Abstract

This paper describes a charge-transferred well (CTW) sensing method for high-speed array circuit operation and a level-controllable local power line (LCL) structure for high-speed/low-power operation of peripheral logic circuits, aimed at low voltage operating and/or giga-scale DRAMs. The CTW method achieves 19% faster sensing and the LCL structure realizes 42% faster peripheral logic operation than the conventional scheme, at 1.2 V in 15 Mb-level devices. The LCL structure realizes a subthreshold leakage current reduction of three or four orders of magnitude in sleep mode, compared with a conventional hierarchical power line structure. A negative-voltage word line technique that overcomes the refresh degradation resulting from reduced storage charge (Q/sub s/) at low voltage operation for improved reliability is also discussed. An experimental 1.2 V 16 Mb DRAM with a RAS access time of 49 ns has been successfully developed using these technologies and a 0.4-/spl mu/m CMOS process. The chip size is 7.9/spl times/16.7 mm/sup 2/ and cell size is 1.35/spl times/2.8 /spl mu/m/sup 2/.