Posts Tagged ‘fan out’
Jeff Wilson of Mentor Graphics writes that, in IC design, we’re currently seeing the makings of a perfect storm when it comes to the growing complexity of fill. The driving factors contributing to the growth of this storm are the shrinking feature sizes and spacing requirements between fill shapes, new manufacturing processes that use fill to meet uniformity requirements, and larger design sizes that require more fill.
Is 3D NAND a Disruptive Technology for Flash Storage? Absolutely! That’s the view of Dr. Er-Xuan Ping of Applied Materials. He said a panel at the 2014 Flash Memory Summit agreed that 3D NAND will be the most viable storage technology in the years to come, although our opinions were mixed on when that disruption would be evident.
Phil Garrou takes a look at some of the “Fan Out” papers that were presented at the 2014 ECTC, focusing on STATSChipPAC (SCP) and the totally encapsulated WLP, Siliconware (SPIL) panel fan-out packaging (P-FO), Nanium’s eWLB Dielectric Selection, and an electronics contact lens for diabetics from Google/Novartis.
Ed Koczynski says he now knows how wafers feel when moving through a fab. Leti in Grenoble, France does so much technology integration that in 2010 it opened a custom-developed people-mover to integrate cleanrooms (“Salles Blanches” in French) it calls a Liaison Blanc-Blanc (LBB) so workers can remain in bunny-suits while moving batches of wafers between buildings.
Handel Jones of IBS provides a study titled “How FD-SOI will Enable Innovation and Growth in Mobile Platform Sales” that concludes that the benefits of FD-SOI are overwhelming for mobile platforms through Q4/2017 based on a number of key metrics.
Gabe Moretti of Chip Design blogs that a grown industry looks at the future, not just to short term income. EDA is demonstrating to be such an industry with significant participation by its members to foster and support the education of its future developers and users through educational licenses and other projects that foster education.
The increasing demand for wireless data bandwidth and the emergence of LTE and LTE Advanced standards pushes radio-frequency (RF) IC designers to develop devices with higher levels of integrated RF functions, meeting more and more stringent specification levels. The substrates on which those devices are manufactured play a major role in achieving that level of performance.
Everybody’s talking about it, but just what is DFM? According to various EDA company websites, design for manufacturing can be: generation of yield optimized cells; layout compaction; wafer mapping optimization; planarity fill; or, statistical timing among other definitions. Obviously, there is very little consensus. For me, DFM is what makes my job hard: Characterizing it, and developing tools for it, is the most important item on my agenda.
In nanometer designs, the number of single vias, and the number of via transitions with minimal overlap, can contribute significantly to yield loss. Yet doubling every via leads to other yield-related problems and has a huge impact on design size. While there is still concern over of how many vias can be fixed without rerouting and without creating DRC violations, the Calibre via doubling tool can identify via transitions and recommend areas for second via insertion without increasing area.
Certain measurement methodologies can be inaccurate even if they’re precise, and there are known errors associated with certain system parameters.
The etch loading effect is the dominant factor that impacts final CD control at advanced nodes with shrinking critical dimension.
A look at ways to simplify the optical and resist model calibration and to speed up the entire process.
Fabricating interconnects is one of the most process-intensive and cost-sensitive parts of manufacturing.
Testing interposer-based versions of stacked die and future versions using through-silicon vias.