This Letter proposes a low-cost, single event double-upset tolerant latch which utilises interlocked nodes to keep data, clock gating (CG) in Muller C-element (MCE) to turn off the storage cell, a three-input MCE to block the soft error from the storage cell and a weak keeper to prevent high impedance state. The storage cell in the proposed latch has better reliability than the conventional triple path dual-interlocked storage cell (TPDICE). Most up-to-date single event double-upset (SEDU) tolerant latches are carried out with too large cost penalties. The proposed one saves up to 93.32% area-powerdelay product (APDP) compared with one up-to-date SEDU tolerant latch and even saves 36.36% APDP compared with only single event upset (SEU) tolerant latch in the referential. Simulation results have verified SEU and SEDU tolerance of the proposed latch.
A high performance embedded DRAM with deep trench capacitor and high performance SOI logic has been deployed in 45nm and 32nm technology nodes. Following a yield ramp of the sub-2ns latency 45nm technology, we present, for the first time, a 32nm eDRAM technology fully compatible with high performance logic with high-κ metal gate access transistor and high-κ node dielectric for the deep trench storage capacitor.We also describe the technology advancements required to scale the deep trench as well as the access transistor for optimal cell retention and performance. A clear scaling path is seen for the 22nm technology node.
We present a 65nm embedded DRAM cell (0.127 µm 2 cell size) on unpatterned SOI fabricated using standard high performance SOI technology with dual stress liner (DSL) (1). The cell utilizes a low-leakage 2.2-nm gate oxide pass transistor and a deep trench capacitor. A trench side wall spacer process enables a simplified collarless process. Connection to the buried plate is realized by silicided substrate guardrings with fully landed tungsten contacts. The bitline structure and the deep trench capacitor are designed for high transfer ratio and low RC constant which ensure high performance and sufficient sensing signal. The pass transistor is strain engineered to boost on current and employs optimized S/D junctions to help attain sub-pA off current. This technology has produced fully-functional 2Mb prototype embedded macros with sub-1.5ns latency and sub-2ns random cycle times for on-processor caches. The low leakage device developed also enables for the first time a low standby power SOI technology.
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