Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
CSCE 612: VLSI System Design Instructor: Jason D. Bakos MOSFET Theory p-type body: majority carriers are holes accumulation mode Vt depends on doping and tox VLSI System Design 2 Regions of Operation Gate to channel: Vgs near source Vgd near drain Switching delay is determined by: • time required to charge/discharge gate drain • time for current to travel across channel VLSI System Design 3 Ideal I-V Characteristics I ds Qchannel carrier time Q CV Linear region Vgc Vgs C g ox WL tox Qchannel C g Vgc Vt V Qchannel C g Vgs sd Vt 2 Cox ox C g CoxWL (charge) Vsd 2 ox 3.9 0 0 8.85 10 14 F / cm tox V Qchannel CoxWLVgs sd Vt 2 v E V E ds L (carrier velocity, is mobility) (electric field) L v L2 carrier time Vds carrier time V v ds L I ds Qchannel carrier time V W Vgs Vt ds Vds L 2 V I ds Vgs Vt ds Vds 2 V W I ds k ' Vgs Vt ds Vds L 2 I ds Cox VLSI System Design 4 Ideal I-V Characteristics Saturation region: Vds Vgs Vt Cox into equation… 0, Vgs Vt V I ds Vgs Vt ds Vds , Vds Vdsat 2 2 V V , Vds Vdsat gs t 2 Holes have less mobility than electrons, so pmos’s provide less current (and are slower) than nmos’s of the same size W L nmos cutoff linear saturation n 2 3 p pmos Which parameters do we change to make MOSFETs faster? VLSI System Design 5 Nonideal I-V Effects • Velocity saturation and mobility degradation – Lower Ids than expected • At high lateral field strength (Vds/L), carrier velocity stops increasing linearly with field strength • At high vertical field strength (Vgs / tox) the carriers scatter more often • Channel length modulation – Saturation current increases with higher Vds • Subthreshold conduction – Current drops exponentially when Vgs drops below Vt (not zero) • Body effect – Vt affected by source voltage relative to body voltage • Junction leakage – S/D leaks current into substrate/well • Tunneling – Gate current due to thin gate oxides • Temperature dependence – Mobility and threshold voltage decrease with rising temperature VLSI System Design 6 C-V Characteristics • Capacitors are bad – Slow down circuit (need to use more power), creates crosstalk (noise) • Gate is a good capacitor – Gate is one plate, channel is the other – Needed for operation: attracts charge to invert channel • Source/drain are also capacitors to body (p-n junction) – Parasitic capacitance – “Diffusion capacitance” – Depends on diffusion area, perimeter, depth, doping levels, and voltage • Make as small as possible (also reduces resistance) VLSI System Design 7 Gate Capacitance • Gate’s capacitance – – – – – – Relative to source terminal Cgs=COXWL Assuming minimum length… Cgs=CperW Cper = COXL = (OX/tOX)L Fab processes reduce length and oxide thickness simultaneously • Keeps Cper relatively constant • 1.5 – 2 fF / um of width VLSI System Design 8 Gate Capacitance Five components: Intrinsic: Cgb, Cgs, Cgd Overlap: Cgs(overlap), Cgd(overlap) C0 = WLCox Parameter Cutoff Linear Saturation Cgb C0 0 0 Cgs 0 C0/2 2/3 C0 Cgd 0 C0/2 0 Sum C0 C0 2/3 C0 Cgsol=Cgdol=0.20.4 fF / um of width VLSI System Design 9 Parasitic Capacitance • Source and drain capacitance – From reverse-biased PN junction (diffusion to body) – Csb, Cdb – Depends of area and perimeter of diffusion, depth, doping level, voltage – Diffusion has high capacitance and resistance • Made small as possible in layout – Approximately same as gate capacitance (1.5 – 2 fF / um of gate width) Isolated, shared, and merged diffusion regions for transistors in series VLSI System Design 10 Switch-Level RC Delay Models Delay can be estimated as R * 6C FET passing weak value has twice the resistance VLSI System Design 11