Semi Networking Day Packaging Key for System Integration

Semi Networking Day Packaging Key for System Integration Le Quartz, 75 Cours Emile Zola 69100 Villeurbanne, France Tel : +33 472 83 01 80 - Fax : +33 472 83 01 83 Web: http://www.yole.fr

Semi Networking Day Christophe Fitamant Sales & Marketing Director, Yole Développement Christophe Fitamant joined Yole Développement in 2013 to lead Média and Sales activities. He holds an engineering degree of INP Grenoble - Phelma - with a major in Chemical Process Engineering. He has worked at IBM Corbeil-Essonnes, and Applied Materials. He s lived in California when he managed the Applied etch product support group for Taiwan and Japan. Back to France for Lam Research he first took the responsibility of the ST Crolles site, before taking the Sales Account Management for Europe. With the acquisition of SEZ in Austria by Lam in 2008, he led Sales and Marketing for Lam penetration in MEMS and Advanced Packaging for Clean. 2013 2 2013 Copyrights Yole Développement SA. All right reserved.

Fields of Expertise Yole Developpement is a market, technology and strategy consulting company, founded in 1998. We operate in the following areas: Photovoltaic Power Electronics Microfluidic & Med Tech Advanced Packaging Our expertise is based on research done by our in-house analysts, conducting open-ended interviews with most industry players. 30+ full time analysts with technical and marketing degrees Primary research including over 3,500 interviews per year 2013 3 HB LED, LED & LD Equipment and materials MEMS & image sensors

Yole Activities in a Nutshell MEDIA News feed / Magazines / Webcasts REPORTS Market & technology Patent Analysis Reverse costing report CONSULTING Market research Technology & Strategy Patent Analysis www.yole.fr YOLE FINANCE M&A / Due Diligence / Fund raising services 2013 4 2013 Copyrights Yole Développement SA. All right reserved.

Semi Networking Day Rozalia Beica Chief Technical Officer, Yole Développement Rozalia Beica is the CTO and Business Unit Manager leading Advanced / 3D Packaging and Semiconductor Manufacturing activities within Yole Développement. For more than 15 years she has been involved in research, strategic marketing and application of WLP and 3D/TSV at materials (Rohm and Haas), equipment (Semitool, Applied Materials, Lam Research) and device manufacturing (Maxim IC) organizations. Rozalia has authored over 50 papers and publications and she is actively participating in several 3D & Advanced Packaging Committees worldwide. Rozalia holds a M.Sc. in Chemical Engineering (Romania), a M. Sc. In Management of Technology (USA) and a GXMBA from IE University (Spain). 2013 5 2013 Copyrights Yole Développement SA. All right reserved.

Business Trends in Advanced Packaging Nokia Rozalia Beica SEMI Networking Day: Packaging - Key for System Integration Porto June 27, 2013 Courtesy of Fraunhofer-IZM 2013

Presentation Outline Advanced Packaging Platforms Emerging Packaging Technologies FOWLP Market Forecasts Cost Considerations IP Activities Conclusions FCI NXP 2013 7

Introduction The evolution of semiconductor packaging technologies over the past 40 years has been driven by the need to bridge the increasing I/O interconnect gap, between the fast decreasing silicon geometries (Moore s law) and the slower shrink of the Printed Circuit Board technologies Wafer-level-packaging market is gaining more and more significance in the semiconductor industry; it shows the greatest potential for significant future growth in the semiconductor industry. Historically supported by the market growth in flip-chip wafer bumping with electroplated gold, solder bumps and today copper pillars; wafer-level-packages are actually coming in many different, namely Fan-in WLCSP packages, 3D WLP, FO WLP packages, 2.5D Glass / Silicon interposers and of course 3DIC integration with TSV interconnects. 2013 8

Wafer shipments (in Munits of 300mm wafers eq.) % penetration Ratio Wafer-Level-Packaging In the semiconductor IC wafer processing industry % Ratio of WW Semiconductor IC Wafers Packaged at the Wafer-Scale (Volume in millions of 300mm wafers eq.) 160 140 120 100 Yole Développement October 2012 50% 45% 40% 35% 30% 80 60 40 20 0 2011 2012 2013 2014 2015 2016 2017 TOT Semiconductor IC wafers 84 92 101 111 122 135 148 TOT Wafer-Scale-Packaged IC wafers 13 14 17 21 25 31 35 % ratio 15% 16% 17% 19% 20% 23% 23% 25% 20% 15% 10% 5% 0% CAGR 10% 21% In 2012, ~ 16% of overall semiconductor IC wafers were manufactured with packaging features (bumping, RDL, TSV, etc ) processed at the wafer-scale 2013 9

