A new soft-error phenomenon in which the soft-error rate (SER) decreases as cycle time becomes shorter has been found in static RAM's (SRAM's) employing a high-resistive load memory cell. This inverted dependence is observed during the read cycle in the SRAM's involving the PMOS bit-line load. The SER at the cycle time of 100 ns is reduced by 1.5-orders of magnitude compared with that of conventional SRAM's. The convertional dependence of SER on cycle time has been explained with the time constant to charge up the "High" storage node potential through the high-resistive load. The mechanism of the inverted dependence becomes clear in consideration of the time constant of the potential drop of the "High" storage node. The analysis is applied to explain that three kinds of dependence of SER on cycle time, which are the conventional dependence, the inverted dependence, and no dependence, will be observed when the following cell parameters are changed. One is the threshold voltage of driver transistors in the cell, and the other is the impedance of the high-resistive load.

This paper describes a new hierarchical bit line organization utilizing a T-shaped bit line(H-BLT) and its practical implementation in a 4-Mb SRAM using a 0.4µm CMOS process. The H-BLT has reduced the number of I/O circuits for multiplexers, sense amplifiers and write drivers, resulting in an efficient multiple blockdivision of the memory cell array. The size of the SRAM die was reduced by 14% without an access penalty. The active current is 30mA at 5 V and 10 MHz. The typical address access time is 35 ns with a 4.5 V supply voltage and a 30 pF load capacitance. The operating voltage range is 2.5 V to 6.0 V. H-BLT is a bright and useful architecture for the high density SRAMs of the future.