Characterization of Micro-Bump C4 Interconnects for Si-Carrier SOP Applications

Wright, S. L.; Polastre, R.; Gan, Hua; Buchwalter, L.P.; Horton, R.; Andry, Paul; Sprogis, E.; Patel, C.S.; Tsang, C. K.; Knickerbocker, John; Lloyd, J. R.; Sharma, A.; Sri-Jayantha, M.S.

doi:10.1109/ectc.2006.1645716

Cited by 80 publications

(54 citation statements)

References 20 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…New defects emerge for 3D chips due to processing steps that did not exist in 2D chips, e.g., wafer thinning, alignment and bonding [100]. Micro-bumps in 3D chips are susceptible to open/bridging defects [101]. New decisions specific to 3D chips also complicate the test flow; there are multiple points at which 3D chips may have to be tested.…”

Section: From 2d To 3d Chip Testingmentioning

confidence: 99%

Large-Scale 3D Chips: Challenges and Solutions for Design Automation, Testing, and Trustworthy Integration

Knechtel

Sinanoglu

Elfadel

et al. 2017

IPSJ Transactions on System LSI Design Methodology

View full text Add to dashboard Cite

Three-dimensional (3D) integration of electronic chips has been advocated by both industry and academia for many years. It is acknowledged as one of the most promising approaches to meet ever-increasing demands on performance, functionality, and power consumption. Furthermore, 3D integration has been shown to be most effective and efficient once large-scale integration is targeted for. However, a multitude of challenges has thus far obstructed the mainstream transition from "classical 2D chips" to such large-scale 3D chips. In this paper, we survey all popular 3D integration options available and advocate that using an interposer as system-level integration backbone would be the most practical for large-scale industrial applications and design reuse. We review major design (automation) challenges and related promising solutions for interposer-based 3D chips in particular, among the other 3D options. Thereby we outline (i) the need for a unified workflow, especially once full-custom design is considered, (ii) the current design-automation solutions and future prospects for both classical (digital) and advanced (heterogeneous) interposer stacks, (iii) the state-of-art and open challenges for testing of 3D chips, and (iv) the challenges of securing hardware in general and the prospects for large-scale and trustworthy 3D chips in particular.

show abstract

Section: From 2d To 3d Chip Testingmentioning

confidence: 99%

Large-Scale 3D Chips: Challenges and Solutions for Design Automation, Testing, and Trustworthy Integration

Knechtel

Sinanoglu

Elfadel

et al. 2017

IPSJ Transactions on System LSI Design Methodology

View full text Add to dashboard Cite

show abstract

“…Area array micro-bumps with nominal diameters of 50 μm and 25 μm and pitch of 100 μm and 50 μm, respectively, have been fabricated (see Figure 3) on the silicon carrier and electrically characterized [16,22]. DC contact resistances equaling 14 mΩ and 17 mΩ were obtained for 50 μm and 25 μm micro-bumps, respectively [22].…”

Section: Characterization Of Silicon Carrier Electrical Elements 31 mentioning

confidence: 99%

“…The delay and the losses are expected to reduce as the micro-bump diameter and its respective pad is scaled down to smaller dimensions. Non-uniform current crowding and spreading resistance play a significant role in determining the electrical parasitics of micro-bumps [22] and make it difficult to deduce a simple scalar model that predicts the impact of microbump dimension scaling on its electrical parasitics. Derivation of such model is a subject for future investigation.…”

Section: Figure 3 Silicon Carrier With 50 μM Pitch Micro-bumpsmentioning

confidence: 99%

“…To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Several papers have been published recently by IBM research that introduced the silicon carrier technology for a wide range of twoand three-dimensional product applications and presented detailed descriptions of its key technology enablers [2,5,7,15,16,22]. In its most basic form, the silicon carrier is a silicon substrate that has fine pitch I/Os and high speed wiring on one side, a typical C4 solder bump on the other side and through-vias that connect the two sides (see Figure 1).…”

Section: Figure 1 Silicon Carrier and Its Electrical Elementsmentioning

confidence: 99%

See 1 more Smart Citation

Silicon carrier for computer systems

Patel¹

2006

2006 43rd ACM/IEEE Design Automation Conference

View full text Add to dashboard Cite

System-on-Package (SOP) based on silicon carriers has the potential to provide modular design flexibility and high-performance integration of heterogeneous chip technologies for a wide range of two-and three-dimensional product applications. Key technology enablers include silicon through-vias, high-density wiring, high-I/O chip interconnection, and supporting test and assembly technologies. This paper describes the electrical characterization of key technical elements of the silicon carrier and discusses the significance of those elements in enhancing the overall system performance. The paper also discusses some methodologies that may allow silicon carrier technical elements to be easily integrated within existing EDA tools.

show abstract

“…There are three major reasons [2,3] for the reduced energy efficiency in current devices: (1) energy required for communication in large chips vis-a-vis computation, (2) losses in power delivery and (3) energy required Mohamed M. Sabry and Arvind Sridhar are authors of equal contributions to this work. This work was partly funded by the EC FP7 STREP GreenDataNet project (no.…”

Section: Introductionmentioning

confidence: 99%

Integrated microfluidic power generation and cooling for bright silicon MPSoCs

Sabry

Sridhar

Atienza

et al. 2014

Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition (DATE), 2014

View full text Add to dashboard Cite

Abstract-The soaring demand for computing power in our digital information age has produced, as an undesirable sideeffect, a surge in power consumption and heat density for Multiprocessors Systems-on-Chip (MPSoCs). The resulting temperature rise results in operating conditions that already preclude operating all the cores at maximum performance levels, in order to prevent system overheating and failures. With more power demands, MPSoCs will face a power delivery wall due to the reliability limitations of the underlying power delivery medium. Thus, state-of-the-art power and cooling delivery solutions are reaching their performance limits and it will no longer be possible to power up simultaneously all the available on-chip cores (situation known as dark silicon). In this paper we investigate a recently proposed disruptive approach to overcome the prevailing worst-case power and cooling provisioning paradigms for MPSoCs. This proposed approach integrates MPSoC with an on-chip microfluidic fuel cell network for joint cooling and power supply (i.e., localized power generation and delivery). By providing alternative means to power delivery integrated with cooling, MPSoCs are expected to gain in I/O connectivity. Based on this disruptive technology, we can envision the removal of the current limits of power delivery and heat dissipation in MPSoC designs, subsequently avoiding dark silicon and enabling a paradigm shift in future energy-proportional computing architecture designs.

show abstract

Characterization of Micro-Bump C4 Interconnects for Si-Carrier SOP Applications

Cited by 80 publications

References 20 publications

Large-Scale 3D Chips: Challenges and Solutions for Design Automation, Testing, and Trustworthy Integration

Large-Scale 3D Chips: Challenges and Solutions for Design Automation, Testing, and Trustworthy Integration

Silicon carrier for computer systems

Integrated microfluidic power generation and cooling for bright silicon MPSoCs

Contact Info

Product

Resources

About