Lattice ispMACH 4000 V/B/C/ZC/ZE Product Family Qualification Summary Lattice Document # 25 -105900 October 2012 © 2012 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are listed at www.latticesemi.com/legal. All other brand or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice. www.latticesemi.com Dear Customer, Welcome to the Lattice Semiconductor Corp. ispMACH® 4000 Product Family Qualification Report. This report reflects our continued commitment to product quality and reliability. The information in this report is drawn from an extensive qualification program of the wafer technology and packaging assembly processes used to manufacture our products. The program adheres to JEDEC and Automotive Industry standards for qualification of the technology and device packaging. This program ensures you only receive product that meets the most demanding requirements for Quality and Reliability. The information contained in this document is extensive, and represents the entire qualification effort for this device family. Our goal is to provide this information to support your decision making process, and to facilitate the selection and use of our products. As always, your feedback is valuable to Lattice. Our goal is to continuously improve our systems, including the generation of this report and the data included. Please feel free to forward your comments and suggestions to your local Lattice representative. We will use that feedback carefully and wisely in our effort to maximize customer satisfaction. Sincerely, Michael J. Gariepy VP Corporate and Customer Quality LATTICE SEMICONDUCTOR CORP. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 2 1.0 INTRODUCTION .................................................................................................................................................. 5 Table 1.1 Lattice ispMACH 4000 V/B/C Product Family Attributes ........................................................................................... 5 Table 1.2 Lattice ispMACH 4000ZC Product Family Attributes ................................................................................................ 6 Table 1.3 Lattice ispMACH 4000ZE Product Family Attributes ................................................................................................. 6 Table 1.4 Lattice Automotive LA-ispMACH 4000V Product Family Attributes .......................................................................... 7 Table 1.5 Lattice Automotive LA-ispMACH 4000ZC Product Family Attributes........................................................................ 8 2.0 LATTICE PRODUCT QUALIFICATION PROGRAM .......................................................................................... 9 Figure 2.1: ispMACH 4000 Product Qualification Process Flow ............................................................................................ 10 Table 2.2: Standard Qualification Testing ................................................................................................................................ 12 3.0 QUALIFICATION DATA FOR EE9 PROCESS TECHNOLOGY ...................................................................... 13 3.1 EE9 PRODUCT FAMILY LIFE DATA ............................................................................................................................................ 14 Table 3.1.1: EE9 Product Family HTOL Results ...................................................................................................................... 14 Table 3.1.2: EE9 Product Family LTOL Results ....................................................................................................................... 16 3.2 ISPMACH 4000 PRODUCT FAMILY HIGH TEMPERATURE DATA RETENTION (HTRX) ............................................................... 17 Table 3.2.1: EE9 High Temperature Data Retention Results .................................................................................................... 17 3.3 ISPMACH 4000 PRODUCT FAMILY ENDURANCE CYCLING DATA .............................................................................................. 18 Table 3.3.1: EE9 Endurance Cycling Results ........................................................................................................................... 18 ........................................................................................................................................................................................................ 18 3.4 ISPMACH 4000 PRODUCT FAMILY – ESD AND LATCH UP DATA (COMMERCIAL/INDUSTRIAL): ............................................... 19 Table 3.4.1 ispMACH 4000 ESD-HBM Data (Commercial/Industrial):................................................................................... 19 Table 3.4.3 ispMACH 4000 ESD-CDM Data (Commercial/Industrial): .................................................................................. 20 Table 3.4.5 ispMACH4000 I/O Latch Up Data (Commercial/Industrial): ................................................................................ 21 Table 3.4.6 ispMACH4000 V-Supply (Over Voltage) Latch Up Data (Commercial/Industrial):.............................................. 22 3.5 LA-ISPMACH 4000V/Z PRODUCT FAMILY – ESD AND LATCH UP DATA (AUTMOTIVE): ......................................................... 23 Table 3.4.2 LA-ispMACH 4000 ESD-HBM Data (Autmotive): ................................................................................................. 23 Table 3.4.4 LA-ispMACH 4000 ESD-CDM Data (Autmotive): ................................................................................................. 23 Table 3.4.7 LA-ispMACH4000 I/O Latch Up Data (Autmotive): .............................................................................................. 24 4.0 PACKAGE QUALIFICATION DATA FOR ISPMACH 4000 FAMILIES ............................................................ 