Advanced Packaging Platforms Wafer-level-packages have emerged in many different varieties that can be categorized into different advanced packaging technology platforms Wafer-Level Interface / Encapsulation PANEL / WLP Platforms Wafer-Level Electrical Redistribution Flip-chip & Wafer-Level Stacking / Integration 3D WLP WL CSP Glass / Silicon FOWLP Embedded die 3D IC WLOptics 2.5D For MEMS & sensors Fan-in Fan-out in PCB / laminate & TSV (also called 3D SiP sometimes) interposers LED & Sensors Flip-chip wafer bumping on BGA Historically supported by flip-chip wafer bumping with electroplated gold & solder bumps, today there are an array of solutions, such as: copper pillars, Fan-in WLCSP packages, 3D WLP, FO-WLP packages, 2.5D Glass / Silicon interposers and 3DIC with TSV interconnects 2013 10

WLP Middle-End Technologies Wafer level packages are true Middle-end technologies, leverage similar type of process manufacturing know-how Middle end technologies are found in the overlap area between the IDMs or CMOS foundries backend of line (BEOL) wafer fabs and the the back-end wafer bumping assembly facilities of the OSATs and wafer bumping houses Middle-end vs Front-End vs Back-End FE wafer manufacturing PVD CMP implant etch inspection cleaning CVD Wafer test TSV RDL / wiring Middle-end Courtesy of Stats ChipPAC BE assembly & test dicing handling thinning BGA C2C / C2S bumping inspection W2W C2W underfill molding Final test Middle-end is a strategic area where Foundries, OSATs, WLP Houses and IDMs stepped in, an infrastructure that has emerged by itself in the last 5 years. Middle-end infrastructure is growing and is the leading driver and the fastest growing semiconductor packaging technology with more than 18% CAGR in units over the next 6 years 2013 11

Technological Differences Packaging applications, as a function of pitch size requirements are divided in flip chip and wafer level packaging. FLIP CHIP Chip on Board COF/COG WAFER BUMPING Silicon on silicon microbumping WAFER LEVEL PACKAGING FC BGA FC CSP FAN IN FAN OUT CHIP EMBEDDIN G Bump characteristics Bump characteristics Bump characteristics Bump characteristics Bump characteristics Plating, screen printing pitch: <180µm Plating, screen printing, stud pitch: < 150µm Plating pitch: <150µm Plating pitch: < 60µm Ball dropping pitch: 400-500µm Courtesy of Statschippac Courtesy of 3M Courtesy of SPIL Courtesy of NXP and FCI While flip chip is more economically feasible to smaller size pitches (< 200um), larger pitch size requirements are addressed using embedded technologies 2013 12

Volume (in Munits of 300mm wafer eq.) Middle-end Infrastructure is Growing «Mid-End» infrastructure the leading driver and the fastest growing semiconductor packaging technology with more than 18% CAGR in units over the next 6 years 40,0 35,0 Global Wafer-Level-Packaging Demand (in Munits of 300mm wafer eq. ) Yole Développement October 2012 3DIC 3D SiP 30,0 25,0 20,0 15,0 10,0 FO WLP 3D WLP WL CSP 2.5D interposers 5,0 0,0 2011 2012 2013 2014 2015 2016 2017 Flip-chip Significant growth of 3D Packages: 3D IC, Embedded (3D SIP and FOWLP) and Interposers 2013 13

Sales forecasts (M$) $4 000 M $3 500 M Equipment Market Needs for WLP Global Equipment Market Forecast for 3DIC & Wafer-Level-Packaging (in M$) Yole Développement October 2012 3DIC TSV stacks $3 000 M FO WLP / SiP $2 500 M $2 000 M $1 500 M $1 000 M $500 M 3D WLP Fan-in WL CSP 2.5D interposers Flip-chip wafer bumping $0 M 2011 2012 2013 2014 2015 2016 2017 TOT $867 M $642 M $863 M $1,204M $1,721M $2,578M $3,782M 28% In 2012, the equipment market is lower compared to the market in 2011 due to the high investment made in 2011 for 3D IC & WLP applications. 2013 14

