Introduction to CMOS VLSI Design Lecture 3 CMOS
- Slides: 40
Introduction to CMOS VLSI Design Lecture 3: CMOS Transistor Theory Credits: David Harris Harvey Mudd College (Material taken/adapted from Harris’ lecture notes) 3: CMOS Transistor Theory 1
Outline q q q q Introduction MOS Capacitor n. MOS I-V Characteristics p. MOS I-V Characteristics Gate and Diffusion Capacitance Pass Transistors RC Delay Models 3: CMOS Transistor Theory CMOS VLSI Design 2
Introduction q So far, we have treated transistors as ideal switches q An ON transistor passes a finite amount of current – Depends on terminal voltages – Derive current-voltage (I-V) relationships q Transistor gate, source, drain all have capacitance – I = C (DV/Dt) -> Dt = (C/I) DV – Capacitance and current determine speed q Also explore what a “degraded level” really means 3: CMOS Transistor Theory CMOS VLSI Design 3
MOS Capacitor q Gate and body form MOS capacitor q Operating modes – Accumulation – Depletion – Inversion 3: CMOS Transistor Theory CMOS VLSI Design 4
Terminal Voltages q Mode of operation depends on Vg, Vd, Vs – Vgs = Vg – Vs – Vgd = Vg – Vds = Vd – Vs = Vgs - Vgd q Source and drain are symmetric diffusion terminals – By convention, source is terminal at lower voltage – Hence Vds 0 q n. MOS body is grounded. First assume source is 0 too. q Three regions of operation – Cutoff – Linear – Saturation 3: CMOS Transistor Theory CMOS VLSI Design 5
n. MOS Cutoff q No channel q Ids = 0 3: CMOS Transistor Theory CMOS VLSI Design 6
n. MOS Linear q Channel forms q Current flows from d to s – e- from s to d q Ids increases with Vds q Similar to linear resistor 3: CMOS Transistor Theory CMOS VLSI Design 7
n. MOS Saturation q q Channel pinches off Ids independent of Vds We say current saturates Similar to current source 3: CMOS Transistor Theory CMOS VLSI Design 8
I-V Characteristics q In Linear region, Ids depends on – How much charge is in the channel? – How fast is the charge moving? 3: CMOS Transistor Theory CMOS VLSI Design 9
Channel Charge q MOS structure looks like parallel plate capacitor while operating in inversion – Gate – oxide – channel q Qchannel = 3: CMOS Transistor Theory CMOS VLSI Design 10
Channel Charge q MOS structure looks like parallel plate capacitor while operating in inversion – Gate – oxide – channel q Qchannel = CV q C= 3: CMOS Transistor Theory CMOS VLSI Design 11
Channel Charge q MOS structure looks like parallel plate capacitor while operating in inversion – Gate – oxide – channel q Qchannel = CV Cox = eox / tox q C = Cg = eox. WL/tox = Cox. WL q V= 3: CMOS Transistor Theory CMOS VLSI Design 12
Channel Charge q MOS structure looks like parallel plate capacitor while operating in inversion – Gate – oxide – channel q Qchannel = CV Cox = eox / tox q C = Cg = eox. WL/tox = Cox. WL q V = Vgc – Vt = (Vgs – Vds/2) – Vt 3: CMOS Transistor Theory CMOS VLSI Design 13
Carrier velocity q Charge is carried by eq Carrier velocity v proportional to lateral E-field between source and drain q v= 3: CMOS Transistor Theory CMOS VLSI Design 14
Carrier velocity q Charge is carried by eq Carrier velocity v proportional to lateral E-field between source and drain q v = m. E m called mobility q E= 3: CMOS Transistor Theory CMOS VLSI Design 15
Carrier velocity q Charge is carried by eq Carrier velocity v proportional to lateral E-field between source and drain q v = m. E m called mobility q E = Vds/L q Time for carrier to cross channel: – t= 3: CMOS Transistor Theory CMOS VLSI Design 16
Carrier velocity q Charge is carried by eq Carrier velocity v proportional to lateral E-field between source and drain q v = m. E m called mobility q E = Vds/L q Time for carrier to cross channel: – t=L/v 3: CMOS Transistor Theory CMOS VLSI Design 17
n. MOS Linear I-V q Now we know – How much charge Qchannel is in the channel – How much time t each carrier takes to cross 3: CMOS Transistor Theory CMOS VLSI Design 18
n. MOS Linear I-V q Now we know – How much charge Qchannel is in the channel – How much time t each carrier takes to cross 3: CMOS Transistor Theory CMOS VLSI Design 19
n. MOS Linear I-V q Now we know – How much charge Qchannel is in the channel – How much time t each carrier takes to cross 3: CMOS Transistor Theory CMOS VLSI Design 20
n. MOS Saturation I-V q If Vgd < Vt, channel pinches off near drain – When Vds > Vdsat = Vgs – Vt q Now drain voltage no longer increases current 3: CMOS Transistor Theory CMOS VLSI Design 21