25 Table 4.1 ispMACH 4000 Product-Package Qualification-By-Extension Matrix ..................................................................... 25 Table 4.2 LA-ispMACH 4000 (Automotive) Product-Package Qualification-By-Extension Matrix ......................................... 26 Table 4.3 ispMACH 4000ZE Copper (Cu) Bond Wire Product-Package Qualification-By-Extension Matrix ......................... 26 4.1 ISPMACH 4000 PRODUCT FAMILY SURFACE MOUNT PRECONDITIONING TESTING ................................................................... 27 Table 4.1.1 Surface Mount Precondition Data .......................................................................................................................... 27 4.2 ISPMACH 4000 PRODUCT FAMILY TEMPERATURE CYCLING DATA .......................................................................................... 30 Table 4.2.1: Temperature Cycling Data .................................................................................................................................... 30 4.3 ISPMACH 4000 PRODUCT FAMILY UNBIASED HAST DATA ..................................................................................................... 32 Table 4.3.1: Unbiased HAST Data ............................................................................................................................................ 32 4.4 ISPMACH 4000 PRODUCT FAMILY THB: BIASED HAST DATA ................................................................................................ 34 Table 4.4.1: Biased HAST Data ................................................................................................................................................ 34 4.5 ISPMACH 4000 PRODUCT FAMILY HIGH TEMPERATURE STORAGE LIFE (HTSL)...................................................................... 36 Table 3.2.2: High Temperature Storage Life Results ................................................................................................................ 36 5.0 ISPMACH 4000 PROCESS RELIABILITY WAFER LEVEL REVIEW ............................................................. 37 Table 5.1 – Wafer Level Reliability Results for Seiko EE9 (180nm) Process Technology ........................................................ 37 Table 5.2 – Wafer Level Reliability Results for UMC EE9 (180nm) Process Technology ........................................................ 38 6.0 ISPMACH 4000V/B/C/ZC/ZE SOFT ERROR RATE DATA .............................................................................. 39 7.0 ISPMACH 4000 PACKAGE ASSEMBLY INTEGRITY TESTS......................................................................... 40 7.1 WIRE BOND SHEAR TEST........................................................................................................................................................... 40 7.2 WIRE BOND PULL ...................................................................................................................................................................... 40 7.3 SOLDERABILITY ......................................................................................................................................................................... 40 7.4 PHYSICAL DIMENSIONS ............................................................................................................................................................. 40 7.5 SOLDER BALL SHEAR ................................................................................................................................................................ 40 8.0 ISPMACH 4000 ADDITIONAL FAMILY DATA ................................................................................................. 41 Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 3 Table 8.1: ispMACH 4000 Package Assembly Data – csBGA/ ftBGA ...................................................................................... 41 Table 8.2: ispMACH 4000 Package Assembly Data – Au-Wire TQFP ..................................................................................... 42 Table 8.3: ispMACH 4000 Package Assembly Data – Cu-Wire TQFP..................................................................................... 43 9.0 REVISION HISTORY ......................................................................................................................................... 44 Table 9.1: Lattice ispMACH 4000 V/B/C/ZC/ZE Product Family Qualification Summary revisions ........................... 44 Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 4 1.0 INTRODUCTION The ispMACH 4000 Product Family offers a SuperFAST CPLD solution. The ispMACH 4000 Family includes 3.3, 2.5, 1.8 volt power supply, and 1.8- volt zero power versions, designated ispMACH 4000V, ispMACH 4000B, ispMACH 4000C, ispMACH 4000ZC and ispMACH 4000ZE devices respectively. The ispMACH 4000V/B/C/ZC/ZE Product Family offers densities ranging from 32 to 512 macrocells. The ispMACH 4000V/B/C/ZC/ZE product families are built on Lattice Semiconductor’s 3.3V/2.5V/1.8V EE9 process. EE9 is a shallow trench isolated 0.18um Leff CMOS process with Electrically Erasable cell (E2 cell) modules. This process uses five, planarized metal interconnect layers and single layer polysilicon. The ispMACH 4000V/B/C/ZC product family was initially built at United Microelectronics Company (UMC). The Lattice ispMACH 4256 device was the initial product released to production in May 2001. The additional foundry, Seiko Epson, was released in July 2003. In 2002, Lattice Semiconductor introduced the extended temperature grade, -40 to 130°C junction (TJ), ispMACH 4000V/ ZC products (V = 3.3V, Z = zero power, 1.8 V). This report details the reliability qualification results of the initial ispMACH 4000V/B/C/ZC/ZE product introduction built at Seiko Epson and United Microelectronics Company (UMC). To verify product reliability, Lattice Semiconductor maintains an active Early Life and Inherent Life Reliability