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Wafer-Level Packaging and Wafer-Scale Assembly
Wafer-Level Packaging and Wafer-Scale Assembly Technologies May 17, 2010 CS MANTECH Workshop 6 Portland OR Patty Chang-Chien Northrop Grumman Aerospace Systems Acknowledgement • Multi-center effort at NGAS: Microelectronics, RF Product Center, Manufacturing, Product Engineering, Materials, Antenna Product • Kelly Hennig, Xiang Zeng, David Eaves, Phil Hon, Peter Chou, Gerry Mei, Roger Tsai, David Farkas, John Chen, Keang Kho, Mike Battung, Yun Chung, Pei-Lan Hsu, Jeff Yang, Wendy Lee, Matt Nishimoto, Tony Long, Greg Rowan, Sean Shih, Dah-Weih Duan, Jose Padilla, Pin-Pin Huang, Minhdao Truong, Richard To, K.K. Loi, Hui Ma, Jeremy Ou-Yang, Craig Geiger, Gershon Akerling, Chi Cheung, Sujane Wang, Jane Lee, Danny Li, Peter Nam, Peter Ngo, Martin IIyama, Ging Wang, Tom Chung, Gary Gurling, Randy Duprey, Cesar Romo, Ben Heying, Randy Sandhu, Ben Poust, Matt Parlee, Denise Leung, David Eng, Eric Kaneshiro, Rich Kono, Jansen Uyeda, Mike Barsky, Jennifer Gan, Ke Luo, Fred Dai, Edna Yamada, Mike Wojtowicz, Rich Lai, Augusto Gutierrez, Aaron Oki and many more! 2 Agenda • Overview – Technology description – Benefits • 2-Layer WLP/WSA – Process description – Examples • Interconnects & Transitions • Package Performance • Multi-Layer WLP/WSA – Process description – Examples • Higher Order Integration 3 What is Wafer-Level-Packaging? Wafer-Level Packaging (WLP) AKA: Micro Packaging AKA: Wafer-Scale Assemlby (WSA) State-of-the-art MMIC Wafer 3-D Wafer Scale Assembled IC • • Add inter-cavity interconnects and cavity ring Stack and bond multiple wafers, then dice • • Forms a hermetically packaged 3-D integrated circuit Enables integration of different MMIC technologies WLP provides low cost, high volume, hermetic packaging 4 Advanced Capabilities for Next-Generation Systems • Next-generation system needs performance superiority & affordability • WLP performance superiority – Advanced integration • best semiconductor technology for the function – Ultra-compact, light weight packaging • size & weight savings – High functional density & low loss interconnects • Superior circuit performance – Hermetic MMIC packaging • Enhanced circuit reliability • WLP Military Systems Affordability – Batch fabrication processes • Low cost, high volume – Fully compatible with NGAS MMIC production processes • Existing & proven MMIC technologies • Next-generation MMIC technologies – Reduce higher order assembly cost, relax module assembly requirement 5 Large Aperture Phased Arrays Satellite Comm. Restricted WLP Benefits • Heterogeneous Integration using WLP Superiority – Hermetic compact MMIC packaging – Performance enabler • High functional density • Superior circuit performance • Affordability Combine multiple MMIC wafers by wafer bonding technology – Batch fabrication processes, low cost, high volume – Reduce higher order assembly cost, relax module assembly requirement Integrated Microwave Assembly (IMA) Wafer-LevelPackage (WLP) Size reduction 1 1,000X Weight reduction 1 1,000X Cost reduction 1 10-100X Tri-layer WLP TR Module X-band operation Mass: <15mg Size: 2.5mm x 2mm x 0.46mm WLP content: 3 bit PS, LNA, PA