreaQ(x) = - COX [ VGS – V(x) – Vth]

Where COX = εOX/ tOX capacitance per unit area due to gate oxide

Drain current IDS = vn(x) Q(x)Wvn(x) = drift velocity of electron

Page 6: NMOS Fundamentals

MOS-SLIDES-AKM 6

NMOS Transistor Analysis Contd

• vn(x) = - μn E(x) = μn dV/dx• μn = Mobility of electrons• Hence IDS = - μn Q(x)W dV/dx• Substituting for Q(x),• IDS dx = μn COX W[VGS– V(x) – Vth] dV

Integrating• IDS= μn COX W/L[(VGS - Vth ) - VDS /2 ] VDS• IDS = ηn [(VGS - Vth ) - VDS /2 ] VDS

Page 7: NMOS Fundamentals

MOS-SLIDES-AKM 7

NMOS Transistor Analysis in Linear Region

• kn =μn COX = μn εOX/ tOX is called process transconductance parameter

• ηn = kn(W/L) is called gain factor• For small VDS , VDS

2 /2 can be ignored and IDS depends linearly on VDS

• Rlinear = 1/ (ηn (VGS - Vth))

Page 8: NMOS Fundamentals

MOS-SLIDES-AKM 8

NMOS Transistor Analysis in Linear Region

• Transconductance of NMOS transistor• gm = (dIDS/ dVGS)│ VDS = constant

In linear regiongm = ηn VDS

Page 9: NMOS Fundamentals

MOS-SLIDES-AKM 9

NMOS Transistor Analysis Saturation Region

• VDS ≥ VGS – Vth• Channel is pinched off• Assuming voltage difference over induced

channel from source to pinch off point fixed at VGS – Vth

• IDS = ηn /2 (VGS – Vth)2

• In saturation region, MOS transistor acts as a constant current source.

• Transconductance in saturation region• gm = ηn (VGS – Vth)

Page 10: NMOS Fundamentals

MOS-SLIDES-AKM 10

Current – Voltage Relationship of NMOS Transistor

• The drain-to-source current-voltage dependence for a NMOS transistor is given by the following equations

• IDS = 0 for VDS < Vth (off)

• IDS = ηn/2.(VGS – Vth)2 for 0 < VDS – Vth < VDS (saturation)

• IDS = ηn(VGS – Vth – VDS/2)VDS for VGS > Vth and VGS – Vth≥ VDS (linear)

ηn = (μnεox/tox).W/L

where μn is the mobility of electron, εox is the permittivity of the oxide material, and tox is the thickness of the oxide.

Page 11: NMOS Fundamentals

MOS-SLIDES-AKM 11

Channel Length Modulation

• In saturation region, the transistor does not operate as a perfect current source, i.e. IDS is not independent of VDS

• As VDS is increased beyond (VGS– Vth) effective channel length decreases.

• Since IDS α 1/L, reduction in effective channel length increases IDS

• More accurate representation• IDS = ηn/2.(Vgs – Vth)2 ( 1 + λVDS)

Page 12: NMOS Fundamentals

MOS-SLIDES-AKM 12

Current – Voltage Relationship of PMOS Transistor

• Cut off VGS > VthIDS = 0

• Linear Region: VGS ≤ Vth and VDS > VGS – VthIDS = ηp(VGS – Vth – VDS/2)VDS

• Saturation region VGS ≤ Vth, and VDS < VGS–VthIDS = ηp/2.(VGS–Vth)2

where the gain factorηp = (μpεox/tox).W/L and μp is mobility of holes

Page 13: NMOS Fundamentals

MOS-SLIDES-AKM 13

Velocity Saturation

• Electron mobility cannot be considered to be constant with increasing electric field

• For short channel devices velocity saturates

Page 14: NMOS Fundamentals

MOS-SLIDES-AKM 14

Velocity saturation effect

• Let VDSAT : drain-source voltage at which the critical field for velocity saturation is reached

• First order approximation:• For VDS < VDSAT, IDS expression is similar to long

channel model• For VDS ≥ VDSAT IDS =IDSAT =

νSAT Cox W [ VGS – Vth – VDSAT/2 ] • Where νSAT =μ VDSAT / L is the saturation velocity