Monitor program on the ispMACH 4000 products. Lattice Semiconductor publishes the Reliability Monitor Data quarterly. Table 1.1 Lattice ispMACH 4000 V/B/C Product Family Attributes Macrocells I/O + Dedicated Inputs tPD (ns) tS (ns) tCO (ns) fMAX (MHz) Supply Voltages (V) Fabrication Site Process Technology Die Size (W x L x T) Die Metallization Die Interconnect Dielectric Pins/Package ispMACH 4032V/B/C 32 30+2/32+4 2.5 1.8 2.2 400 3.3/2.5/1.8V ispMACH 4064V/B/C 64 30+2/32+4/64+ 10 2.5 1.8 2.2 400 3.3/2.5/1.8V Seiko Epson / UMC Taiwan Seiko Epson / UMC Taiwan ispMACH 4128V/B/C 128 64+10/92+4/ 96+4 2.7 1.8 2.7 333 3.3/2.5/1.8V Seiko Epson / UMC Taiwan ispMACH 4256V/B/C 256 64+10/96+14/ 128+4/160+4 3.0 2.0 2.7 322 3.3/2.5/1.8V Seiko Epson / UMC Taiwan ispMACH 4384V/B/C 384 128+4/192+4 ispMACH 4512V/B/C 512 128+4/208+4 3.5 2.0 2.7 322 3.3/2.5/1.8V 3.5 2.0 2.7 322 3.3/2.5/1.8V Seiko Epson / UMC Taiwan Seiko Epson / UMC Taiwan EE9 180nm (E2 cell) EE9 180nm (E2 cell) EE9 180nm (E2 cell) EE9 180nm (E2 cell) EE9 180nm (E2 cell) EE9 180nm (E2 cell) 1770 x 1910 x 330-381 (um) Al – 0.5% Cu Plasmaenhanced TEOS 44 TQFP 48 TQFP 2530 x 2330 x 330-381 (um) Al – 0.5% Cu Plasmaenhanced TEOS 3280 x 3150 x 330-381 (um) Al – 0.5% Cu Plasmaenhanced TEOS 3530 x 4180 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS 5300 x 5000 x 330-381 (um) Al – 0.5% Cu Plasmaenhanced TEOS 5400 x 5500 x 330-381 (um) Al – 0.5% Cu Plasmaenhanced TEOS 100 TQFP 128 TQFP 144 TQFP1 100 TQFP 176 TQFP 256 ftBGA/fpBGA3 176 TQFP 256 ftBGA/fpBGA3 44 TQFP 48 TQFP 100 TQFP 144 TQFP1 176 TQFP 256 ftBGA²/fpBGA2, 3 1. 3.3V (4000V) only. 2. 128-I/O and 160-I/O configurations. 3. Use 256 ftBGA package for all new designs. Refer to PCN#14A-07 for 256 fpBGA package discontinuance. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 5 Table 1.2 Lattice ispMACH 4000ZC Product Family Attributes Macrocells I/O + Dedicated Inputs tPD (ns) tS (ns) tCO (ns) fMAX (MHz) Supply Voltages (V) Max, Standby Icc (µA) Fabrication Site Process Technology Die Size (W x L x T) Die Metallization Die Interconnect Dielectric Pins/Package ispMACH 4032ZC 32 32+4/32+4 3.5 2.2 3.0 267 1.8 20 Seiko Epson / UMC Taiwan EE9 180nm (E2 cell) 1770 x 1910 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS 48 TQFP 56 csBGA ispMACH 4064ZC 64 32+4/32+12/ 64+10/64+10 3.7 2.5 3.2 250 1.8 25 Seiko Epson / UMC Taiwan EE9 180nm (E2 cell) 2490 x 1960 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS ispMACH 4064ZC 128 64+10/96+4 4.2 2.7 3.5 220 1.8 35 Seiko Epson / UMC Taiwan EE9 180nm (E2 cell) 2490 x 1960 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS 48 TQFP 56 csBGA 100 TQFP 132 csBGA 100 TQFP 132 csBGA ispMACH 4256ZC 256 64+10/96+6/ 128+4 4.5 2.9 3.8 200 1.8 55 Seiko Epson / UMC Taiwan EE9 180nm (E2 cell) 3530 x 4180 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS 100 TQFP 132 csBGA 176 TQFP Table 1.3 Lattice ispMACH 4000ZE Product Family Attributes tPD (ns) tS (ns) tCO (ns) fMAX (MHz) Supply Voltages (V) Fabrication Site 4.4 2.2 3.0 260 1.8V Seiko Epson / UMC Taiwan ispMACH 4064ZE 64 32+4/48+4/48+4 64+10/64+10 4.7 2.5 3.2 241 1.8V Seiko Epson / UMC Taiwan Process Technology Die Size (W x L x T) Die Metallization Die Interconnect Dielectric Pins/Packages (Lead-Free only) EE9 180nm (E2 cell) 1770 x 1910 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS EE9 180nm (E2 cell) 2490 x 1960 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS 48 TQFP 64 csBGA 48 TQFP 64 csBGA 64 ucBGA 100 TQFP Macrocells I/O + Dedicated Inputs ispMACH 4032ZE 32 32+4/32+4 144 csBGA ispMACH 4128ZE 128 64+10/96+4/96+4/ 96+4 5.8 2.9 3.8 200 1.8V Seiko Epson ispMACH 4256ZE 256 64+10/96+14/ 108+4 5.8 2.9 3.8 200 1.8V Seiko Epson EE9 180nm (E2 cell) 3280 x 3150 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS EE9 180nm (E2 cell) 3530 x 4180 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS 100 TQFP 132 ucBGA 144 TQFP 144 csBGA 100 TQFP 144 TQFP 144 csBGA Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 6 Lattice offers automotive version of ispMACH 4000 family. This high performance LA-ispMACH 4000V automotive family offers a SuperFAST 3.3 volt CPLD solution that is tested and qualified to the AEC-Q100 standard. The LA-ispMACH 4000ZC automotive family combines high speed and low power with the flexibility needed for ease of design. With its robust Global Routing Pool and Output Routing Pool, this family delivers excellent First-Time-Fit, timing predictability, routing, pin-out retention and density migration. The LA-ispMACH 4000V automotive family offers densities ranging from 32 to 128 macrocells. There are multiple density-I/O combinations in Thin Quad Flat Pack (TQFP) packages ranging from 44 to 144 pins. Table 1.4 shows the macrocell, package and I/O options, along with other key parameters. Table 1.4 Lattice Automotive LA-ispMACH 4000V Product Family Attributes Macrocells I/O + Dedicated Inputs tPD (ns) tS (ns) tCO (ns) fMAX (MHz) Supply Voltage (V) Fabrication Site Process Technology Die Size (W x L x T) Die Metallization Die Interconnect Dielectric Pins/Package (Lead-Free Only) LA-ispMACH 4032V 32 30+2/32+4 7.5 4.5 4.5 168 3.3V Seiko Epson EE9 180nm (E2 cell) 1770 x 1910 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS 44 TQFP 48 TQFP LA-ispMACH 4064V 64 30+2/32+4/64+10 7.5 4.5 4.5 168 3.3V Seiko Epson EE9 180nm (E2 cell) 2490 x 1960 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS 44 TQFP 48 TQFP 100 TQFP LA-ispMACH 4128V 128 64+10/92+4/96+4 7.5 4.5 4.5 168 3.3V Seiko Epson EE9 180nm (E2 cell) 3280 x 3150 x 330-381 (um) Al – 0.5% Cu Plasma-enhanced TEOS 100 TQFP 128 TQFP 144 TQFP The LA-ispMACH 4000V automotive family has enhanced system integration capabilities. It supports 3.3V supply voltages and 3.3V, 2.5V and 1.8V interface voltages. Additionally, inputs can be safely driven up to 5.5V when an I/O bank is configured for 3.3V operation, making this family 5V tolerant. The LA-ispMACH 4000V also offers enhanced I/O features such as slew rate control, PCI compatibility, bus-keeper latches, pull-up resistors, pull-down resistors, open drain outputs and hot socketing. The LA-ispMACH 4000V automotive family is in-system programmable through the IEEE Standard 1532 interface. IEEE Standard 1149.1 boundary scan testing capability also allows product testing on automated test equipment. The LA-ispMACH 4000ZC automotive family shares most of the same traits as the LA-ispMACH4000V family. The exception is that the Supply Voltage is 1.8V which categorizes this part as Low-Power. The LAispMACH 4000ZC automotive family offers densities ranging from 32 to 128 macrocells. There are multiple density-I/O combinations in Thin Quad Flat Pack (TQFP) packages ranging from 44 to 144 pins. Table 1.5 shows the macrocell, package and I/O options, along with other key parameters. