3 research outputs found
Enabling Fine-Grain Restricted Coset Coding Through Word-Level Compression for PCM
Phase change memory (PCM) has recently emerged as a promising technology to
meet the fast growing demand for large capacity memory in computer systems,
replacing DRAM that is impeded by physical limitations. Multi-level cell (MLC)
PCM offers high density with low per-byte fabrication cost. However, despite
many advantages, such as scalability and low leakage, the energy for
programming intermediate states is considerably larger than programing
single-level cell PCM. In this paper, we study encoding techniques to reduce
write energy for MLC PCM when the encoding granularity is lowered below the
typical cache line size. We observe that encoding data blocks at small
granularity to reduce write energy actually increases the write energy because
of the auxiliary encoding bits. We mitigate this adverse effect by 1) designing
suitable codeword mappings that use fewer auxiliary bits and 2) proposing a new
Word-Level Compression (WLC) which compresses more than 91% of the memory lines
and provides enough room to store the auxiliary data using a novel restricted
coset encoding applied at small data block granularities.
Experimental results show that the proposed encoding at 16-bit data
granularity reduces the write energy by 39%, on average, versus the leading
encoding approach for write energy reduction. Furthermore, it improves
endurance by 20% and is more reliable than the leading approach. Hardware
synthesis evaluation shows that the proposed encoding can be implemented
on-chip with only a nominal area overhead.Comment: 12 page