Page 15: NMOS Fundamentals

MOS-SLIDES-AKM 15

MOS Transistor Threshold Voltage

• Depletion region charge density - due to fixed acceptor ions in the p-type substrate:

where, Vdep is the voltage across the depletion layer at the oxide silicon boundary

• Channel inversion occurs when Vdep = 2φF

where the Fermi potential φF = kT/q ln( NA/ ni)

• φF ≈ -0.3 V for nMOS

2dep si A depQ q N V= − ε

Page 16: NMOS Fundamentals

MOS-SLIDES-AKM 16

Threshold Voltage

• At strong inversion depletion layer charge density:

Where VSB is the substrate bias

With zero substrate bias, threshold voltage

Vth0 = φGC -2 φF - Qdep / Cox - Qi / Cox

where is φGC the work function difference between the gate and substrate (flat band voltage) and Qi is due to impurities at the interface between the gate oxide and silicon substrate

( )2 | 2 |dep si A F SBQ q N V=− ε − ϕ +

Page 17: NMOS Fundamentals

MOS-SLIDES-AKM 17

Threshold Voltage

• Threshold voltage with non-zero substrate bias

where the parameter γ is called body-effect (substrate bias) coefficient.

( )0 | 2 | | 2 |th th F SB FV V V= +γ − ϕ + − − ϕ

Page 18: NMOS Fundamentals

MOS-SLIDES-AKM 18

Threshold Variations in Short Channel Devices

• Threshold depends on L, W and VDS• Due to depletion regions of the source and reverse-

biased drain junction.• Drain-induced barrier lowering (DIBL) : Vth0 decreases

with increasing VDS . • Very high drain voltage source and drain depletion

regions may get shorted (punch-through)• Narrow channel effects: Vth0 increases since depletion

regions does not abruptly stops at the edges of the transistors but extends to isolating field oxide regions. Gate voltage must support the extra depletion charge to establish conducting channel.

Page 19: NMOS Fundamentals

MOS-SLIDES-AKM 19

Sub-threshold / Weak-Inversion Current

• Channel current when VGS < Vth

• IDS (sub-threshold) has exponential dependence on both gate and drain voltages and can be expressed as

)(/ DSGS BVAVkTqSeI +

Slope factor: S - rate of decline of the current with respect to VGS below Vthin mv/ decade( ≈ 2.3 kT/Aq). With A =1, S evaluates to 60mV/decade (i.e. current drops by a factor of ten for a reduction of VGS by 60mv)

usually A<1 and current falls at a reduced rate e.g 90mV/decade

Page 20: NMOS Fundamentals

MOS-SLIDES-AKM 20

ReverseReverse--Biased Diode LeakageBiased Diode Leakage

Np+ p+

Reverse Leakage Current

+

-Vdd

GATE

IDL = JS × A

Reverse leakage Current of a p-n junction Ireverse= A JS(e - 1)qVbias/kT

Reverse saturation current Density JS = 10-100 pA/μm2 at 25 deg C for 0.25μm CMOS, JS doubles for every 9 deg C!

Page 21: NMOS Fundamentals

MOS-SLIDES-AKM 21

Lateral diffusion of source and drain regions

Lateral diffusion = Ld

Effective channel length Leff = L -2 Ld

Page 22: NMOS Fundamentals

MOS-SLIDES-AKM 22

MOSFET Capacitances

Oxide related (Gate ) capacitances: CGS, CGD, CGB

Junction capacitances : CSB, CDB - due to source / drain diffusion regions in the substrate

Page 23: NMOS Fundamentals

MOS-SLIDES-AKM 23

MOS transistor gate capacitances for three operating regions

Capacitance Cutoff Linear Saturation CGB CoxW Leff 0 0 CGS Cox W Ld CoxW Ld + ½ CoxW Leff CoxW Ld + 2/3 CoxW Leff CGD Cox W Ld CoxW Ld + ½ CoxW Leff CoxW Ld

Page 24: NMOS Fundamentals

MOS-SLIDES-AKM 24

NMOS Inverter

Page 25: NMOS Fundamentals

MOS-SLIDES-AKM 25

Pull Up and Pull Down transistors

• The depletion mode transistor is a pull up device. It is always on (Vgs = 0)

• The enhancement mode transistor is the pull down device.

• With no current drawn from output, current in both pull up and pull down transistors must be same.