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 7 Table 1.5 Lattice Automotive LA-ispMACH 4000ZC Product Family Attributes LA-ispMACH 4032ZC 32 LA-ispMACH 4064ZC 64 LA-ispMACH 4128ZC 128 32+4 32+4/64+10 64+10 tPD (ns) 7.5 7.5 7.5 tS (ns) 4.5 4.5 4.5 tCO (ns) 4.5 4.5 4.5 Macrocells I/O + Dedicated Inputs fMAX (MHz) 168 168 168 Supply Voltage (V) 1.8V 1.8V 1.8V Seiko Epson Seiko Epson Seiko Epson Process Technology EE9 180nm (E2 cell) EE9 180nm (E2 cell) EE9 180nm (E2 cell) Die Size (W x L x T) 1770 x 1910 x 330-381 (um) 2490 x 1960 x 330-381 (um) 3280 x 3150 x 330-381 (um) Al – 0.5% Cu Al – 0.5% Cu Al – 0.5% Cu Plasma-enhanced TEOS Plasma-enhanced TEOS 48 TQFP 100 TQFP Plasma-enhanced TEOS Fabrication Site Die Metallization Die Interconnect Dielectric Pins/Package (Lead-Free Only) 48 TQFP 100 TQFP The LA-ispMACH 4000V/ZC automotive family is built on the 0.18 um EE9 Electrically Erasable (E2 cell based) CMOS process at Seiko Epson and assembled at Amkor Technology, Korea and Advance Semiconductor Engineering, Malaysia (ASEM) in Pb-free TQFP packages. This report includes the automotive reliability qualification and device characterization results of the initial Lattice Automotive LA4000V/ZC Product Family introduction. This report summarizes the qualification results for all Lattice ispMACH 4000V/B/C/ZC/ZE and LAispMACH4000V/ZC products as ofJuly 2011. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 8 2.0 LATTICE PRODUCT QUALIFICATION PROGRAM Lattice Semiconductor Corp. maintains a comprehensive reliability qualification program to assure that each product achieves its reliability goals. After initial qualification, the continued high reliability of Lattice products is assured through ongoing monitor programs as described in Reliability Monitor Program Procedure (Doc. #70-101667). All product qualification plans are generated in conformance with Lattice Semiconductor’s Qualification Procedure (Doc. #70-100164) with failure analysis performed in conformance with Lattice Semiconductor’s Failure Analysis Procedure (Doc. #70100166). Both documents are referenced in Lattice Semiconductor’s Quality Assurance Manual, which can be obtained upon request from a Lattice Semiconductor sales office. Figure 2.1 shows the Product Qualification Process Flow. If failures occur during qualification, an 8 Discipline (8D) process is used to find root cause and eliminate the failure mode from the design, materials, or process. The effectiveness of any fix or change is validated through additional testing as required. Final testing results are reported in the qualification reports. Failure rates in this reliability report are expressed in FITS. Due to the very low failure rate of integrated circuits, it is convenient to refer to failures in a population during a period of 109 device hours; one failure in 109 device hours is defined as one FIT. Product families are qualified based upon the requirements outlined in Tables 2.2. In general, Lattice Semiconductor follows the current Joint Electron Device Engineering Council (JEDEC) and Military Standard testing methods. Lattice automotive products are qualified and characterized to the Automotive Electronics Council (AEC) testing requirements and methods. Product family qualification will include products with a wide range of circuit densities, package types, and package lead counts. Major changes to products, processes, or vendors require additional qualification before implementation. The ispMACH 4000V/B/C/ZC/ZE and LA-ispMACH 4000V/ZC product families are built on Lattice Semiconductor’s 1.8V/2.5V/3.3V EE9 process. EE9 is a shallow trench isolated 0.18um Leff CMOS process with Electrically Erasable cell (E2 cell) modules. This process uses five, planarized metal interconnect layers and single layer polysilicon. Lattice Semiconductor maintains a regular reliability monitor program. The current Lattice Reliability Monitor Report can be found at www.latticesemi.com/lit/docs/qa/product_reliability_monitor.pdf . Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 9 Figure 2.1: ispMACH 4000 Product Qualification Process Flow Qualification Plan Request Determine Generic Qualification Type New Foundry Technology Process Change Foundry Transfer New Product Family Add Product to Family Design Change New Package Technology Package Materials Change Assembly Transfer Expand Die or Package Size Automotive or Commercial? Automotive AEC-Q100 Standard Qualification Requirements Commercial / Industrial JESD47 Standard Qualification Check for Customer Specific Requirements Generate FMEA: Risk Management & Lessons Learned Generate Qualification Plan Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 10 Approved Qualification Plan Qualifiable Material Review Commercial Automotive Automotive or Commercial? Commercial Room Temperature Pre-stress testing & data logging Automotive 3-Temperature Pre-stress testing & data logging JEDEC standard based reliability stressing Room Temperature Post-stress testing & data logging 3-Temperature Post-stress testing & data logging Qualification Failures? Failure Analysis Qualification Report Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 