Abraham Mathews

A 45 nm SOI Embedded DRAM Macro for the POWER™ Processor 32 MByte On-Chip L3 Cache

A 1.35 ns random access and 1.7 ns-random-cycle SOI embedded-DRAM macro has been developed for the POWER7™ high-performance microprocessor. The macro employs a 6 transistor micro sense-amplifier architecture with extended precharge scheme to enhance the sensing margin for product quality. The detailed study shows a 67% bit-line power reduction with only 1.7% area overhead, while improving a read zero margin by more than 500ps. The array voltage window is improved by the programmable BL voltage generator, allowing the embedded DRAM to operate reliably without constraining of the microprocessor voltage supply windows. The 2.5nm gate oxide transistor cell with deep-trench capacitor is accessed by the 1.7 V wordline high voltage (VPP) with V WL low voltage (VWL), and both are generated internally within the microprocessor. This results in a 32 MB on-chip L3 on-chip-cache for 8 cores in a 567 mm POWER7™ die.

A 1 MB Cache Subsystem Prototype With 1.8 ns Embedded DRAMs in 45 nm SOI CMOS

We describe a single voltage supply, 1 MB cache subsystem prototype that integrates 2 GHz embedded DRAM (eDRAM) macros with on-chip word-line voltage supply generation , a 4 Kb one-time-programmable read-only memory (OTPROM) for redundancy and repair control, on-chip OTPROM programming voltage generation, clock generation and distribution, array built-in self-test circuitry (ABIST), user logic and pervasive logic. The eDRAM employs a programmable pipeline, achieving 1.8 ns latency, and features concurrent refresh capability.

A 45nm SOI embedded DRAM macro for POWER7TM 32MB on-chip L3 cache

Logic-based embedded DRAM has matured into a wide range of ASIC applications, SRAM replacements [1] and off-chip caches for microprocessors [2]. While embedded DRAM has been leveraged in supercomputers such as IBMs BlueGene/L [3], its use has been limited to moderate performance bulk logic technologies. Although prototypes have been demonstrated [4], DRAM has yet to be embedded on a high performance microprocessor. This paper discloses an SOI DRAM macro implemented on-chip with the IBM POWER7™ high performance microprocessor [5], and introduces enhancements to the micro sense amp (µSA) architecture [6]. This high performance DRAM macro is used to construct a large 32MB L3 cache on-chip, eliminating delay, area and power from the off-chip interface, simultaneously improving system performance, reducing cost, power and soft error vulnerability. Figure 19.1.1a shows an SEM of the 45nm SOI DRAM Device and Deep Trench (DT) capacitor [7]. DT offers 25x more capacitance than planar structures and was also utilized to reduce on-chip voltage island supply noise.

A one MB cache subsystem prototype with 2GHz embedded DRAMs in 45nm SOI CMOS

We present a 1 MB cache subsystem that integrates 2 GHz embedded DRAM macros, charge pump circuits, a 4 Kb one-time-programmable ROM, clock multipliers, and built-in self test circuitry, having a 36.5 GB/s peak system data-rate. The eDRAM employs a programmable pipeline, achieving a 1.8 ns latency.

An on-chip dual supply charge pump system for 45nm PD SOI eDRAM

We present an on-chip word line (WL) dual supply system for server class embedded DRAM (eDRAM) applications. The design consists of switched capacitor charge pumps, voltage regulators, reference and clock circuits. Charge pump engines feature efficient charge transfer and energy conversion, boosting unregulated rails to 1.8x supply. At vdd=1 V, regulated high (1.5 to 1.7 V) and low (-0.3 to -0.6 V) levels ensure WL overdrive and cell turn-off, respectively, with rippling <plusmn35 mV and maintenance power <780 muW/2Mb-DRAM. The system supports >2 GHz AC array access and can endure excessive DC load.

A 14 nm 1.1 Mb Embedded DRAM Macro With 1 ns Access

A 1.1 Mb embedded DRAM macro (eDRAM), for next-generation IBM SOI processors, employs 14 nm FinFET logic technology with 0.0174 μm2 deep-trench capacitor cell. A Gated-feedback sense amplifier enables a high voltage gain of a power-gated inverter at mid-level input voltage, while supporting 66 cells per local bit-line. A dynamic-and-gate-thin-oxide word-line driver that tracks standard logic process variation improves the eDRAM array performance with reduced area. The 1.1 Mb macro composed of 8 ×2 72 Kb subarrays is organized with a center interface block architecture, allowing 1 ns access latency and 1 ns bank interleaving operation using two banks, each having 2 ns random access cycle. 5 GHz operation has been demonstrated in a system prototype, which includes 6 instances of 1.1 Mb eDRAM macros, integrated with an array-built-in-self-test engine, phase-locked loop (PLL), and word-line high and word-line low voltage generators. The advantage of the 14 nm FinFET array over the 22 nm array was confirmed using direct tester control of the 1.1 Mb eDRAM macros integrated in 16 Mb inline monitor.

17.4 A 14nm 1.1Mb embedded DRAM macro with 1ns access

IBM introduced trench capacitor eDRAM into its high performance microprocessors beginning with 45nm and Power 7 [1] to provide a higher density cache without chip crossings. Whereas the 45 and 32nm designs employ a micro sense amplifier [2] and three-level bitline hierarchy, the design implemented for 22nm utilizes a higher gain sense amplifier and two-level bitline architecture that together provide significant reductions in area, latency, and power. This 22nm design style has been migrated into a 14nm FinFET [3] learning vehicle, complete with an ABIST engine, wordline charge pumps (VPP and VWL), and padcage interface circuitry.