Sales forecasts (M$) Materials Market Needs for WLP $2 500 M $2 000 M Global Materials Market Forecast Breakdown for 3DIC & Wafer-Level-Packaging (in M$) Global Materials market forecast breakdown for 3DIC & Wafer-Level-Packaging (in M$) Yole Développement October 2012 3DIC TSV stacks FO WLP / SiP $1 500 M 3D WLP $1 000 M $500 M $0 M 2011 2012 2013 2014 2015 2016 2017 2011 2012 2013 2014 2015 2016 2017 Fan-in WL CSP 2.5D interposers CAGR Flip-chip wafer bumping The material market will grow from ~$590M this year to over $2B by 2017 with a CAGR of 23%, driven mainly by the expansion of 2.5D interposers and 3D TSV& WLP platforms. 2013 15

Embedded Wafer Level Packaging FOWLP (based on electrical redistribution) PANEL / WLP Platforms Wafer-Level Interface / Encapsulation Wafer-Level Electrical Redistribution Embedded Technologies Flip-chip & Wafer-Level Stacking / Integration 3D WLP WL CSP Glass / Silicon FOWLP Embedded die 3D IC WLOptics 2.5D For MEMS & sensors Fan-in Fan-out in PCB / laminate & TSV (also called 3D SiP sometimes) interposers LED & Sensors Flip-chip wafer bumping on BGA Embedded die in PCB/laminate (based on stacking/integration approach) 2013 16

Market Trends The move to embedded wafer-level-packages Embedded wafer-level-packaging technologies are not new Several players, such as Freescale with RCP, Infineon with ewlb, and Ibiden for die embedding into PCB laminated substrates have developed dedicated technologies and have processed IP in this area for years. Benefits of embedded package integration include: Miniaturization, electrical and thermal performance improvement, cost reduction and simplification of logistic for OEMs 1 st -generation ewlb cross-section (Courtesy of Infineon) Embedded die ibga package (Courtesy of Imbera/Daeduck) Multi-chip SiP Module based on Chip Embedding technology (Courtesy of AT&S) Integrated passive IC ready for embedding into PCB laminate (Courtesy of NXP/FCI) 2013 17

Concepts for FOWLP/Embedded Die in Package Two types of Embedded Wafer-level-packages are emerging FOWLP is based on a reconfigured molded wafer infrastructure Embedded die in package is based on a PCB type of panel infrastructure NANIUM AT&S Courtesy of AT&S Embedded die Single chip FO MCP FO PoP Embedded MCP Embedded PoP FOWLP 1 st generation FO SiP Embedded SiP 2013 18

Fan-out WLP NANIUM 2013

FOWLP Cost Motivation to Continue Die Shrinkage! Fan-in WLCSP Wireless SOC 90nm Next CMOS generation Fan-Out WLP PCB 0.5mm pitch Wireless SOC 45nm FC-CSP, WB/FC-BGA PCB 0.5mm pitch Wireless SOC 65nm Next CMOS generation PCB 0.4mm pitch Smaller die size Lower front-end cost thanks to more advanced lithography No more interposer substrate/micro-bumps/wb RDL on Fan-Out area provided are sufficient! Higher functionality when moving to Combo(s) Same or even higher pin-counts are possible PCB mother-board need to remain cheap Pitch evolution is typically limited to 0.5-0.4mm Filling the I/O gap between IC and PCB evolution Some restrictions are appearing at the package level, since global chip trends tend toward smaller chip areas with an increasing number of interconnects: so the shrinkage of the pitches and pads at the chip/package interface is happening much faster than the shrinkage at the package/board. As a result: FC-CSP, WB/FC-BGA package cost is increasing fast with I/O density (mainly due to interposer substrate cost) Fan-in WLCSP are substrate-less but face inherent limitations due to available die area for re-routing Fan-out WLP has the potential to realize any number of interconnects with standard pitches at any shrink stage of the wafer node technology 2013 20

FOWLP Thickness Motivation WB-BGA 0.8mm PMU chip Fan-Out WLP PMU chip 0.55mm PCB 0.5mm pitch PCB 0.5mm pitch I/O pads are all located at the center of the die Front-end IC design constraint! Issues are: package height (necessary for Wire- Bonds) and thermal dissipation (flip-chip packages would be better) No Wire-Bond Lower package height Better heat dissipation FC configuration No more interposer substrate/micro-bumps/wb RDL on Fan-Out area provided are sufficient! Meeting with new form factor and package performance Some specific Power Management Units (PMU) have > 120 I/Os pads, all located at the center of the PMU chip due to specific IC design reasons. Using Wire Bonds takes a lot of height to connect the chip to the UFBGA substrate Move to FC-BGA/FOWLP First simulations show that electrical performance and heat dissipation are expected to be better than WB-BGA/FC-BGA configurations (please see next slides) 2013 21