11 Table 2.2: Standard Qualification Testing TEST STANDARD TEST CONDITIONS High Temperature Operating Life HTOL Lattice Procedure # 87-101943, MIL-STD-883, Method 1005.8, JESD22-A10 125° C, Maximum operating Vcc, 168, 500, 1000, 2000 hrs. High Temp Data Retention HTRX ispMACH-4000 LA-ispMACH-4000 Lattice Procedure # 87-101925, JESD22-A117 ispMACH-4000 LA-ispMACH-4000 High Temp Storage Lattice Procedure Life # 87-101925, HTSL JESD22-A103 Endurance Program/Erase Cycling Flash based Products ESD HBM ESD CDM Latch Up Resistance LU ispMACH-4000 LA-ispMACH-4000 Lattice Procedure, # 70-104633 JESD22-A117 ispMACH-4000 LA-ispMACH-4000 Lattice Procedure # 70-100844, MIL-STD-883, Method 3015.7 JESD22-A114 Lattice Procedure # 70-100844, JESD22-C101 Lattice Procedure # 70-101570, JESD78 Surface Mount Pre- Lattice Procedure conditioning # 70-103467, SMPC IPC/JEDEC J-STD-020D.1 JESD-A113 Temperature Cycling TC Unbiased HAST UHAST CPLD/FPGA - MSL 3 Lattice Procedure #70-101568, MIL-STD- 883, Method 1010, Condition B JESD22-A104 Lattice Procedure # 70-104285 JESD22-A118 SAMPLE SIZE PERFORMED ON (Typ) 77/lot Design, Foundry 2-3 lots Process, Package Qualification Preconditioned with 100 read/write cycles 150° C, Maximum operating Vcc, 168, 500, 1000, 2000 hrs. 100/lot 2-3 lots Design, Foundry Process, Package Qualification Preconditioned with 100 read/write cycles 150° C, at 168, 500, 1000, 2000 hours. Program/Erase devices to 10,000 cycles E2 Cell Products Flash based Products 77/lot 2-3 lots Design, Foundry Process, Package Qualification 10/lot Design, Foundry 2-3 lots typical Process, Package Qualification Program/Erase devices to 10X cycles of data sheet specification Human Body Model 3 parts/lot Design, Foundry Process (HBM) sweep to 2000 volts 1-3 lots typical – (130nm and older) Charged Device model (CDM) sweep to 1000 volts (130nm and older) ±100 ma on I/O's, Vcc +50% on Power Supplies. (Max operating temp.) 10 Temp cycles, 24 hr 125° C Bake 192hr. 30/60 Soak 3 SMT simulation cycles 3 parts/lot Design, Foundry Process 1-3 lots typical 6 parts/lot Design, Foundry Process 1-3 lots typical All units going Plastic Packages only into Temp Cycling, UHAST, BHAST, 85/85 (1000 cycles) Repeatedly cycled between -55° C and +125° C in an air environment 45 parts/lot 2-3 lots Design, Foundry Process, Package Qualification 96 hrs, 130 C, or 264 hrs 110 C, and 85% Relative Humidity 45 parts/lot 2-3 lots Foundry Process, Package Qualification Plastic Packages only Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 12 TEST STANDARD Moisture Resistance Lattice Procedure Temperature # 70-101571, Humidity Bias JESD22-A101 85/85 THBS or Biased HAST BHAST JESD22-A110 TEST CONDITIONS SAMPLE SIZE PERFORMED ON (Typ) Biased to maximum 45 devices/lot Design, Foundry operating Vcc, 85° C, 85% 2-3 lots Process, Package Relative Humidity, Qualification 1000 hours Plastic Packages only or Biased to maximum operating Vcc, 96 hrs, 130 C, 85% Relative Humidity or Biased to maximum operating Vcc, 264 hrs 110 C, and 85% Relative Humidity Measure all dimensions listed on the case outline. Physical Dimensions Lattice Procedure # 70-100211, MIL-STD- 883 Method 2016 or applicable LSC case outline drawings Wire Bond Strength Lattice Procedure Per package type # 70-100220 Solderability Lattice Procedure # 70-100212, MIL-STD-883, Method 2003 Steam Pre-conditioning 4-8 hours. Solder dip at 245°C+5°C 5 devices Package Qualification 15 devices per Design, Foundry pkg. per year Process, Package Qualification 22 leads/ All packages except 3 devices/ BGAs Package family 3.0 QUALIFICATION DATA FOR EE9 PROCESS TECHNOLOGY The ispMACH 4000V/B/C/ZC/ZE product family is built on Lattice Semiconductor’s EE9 180nm E2CMOS process technology. The ispMACH 4000V/B/C/ZC product family was initially built at United Microelectronics Company (UMC). The Lattice ispMACH 4256 device was the initial product released to production in May 2001. The additional foundry, Seiko Epson, was released in July 2003. The LA-ispMACH 4000V/ZC automotive family was qualified for automotive applications using the Stress Test Qualification for Integrated Circuits, AEC-Q100-Rev-F, test requirements and methods. The LA-ispMACH 4000V/ZC automotive family operates over the Automotive Grade 1 (-400C to +1250C) ambient operation temperature range. All low and high temperature test read-outs were performed at the Grade 1 temperature extremes. Product Family: ispMACH 4000V/B/C/ZC/ZE, LA-ispMACH 4000V/ZC Packages offered: csBGA, ftBGA, fpBGA, ucBGA and TQFP Process Technology Node: 180nm Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 13 3.1 EE9 Product Family Life Data High Temperature Operating Life (HTOL) Test The High Temperature Operating Life test is used to thermally accelerate those wear out and failure mechanisms that would occur as a result of operating the device continuously in a system application. Consistent with JEDEC JESD22-A108 “Temperature, Bias, and Operating Life”, a pattern specifically designed to exercise the maximum amount of circuitry is programmed into the device and this pattern is continuously exercised at specified voltages as described in test conditions for each device type. EE9 Life Test (HTOL) Conditions: Stress Duration: 48, 168, 500, 1000, 2000 hours. Temperature: 125°C Stress Voltage ispMACH 4000V/B/C/ZC/ZE: VCC=1.95V Stress Voltage LA-ispMACH 4000V: VCC=3.6V/ VCCIO=3.6V Stress Voltage LA-ispMACH 4000ZC: VCC=2.0V / VCCIO=3.6V Preconditioned with 1000 read/write cycles Method: Lattice Document # 87-101943 and JESD22-A108C Table 3.1.1: EE9 Product Family HTOL Results 77 168 Hrs Result 0 500 Hrs Result 0 Lot #2 77 0 0 0 Seiko Lot #1 77 0 0 0 77,000 Seiko Lot #2 77 0 0 0 77,000 LC4064ZC Seiko Lot #1 77 0 0 0 77,000 LC4064ZC Seiko Lot #2 77 0 0 0 77,000 0 0 76,000* Product Name Foundry Lot # Qty LC4032ZC Seiko Lot #1 LC4032ZC Seiko LC4032ZE LC4032ZE LC4064ZE Seiko Lot #1 48 Hrs Result 77 1 A B 1000 Hrs 2000 Hrs Result Result 