Electrical Design Optimization and Characterization in Cell Broadband Engine Package

Goto, Yuichi; Hosomi, E.; Harvey, Paul; Kawasaki, Ken-íchi; Noma, Hirokazu; Mori, Hiroyuki; Miura, M.; Takiguchi, I.; Audet, Jean; Mandrekar, R.; Nishio, T.

doi:10.1109/ectc.2006.1645647

Cited by 3 publications

(7 citation statements)

References 4 publications

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“…The details of this statistical approach can be found in a previous paper [1]. Figure 5 outlines the factors and tolerances in the study.…”

Section: Signal Distribution Analysismentioning

confidence: 98%

“…High speed signals were routed on the top build-up layers in the package and then down thru via stacks to the corresponding BGA balls. This was done successfully in the 90nm package design which has been in high volume production for some time [1].…”

Section: Cell Be Chip and Package Descriptionmentioning

confidence: 99%

“…In the laminate construction for the original 90nm Cell processor, the C4 footprint was devised to meet the minimum PTH pitch available from the laminate suppliers at reasonable cost [1]. This provided a well optimized current loop with minimal inductance from the chip, thru the substrate, to the decoupling capacitors on the backside.…”

Section: Power Distribution Analysismentioning

confidence: 99%

“…The package design and construction were driven by principal chip performance requirements for the efficient power and signal distribution at optimal cost. The optimization of these design factors in the 90nm CELL BE packaging was described previously [1]. CELL [3,4].…”

Section: Cell Be Chip and Package Descriptionmentioning

confidence: 99%

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mentioning

confidence: 99%

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Chip/Package Design and Technology Trade-offs in the 65nm Cell Broadband Engine

Harvey¹,

Zhou²,

Yamada³

et al. 2007

2007 Proceedings 57th Electronic Components and Technology Conference

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Technology migration of the Cell Broadband Engine.TM (BE) Microprocessor to 65nm chip technology precipitated a redesign of the original IC packaging [1,2]. While many of the design changes were necessitated by the chip technology migration, other modifications were implemented to enhance the robustness and overall manufacturability of the product. This paper will discuss key aspects of the 65nm chip technology that drove changes to the package design and also describe some of the modifications to enhance the manufacturability of the product. The paper will outline the statistical analysis, modeling, simulation and characterization employed in the electrical and thermal design, specification and tolerancing of the microprocessor package. The paper will be of specific interest to those involved in the costeffective, high performance IC package design and development and will be of general interest to those developing and refining analysis methods employed in overall design and technology trade-offs in advanced packaging. IntroductionTechnology progression in semiconductor materials and processing has been a forgone conclusion in the electronics industry for the past 25 years enabling sweeps in functional design scope and significant performance enhancements and/or cost reductions. Technology migration of existing designs typically involves a combination of design scope changes and performance enhancements; however, in cost sensitive applications, technology migrations can be motivated principally by the potential for cost reduction. These reductions come mainly by shrinking the overall chip area required to accommodate the design. This is done by employing a more advanced CMOS process technology, hence the term 'technology shrink'. As yield learning progresses in the more advanced process technology, the enhanced productivity in terms of number of chips per wafer and the improved capital equipment utilization in manufacturing quickly provides economic justification for a lower price on each chip. More advanced chip technology also requires a lower operating voltage for the on-chip circuits. This reduces the overall power consumption on the die. This reduction in power consumption leads to lower system thermal management costs. Thus the technology migration achieves the principal design objective by lowering both chip-level and system-level costs. In this design environment, most executives and program managers also

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“…The details of this statistical approach can be found in a previous paper [1]. Figure 5 outlines the factors and tolerances in the study.…”

Section: Signal Distribution Analysismentioning

confidence: 98%

Section: Cell Be Chip and Package Descriptionmentioning

confidence: 99%

Section: Power Distribution Analysismentioning

confidence: 99%

Section: Cell Be Chip and Package Descriptionmentioning

confidence: 99%

“…

…”

mentioning

confidence: 99%

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Chip/Package Design and Technology Trade-offs in the 65nm Cell Broadband Engine

Harvey¹,

Zhou²,

Yamada³

et al. 2007

2007 Proceedings 57th Electronic Components and Technology Conference

Self Cite

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Packaging the Cell Broadband Engine microprocessor for supercomputer applications

Harvey¹,

Mandrekar²,

Zhou³

et al. 2008

2008 58th Electronic Components and Technology Conference

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The Cell Broadband Engine TM (Cell BE) processor initially designed for high-end consumer electronics, has been enhanced by IBM for supercomputer applications. The enhancements to the chip also necessitated the design and development of a new package. The modifications to the chip included replacement of the 3.2 Gb/s XDR interface with a 800Mb/s DDR2 interface of equal bandwidth. This required the addition of several hundred chip-level connections (C4's) and package BGA balls. Incorporating this and other enhancements to the chip resulted in a ~20% larger chip and a larger and more complex package. Additional noise from this large memory interface also drove decoupling requirements that necessitated mounting capacitors on both the top and bottom sides of the package.This paper describes the design of this new package as well as the analysis and characterization techniques used to address the packaging concerns outlined above. It includes a comprehensive noise analysis as well as a thorough characterization of the DDR2 interface in the final prototypes. The paper also outlines the design and analysis of the power distribution to the various voltage domains on the chip. Along with electrical design and performance, the paper also includes finite element modeling of the mechanical stresses resident in this FCPBGA package. Finally, the concluding portions of the paper will discuss the trade-offs between electrical performance and mechanical stability, reliability and relative cost. IntroductionThe initial Cell BE processor was designed for high end consumer electronics applications and is now shipping in high volume [1,2]. But the Cell architecture was intended for much more than consumer electronics. Shortly after completion of the original Cell BE processor, IBM and Los Alamos National Labs announced plans to use this chip to build a supercomputer with a sustained performance of over 1 petaflop, quadruple the processing performance of today's most powerful supercomputer [3,4,5]. As part of this project, several enhancements to the original Cell BE were planned to augment the processor's capabilities in a supercomputer application environment. The new chip was dubbed the PowerXCell TM 8i (PowerXCell).

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System-in-Package: Electrical and Layout Perspectives

Elassaad

Shi

et al. 2011

FNT in Electronic Design Automation

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Electrical Design Optimization and Characterization in Cell Broadband Engine Package

Cited by 3 publications

References 4 publications

Chip/Package Design and Technology Trade-offs in the 65nm Cell Broadband Engine

Chip/Package Design and Technology Trade-offs in the 65nm Cell Broadband Engine

Packaging the Cell Broadband Engine microprocessor for supercomputer applications

System-in-Package: Electrical and Layout Perspectives

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