WLP offers superiority in performance and affordability in cost 6 Integrated Microwave Assembly Packaging GaAs InP IMA 7 GaN CMOS Wafer-Level Integration Benefits • Hermetic • Ultra-light weight, ultra-compact • Low cost, high volume • Performance enhancement IMAs Weight: g to >1000g Size: cm x cm x cm Assembly: serial, manual Package near a thumb tack Wafer-Level Integrated Package Weight: < 50 mg Size: mm x mm x mm Assembly: mass parallel, wafer scale 8 Integration Using Wafer-Level Packaging • WLP is assembled using a low temperature wafer bonding process • WLP technology is fully compatible with NGAS MMIC production processes a. Diagram and photograph of WLP LNA Bonding Ring (wafer 1) Through Via Low-Noise Circuit with Wafer Bonding Ring Amplifier Wafer Bonding Circuit (low-noise amplifier) Bonding Ring (wafer 2) Bonding Ring Low temperature wafer bonding process is 20 key to MMIC compatible, robust WLP b. Measured data from WLP LNA circuits 10 ) 9 2-LAYER WLP 10 2-Layer WLP • Wafers are individually processed prior to bonding – No changes to standard MMIC processes • ICIC = Intra-Cavity InterConnections 2-layer Bonding Process Flow ICIC • BICIC = Backside ICIC Wafer 2 Wafer 1 2-layer Bonding Process Flow BICIC Flip & align ICIC (Front side) BICIC (backside) Bonding Layer Wafer Bonding 2-Layer WLP is constructed by bonding 2 individually processed wafers 11 Bonded pair WLP Demonstrations • WLP is fully compatible with NGAS’s MMIC production processes Frequency bands w/ • X-band • Ku-band • V-band Different circuit types • LNAs • Oscillators • Shift registers WLP Ka-band Q-band W-band w/ WLP PAs Phase shifters Switches Substrate combinations w/ WLP • GaAs + GaAs • InP + GaAs • InP + InP • Quartz + Quartz • Si + InP • Glass + Glass • GaAs + Duroid • GaAs + InP + GaAs • GaAs + InP + InP • SiC + SiC • Multiple GaAs integrations • Multiple InP integrations Different compound-semiconductor technologies w/ WLP InP HEMTs InP HBTs ABCS HEMT GaAs HEMTs MEMS switches GaAs HBTs Passives GaAs Schottky diodes GaN HEMTs InP diodes NGAS has extensive experience in heterogeneous integration using WLP 12 Examples of Packaged MMICs Ku Band LNA, WLP GaAs HEMT circuit Ku Band PA, WLP GaAs HEMT circuit 25 30 20 25 S21 (dB) S21 (dB) 20 15 10 15 10 5 5 0 0 0 5 10 15 20 15 20 25 W-Band PA, WLP GaAs HEMT circuit WLP Q-Band (IRFFE) Q-Band LNA, WLPLNA GaAs HEMT Circuit 16 20 14 10 12 S21 (dB) S21 (dB) 10 Frequency (GHz) Frequency (GHz) 0 LNA -10 -20 10 8 6 4 Bonding Ring -30 2 0 -40 0 10 20 30 Frequency (GHz) 13 5 25 40 50 80 85 90 95 100 Frequency (GHz) 105 110 Wafer Level Packaging (WLP) MMICs Proven across the bands 4-bit PHSH -Chip size: x=3.3mm, y=2.7mm -TTL compatible -avg RMS Amp Error=1.08dB -avg RMS Phase Error=16.5º 2-Stage, self-biased LNA -Chip size: x=3.3mm, y=2.7mm -bias: 4V, 26 mA -Gain > 26.5 dB at 16 GHz 2-Stage PA -Chip size: x=3.3mm, y=2.7mm -bias: 4V, 120 mA -Gain > 19 dB at 16 GHz KU 3-Stage, self-biased LNA -Chip size: x=4.2mm, y=4.2mm -bias: 4V, 45 mA -Gain > 24 dB at 35 GHz 3-Stage, self-biased LNA -Chip size: x=4.2mm, y=4.2mm -bias: 4V, 60 mA -Gain > 11.8 dB from 30-50 GHz KA Miniaturized WLP T/R modules for large arrays 14 Q GaN WLP Technology • Developed world’s