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Digital Integrated Circuits A Design Perspective

Digital Integrated Circuits A Design Perspective. Jan M. Rabaey Anantha Chandrakasan Borivoje Nikolic. The Inverter. July 30, 2002. V. DD. V. V. in. out. C. L. The CMOS Inverter: A First Glance. V. DD. CMOS Inverter. N Well. PMOS. 2 l. Contacts. Out. In. Metal 1.

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Digital Integrated Circuits A Design Perspective

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  1. Digital Integrated CircuitsA Design Perspective Jan M. Rabaey Anantha Chandrakasan Borivoje Nikolic The Inverter July 30, 2002

  2. V DD V V in out C L The CMOS Inverter: A First Glance

  3. V DD CMOS Inverter N Well PMOS 2l Contacts Out In Metal 1 Polysilicon NMOS GND

  4. Two Inverters Share power and ground Abut cells Connect in Metal

  5. V V DD DD R p V out V out R n V V V 0 = = in DD in CMOS InverterFirst-Order DC Analysis VOL = 0 VOH = VDD VM = f(Rn, Rp)

  6. t = f(R .C ) pHL on L = 0.69 R C on L CMOS Inverter: Transient Response V V DD DD R p V out V out C L C L R n V 0 V V = = in DD in (a) Low-to-high (b) High-to-low

  7. Voltage TransferCharacteristic

  8. I Dn V = V +V in DD GSp I = - I Dn Dp V = V +V out DD DSp V out I I I Dp Dn Dn V =0 V =0 in in V =1.5 V =1.5 in in V V V DSp DSp out V =-1 GSp V =-2.5 GSp V = V +V V = V +V in DD GSp out DD DSp I = - I Dn Dp PMOS Load Lines

  9. CMOS Inverter Load Characteristics

  10. CMOS Inverter VTC

  11. Switching Threshold as a function of Transistor Ratio

  12. 1.8 1.7 1.6 1.5 1.4 (V) 1.3 M V 1.2 1.1 1 0.9 0.8 0 1 10 10 /W W p n Switching Threshold as a function of Transistor Ratio

  13. V out V OH V M V in V OL V V IL IH Determining VIH and VIL IL IH A simplified approach

  14. Inverter Gain

  15. Simulated VTC

  16. 2.5 2 Good PMOS Bad NMOS 1.5 Nominal (V) out Good NMOS Bad PMOS V 1 0.5 0 0 0.5 1 1.5 2 2.5 V (V) in Impact of Process Variations

  17. Propagation Delay

  18. CMOS Inverter Propagation DelayApproach 1

  19. CMOS Inverter Propagation DelayApproach 2

  20. V DD PMOS Metal1 Polysilicon NMOS CMOS Inverters 1.2 m m =2l Out In GND

  21. Transient Response ? tp = 0.69 CL (Reqn+Reqp)/2 tpHL tpLH

  22. Design for Performance • Keep capacitances small • Increase transistor sizes • watch out for self-loading! • Increase VDD (????)

  23. Delay as a function of VDD

  24. Device Sizing (for fixed load) Self-loading effect: Intrinsic capacitances dominate

  25. NMOS/PMOS ratio tpHL tpLH tp b = Wp/Wn

  26. Impact of Rise Time on Delay

  27. Inverter Sizing

  28. Inverter Chain In Out CL • If CL is given: • How many stages are needed to minimize the delay? • How to size the inverters? • May need some additional constraints.

  29. Inverter Delay • Minimum length devices, L=0.25mm • Assume that for WP = 2WN =2W • same pull-up and pull-down currents • approx. equal resistances RN = RP • approx. equal rise tpLH and fall tpHL delays • Analyze as an RC network 2W W tpHL = (ln 2) RNCL Delay (D): tpLH = (ln 2) RPCL Load for the next stage:

  30. Inverter with Load Delay RW CL RW Load (CL) tp = kRWCL k is a constant, equal to 0.69 Assumptions: no load -> zero delay Wunit = 1

  31. Inverter with Load CP = 2Cunit Delay 2W W Cint CL Load CN = Cunit Delay = kRW(Cint + CL) = kRWCint + kRWCL = kRW Cint(1+ CL /Cint) = Delay (Internal) + Delay (Load)

  32. Delay Formula Cint = gCgin withg 1 f = CL/Cgin- effective fanout R = Runit/W ; Cint =WCunit tp0 = 0.69RunitCunit

  33. Apply to Inverter Chain In Out CL 1 2 N tp = tp1 + tp2 + …+ tpN

  34. Optimal Tapering for Given N • Delay equation has N - 1 unknowns, Cgin,2 – Cgin,N • Minimize the delay, find N - 1 partial derivatives • Result: Cgin,j+1/Cgin,j = Cgin,j/Cgin,j-1 • Size of each stage is the geometric mean of two neighbors • each stage has the same effective fanout (Cout/Cin) • each stage has the same delay

  35. Optimum Delay and Number of Stages When each stage is sized by f and has same eff. fanout f: Effective fanout of each stage: Minimum path delay

  36. Example In Out CL= 8 C1 1 f f2 C1 CL/C1 has to be evenly distributed across N = 3 stages:

  37. Optimum Number of Stages For a given load, CL and given input capacitance Cin Find optimal sizing f For g = 0, f = e, N = lnF

  38. Optimum Effective Fanout f Optimum f for given process defined by g fopt = 3.6 forg=1

  39. Impact of Self-Loading on tp No Self-Loading, g=0 With Self-Loading g=1

  40. Normalized delay function of F

  41. Buffer Design N f tp 1 64 65 2 8 18 3 4 15 4 2.8 15.3 1 64 1 8 64 1 4 64 16 1 64 22.6 8 2.8

  42. Power Dissipation

  43. Where Does Power Go in CMOS?

  44. Vdd Vin Vout C L Dynamic Power Dissipation 2 Energy/transition = C * V L dd 2 Power = Energy/transition * f = C * V * f L dd Not a function of transistor sizes! Need to reduce C , V , and f to reduce power. L dd

  45. Modification for Circuits with Reduced Swing

  46. Node Transition Activity and Power

  47. Transistor Sizing for Minimum Energy • Goal: Minimize Energy of whole circuit • Design parameters: f and VDD • tp tpref of circuit with f=1 and VDD =Vref (VTE=VT+VDSAT/2)

  48. Transistor Sizing (2) • Performance Constraint (g=1) • Energy for single Transition

  49. Transistor Sizing (3) VDD=f(f) E/Eref=f(f) F=1 2 5 10 20

  50. Short Circuit Currents

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