LTCC – What is it and Where is it Going?
LTCC – What is it and Where is it Going? A Personal View Dr Peter Barnwell President, IMAPS North America [email protected] Peter Barnwell Circuit Materials Division LTCC – What and Why Peter Barnwell Circuit Materials Division What is it? z z Low Temperature Co-fired Ceramic Manufactured by:• Tape casting unfired ceramic material with binder • Printing conductor & other patterns • Laminating • Firing at around 850 Celsius Peter Barnwell Circuit Materials Division LTCC Process "Green Tape" Collating Blanking Laminating Via Punching Co-Firing Via Fill Post Printing Post Firing Conductor Print Trimming & Electrical Test Final Test © 2000 Midas Vision Systems, Inc. Peter Barnwell Circuit Materials Division LTCC Key Points z Parallel processing:• High yield • Quick turnaround • Volume manufacture z z High layer count readily available Integrated components:• Microwave circuit structures • L, C & R Peter Barnwell Circuit Materials Division LTCC Market Growth to 2000 z z Initially a military market Volume applications developed in 1990’s:• Europe – automotive • US - disk drive module – now finished z 2000 Applications • Wireless packages (power amplifiers, radio, VCO, synthesizers, mixed signal packages) • Bluetooth modules • Components - antennae; baluns; filters • Other microwave modules • Automotive (engine, steering, and transmission control, sensors) Peter Barnwell Circuit Materials Division LTCC Manufacturing Infrastructure - 2002 z z z z z z C-MAC acquires Scrantom Engineering & Thomson VS - April 1999. Major expansion in 2000 Disk drive amplifier market created CTS’s infrastructure – CTS now telecomm & automotive National moves facility to Irvine, CA and expands Kyocera and Coors diversify from HTCC to LTCC. Kyocera acquire Vispro in 2000 Several companies –in both Europe (Selmic, Via, Epcos) and US (Amitron; Barry; CPT) developing LTCC facilities Asia – major developments Peter Barnwell Circuit Materials Division Ceramic Interconnect Initiative - CII Brings together circuit manufacturers with suppliers of materials, equipment, substrates and services to work to advance the ceramic interconnect industry. Peter Barnwell > 40 companies participating Communication Education Roadmaps Homepage Circuit Materials Division Benefits of Ceramic FEATURES Hi Q / Low Loss / Low Tf Precisely Defined Properties Circuit Density / Integral Components Environmental Robustness & Stability Thermal performance High K BENEFITS Performance, Talk Time, Smaller IC’s = COST Ease of Design, Time-to-market = COST Size, functionality, performance = COST Performance, Reliability = COST Size, Reliability = COST Small size microwave = COST AND – Loves Lead Free! Peter Barnwell Circuit Materials Division Vertical Integration in Packaging A Paradigm Shift # of Passives: 200 Assumptions: Comp. Value: 20pF/20nH Comp Size: 3 mm Sq Q Value: 30 - 100 # Layers: 8 Area: 25 X 25 mm Cost Savings: Peter Barnwell > $8.00 Circuit Materials Division Why bury components? Active Components Inductance and Coupling Several in the X - Y space of one Peter Barnwell Circuit Materials Division LTCC - A Key Automotive Technology • • • • working temperature up to 155°C high vibration stress up to 50g direct engine mountability high packaging density (Thick Film -> LTCC) • good thermal conductivity high power dissipation • max. power density • Rth-values 1W/mm² ...4 K/W • buried components • environment friendly • high innovation rate Peter Barnwell Circuit Materials Division COST ($ /in2/layer) Cost Gap Narrows MicroVia HDI PWB LTCC ML PWB PWB Peter Barnwell Year ‘99 Circuit Materials Division Substrate Test Substrate Test LTCC is: Half the Size 80% the Cost Assembly Passives ICs Assembly ICs Bluetooth Cost Comparison - LTCC Vs. FR4 Passives 100% FR4 80% 60% 40% 20% Source: Ray Brown IEEE/MTTS 2000 0% ICs Peter Barnwell Passives Assembly LTCC Test Organic Substrate Module Circuit Materials Division Bluetooth Module Peter Barnwell Circuit Materials Division Where is the Technology Now? Peter Barnwell Circuit Materials Division LTCC z Benefits:• • • • • • z Parallel processing High yield Quick turnaround Three dimensional Good power handling Excellent microwave performance Drawbacks:• • • • Peter Barnwell Shrinkage on processing Dimensional variation Reduced number of parts per tile Warpage Circuit Materials Division Materials properties z A range of materials offering:• Permittivity from 6 to 9.1 • Loss tangents in the range 10-3 up • Full range of conductor pastes – gold, silver, solderable conductors • Limited buried component capability • Shrinkage in all directions on firing – 12 to 16% • Line definition – 100 micron by printing Peter Barnwell Circuit Materials Division Manufacturing Status z z z z Tile sizes typically in region of 6 to 8 inch square Punching normally sequential mechanical Simple printing techniques Very limited integrated passives Peter Barnwell Circuit Materials Division So – What are the New Technologies? z z Photo conductors Buried passives:• High K tape • Resistors z z Lower permittivity and loss Constrained sintering:– • zero x & y