first GaN wafer level package process for record power density • Demonstrated >99% GaN WLP interconnect yield Passive Cover Wafer Active GaN Wafer Photo of GaN WLP MMIC GaN WLP chip GaN WLP TEG chip 15 W-Band WSA Oscillator • W-Band oscillator with built-in on chip resonant cavity • 2-layer active MMIC integration: – InP HEMT + GaAs HBT Measured spectrum of Oscillator 1st and 2nd Half of Resonant Cavity Coupling Through Wafer Slot RF Transition Active Device Through Wafer RF Transition (Backside Probe Location) Photo of the integrated oscillator chip Demonstrated 2-Layer WSA Oscillator 16 Comparison of WLP and non-WLP circuits ALH 140 ALH140 vs. ALH140V3 1.4mm ALH140_1 ALH140_2 ALH140_3 ALH140_4 ALH140_5 ALH140_6 ALH140_7 ALH140_8 ALH140_9 ALH140_10 ALH140_11 ALH140_12 ALH140_V3_1 ALH140_V3_2 ALH140_V3_3 ALH140_V3_4 ALH140_V3_5 ALH140_V3_6 ALH140_V3_7 ALH140_V3_8 ALH140_V3_9 ALH140_V3_10 ALH140_V3_11 ALH140_V3_12 18 16 14 12 ALH 140V3 (WLP) S21 (dB) 2.5mm 10 1.9mm 8 : Conventional ALH140 (FIDR1/A-J103 1146A-031) 6 : ALH140V3 with WLP cover (WLP5/1/P200-001) 4 2 0 30 31 32 33 34 35 36 37 38 39 Frequency (GHz) 3.2mm RF performance similar for WLP and non-WLP circuits 17 40 2-LAYER INTEGRATED WLP/WSA EXAMPLES 18 Heterogeneous Integration Example • Integrated RF front end module with antenna – – – – Amplifier (GaAs HEMT) 3 bit phase shifter (GaAs HEMT) Interconnections (ICICs) Antenna WLP bottom side WLP top side (antenna) Integrated RF Front-End Module Sealing Ring (Wafer 2) Wafer 1 antenna Wafer 2 Wafer Bonding Phase shifter 19 ICIC Sealing Ring (Wafer 1) Amplifier Wafer 1 Ground Fence Through wafer via On-Wafer Measured Data •WLP technology - Wafer1=passive, 4-mil GaAs - Wafer2=0.1um, 4-mil GaAs •2-stage balanced Amplifier •3-bit reflective phase shifter Phase Shifter Phase States 20 400 S21 0 Phase (deg) Magnitude (dB) Amplifier S-Parameter S11 -20 S22 -40 200 100 0 10 20 300 20 30 40 Frequency (GHz) 50 1 2 3 4 5 6 Phase States 7 8 WLP Linear Array Demonstration Measured Beam Pattern • Demonstrated fully functional front-end modules with a linear 4-element array -5 =0 -10 E-Field Magnitude (dB) – GaAs HEMT + passive – Amplifier + 3bit PS + antenna in an integrated Q-Band WLP package – Successful integration to BFN board – Demonstrated electronic beam steering 0 -15 -20 -25 -30 =15 -35 Integrated RF front-end modules w/ antenna -40 -60 -40 -20 0 (deg) WLP bottom side Beam Forming Network (board) 21 20 40 WLP top side (antenna) 60 INTERCONNECTS & TRANSITIONS 22 RF ICICs • RF ICIC 50 Ohm Coaxial Transition • Designed to provide minimal mismatch between 50 Ohm microstrip line (wafer 1) and 50 Ohm CPW line (wafer 2) Measured Data from RF ICIC Structure (2 RF ICIC transition + thru line) 0 -0.1 -0.2 S21 (dB) -0.3 Wafer 2 – ICIC Coaxial transition to CPW transmission line -0.4 -0.5 (a) -0.6 Wafer 1 – Microtransmission line to ICIC Coaxial transition -0.7 -0.8 (b) -0.9 -1 0 5 10 Frequency (GHz) 15 Demonstrated Low Loss, RF ICICs 23 20 Low Loss RF Vias • RF via transitions RF Via Test Structure – Low loss up to 50GHz – <0.1dB insertion loss up to 30GHz • DC interconnects – > 99% yield • Calibration structures – To ensure accurate measurement RF calibration and Test Structures