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Chapter 4

Structure and Physical Operation I -V characteristics MOSFET DC circuits CMOS Inverter MOSFET amplifiers Biasing MOSFETS High Frequency MOS model SPICE MOSFET model parameters. Chapter 4. MOSFET ID-VG, ID-VDS. Output Charc. Input Charc.

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Chapter 4

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  1. Structure and Physical Operation I -V characteristics MOSFET DC circuits CMOS Inverter MOSFET amplifiers Biasing MOSFETS High Frequency MOS model SPICE MOSFET model parameters Chapter 4

  2. MOSFET ID-VG, ID-VDS Output Charc. Input Charc. IDsat = n Cox W/L (VGS - VTN)2/2 --- SQUARE LAW L>250nm Subthreshold Leakage

  3. MOSFET ID-VG, ID-VDS Output Charc. Input Charc. IDsat = vsat Cox W K (VGS - VTN) “Linear” L<250nm VTN Subthreshold Leakage

  4. MOSFET ID-VG, ID-VDS Digital Logic Analog VTN VDD = 1

  5. Anatomy of an Inverter PMOS NMOS PMOS Oxide NMOS

  6. MOS Transistor Operating Regions VDD VDD

  7. MOS Structure Symbols

  8. MOS Transistor Operation

  9. Triode or Linear Region OFF VGS < VT or VTO

  10. Triode or Linear Region TRIODE VDS < VGS -VT

  11. Increasing VDS – ID saturates

  12. Increasing VDS – ID saturates

  13. Cgs ON/Triode: V > 0 or VGS > VTO Cgs = WL Cox; V > VDS OFF: V < 0 or VGS < VTO Cgs  WL Cox Sat: V < 0 or VGS < VTO Cgs = 2/3 WL Cox ; V < VDS NMOS N Diffusion PMOS P Diffusion PolySilicon

  14. Significant Process Parameter Constants

  15. SPICE MODEL parameters Over 200 parameters define Modern 65nm MOSFETs 2000nm V = VGS-VT0 KP = Uo Cox

  16. ID vs. VGS; VDS > V L > 250nm Square Law L < 250nm Vel. Sat.

  17. ID vs. VGS; VDS > V Supplemental Taking the square root of ID and solving for slope & intercept; Extract VTO and KP

  18. Enhancement/ Depletion Mode NMOS – 1st Quadrant PMOS – 3rd Quadrant Enhancement VTN > 0V VTP < 0V Depletion Mode VTN > 0V VTP < 0V

  19. MOSFET parameters Ex -graphical ; V < VDS ID= W/LnCox (VGS - VTN)2/2 --- Sat. n Cox W/L =  ID = W/L n Cox {V VDS + VDS2/2}---Triode or Lin Region

  20. CMOS Inverter – Strong pull up & down Rise time Fall Time

  21. INVERTER POWER Supplemental

  22. CMOS Logic

  23. Why CMOS Inverter NMOS PMOS

  24. CMOS Logic NMOS pull dwn Zbar = AB+CD

  25. CMOS Logic PMOS pull UP Z = A’+B’  C’+D’

  26. CMOS Logic PMOS pull UP Z = A’+B’  C’+D’

  27. CMOS Logic PMOS pull UP Z = A’+B’  C’+D’ Supplemental

  28. CMOS Logic Supplemental

  29. CMOS Logic & Scaling If CL 3 minimum loads or 7.5fF 0.5um process OR 0.25fF 90nm process tr & tf equal? No!!!

  30. CMOS Logic & Scaling > 300X less Pwr

  31. CMOS Logic NMOS pull DWN Z’ = A(D+E) + (BC) PMOS pull UP Z = [A+(D E)]  (B+C) PMOS pull UP Z = A’+B’ + C Supplemental NMOS pull DWN Z’ = ABC

  32. Shifting the Qpt for Gain A Gain A = ΔVDS/ ΔVGS

  33. CMOS Analog ID vs. VDS & rds Early Voltage and Lambda Take Away – effective output resistance Modeled by 1/ID or VA/ID

  34. Modeling rout & gm

  35. ID vs. VGS - ID vs. VDS; Amplification & gm

  36. ID vs. VGS - ID vs. VDS; Amplification

  37. Q pt Bias Stabilization Amplification

  38. Q pt Bias Stabilization Amplification

  39. f1 Bias Considerations Amplification

  40. f2 Considerations Amplification

  41. Common Source Summary • Select Qpt = (VGS, ID, & VDS)and estimate gm and gds =ID/VA • Stabilize the Bias or Quiescent point – VGG =VGSQ + ID RS • RG1, RG2 and RS VGG =VDD RG1/{RG1|| RG2} • Determine Cc1, Cc2, CS • Determine RD after finding gm and gds. • gain = -gm RD||rds||RL mid band gain • Generally – RL >> RD or rds & RG = RG||RG >> Rgen

  42. Common Source Summary``

  43. Common Drain in ICs

  44. Large Signal Equivalent CktReview Summary

  45. MOSFET DC BIAS

  46. Distorting the Signal Distortion

  47. Shifting the Qpt con’t Analytical ΔID ΔVGS gm = ΔID/ ΔVGS

  48. MOSFET DC BIAS

  49. MOSFET DC BIAS-CS,CD,CG Gain – modest Rin – High Ro – High Inverting Gain – modest Rin – low Ro – High noninverting Gain –Unity Rin – High Ro – Low Noninverting buffer

  50. Bias Stabilization – Depletion & Enhancement

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