Page 26: NMOS Fundamentals

MOS-SLIDES-AKM 26

Current Voltage Characteristics of NMOS Inverter

Page 27: NMOS Fundamentals

MOS-SLIDES-AKM 27

NMOS Inverter• The points of intersection of the pull up (for Vgs =0 )

and pull down curves give points on the transfer characteristics for the inverter

• As Vin exceeds VTpd (pull down transistor threshold) current will flow and Vout falls. Further increase in Vin will cause pull down transistor to be out of saturation and will behave as resistor

• Pull up device is initially resistive when pull down is turned on

• The point at which Vin = Vout is called Vinv• Vinv can be shifted by variation of ratios of pull up and

down resistances – determined by the length to width ratio of the transistor.

Page 28: NMOS Fundamentals

MOS-SLIDES-AKM 28

NMOS Inverter

• With NMOS Depletion Mode transistor• High Dissipation: When VIN is high current

flows through both the devices.• Output switching: occurs when Vin

exceeds Vthpd• During fall 1→ 0 transition, pull up offers

lower resistance to charge capacitive load.• Degrades 0 value : Low output value is

determined by pull down resistance.

Page 29: NMOS Fundamentals

MOS-SLIDES-AKM 29

CMOS INVERTER

Page 30: NMOS Fundamentals

MOS-SLIDES-AKM 30

CMOS Inverter

Polysilicon

In Out

VDD

GND

PMOS 2λ

Metal 1

NMOS

OutIn

VDD

PMOS

NMOS

Contacts

N Well

Page 31: NMOS Fundamentals

MOS-SLIDES-AKM 31

CMOS Fabrication

Page 32: NMOS Fundamentals

MOS-SLIDES-AKM 32

CMOS Fabrication

Page 33: NMOS Fundamentals

MOS-SLIDES-AKM 33

Current Voltage Characteristics

Page 34: NMOS Fundamentals

MOS-SLIDES-AKM 34

CMOS INVERTER –VOLTAGE TRANSFER CHARACTERISTICS

Page 35: NMOS Fundamentals

MOS-SLIDES-AKM 35

CMOS INVERTER - CONTD

• Region R1: 0 < Vin < Vthn, NMOS transistor is off, PMOS device operates in the linear region.

• Region R2: Vthn< Vin< VDD - |Vthp| and Vin + |Vthp| < Vout≤ VDD, NMOS transistor in saturation, and PMOS transistor still in the linear region.

• Region R3: Vthn<Vin<VDD - |Vthp| and Vin - Vthn ≤ Vout ≤Vin + |Vthp|, both the transistors are in saturation.

• Region R4: Vthn < Vin< VDD – |Vthp| and Vout < Vin - Vthn, NMOS transistor is in the linear region and PMOS remains in saturation.

• Region R5: VDD – |Vthp| < Vin < VDD, PMOS transistor in cut-off, NMOS in the linear region.

Page 36: NMOS Fundamentals

MOS-SLIDES-AKM 36

CMOS Inverter Characteristics

Page 37: NMOS Fundamentals

MOS-SLIDES-AKM 37

Static Analysis of CMOS Inverter

Current – Voltage Relationship of NMOS transistor : VGSn = Vin , VDSn = Vout

ηn = (μn ε/tox) (W/L)n

Cut-off (Vin ≤ Vthn) : IDS = 0

Linear (Vin – Vthn ≥ Vout) : IDS = ηn(VGSn – Vthn – VDSn/2)VDSn

Saturation ( Vthn ≤ Vin, Vout > Vin – Vthn): IDS = ηn/2(VGSn – Vthn)2

Page 38: NMOS Fundamentals

MOS-SLIDES-AKM 38

Current – Voltage Relationship of PMOS transistor

Cut-off (Vin > VDD - |Vthp|) : IDS = 0

Linear (Vin ≤ VDD - |Vthp|) and (Vout >Vin +|Vthn|) : IDS = ηn(VGSp – |Vthp| –VDSp/2)VDSp

Saturation (Vin ≤ VDD - |Vthp|) and (Vout ≤ Vin +|Vthp|):IDS = ηp/2(VGSn – |Vthp|)2