Measured Data Simulation Demonstrated Low Loss RF Vias for WLP devices 24 High Frequency RF Interconnects Electro-Magnetic Simulation of Transition • First-of-a-kind W-band WLP RF interconnect — Insertion Loss < 0.2 dB — Return Loss > 20 dB — 20 dB isolation Input ~0.2 mm Output Top Wafer Measured Transition-Line-Transition Response Bottom Wafer Ground Vias connecting top and bottom ground planes Bottom Wafer Back-to-Back Interconnect Cross Section Demonstrated Low Loss, High Isolation W-Band WLP Interconnects 25 Isolation Using Ground Fence Isolation Fence • Isolation fence can be built using 3D interconnects within WSA ICIC • Demonstrated 30dB isolation improvement in W-band using ground fence • 3D WSA offers design flexibility and performance improvement Thru-Wafer Via RF Transition Line Simulated Isolation Fence Response 0 Isolation (dB) Loss (dB) Isolation 0 Isolation Loss (dB) -10 Isolation (dB) 0 Measured Isolation Fence Response 0 -20 Blue: no via fence Red: with via fence -30 -40 No via fence -10 -20 -20 DB(|S(2,1)|) DF_MS22_ISO_0_1a -30 Single via fence DB(|S(2,1)|) DF_MS22_ISO_1_1a -40 -40 -50 -60 -60 -50 -70 -60 -60 91 91 92 93 94 95 Frequency (GHz) Frequency (GHz) 96 97 97 -80 -80 91 91 92 94 95 Frequency (GHz) Frequency (GHz) 93 RF Isolation Design For WSA MMIC 26 96 97 97 PACKAGE PERFORMANCE 27 Package Mechanical and Thermal Integrity • WLP chips Passed the many military standard tests: – Vibration-Sine • MIL-STD 883F, Method 2007.3, condition B – Mechanical Shock (Pyroshock) Mechanical Robustness • MIL-STD 883F, Method 2002.4, condition B – Die Shear • MIL-STD 883F, method 2019.7 – Temperature Cycling • MIL-STD 883F, Method 1010.8, condition B • -55ºC to 125ºC, 50 cycles, MEMS Thermal Robustness • -55ºC to 85ºC, 300+ cycles, W-Band GaAs circuits • -55ºC to 125ºC, 500 cycles, GaAs PA – Hermeticity • MIL-STD 883F, Method 1014.11 Seal Robustness • He fine leak, condition A2, flexible • Radioisotope fine leak, condition B • Penetrate dye gross leak, condition D • Environmental test: 85C 85% humidity 7 days Ku band GaAs MMICs WLP packages are hermetic, thermally and mechanically robust 28 Thermal Robustness • 24 to 40 GHz GaAs HEMT LNA • Thermal cycling, -55 C to 125 C • 500+ cycles Measured s21 response as function of thermal cycles Photo of WLP GaAs LNA 20 15 10 9-R6C6M0 5 0 0 -5 1 -10 -15 -20 -25 11 -10 S11 (dB) S21 (dB) -5 1 11 21 31 21 29 31 41 Post_500 Cycles -15 Post_300 Cycles -20 Post_100 Cycles -25 Post_10 Cycles -30 Pre_Cycle -35 -30 41 -40 Frequency (GHz) Frequency (GHz) MULTI-LAYER WLP/WSA 30 Advanced Integration: Multiple Layer WLP 4-layer Bonding Process Flow • Example: 4-layer construction Bonded Pair 1 – Use bonded pair as starting units Multiple Layer WSA Flow Bonded Pair 1 Bonded Pair 2 or single wafer Process Bonding layer if necessary (backside) ICIC (Front side) BICIC (backside) Bonding Layer Wafer Bonding 4-Layer Construction is Achieved By Bonding 2 bonded WLP pairs 31 Bonded Pair 2 X-Band Tri-Layer Tx/Rx Modules WLP Tx/Rx Module Average mass: 12.9mg Size: 2.5mm x 2mm x 0.46mm ABCS HEMT LNA Low Noise Amplifier ABCS HEMT 32 InP HBT PA & digital control Power Amplifier Shift Register GaAs HEMT h Phase Shifter Sw itc h InP HBT Sw