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The Devices: MOS Transistor [Adapted from Rabaey’s Digital Integrated Circuits, ©2002, J. Rabaey et al.] EE415 VLSI Design The MOS Transistor Polysilicon EE415 VLSI Design Aluminum The MOS Transistor Gate Oxyde Gate Source Polysilicon n+ Drain n+ p-substrate Bulk Contact CROSS-SECTION of NMOS Transistor EE415 VLSI Design Field-Oxyde (SiO2) p+ stopper Switch Model of NMOS Transistor | VGS | Source (of carriers) Open (off) (Gate = ‘0’) Gate Drain (of carriers) Closed (on) (Gate = ‘1’) Ron | VGS | < | VT | EE415 VLSI Design | VGS | > | VT | Switch Model of PMOS Transistor | VGS | Source (of carriers) Open (off) (Gate = ‘1’) Gate Drain (of carriers) Closed (on) (Gate = ‘0’) Ron | VGS | > | VDD – | VT | | EE415 VLSI Design | VGS | < | VDD – |VT| | MOS transistors Symbols D D G G S S NMOS Enhancement NMOS Depletion D G G S PMOS Enhancement EE415 VLSI Design D B S NMOS with Bulk Contact Channel MOSFET Static Behavior Positive voltage applied to the gate (VGS > 0) •The gate and substrate form the plates of a capacitor. •Negative charges accumulate on the substrate side (repels mobile holes) •A depletion region is formed under the gate (like pn junction diode) + S VGS - D G n+ n+ n-channel Depletion Region p-substrate EE415 VLSI Design B Current-Voltage Relations Assume VGS > VT •A voltage difference VDS will cause ID to flow from drain to source •At a point x along the channel, the voltage is V(x), and the gate-tochannel voltage is VGS - V(x) •For channel to be present from drain to source, VGS - V(x) > VT, i.e. VGS - VDS > VT for channel to exist from drain to source VGS VDS S G n+ – V(x) ID D n+ + L x p-substrate B EE415 VLSI Design MOS transistor and its bias conditions Linear (triode) Region •When VGS - VDS > VT , the channel exists from drain to source •Transistor behaves like voltage controlled resistor EE415 VLSI Design Saturation Region •When VGS - VDS VT , the channel is pinched off •Electrons are injected into depletion region and accelerated towards drain by electric field •Transistor behaves like voltage-controlled current source EE415 VLSI Design Pinch-off Current-Voltage Relations Long-Channel Device EE415 VLSI Design Current-Voltage Relations Long Channel transistor 6 x 10 -4 VGS= 2.5 V 5 VDS = VGS - VT Resistive Saturation 4 ID (A) VGS= 2.0 V 3 Quadratic Relationship VDS = VGS - VT 2 VGS= 1.5 V cut-off 1 0 VGS= 1.0 V 0 0.5 1 1.5 2 2.5 VDS (V) NMOS transistor, 0.25um, Ld = 10um, W/L = 1.5, VDD = 2.5V, VT = 0.4V EE415 VLSI Design
