{"title":"会议25概述:DRAM内存小组委员会","authors":"Dong-Uk Lee, Bor-Doou Rong, Kyu-Hyoun Kim","doi":"10.1109/ISSCC42613.2021.9365948","DOIUrl":null,"url":null,"abstract":"First devices for the new DRAM standards LPDDR5 and DDR5 are implementing improvements in bandwidth and power efficiency. The new devices will have a huge impact on a very wide range of applications, from IoT applications and smartphones to server and workstation applications. A new proposal for managed LRDIMM promises to reduce cost and power, and to provide capacities up to 512GB. For next generation DRAM interfaces a PAM-3 transceiver with 27Gb/s/pin on the base of 3 bits per 2 symbols is presented. -generation LPDDR5 the maximum bandwidth as WCK clocking and non-target ODT (NT-ODT). power consumption using techniques such as dynamic voltage frequency scaling (DVFS), and a deep-sleep mode (DSM). presents a DDR5 SDRAM to overcome bandwidth, power and capacity limitations of DDR4. This paper presents a 16Gb 6.4Gb/s/pin DDR5 SDRAM with a phase-rotator-based DLL, write-level training, and RX/TX with the enhanced DFE/FFE. The energy efficiency is improved by more than 30% with 1.1V/1.8V VDD and VPP. a 3bit/2UI 1.03pJ/bit PAM-3 single-ended TRX. An 27Gb/s PAM-3 symbol is generated with an output driver voltage of 0.6V and a 1/3-rate forwarded clock frequency of 9GHz. The RX adopts a 1-tap tri-level DFE, which has the same complexity as for NRZ signaling to equalize the PAM-3 signal. Fabricated in a 28nm CMOS technology, the proposed PAM-3 TRX can be utilized for the next generation memory interface with low power. (ODP) structured (media) and ODP structure of for cost minimization, pre-CMD scheme for reduction. Dies per wafer increase of compared to conventional DRAM with same process and same capacity was achieved. DIMM power consumption is","PeriodicalId":6511,"journal":{"name":"2016 IEEE International Solid-State Circuits Conference (ISSCC)","volume":"26 1","pages":"342-343"},"PeriodicalIF":0.0000,"publicationDate":"2021-02-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Session 25 Overview: DRAM Memory Subcommittee\",\"authors\":\"Dong-Uk Lee, Bor-Doou Rong, Kyu-Hyoun Kim\",\"doi\":\"10.1109/ISSCC42613.2021.9365948\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"First devices for the new DRAM standards LPDDR5 and DDR5 are implementing improvements in bandwidth and power efficiency. The new devices will have a huge impact on a very wide range of applications, from IoT applications and smartphones to server and workstation applications. A new proposal for managed LRDIMM promises to reduce cost and power, and to provide capacities up to 512GB. For next generation DRAM interfaces a PAM-3 transceiver with 27Gb/s/pin on the base of 3 bits per 2 symbols is presented. -generation LPDDR5 the maximum bandwidth as WCK clocking and non-target ODT (NT-ODT). power consumption using techniques such as dynamic voltage frequency scaling (DVFS), and a deep-sleep mode (DSM). presents a DDR5 SDRAM to overcome bandwidth, power and capacity limitations of DDR4. This paper presents a 16Gb 6.4Gb/s/pin DDR5 SDRAM with a phase-rotator-based DLL, write-level training, and RX/TX with the enhanced DFE/FFE. The energy efficiency is improved by more than 30% with 1.1V/1.8V VDD and VPP. a 3bit/2UI 1.03pJ/bit PAM-3 single-ended TRX. An 27Gb/s PAM-3 symbol is generated with an output driver voltage of 0.6V and a 1/3-rate forwarded clock frequency of 9GHz. The RX adopts a 1-tap tri-level DFE, which has the same complexity as for NRZ signaling to equalize the PAM-3 signal. Fabricated in a 28nm CMOS technology, the proposed PAM-3 TRX can be utilized for the next generation memory interface with low power. (ODP) structured (media) and ODP structure of for cost minimization, pre-CMD scheme for reduction. Dies per wafer increase of compared to conventional DRAM with same process and same capacity was achieved. 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First devices for the new DRAM standards LPDDR5 and DDR5 are implementing improvements in bandwidth and power efficiency. The new devices will have a huge impact on a very wide range of applications, from IoT applications and smartphones to server and workstation applications. A new proposal for managed LRDIMM promises to reduce cost and power, and to provide capacities up to 512GB. For next generation DRAM interfaces a PAM-3 transceiver with 27Gb/s/pin on the base of 3 bits per 2 symbols is presented. -generation LPDDR5 the maximum bandwidth as WCK clocking and non-target ODT (NT-ODT). power consumption using techniques such as dynamic voltage frequency scaling (DVFS), and a deep-sleep mode (DSM). presents a DDR5 SDRAM to overcome bandwidth, power and capacity limitations of DDR4. This paper presents a 16Gb 6.4Gb/s/pin DDR5 SDRAM with a phase-rotator-based DLL, write-level training, and RX/TX with the enhanced DFE/FFE. The energy efficiency is improved by more than 30% with 1.1V/1.8V VDD and VPP. a 3bit/2UI 1.03pJ/bit PAM-3 single-ended TRX. An 27Gb/s PAM-3 symbol is generated with an output driver voltage of 0.6V and a 1/3-rate forwarded clock frequency of 9GHz. The RX adopts a 1-tap tri-level DFE, which has the same complexity as for NRZ signaling to equalize the PAM-3 signal. Fabricated in a 28nm CMOS technology, the proposed PAM-3 TRX can be utilized for the next generation memory interface with low power. (ODP) structured (media) and ODP structure of for cost minimization, pre-CMD scheme for reduction. Dies per wafer increase of compared to conventional DRAM with same process and same capacity was achieved. DIMM power consumption is