0 0 0 0 Cumulative Hours 154,000 154,000 LC4064ZE Seiko Lot #2 77 0 1 LC4128 Seiko Lot #1 77 0 0 0 0 76,000* 154,000 LC4128 Seiko Lot #2 77 0 0 0 0 154,000 LC4256 Seiko Lot #1 77 0 0 0 0 154,000 LC4256 Seiko Lot #2 64 0 0 0 0 128,000 LC4256 Seiko Lot #3 129 0 0 0 0 258,000 LC4256 Seiko Lot #4 120 0 0 0 0 240,000 LC4256 Seiko Lot #5 120 0 0 0 0 240,000 LC4032 UMC Lot#1 77 0 0 0 0 154,000 LC4032ZC UMC Lot#1 77 0 0 0 0 154,000 LC4064 UMC Lot#1 77 0 0 0 0 154,000 LC4064 UMC Lot#2 77 0 0 0 0 154,000 LC4128 UMC Lot#1 77 0 0 0 0 154,000 LC4256 UMC Lot#1 174 0 0 0 0 0 174,000 C LC4256 UMC Lot#2A 169 1 LC4256 UMC Lot#2B 186 0 0 372,000 Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 14 Product Name Foundry Lot # Qty 48 Hrs Result LC4256 UMC Lot#2C 179 168 Hrs Result 0 LC4256 UMC Lot#3 173 0 LC4256 UMC Lot#4 83 0 0 0 0 166,000 LC4256 UMC Lot#5 90 0 0 0 0 180,000 LC4256 UMC Lot#6 90 0 0 0 LC4384 UMC Lot#1 77 0 0 0 0 154,000 LC4512 UMC Lot#1 77 0 0 0 0 154,000 LC4512 UMC Lot#2 77 0 0 0 0 154,000 LA4064V Seiko Lot#1 77 0 0 0 77,000 LA4064V Seiko Lot#2 77 0 0 0 77,000 LA4064V Seiko Lot#3 78 0 0 0 77,000 LA4064V Seiko Lot#1 80 0 0 0 80,000 LA4064V Seiko Lot#2 80 0 0 0 80,000 LA4064V Seiko Lot#3 79 0 0 0 79,000 LA4064ZC Seiko Lot#4 128 0 0 0 128,000 LA4064ZC Seiko Lot#5 130 0 0 0 130,000 LA4032ZC Seiko Lot#1 793 0 LA4032ZC Seiko Lot#2 799 0 LA4032ZC Seiko Lot#3 802 0 LA4032V Seiko Lot#1 798 0 LA4032V Seiko Lot#2 800 0 LA4032V Seiko Lot#3 798 0 LC4032ZE UMC Lot#1 800 0 LC4032ZE UMC Lot#2 744 0 LC4064ZE UMC Lot#3 730 0 A: 1* unit failed for EOS. FAR#1376 B: 1* unit failed for EOS. FAR#1376 500 Hrs Result 0 1000 Hrs 2000 Hrs Result Result 0 Cumulative Hours 179,000 90,000 FIT Rate Assumptions: Tjstress=125C, Tjref=55C, Activation Energy = 0.5eV * EOS units discounted from cumulative hours. C: 1 unit failed ELFR. Root cause unknown. EE9 Cumulative HTOL Device Hours = 5,613,360 EE9 Cumulative HTOL Sample Size = 1 / 3,426 EE9 FIT Rate = 16 FIT EE9 Seiko Cumulative HTOL Device Hours = 3,053,920 EE9 Seiko HTOL Sample Size = 0 / 2,008 EE9 Seiko FIT Rate = 13 FIT EE9 UMC Cumulative HTOL Device Hours = 2,559,440 EE9 UMC HTOL Sample Size = 1 / 1,418 EE9 UMC FIT Rate = 35 FIT EE9 ELFR (48 or 168 Hrs) Cumulative Results = 1 / 10,833 EE9 UMC ELFR (48 or 168 Hrs) Results = 1 / 4,034 EE9 Seiko ELFR (48 or 168 Hrs) Results = 0 / 6,838 Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 15 Low Temperature Operating Life (LTOL) Test The Low Temperature Operating Life test is used to accelerate gain onto the floating gate due to hot electron effects. A pattern specifically designed to exercise the maximum amount of circuitry is programmed into the device and this pattern is continuously exercised at 1.95V and -55°C. EE9 Life Test (LTOL) Conditions: Stress Duration: 168, 500, 1000 hours. Temperature: -55°C Stress Voltage ispMACH 4000: VCC=1.95V Preconditioned with 1000 read/write cycles Method: Lattice Document # 87-101943 and JESD22-A108C Table 3.1.2: EE9 Product Family LTOL Results Product Name LC4256 Foundry UMC Lot # Qty 168 Hrs Result 500 Hrs Result Lot #2 45 0 0 1000 Hrs Cumulative Result Hours 0 45000 EE9 Cumulative LTOL Failure Rate = 0 / 45 EE9 Cumulative LTOL Device Hours = 45,000 Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 16 3.2 ispMACH 4000 Product Family High Temperature Data Retention (HTRX) High Temperature Data Retention (HTRX) The High Temperature Data Retention test measures the Electrically Erasable cell (E2 cell) reliability while the High Temperature Operating Life test is structured to measure functional operating circuitry failure mechanisms. The High Temperature Data Retention test is specifically designed to accelerate charge gain on to or charge loss off of the floating gates in the device's array. Since the charge on these gates determines the actual pattern and function of the device, this test is a measure of the reliability of the device in retaining programmed information. In High Temperature Data Retention, the E2 cell reliability is determined by monitoring the cell margin after biased static operation at 150°C. All cells in all arrays are life tested in both programmed and erased states. EE9 Data Retention (HTRX) Conditions: Stress Duration: 168, 500, 1000, 2000 hours. Temperature: 150°C Stress Voltage ispMACH 4000: VCC = 1.95V Stress Voltage LA-ispMACH 4064V: VCC = 3.6V Method: Lattice Document # 87-101925 and JESD22-A103C / JESD22-A117A Table 3.2.1: EE9 High Temperature Data Retention Results Product Name Foundry Lot # Qty 168 Hrs Result 500 Hrs Result 1000 Hrs 2000 Hrs Cumulative Result Result Hours LC4128 Seiko Lot #1 40 0 0 0 0 80,000 LC4128 Seiko Lot #2 40 0 0 0 0 80,000 LC4256 Seiko Lot #1 45 0 0 0 0 90,000 LC4256 Seiko Lot #3 110 0 0 0 0 220,000 LC4256 Seiko Lot #4 90 0 0 0 0 180,000 LC4256 Seiko Lot #5 90 0 0 0 0 180,000 LC4256 UMC Lot #1 90 0 0 45,000 LC4256 UMC Lot #2 90 0 0 45,000 LC4256 UMC Lot #3 90 0 0 45,000 LC4256 UMC Lot #4 90 0 0 45,000 LC4256 UMC Lot #5 90 0 0 0 90,000 LC4256 UMC Lot #6 90 0 0 0 90,000 LC4256 UMC Lot #1 90 0 0 0 90,000 LA4064V Seiko Lot #1 79 0 0 0 79,000 LA4064V Seiko Lot #2 79 0 0 0 79,000 LA4064V Seiko Lot #3 80 0 0 0 80,000 EE9 Cumulative HTRX Failure Rate = 0 / 1,283 EE9 Cumulative HTRX Device Hours = 1,518,000 EE9 Seiko HTRX Results = 0 / 653 EE9 UMC HTRX Results = 0 / 630 Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 17 3.3 ispMACH 4000 Product Family Endurance Cycling Data Endurance testing measures the durability of the device through programming and erase cycles. Endurance testing consists of repeatedly programming and erasing all cells in the array at 25°C to simulate programming cycles the user would perform. This test evaluates the integrity of the thin tunnel oxide through which current passes to program the floating gate in each cell of the array. EE9 Endurance Cycling Test Conditions: Stress Duration: 1K, 2K, 3K, 5K, 10K Cycles Temperature: 25°C Stress Voltage ispMACH 4000: VCC = 1.8V Method: Lattice Document # 