Expected Fan-Out WLP Technology Benefits Fan-out Wafer Level Packages like ewlb offer the following differentiated advantages Over flip-chip BGA: Slightly smaller footprint (clearance distances to the edges are smaller) Thinner package Substrate-less package (shorter interconnections meaning higher electrical performance and cheaper in the long run) Future potential for SiP and 3D integration Lower thermal resistance Simplified supply chain infrastructure Over fan-in WLCSP: Higher board-level reliability Fan-out area to counter the pad limitation issue, adaptable to customer needs Only confirmed good dice are packaged Potential for SiP integration Lower thermal resistance Built-in back-side protection No restriction in bump pitch Fan-Out WLP IC FC BGA IC Fan-in WLCSP IC 2013 22

First ewlb Package in High-Volume Production! First design win for ewlb In early 2009, Infineon (GE) was the first company to commercialize its own ewlb packaging technology in an LGE cell-phone ASE and STATSChipPAC are qualified as subcontractors for ewlb manufacturing Infineon s chip is a wireless baseband SOC with multiple integrated functions (GPS, FM radio, BT) The same ewlb product is in production in some Nokia handsets since 2010 The first ewlb package with Infineon s wireless Baseband SOC was found in an LG cellphone (Reverse Engineering pictures courtesy of SystemPlus Consulting and Binghamton University ) 2013 23

BGA vs. FOWLP Cost Structure* * For a reference scenario of 64 I/Os, 0.4mm pitch, same IC application Depreciation of equipments 25% WB BGA package WB BGA Package - Cost structure scenario in 2010 - Test 25% Test 15% FO WLP package FOWLP Package - Cost structure scenario in 2010 - Assembly Process + Materials (wire bonds, die attach, molding ) 20% Substrate 30% Depreciation of equipments 30% Materials Direct / Indirect (mold compound, passivation resists, chemistries and cleaners) 55% BGA packaging technology has today reached a maturation point where it is difficult to scale the cost down further. On the other hand, FOWLP platform has a new value proposal because: Substrate, Wire bonds, underfill and µ-bumps are removed Reduced cost and no more substrate inventories! The BOM Bill Of Materials is likely to aggressively scale down in cost with time, thanks to Standardization of new material selection (mold compound, passivation resists, chemistries & cleaners, etc.) Amortization of the infrastructures (linked to new equipment introduced) Combinations and synergy between Wafer Test/Final Test procedures 2013 24

Price per pin (c$) FOWLP Cost Model (2012 Data Update) 0.8 0.6 FC BGA 0.5 0.4 0.3 0.2 0.1 QFN WL CSP 300mm FOWLP double RDL 300mm FOWLP single RDL WB-BGA 0 10 35 100 350 750 Pin count # FOWLP is now a lower-cost package platform than any competing flip-chip solution The FOWLP cost position (0.002-0.003 $/IO) is a clear advantage compared to flip-chip packages today However, the application window is still quite narrow (between 35 700 IOs only) and there s strong restriction in terms of chip to package IC co-design environment only a few companies are mature enough to design their chip/package for FOWLP at this early stage 2013 25

FOWLP Cost Analysis Conclusion There is no barrier to entry for FOWLP from the end-user perspective, as it is estimated that FOWLP manufacturing cost will be reduced by 2-2.5x in a five-year time frame between 2010-2015, thanks to several different factors: FOWLP Cost/die* $0.5 $0.30 200mm FOWLP Yield, test and productivity of FOWLP lines will rapidly increase with time Production volume will increase dramatically with time Depreciation of the infrastructure with time New infrastructure will emerge for PANEL 300mm FOWLP * for a reference scenario FOWLP manufacturing using Gen2 LCD display old fabs $0.20 $0.10 2.5x Cost reduction! PANEL FOWLP 470mmx370mm 2008 2010 2012 2014 2016 2013 26

FO-WLP Revenues (M $) FOWLP Activity Market Evolution & Forecast FOWLP activity revenues (M$) Overall evolution since ewlb technology introduction $700M $600M Yole Developpement October 2012 Ramp-up with fab-less wireless IC players and wide FOWLP infrastructure/supply-chain $500M $400M $300M $200M Intel Mobile/ IFX ewlb driven Transition phase CAGR ~ 0% $100M $0M 2008 2009 2010 2011 2012F 2013F 2014F 2015F 2016F 2017F 2018F 2019F 2020F TOT FOWLP (M$) $13M $48M $75M $107M $114M $107M $118M $195M $280M $374M $477M $571M $641M 2013 27

