7.2 4Mb STT-MRAM-based cache with memory-access-aware power optimization and write-verify-write / read-modify-write scheme

Two performance gaps in the memory hierarchy, between CPU cache and main memory, and main memory and mass storage, will become increasingly severe bottlenecks for computing-system performance. Although it is necessary to increase memory capacity to fill these gaps, power also increases when conventional volatile memories are used. A new nonvolatile memory for this purpose has been anticipated. Storage class memory is used to fill the second gap. Many candidates exist: ReRAM, PRAM, and 3D-cross point type with resistive change RAM. However, nonvolatile last level cache (LLC) is used to fill the first gap. Advanced STT-MRAM has achieved sub-4ns read and write accesses with perpendicular magnetic tunnel junctions (p-MTJ) [1-2]. Furthermore, mature integration processes have been developed and 8Mb STT-MRAM with sub-5ns operation has shown high reliability [3]. Moreover, because of its non-volatility, STT-MRAM can reduce operation energy by more than 81% compared to SRAM for cache [1]. This paper presents STT-MRAM-based last level cache memory (LLC) including MRAM memory core, peripherals and cache logic circuits, using novel power optimization with high-speed power gating (HS-PG),considering processor architectures and cache memory accesses. The STT-MRAM-based cache has high reliability to reduce the write-error rate with novel write-verify-write. Furthermore, a read-modify-write scheme is implemented to reduce active power without penalty. Figure 7.2.1 presents a block diagram of a 4Mb STT-MRAM based cache.