Abstract:
Advances in virtual reality, artificial intelligence, and big data have increased demand for high-bandwidth memory. Accordingly, pre-fetch sizes have also increased with ...Show MoreMetadata
Abstract:
Advances in virtual reality, artificial intelligence, and big data have increased demand for high-bandwidth memory. Accordingly, pre-fetch sizes have also increased with DRAM generations, meaning an increased number of global bus lines. An increase to this number is limited as it also increases the chip size; instead, the data-rate per lane can be increased for higher throughput [1]. As the global bus lines are on-chip wires in a DRAM chip, they can be driven capacitively. Prior work [2], [3] has shown the superior efficiency of capacitive drivers, over conventional repeaters, in driving on-chip wires at the cost of a reduced voltage swing. However, as there is no well-defined DC level on the capacitively-driven wires [4], wire biasing is fraught with implementation challenges [3]. To define the DC potential on the interconnect, prior work sent signals differentially [2], [4], [5] or dissipated static power to define the DC level [3]. Unfortunately, these approaches may not be preferable for DRAM chips that require dense and energy-efficient data transfers.
Date of Conference: 20-26 February 2022
Date Added to IEEE Xplore: 17 March 2022
ISBN Information: