1 / 25

Models for Hand Analysis

Models for Hand Analysis. NMOS Transistor. V DSN  V GSN -V TN. V DSN  V GSN -V TN. K N =(W/L)K’ N. PMOS Transistor. V DSP  V GSP -V TP. V DSP  V GSP -V TP. K P =(W/L)K’ P. pMOS Current model. VDSP>VGSP -VTP. VDSP <VGSP-VTP. Channel Resistance. R=. R=.

page
Download Presentation

Models for Hand Analysis

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Models for Hand Analysis NMOS Transistor VDSN  VGSN-VTN VDSN VGSN-VTN KN=(W/L)K’N PMOS Transistor VDSP VGSP -VTP VDSP VGSP-VTP KP=(W/L)K’P

  2. pMOS Current model VDSP>VGSP -VTP VDSP <VGSP-VTP

  3. Channel Resistance R= R=

  4. Variation of resistance with Vgs

  5. Linear Scaling

  6. Scalling Effects

  7. Velocity Saturation and mobility Degradation

  8. TOH’s Model for Short Channel for for

  9. Secondary Effects • Subthreshold current: is the small current that flows from drain at Vgs < Vt • Punch through:If a large voltage is applied to Vds, then the depletion region of the drain can extend to the source, a punch through occurs and under these condition a large current can flow from the drain to source. • Hot carrier:As a results of scaling, device dimensions are reduced while, doping concentrations are increased, while voltages are not reduced to the same proportion, as a consequence there is an increase in electric field in the channel region while, the thickness of the gate insulating layer is thinner. Due to the acceleration of electrons by the Vds, electrons and holes gaining high speed can penetrate the gate insulator and change its characteristics. • Channel hot electrons:If the Vds is increased, then the lateral electric field is increased and the electric field accelerates the electrons near the drain with high kinetic energy they are injected into the oxide near the drain.

  10. Semiconductor Resistors Resistance R=  (l /A) = (/t). (l /w) = Rsh. (l /w) Rsh = sheet resistance Ω/ For 0.5u process: N+ diffusion : 70 Ω/ M1: 0.06 Ω/ P+ diffusion : 140 Ω/ M2: 0.06 Ω/ Polysilicon : 12 Ω/ M3: 0.03 Ω/ Polycide:2-3 Ω/ P-well: 2.5K Ω/ N-well: 1K Ω/ current t l w (A)

  11. Semiconductor Resistors polysilicon Diffusion n+ Al Al SiO2 Field oxide n+ Polysilicon Resistor Diffusion Resistor

  12. Variations in Width and Length polysilicon 1. Width Oxide encroachment Weff = Wdrawn- 2WD 2. Length Lateral diffusion LD= 0.7Xj Leff = Ldrawn- 2LD Weff WD WD Wdrawn polysilicon Ldrawn LD Leff LD

  13. Semiconductor Capacitors 1. Poly Capacitor: a. Poly to substrate b. Poly1 to Poly2 2. Diffusion Capacitor sidewall capacitances depletion region n+ (ND) bottomwall capacitance substrate (NA)

  14. RS Rch RD Transistor Resistance Two Components: Drain/ Sources Resistance: RD(S) = Rsh x no. of squares+ contact resistance. Channel Resistance: Depends on the region of operation: (G) : L (S) (D) n+ n+ W Linear Saturation

  15. Dynamic Behavior of MOS Transistor Prentice Hall/Rabaey

  16. The Gate Capacitance Prentice Hall/Rabaey

  17. Average Gate Capacitance Different distributions of gate capacitance for varying operating conditions Most important regions in digital design: saturation and cut-off Prentice Hall/Rabaey

  18. Diffusion Capacitance Prentice Hall/Rabaey

  19. Diffusion Capacitance

  20. SPICE TRANSISTOR MODEL

  21. SPICE MODELS

  22. MAIN MOS SPICE PARAMETERS Prentice Hall/Rabaey

  23. SPICE Parameters for Parasitics Prentice Hall/Rabaey

  24. SPICE Transistors Parameters Prentice Hall/Rabaey

  25. Example

More Related