Device count (Munits) FOWLP Unit Forecast Shipment by Industry FOWLP Forecast Shipment (Munits): Breakdown by industry 2 500 Yole Developpement October 2012 2 000 1 500 1 000 500 0 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 3D Stacked DRAM 0 0 0 0 0 1 2 3 4 4 5 3D Stacked NAND Flash 0 0 0 0 0 9 19 33 49 68 84 MEMS / Sensors 0 0 0 0 4 23 40 63 78 105 123 Logic 3D SiP / SoC 243 324 323 281 241 334 469 623 780 944 1 066 RF, Power, Analog & Mixed signal 10 32 57 89 136 300 432 531 686 758 925 Beyond digital wireless SOC applications (APE/BB, BB, ASICs, FPGA, etc.), FOWLP market demand will be driven by very different application fields, such as RF, Analog, MEMS and stacked memory markets 2013 28

No. of Patent Families Overall Trend of Patent Filing in the Domain Preliminary remark: for all of the evolution charts, the data corresponding to the years 2010 and 2011 may not be complete, since a significant number of patent applications filed during those years might not have been published yet. 100 80 Patent filing trends for FOWLP technologies Yole Developpement July 2012 60 40 20 0 1967 1994 1996 1998 2000 2002 2004 2006 2008 2010 Priority Years The FOWLP technological area has picked up significantly only in recent years, coinciding with the need to meet future device packaging requirements 2013 29

Evolution of Top 10 Assignees for FOWLP Patents Evolution of top 10 assignees for FOWLP patents (includes related and relevant) ACE (TW) Yole Developpement July 2012 14 41 INFINEON (GE) SAMSUNG (KR) 15 40 STATS CHIPPAC (SG) 1 19 17 TESSERA (USA) Priority Years 2 34 14 13 2 4 1 16 11 2 2 19 2 13 1 8 3 8 3 Up to 1995 1996-2000 2001-2005 2006-2011 Bubble size represent number of Patent Families ASE (TW) FREESCALE (USA) MICRON (USA) MEGICA (TW) QIMONDA (GE) In recent years (i.e. from 2005), most players have increased their focus on innovation Exceptions: Tessera and Micron, whose filings in the last few years have decreased. 2013 30

Most Patented FOWLP Steps and Most Active Assignees Yole Developpement, July 2012 RDL (multiple) 14 Bump 11 Singulation KGD 1 Contact pad 3 Die placement - Carrier 47 Basic step RDL (single) Most active assignee ACE, Tessera Die placement - Carrier ACE Encapsulation Infineon, Tessera RDL (multiple) Freescale Bump Infineon RDL (single) 58 Bonding 10 Bonding Passivation Contact pad Amkor Infineon, ST, ACE Infineon Passivation 3 Carrier Debonding 1 Encapsulation 29 Singulation, KGD Carrier Debonding Samsung Infineon Most efforts are dedicated to RDL (to improve signal redistribution), die placement (to limit die shift issue) and encapsulation (to reduce CTE mismatch) 2013 31

FOWLP Conclusions FOWLP is a new packaging platform offering new solutions towards integration and miniaturization (10um line/space, reduced package thickness < 0.5mm, etc.) FOWLP technology basically extends the concept of wafer scale packaging to many new applications that are today packaged in BGA and WL CSP packages. Key applications driving initial FOWLP volume demand will be wireless basebands, RF transceivers and power management units. Other applications include stacked memories and analog-specific ICs such as audio codec, MEMS & Sensors, network switches, etc. A new production infrastructure and opportunity to scale packaging cost down by: Increasing wafer diameter (300mm) and moving to PANEL size Decreasing importance of material volume in general (as substrate is removed) Simplifying the manufacturing infrastructure Optimizing supply chain, inventory and cycle times Value chain consolidation Main challenges facing FOWLP are: CTE mismatch on bigger package dimensions > 8x8mm (target are 10x10mm, 12x12mm) Cost and market acceptance Co-design tool implementation Manufacturing yield improvements (70% 80% 95-98%) Testing approach is yet to be defined (the ultimate goal being to realize the Wafer Test and Final Test in the same infrastructure) Development of 2 nd -generation FOWLP with multi-die and double-side RDL to enter in the 3D SiP dimension 2013 32

Thank you! 2013

Yole Activities in a Nutshell MEDIA News feed / Magazines / Webcasts REPORTS Market & technology Patent Analysis Reverse costing report CONSULTING Market research Technology & Strategy Patent Analysis www.yole.fr YOLE FINANCE M&A / Due Diligence / Fund raising services 2013 34 2013 Copyrights Yole Développement SA. All right reserved.