VGSp = - (VDD – Vin), VDSp = - (VDD – Vout)ηp = (μp ε/tox) (W/L)n

Page 39: NMOS Fundamentals

MOS-SLIDES-AKM 39

Static Analysis of CMOS Inverter-Contd

• VOH = VDD

• VOL = 0 • Vinv = [ Vthn + (1/√β)(VDD + Vthp)] / (1 + 1/√β) • β = ηn/ηp

=[μn(εox/tox)n (W/L)n ]/ [μp(εox/tox)p(W/L)p] • for β = 1, • (W/L)n / (W/L)p = μp/μn ≈ 1/2.5• (W/L)p ≈ 2.5 (W/L)n

Page 40: NMOS Fundamentals

MOS-SLIDES-AKM 40

Static Analysis of CMOS Inverter-Contd

• VIL = (2Vout + Vthp – VDD + βVthn) / (1 + β) • β = 1, and Vthn = │Vthp│• VIL = 1/8 (3VDD +2 Vthn) • VIH = [VDD + Vthp + β(2 Vout + Vthn)] / (1 + β) • with β = 1, and Vthn = │Vthp│, • VIH = (5VDD – 2Vthn) /8

Page 41: NMOS Fundamentals

MOS-SLIDES-AKM 41

NOISE MARGINS

• NML = VIL – VOL = VIL

• NMH = VOH – VIH = VDD – VIH

Page 42: NMOS Fundamentals

MOS-SLIDES-AKM 42

Switching Characteristics of a CMOS Inverter

Parasitic capacitances in a cascaded CMOS inverter

Page 43: NMOS Fundamentals

MOS-SLIDES-AKM 43

Switch model of a static CMOS inverter

Page 44: NMOS Fundamentals

MOS-SLIDES-AKM 44

Propagation delay times and rise and fall times of an inverter

Page 45: NMOS Fundamentals

MOS-SLIDES-AKM 45

CMOS inverter equivalent circuit during high-to-low and low-to-high output transitions

Page 46: NMOS Fundamentals

MOS-SLIDES-AKM 46

Propagation Delay Estimation• High to Low Transition• τpHL = τpHL1 + τpHL2

• τpHL1 = the period during which Vout drops from VDD to VDD – Vthn.

• τpHL1 = 2 CLVthn / ηn (VDD – Vthn)2

• τpHL2 = the period during which Vout drops from VDD – Vthn to VDD /2.

• τpHL2 = ⎥⎦

⎤⎢⎣

⎡⎟⎟⎠

⎞⎜⎜⎝

⎛−

− DD

thn

thnDDn

L

VV

VVC 43ln

)(η

Page 47: NMOS Fundamentals

MOS-SLIDES-AKM 47

Propagation Delay Estimation –Contd.

• Low to High Transition

• τpLH =

• For τpHL = τpLH , (W/L)p ≈ 2.5 (W/L)n

⎥⎥⎦

⎢⎢⎣

⎡⎟⎟⎠

⎞⎜⎜⎝

⎛−+

−− DD

thp

thpDD

thp

thpDDp

L

VV

VVV

VVC ||4

3ln|)|(

||2|)|(η

Page 48: NMOS Fundamentals

MOS-SLIDES-AKM 48

Typical input - output and load capacitor current waveforms in a

CMOS inverter

Page 49: NMOS Fundamentals

MOS-SLIDES-AKM 49

Power Dissipation in CMOS Inverter

• Dynamic Power Consumption

• Short Circuit Currents

• Leakage

Charging and Discharging Capacitors

Short Circuit Path between Supply Rails during Switching

Leaking diodes and transistors

Page 50: NMOS Fundamentals

MOS-SLIDES-AKM

E-charge = CL VDD2

E-discharge = ½ CL VDD2

Average Power dissipation

PAvg= 1/T CL VDD2 = CL VDD

2 f

50

Dynamic Power Consumption

Page 51: NMOS Fundamentals

MOS-SLIDES-AKM 51

Switching Power Dissipation in CMOS Inverter

• fmax = 1/2τp• Power Delay Product, • PDP = Pavg τp• For f = fmax, PDP = CL VDD

2 fmax τp= ½ CL VDD

2

Note: average switching power dissipation of a CMOS inverter is independent of transistor sizes and characteristics provided there is full voltage swing

Analysis is valid when output node of the gate undergoes one transition (0 to VDD) in a clock cycle.