itc •Next-Generation Large Aperture Array T/R Module –Ultra light weight (<15 mg) –Extremely compact (<5 mm2 ) •Transceiver Module Performance –FOM > 10,000 –Reliability: MTTF >106 Hours GaAs HEMT PS & Switches Demonstrated X-Band Integrated T/R Module Tri-Layer T/R Demo • Tri-layer T/R module demonstration – GaAs HEMT + InP HBT + InP HEMT – Demonstrated excellent yield and T/R circuit performance Measured NF (Rx) of the tri-layer WLP T/R module 33 CMOS + III-V Integration Demo WLP 8-bit VAP 5-mil solder ball 8-bit shift register 8-bit CMOS Shift Register WLP 8-bit VAP Measured Phase ShifterMeasured Data Ideal Input Digital CTRL Waveform CLK ENB Data Measured Angle (Deg) 225 180 135 Measured Angle (Deg) 225 Ideal Measured 180 135 90 45 0 90 0 45 90 135 180 Set Angle (Deg) 45 Demonstrated heterogeneously integrated CMOS flip-chip to WLP MMICs 34 0 HIGHER ORDER ASSEMBLY 35 WLP Higher Order Integration Demonstrations Fixture Alumina Organic Board Assembly • Technologies integrated Benefit • CMOS to III/V Integration SWaP reduction • Direct WLP to Board Attach SWaP, cost reduction • 16-element Ku-band Rx Array Near term insertion Techniques demonstrated • 8-element Ku-band Rx SubArray Design to manufacturing • 4-element Q-band Tx Array mmW array implementation – – – – • Demonstrations – – GaAs-GaAs GaAs-InP InP-InP ABCS-InP-GaAs Epoxy to Fixture/Board Bump to Board • Manual • Auto assembly Demonstrated WLP-to-Board Integration 36 Microbump: Chip-Board Integration • Developed microbump technologies for WLP– to-board attachment and integration Cu stud microbump Microbumps on backside of the package Sn/Pb microbump array Microbumps enable direct WLP-to-Board Integration 37 Direct Board Attach Using Microbumps chip board Cu studs X-ray result showing good board to chip interface Excellent Chip-to-Board Microbump Interface 38 Example of Epoxy Attach and Ribbon Bonds Implementation Ku Band subarray board with WLP chips Integrated Subarray Antenna Board 5 WLP MMIC fixture for environmental testing Normalized Amplitude Measured Far Field Pattern -45.0 -25.0 0.0 25.0 Azimuth ( ) WLPs are compatible with epoxy attachment 39 45.0 WLP on Interposer Boards on PWB Front Side: WLP on Interposer Back Side (Solder Ball) WLP on Interposer WLP Interposer board attachment to PWB 40 Higher Order Integration Using WLP/WSA • Demonstrated thermal cycling robustness of WLP-board assembly with underfill • Successfully demonstrated dual side WLP chip-to-board attachment • >200 cycles • from -40C to 100C • Pass without failure WLP chips Dual-Sided Assembly 5mil Solder Balls Dual sided board WLP chips 2-layer WLP chip WLP cavity 5mil solder balls underfill PWB Chips on the front side of PWB after backside assembly 41 Chips on the backside of PWB Summary • WLP technology offers performance superiority and affordability for next-generation systems • WLP offers significant size, weight and cost savings for future systems • Demonstrated multiple advanced technology integration with WLP • Verified robustness of WLP packaging by MIL-STD tests • Demonstrated WLP integrated MMICs & modules across the bands • NGAS is committed to mature and improve wafer-scale integration technology for system insertion 42 43
