Title :
Resistor-Less Design of Power-Rail ESD Clamp Circuit in Nanoscale CMOS Technology
Author :
Yeh, Chih-Ting ; Ker, Ming-Dou
Abstract :
A resistor-less power-rail electrostatic discharge (ESD) clamp circuit realized with only thin-gate-oxide devices and with a silicon-controlled rectifier (SCR) as the main ESD clamp device has been proposed and verified in a 65-nm CMOS process. By skillfully utilizing the gate leakage current to realize the equivalent resistor in the ESD-transient detection circuit, the RC-based ESD detection mechanism can be achieved without using an actual resistor to significantly reduce the layout area in I/O cells. From the measured results, the new proposed power-rail ESD clamp circuit with an SCR width of 45 μm can achieve 5-kV human-body-model and 400-V machine-model ESD levels under the ESD stress event while consuming only a standby leakage current of 1.43 nA at room temperature under the normal circuit operating condition with 1-V bias.
Keywords :
CMOS integrated circuits; electrostatic discharge; integrated circuit layout; leakage currents; power integrated circuits; thick film resistors; thyristors; ESD; ESD-transient detection circuit; I-O cell; SCR; current 1.43 nA; equivalent resistor; gate leakage current; nanoscale CMOS technology; resistor-less power-rail electrostatic discharge clamp circuit; silicon-controlled rectifier; size 45 mum; size 65 nm; temperature 293 K to 298 K; thin-gate-oxide device; voltage 1 V; voltage 400 V; voltage 5 kV; CMOS process; Electrostatic discharges; Leakage current; Logic gates; Resistors; Thyristors; Electrostatic discharge (ESD); gate leakage; power-rail ESD clamp circuit; silicon-controlled rectifier (SCR);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2012.2217970
