Title :
A statistical methodology as applied to a 256 Mbit DRAM pass transistor design
Author :
Mozumder, Purnendu K. ; Chatterjee, Amitava
Author_Institution :
Semicond. Process. & Device Center, Texas Instrum. Inc., Dallas, TX, USA
fDate :
8/1/1996 12:00:00 AM
Abstract :
We present a novel design for manufacturing (DFM) methodology that has been applied to the design of a pass transistor for 256 Mbit DRAM. The design inputs that include gate oxide thickness, which limits the booted wordline voltage, the threshold voltage adjust implant, and the substrate bias voltage, for different channel lengths, are optimized to meet the constraints on performance, reliability, and robustness against manufacturing variations. The problems associated with applying conventional DFM techniques are discussed and a new methodology based on “margins” is presented. The results pertaining to the optimized DRAM pass transistor design for a power supply voltage Vcc=2.5 V are presented,
Keywords :
DRAM chips; design for manufacture; integrated circuit design; statistical analysis; 2.5 V; 256 Mbit; DRAM pass transistor; booted wordline voltage; channel length; design for manufacturing; gate oxide thickness; margins; reliability; robustness; statistical methodology; substrate bias voltage; threshold voltage adjust implant; Constraint optimization; Design for manufacture; Design optimization; Implants; Manufacturing; Power supplies; Random access memory; Robustness; Statistical analysis; Threshold voltage;
Journal_Title :
Semiconductor Manufacturing, IEEE Transactions on