Page 52: NMOS Fundamentals

MOS-SLIDES-AKM 52

Switching Power Dissipation - Contd

• When node transition rate is slower than clock rate

• PAvg = CL VDD2 f

• where is the node transition factor (effective number of power consuming transition per cycle)

• Energy Delay Product EDP = PDP τp = ½ CL VDD

2 τp

Page 53: NMOS Fundamentals

MOS-SLIDES-AKM 53

Short Circuit Current in CMOS InverterShort Circuit Current in CMOS Inverter

Page 54: NMOS Fundamentals

MOS-SLIDES-AKM 54

Short Circuit Current

• Short circuit current is large if output load capacitance is low and input rise/fall time is large.

• To reduce short circuit power dissipationinput/output rise and fall times should be of same order =

PAvg(short-circuit) = 1/12[k f (VDD- Vthn -|Vthp|)3]τ

τ

Page 55: NMOS Fundamentals

MOS-SLIDES-AKM 55

Sub Threshold LeakageSub Threshold Leakage

Page 56: NMOS Fundamentals

MOS-SLIDES-AKM 56

Advantages of CMOS Inverter

• The high and low output voltages are equal to Vdd and ground respectively so that the voltage swing is the same as the supply voltage..

• The logic levels are not dependent on the relative device sizes and hence the size of the transistors can be minimized.

• There is always a finite resistance between the output and either Vdd or ground in the steady state. The inverter can, therefore, be designed to have a low input impedance, making it less sensitive to noise.

• The CMOS inverter has a very high input resistance and draws no dc input current as the gate of a MOS transistor is virtually a perfect insulator.

Page 57: NMOS Fundamentals

MOS-SLIDES-AKM 57

Technology Scaling

• Full Scaling (Constant Field Scaling)• Constant Voltage Scaling

Parameter Full Scaling Constant-Voltage Scaling

Channel Length (L) L/κ L/ κ Channel Width (W) W/κ W/κ Gate oxide thickness (tox) tox /κ tox /κ Supply voltage VDD VDD /κ VDD Junction depth (Xj) Xj/κ Xj/κ Threshold voltage (Vth) Vth/κ Vth Doping densities – ND (NA) NDκ (NAκ) NDκ2 (NAκ2)

Page 58: NMOS Fundamentals

MOS-SLIDES-AKM 58

Effects of scaling on MOS transistor characteristics

Parameter Full Scaling

Constant-Voltage Scaling

Gate Area (A = WL)

A/κ2 A/κ2

Oxide capacitance (Cox) κCox κCox Gate capacitance Cg (= CoxWL) Cg/κ Cg/κ Transconductance/Gain factor (η) ηκ ηκ Electric field (E) E κE Drain current (IDS) IDS/κ IDSκ Power dissipation (P) P/κ2 Pκ Power density ( PD = P/area) PD PDκ3

Gate delay (τ) τ /κ τ /κ2

Page 59: NMOS Fundamentals

MOS-SLIDES-AKM 59

Inter-dependence of leakage currents in short channel devices

• Device Geometry (channel length, oxide thickness) and doping profile affects-

• Sub-threshold leakage • Gate leakage• Reverse biased diode (drain/ source –

substrate) leakage

Page 60: NMOS Fundamentals

MOS-SLIDES-AKM 60

Factors affecting scaling

• Constant field scaling requires threshold voltage reduction – to improve propagation delay.

• Low threshold affects: noise margins and sub-threshold conduction.

• Gate oxide thickness reduction: Increases gate leakage due to electron tunneling and hot carrier injection from substrate to gate

Page 61: NMOS Fundamentals

MOS-SLIDES-AKM 61

Threshold Reduction

• By well engineering : changing doping profile in the channel (e.g halo doping). Aims to minimize leakage currents while maximizing linear and saturated currents.

• Multiple threshold CMOC circuits• Variable threshold circuits

Page 62: NMOS Fundamentals

MOS-SLIDES-AKM 62

SPICE SIMULATION

• Active/ passive devices used in the circuit under simulation are represented by suitable models.

• Uses Kirchoff laws for analysis of circuit behavior• Circuit voltage and current signals are represented as

continuous waveforms. • During simulation continuous variables are approximated

by floating point numbers with suitable increment steps specified.

• SPICE supports different modes of analysis of active circuits : DC analysis, transient analysis, small signal analysis, etc.