n. MOS Saturation I-V q If Vgd < Vt, channel pinches off near drain – When Vds > Vdsat = Vgs – Vt q Now drain voltage no longer increases current 3: CMOS Transistor Theory CMOS VLSI Design 22
n. MOS Saturation I-V q If Vgd < Vt, channel pinches off near drain – When Vds > Vdsat = Vgs – Vt q Now drain voltage no longer increases current 3: CMOS Transistor Theory CMOS VLSI Design 23
n. MOS I-V Summary q Shockley 1 st order transistor models 3: CMOS Transistor Theory CMOS VLSI Design 24
Example q Consider a 0. 6 mm process – From AMI Semiconductor – tox = 100 Å – m = 350 cm 2/V*s – Vt = 0. 7 V q Plot Ids vs. Vds – Vgs = 0, 1, 2, 3, 4, 5 – Use W/L = 4/2 l 3: CMOS Transistor Theory CMOS VLSI Design 25
p. MOS I-V q All dopings and voltages are inverted for p. MOS q Mobility mp is determined by holes – Typically 2 -3 x lower than that of electrons mn – 120 cm 2/V*s in AMI 0. 6 mm process q Thus p. MOS must be wider to provide same current – In this class, assume mn / mp = 2 – *** plot I-V here 3: CMOS Transistor Theory CMOS VLSI Design 26
Capacitance q Any two conductors separated by an insulator have capacitance q Gate to channel capacitor is very important – Creates channel charge necessary for operation q Source and drain have capacitance to body – Across reverse-biased diodes – Called diffusion capacitance because it is associated with source/drain diffusion 3: CMOS Transistor Theory CMOS VLSI Design 27
Gate Capacitance q Cgs = eox. WL/tox = Cox. WL = Cpermicron. W q Cpermicron is typically about 2 f. F/mm (for L=0. 6 m) 3: CMOS Transistor Theory CMOS VLSI Design 28
Diffusion Capacitance q Csb, Cdb q Undesirable, called parasitic capacitance q Capacitance depends on area and perimeter – Use small diffusion nodes – Comparable to Cg or for diffusion w/ contact – Reduced for merged transistors (uncontacted) – Varies with process 3: CMOS Transistor Theory CMOS VLSI Design 29
Pass Transistors q We have assumed source is grounded q What if source > 0? – e. g. pass transistor passing VDD 3: CMOS Transistor Theory CMOS VLSI Design 30
Pass Transistors q We have assumed source is grounded q What if source > 0? – e. g. pass transistor passing VDD q Vg = VDD – If Vs > VDD-Vt, Vgs < Vt – Hence transistor would turn itself off q n. MOS pass transistors pull no higher than VDD-Vtn – Called a degraded “ 1” – Approach degraded value slowly (low Ids) q p. MOS pass transistors pull no lower than Vtp 3: CMOS Transistor Theory CMOS VLSI Design 31
Pass Transistor Ckts 3: CMOS Transistor Theory CMOS VLSI Design 32
Pass Transistor Ckts 3: CMOS Transistor Theory CMOS VLSI Design 33
Effective Resistance q Shockley models have limited value – Not accurate enough for modern transistors – Too complicated for much hand analysis q Simplification: treat transistor as resistor – Replace Ids(Vds, Vgs) with effective resistance R • Ids = Vds/R – R averaged across switching of digital gate q Too inaccurate to predict current at any given time – But good enough to predict delays 3: CMOS Transistor Theory CMOS VLSI Design 34
RC Delay Model q Use equivalent circuits for MOS transistors – Ideal switch + capacitance and ON resistance – Unit n. MOS has resistance R, capacitance C – Unit p. MOS has resistance 2 R, capacitance C q Capacitance proportional to width q Resistance inversely proportional to width 3: CMOS Transistor Theory CMOS VLSI Design 35
RC Values q Capacitance – C = Cg = Cs = Cd = 2 f. F/mm of gate width – Values similar across many processes q Resistance – R 6 KW*mm in 0. 6 um process – Improves with shorter channel lengths q Unit transistors – May refer to minimum contacted device (4/2 l) – Or maybe 1 mm wide device – Doesn’t matter as long as you are consistent 3: CMOS Transistor Theory CMOS VLSI Design 36
Inverter Delay Estimate q Estimate the delay of a fanout-of-1 inverter 3: CMOS Transistor Theory CMOS VLSI Design 37
Inverter Delay Estimate q Estimate the delay of a fanout-of-1 inverter 3: CMOS Transistor Theory CMOS VLSI Design 38
Inverter Delay Estimate q Estimate the delay of a fanout-of-1 inverter 3: CMOS Transistor Theory CMOS VLSI Design 39
Inverter Delay Estimate q Estimate the delay of a fanout-of-1 inverter d = 6 RC 3: CMOS Transistor Theory CMOS VLSI Design 40
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