shrinkage • Many advantages Peter Barnwell Circuit Materials Division Critical properties for electrical performance of LTCC z z z z z z z Relative permittivity - εr Loss tangent – tan δ Resonant frequency vs. temperature – Tf Conductor resistance Surface roughness Line resolution and edge precision Control of parameters with process & batch Peter Barnwell Circuit Materials Division Line Losses - Silver Conductor All Lines 0.635 mm Wide, 50 ohms Impedance, Identical Conductor Material Cavity 2.4 GHz Tan δ x 10-3 Line Loss dB/mm @ 2 GHz 99.5% Alumina 0.65 0.003 LTCC 1 3.8 0.004 LTCC 2 2.0 0.0035 LTCC 6 – CT2000 1.7 0.0033 Minimal Difference Between Dielectrics Peter Barnwell Circuit Materials Division So – What Does This Mean? • Conductor dominates loss - requires:• High density & high conductivity • Precise geometries • Smooth surface • LTCC dielectric precision important - requires:• Precise Relative Permittivity - εr • • • • • Peter Barnwell Precise geometries & shrinkage Relatively Low Loss - Tan δ ≈ 10-3 Low Tf < 10 ppm/°C – for resonant structures Simple processing Low cost Circuit Materials Division HeratapeTM CT2000 Key Points z z z z z Low price Thin tape available – 2 mil green Excellent thickness control - +/- 2% Highest performance silver conductors – competitive cost Excellent dielectric properties:• Precisely defined εr = 9.1 +/- 0.1 • Low Tf - ≈ 10 ppm/°C • Low loss - ≈ 10-3 – Q ≈ 1,000 z Smooth surface – 0.25 micron Peter Barnwell Circuit Materials Division Insertion Loss (dB) Temp. Coefficient of Resonant Frequency (Tf) Low Tf Material at 80 C High Tf Material at 80 C At 25 C Low Tf is Critical for Filtering and Freq. Generation Circuits Frequency For CT2000 Tf <10 ppm/C For FR4 Tf = 80 ppm/C Other LTCC 40 to 50 ppm/C Peter Barnwell Circuit Materials Division 50 Micron Patterned Lines on LTCC Direct printed on LTCC Peter Barnwell Heraeus TC2301PI photoimaged on LTCC Circuit Materials Division Constrained Sintering The HeraLock® Option Peter Barnwell Circuit Materials Division HeraLock® Benefits z z z z z z Needs no extra processing Virtually zero x & y shrinkage Very precise dimensional control Fires flat Cavities readily available Allows novel structures Peter Barnwell Circuit Materials Division Precise dimensional control:90.2% shrinkage 9Tight shrinkage variation – 140ppm 918” width available Positional Tolerance vs Panel Size 30 Standard LTCC, Free Sintered ± 0.2% 25 PLAS w/ Sacrificial Constraint Layers ± 0.12% HeraLock® HL2000, Free Sintered ± 0.0042% 20 Positional 15 Tolerance (mil) 10 5 0 0 5 10 15 Format size (in) Peter Barnwell Circuit Materials Division Large format size… 7 in 11 in Outstanding shrinkage control on a large panel size… Peter Barnwell Circuit Materials Division 100% Coverage Ground-planes… z Internal or external zCompared to grid structures: 9Higher conductivity 9Better isolation 2” 9Easier designs 9NO localized camber Peter Barnwell Circuit Materials Division Precision cavity structures… Undistorted Channels Narrow slots Non-shrink IC cavities Peter Barnwell Circuit Materials Division Optoelectronic Application Fibre buried in HeraLock® Peter Barnwell Circuit Materials Division Cost Model: Move from 8” to 12” panel in HeraLock® RF (Power Amp) z Labor Overhead/Depr. Materials 8” panel 100% 100% 100% Gross Margin* x% 12” panel 30% 30% 85% 3x% Automotive Labor Overhead/Depr. Materials 8” panel 100% 100% 100% Gross Margin* x% 12” panel 30% 35% 81% 4x% * assumes constant unpopulated part selling price HeraLock can allow lower module pricing, therefore increasing competitiveness Peter Barnwell Circuit Materials Division Where is it Going? A Difficult Question! Peter Barnwell Circuit Materials Division Major Restructuring – LTCC was making its breakthrough just as recession hit z z z National & C-MAC facilities for sale – caused by parent companies concentrating on core business Massive Chinese investment in facilities Many companies holding back on investment Peter Barnwell Circuit Materials Division Market Size? z z z Impossible to answer! Market measured in $ value of finished LTCC substrates Paumonok says $757 million in 2002, going to $833 million in 2003. $1,885 million in 2007. A significant and growing technology Peter Barnwell Circuit Materials Division Major LTCC Opportunities • Microwave:• Modules • Components • Automotive • Power Other LTCC Opportunities • • • • MEM’s Fuel cells Sensors Etc……. Not just a circuit technology! Peter Barnwell Circuit Materials Division Conclusions LTCC to be of great significance and potentially the dominant ceramic circuit technology z US manufacturers face questions:• • • • z z z z z Can they handle high volume market? Need higher margin (lower volume?) products Need to be design intensive. Go offshore for volume production? Similar trends in Europe – DT Microcircuits Japanese very significant – Murata, Kyocera, TDK Continued growth in many countries in Asia – China in particular Design in to be the key factor for large scale uptake LTCC to be dominated by component manufacturers? Peter Barnwell Circuit Materials Division
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