• Different versions of SPICE: PSPICE, HSPICE, T-SPICE

Page 63: NMOS Fundamentals

MOS-SLIDES-AKM 63

MOSFET MODEL

• SPICE syntax for MOSFET device is• .model <name> nmos | pmos level = 1|

2| 3 (parameters)• Some of the parameters are gate oxide

thickness (TOX), channel length (L), channel width (W), drain area (AD), source area (AS), drain resistance (RD), source resistance (RS), etc.

Page 64: NMOS Fundamentals

MOS-SLIDES-AKM 64

MODEL FILE• .model nmos nmos Level=1• + Vto=2.0 Kp=3.0E-5 Gamma=0.35 • + Phi=0.65 Lambda=0.002 Tox=0.1u • + Nsub=1.0E+15 Nss=1.0E+10 Ld=0.8u • + Tpg=1.00 Uo=700.0 Af=1.2• + Kf=1.0E-26 Is=1.0E-15 Js=1.0E-8• + Pb=0.75 Cj=2.0E-4 Mj=0.5• + Cjsw=1.00E-9 Mjsw=0.33 Fc=0.5• + Cgbo=2.0E-10 Cgdo=4.00E-11 Cgso=4.00E-11 • + Rd=10.0 Rs=10.0 Rsh=30.0

• .model pmos pmos Level=1• + Vto=-2.0 Kp=3.0E-5 Gamma=0.35 • + Phi=0.65 Lambda=0.002 Tox=0.1u • + Nsub=1.0E+15 Nss=1.0E+10 Ld=0.8u • + Tpg=1.00 Uo=700.0 Af=1.2• + Kf=1.0E-26 Is=1.0E-15 Js=1.0E-8• + Pb=0.75 Cj=2.0E-4 Mj=0.5• + Cjsw=1.00E-9 Mjsw=0.33 Fc=0.5• + Cgbo=2.0E-10 Cgdo=4.00E-11 Cgso=4.00E-11 • + Rd=10.0 Rs=10.0 Rsh=30.0

Page 65: NMOS Fundamentals

MOS-SLIDES-AKM 65

• * Waveform probing commands• .probe• .options probefilename="INV.dat"• + probesdbfile="C:\Documents and

Settings\smdp\Desktop\inv\INV.sdb"• + probetopmodule="Module0“• .include ml1_1_typ.md (model file included)• vdd vdd 0 5 0• vin vin gnd PULSE (0 5 0 1n 1n 1u 2u) ROUND=0 (input pulse)• .tran .1u 10u start=0 (type of analysis)• .print tran v(vin) v(vout) (probing for the output) • * Main circuit: Module0• M1 vout vin Gnd Gnd NMOS L=2u W=22u AD=66p PD=24u AS=66p

PS=24u • M2 vout vin Vdd Vdd PMOS L=2u W=22u AD=66p PD=24u AS=66p

PS=24u• * End of main circuit: Module0

FORMAT FOR WRITING SPICE NETLIST

Page 66: NMOS Fundamentals

MOS-SLIDES-AKM 66

DC ANALYSIS RESULT

Page 67: NMOS Fundamentals

MOS-SLIDES-AKM 67

AC ANALYSIS RESULT

Page 68: NMOS Fundamentals

MOS-SLIDES-AKM 68

EFFECT OF CHANGE IN THE MODEL FILE PARAMETER

Declaration of model file 1

• .model nmos nmos Level=1• + Vto=2.0 Kp=3.0E-5 Gamma=0.35• .model pmos pmos Level=1• + Vto=-2.0 Kp=3.0E-5 Gamma=0.35

Declaration of model file 2

• .model nmos nmos Level=1• + Vto=1.0 Kp=3.0E-5 Gamma=0.35 • .model pmos pmos Level=1• + Vto=-1.0 Kp=3.0E-5 Gamma=0.35

Page 69: NMOS Fundamentals

RESULT COMPARISON

Page 70: NMOS Fundamentals

MOS-SLIDES-AKM 70

REFERENCES

1. Rabaey J. M.,Chandrakasan A., and Nikolic B., “ Digital Integrated Circuits”, Prentice- Hall of India, 2003.

2. Kang, Sung-Mo and Leblebici, Y.: CMOS Digital Integrated Circuits, McGraw Hill Pub., 2003

3. Weste N.H.E and Eshraghlan, K: Principles of CMOS VLSI Design, Pearson Education, 2004.

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