70-104633 and JESD22-A117A Table 3.3.1: EE9 Endurance Cycling Results 1K CYC 2K CYC Result Result 0 0 3K CYC 5K CYC 10K CYC Cumulative Result Result Result Device Cycles 0 0 0 120,000 Product Name Foundry Lot # Qty LC4256 Seiko Lot #3 12 LC4256 Seiko Lot #4 10 0 0 0 0 0 100,000 LC4256 Seiko Lot #5 10 0 0 0 0 0 100,000 LC4256 UMC Lot #1 29 0 0 0 0 0 290,000 LC4256 UMC Lot #2 23 0 0 0 0 0 230,000 LC4256 UMC Lot #5 10 0 0 0 0 0 100,000 LC4256 UMC Lot #6 10 0 0 0 0 0 100,000 LC4256 UMC Lot #1 10 0 0 0 0 0 100,000 LC4256 UMC Lot #2 10 0 0 0 0 0 100,000 EE9 Cumulative EE Cell Endurance Failure Rate = 0 / 124 EE9 Cumulative EE Cell Endurance Device Cycles = 1,240,000 Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 18 3.4 ispMACH 4000 Product Family – ESD and Latch UP Data (Commercial/Industrial): Electrostatic Discharge-Human Body Model (Commercial/Industrial): ispMACH 4000 product family was tested per the JESD22-A114E Electrostatic Discharge (ESD) Sensitivity Testing Human Body Model (HBM) procedure and Lattice Procedure # 70-100844. All units were tested at 250C prior to reliability stress and after reliability stress. No failures were observed within the passing classification. Table 3.4.1 ispMACH 4000 ESD-HBM Data (Commercial/Industrial): Device LC4032B-TN44 LC4032V-TN44 LC4032ZC-TN44 LC4032ZE-TN48 LC4032ZE-MN64 LC4064B-TN44 LC4064V-TN44 LC4064ZE-TN48 LC4064ZE- MN64 LC4064B-TN100 LC4064V-TN100 LC4064ZC-TN100 LC4064ZE-TN100B LC4064ZE-TCN100C LC4128ZC-TN100 LC4128ZE-TN100B LC4128ZE-TCN100C LC4128C-TN128 LC4128ZE-TN144B LC4128ZE-TCN144C LC4128ZE-MN144 LC4128ZE-TN144D LC4128ZE-MN144D LC4256ZE-TN100 LC4256ZE-TN100B LC4256ZE-MN144 LC4256ZE-TN144B LC4256ZE-TCN144C LC4256B-FN256 LC4256V-FN256 LC4384B-FN256 LC4384V-FN256 LC4512B-FN256 LC4512V-FN256 LC4512B-FT256 LC4512V-FT256 HBM Passing Voltage > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 VA > 2000 VA > 2000 V > 2000 V > 2000 V > 2000 VA > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 1500 V > 1600 V > 1800 V > 1800 V > 1900 V > 1900 V > 1900 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V > 2000 V JEDEC HBM Classification Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 1C Class 1C Class 1C Class 1C Class 1C Class 1C Class 1C Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 Class 2 HBM classification for Commercial/Industrial products, per JESD22-A114 A: LC4064ZE from UMC >2000V for all pins, all lot #s. LC4064ZE from Seiko with Inspection lot # x122xxxx or later meet >2000V for all pins. LC4064ZE from Seiko with Inspection lot # x121xxxx or earlier pass all HBM test conditions of >2000V except for the following combinations, which pass >700V: Positive Vcc to Vss, negative Vss to Vcc, and negative IOs to Vcc. B: LC4064ZE- TN100, LC4128ZE-TN100 and LC4128ZE-TN144 and LC4256ZE-TCN144 from Seiko+UTAC: include 0.8mil diameter Au bond wire. C: LC4064ZE-TCN100, LC4128ZE-TCN100, LC4128ZE-TCN144 and LC4256ZE-TCN144 bill-of-materials include Cu bond wires. D: LC4128ZE-TN144/MN144, data is on UMC silicon. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 19 Electrostatic Discharge-Charged Device Model (Commercial/Industrial): ispMACH4000 product family was tested per the JESD22-C101D, Field-Induced Charged-Device Model Test Method for Electrostatic-Discharge-Withstand Thresholds of Microelectronic Components procedure and Lattice Procedure # 70-100844. All units were tested at 25oC prior to reliability stress and after reliability stress. No failures were observed within the passing classification. Table 3.4.3 ispMACH 4000 ESD-CDM Data (Commercial/Industrial): Device LC4032B-TN44 LC4032V-TN44 LC4032ZC-TN44 LC4032ZE-TN48 LC4032ZE-MN64 LC4064B-TN44 LC4064V-TN44 LC4064ZE-TN48 LC4064ZE-MN64 LC4064V-TN100 LC4064B-TN100 LC4064ZC-TN100 LC4064ZE-TN100B LC4064ZE-TCN100C LC4128ZC-TN100 LC4128ZE-TN100B LC4128ZE-TCN100C LC4128C-TN128 LC4128ZE-TN144B LC4128ZE-TN144D LC4128ZE-TCN144C LC4128ZE-MN144 LC4256ZE-TN100 LC4256ZE-TN100B LC4256ZE-MN144 LC4256ZE-TN144B LC4256ZE-TCN144C LC4256B-FN256 LC4256V-FN256 LC4384B-FN256 LC4384V-FN256 LC4512B-FN256 LC4512V-FN256 LC4512B-FT256 CDM Passing Voltage > 1000V > 1000V > 1000V > 1000V > 1000V > 1000V > 1000V > 1000V > 1000V > 1000V > 1000V > 1000V > 900V > 900V > 1000V > 900V > 1000V > 750V > 700V > 900V > 800V > 1000V > 900V > 1000V > 700V > 800V > 750V > 750V > 750V > 750V > 600V > 600V > 650V > 650V JEDEC CDM Classification Class IV Class IV Class IV Class IV Class IV Class IV Class IV Class IV Class IV Class IV Class IV Class IV Class III Class III Class IV Class III Class IV Class III Class III Class III Class III Class IV Class III Class IV Class III Class III Class III Class III Class III Class III Class III Class III Class III Class III CDM classification for Commercial/Industrial products, per JESD22-C101 B: LC4064ZE- TN100, LC4128ZE-TN100 and LC4128ZE-TN144 and LC4256ZE-TCN144 from Seiko+UTAC: include 0.8mil diameter Au bond wire. C: LC4064ZE-TCN100, LC4128ZE-TCN100, LC4128ZE-TCN144 and LC4256ZE-TCN144 bill-of-materials include Cu bond wires. D: LC4128ZE-TN144, data is on UMC silicon. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 20 Latch-Up (Commercial/Industrial): ispMACH 4000 product family was tested per the JEDEC EIA/JESD78A IC Latch-up Test procedure and Lattice Procedure # 70-101570. All units were tested at 25oC prior to reliability stress and after reliability stress. No failures were observed within the passing classification. Earlier latch-up testing at Lattice was hardware limited to room temperature testing. Additionally, maximum-rated ambient temperature latch-up testing is generally considered to be approximately 2X worse than the trigger values found at room temperature. In order to guard band our room temperature IO latch-up testing the standard was 4X, or +/- 400mA trigger current. Therefore, the previous Lattice I/O LU standard was >400mA at room temperature, while the present standard is >100mA at maximum-rated ambient temperature. Table 3.4.5 ispMACH4000 I/O Latch Up Data (Commercial/Industrial): Device LC4032B-TN44 LC4032V-TN44 LC4032ZC-TN44 LC4032ZE-TN48 LC4064B-TN44 LC4064V-TN44 LC4064B-TN100 LC4064V-TN100 LC4064ZC-TN100 LC4064ZE-TN100B LC4064ZE-TCN100C LC4128ZE-TN100B LC4128ZE-TCN100C LC4128ZC-TN100 LC4128C-TN128 LC4128ZE-TN144B LC4128ZE-TN144D LC4128ZE-MN144D LC4128ZE-TCN144C LC4256ZE-TN100B LC4256ZE-TN144B LC4256ZE-TCN144C LC4256ZE-TN144 LC4256B-FN256 LC4256V-FN256 LC4384B-FN256 LC4384V-FN256 LC4512B-FN256 LC4512V-FN256 LC4512B-FT256 LC4512V-FT256 I/O Latch-up Results +/- 400mA @ 25°C +/- 400mA @ 25°C +/- 400mA @ 25°C +/- 100mA @ 125°C +/- 400mA @ 25°C +/- 400mA @ 25°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 400mA @ 25°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 400mA @ 25°C +/- 400mA @ 25°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 100mA @ 105°C +/- 100mA @ 125°C +/- 400mA @ 25°C +/- 400mA @ 25°C +/- 400mA @ 25°C +/- 400mA @ 25°C +/- 100mA @ 125°C +/- 100mA @ 125°C +/- 100mA @ 105°C +/- 100mA @ 105°C Jedec/JESD78 Latch-up Level Class I, Level B Class I, Level B Class I, Level B Class II, Level A Class I, Level B Class I, Level B Class II, Level A Class II, Level A Class I, Level B Class II, Level A Class II, Level A Class II, Level A Class II, Level A Class I, Level B Class I, Level B Class II, Level A Class II, Level A Class II, Level A Class II, Level A Class II, Level A Class II, Level A Class II, Level A Class II, Level A Class I, Level B Class I, Level B Class I, Level B Class I, Level B Class II, Level A Class II, Level A Class II, Level A Class II, Level A Latch up classification for Commercial/Industrial products, per JESD78 B: LC4064ZE- TN100, LC4128ZE-TN100 and LC4128ZE-TN144 and LC4256ZE-TCN144 from Seiko+UTAC: include 0.8mil diameter Au bond wire. C: LC4064ZE-TCN100, LC4128ZE-TCN100, LC4128ZE-TCN144 and LC4256ZE-TCN144 bill-of-materials include Cu bond wires. D: LC4128ZE-TN144/MN144, data is on UMC silicon. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 21 Table 3.4.6 ispMACH4000 V-Supply (Over Voltage) Latch Up Data (Commercial/Industrial): Device V-supply Over-Voltage LU Jedec/JESD78 Latch-up Level LC4032ZE-TN48 > 1.5X V-supply @ 125°C Class II LC4064V-TN100 > 1.5X V-supply @ 105°C Class II LC4064B-TN100 > 1.5X V-supply @ 105°C Class II LC4064ZE-TN100B > 1.5X V-supply @ 105°C Class II > 1.5X V-supply @ 105°C Class II > 1.5X V-supply @ 105°C Class II > 1.5X V-supply @ 105°C Class II LC4128ZE-TN144 B > 1.5X V-supply @ 105°C Class II LC4128ZE-TN144 D > 1.5X V-supply @ 105°C Class II > 1.5X V-supply @ 105°C Class II > 1.5X V-supply @ 105°C Class II > 1.5X V-supply @ 105°C Class II > 1.5X V-supply @ 105°C Class II LC4064ZE-TCN100 LC4128ZE-TN100 C B LC4128ZE-TCN100C LC4128ZE-MN144 D LC4128ZE-TCN144C LC4256ZE-TN100 B LC4256ZE-TN144 B LC4256ZE-TCN144 C > 1.5X V-supply @ 105°C Class II LC4256B-FN256 > 1.5X V-supply @ 125°C Class II LC4256V-FN256 > 1.5X V-supply @ 125°C Class II LC4384B-FN256 > 1.5X V-supply @ 125°C Class II LC4384V-FN256 > 1.5X V-supply @ 125°C Class II LC4512B-FN256 > 1.5X V-supply @ 125°C Class II LC4512V-FN256 > 1.5X V-supply @ 125°C Class II LC4512B-FT256 > 1.5X V-supply @ 105°C Class II LC4512V-FT256 > 1.5X V-supply @ 105°C Class II Latch up classification for Commercial/Industrial products, per JESD78 B: LC4064ZE- TN100, LC4128ZE-TN100 and LC4128ZE-TN144 and LC4256ZE-TCN144 from Seiko+UTAC: include 0.8mil diameter Au bond wire. C: LC4064ZE-TCN100, LC4128ZE-TCN100, LC4128ZE-TCN144 and LC4256ZE-TCN144 bill-of-materials include Cu bond wires. D: LC4128ZE-TN144/MN144, data is on UMC silicon. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 22 3.5 LA-ispMACH 4000V/Z Product Family – ESD and Latch UP Data (Automotive): LA-ispMACH4000V Automotive Grade product family was tested and classified per the AEC-Q100002-Rev-D Human Body Model (HBM) Electrostatic Discharge (ESD) Test criteria and the JESD22A114C.01 Electrostatic Discharge (ESD) Sensitivity Testing Human Body Model (HBM) procedure. All units were tested at 25oC and +125oC prior to reliability stress and after reliability stress. No failures were observed within the passing classification. Table 3.4.2 LA-ispMACH 4000 ESD-HBM Data (Automotive): Device HBM Passing Voltage AEC-Q100-002 HBM Classification LA4032V-TN44 > 2000 V H2 LA4032ZC-TN48 > 2000 V H2 LA4064V-TN100 > 2000 V H2 LA4064ZC-TN100 > 2000 V H2 LA4128V-TN100 > 2000 V H2 LA4128ZC-TN100 > 2000 V H2 LA4128V-TN144 > 2000 V H2 HBM classification for Automotive products, per AEC-Q100-002-Rev-D LA-ispMACH4000 Automotive Grade product family was tested and Classified per the AEC-Q100011-Rev-B, Charge Device Model (CDM) Electrostatic Discharge Test criteria and the JESD22C101C, Field-Induced Charged-Device Model Test Method for Electrostatic-Discharge-Withstand Thresholds of Microelectronic Components procedure. All units were tested at 25oC and +125oC prior to reliability stress and after reliability stress. No failures were observed within the passing classification. Table 3.4.4 LA-ispMACH 4000 ESD-CDM Data (Automotive): Device CDM Passing Voltage AEC-Q100-011 Classification LA4032V-TN44 > 1000V C5 LA4032ZC-TN48 > 1000V C5 LA4064V-TN100 > 1000V C5 LA4064ZC-TN100 > 1000V C5 LA4128V-TN100 > 750V C4 LA4128ZC-TN100 > 750V C4 LA4128V-TN144 > 750V C4 CDM classification for Commercial/Industrial products, per AEC-Q100-011 Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 23 LA-ispMACH4000V/ZC Automotive Grade product family was tested per the AEC-Q100-004-Rev-C, IC Latch-up Test criteria and JEDEC EIA/JESD78 IC Latch-up Test procedure. All units were tested at 25oC and +125oC prior to reliability stress and after reliability stress. No failures were observed within the passing classification. Table 3.4.7 LA-ispMACH4000 I/O Latch Up Data (Automotive): Device I/O Latch-up Results Jedec/JESD78 Latch-up Level LA4032V-TN44 +/- 100mA @ 125°C Class II, Level A LA4032ZC-TN48 +/- 100mA @ 125°C Class II, Level A LA4064V-TN100 +/- 100mA @ 125°C Class II, Level A LA4064ZC-TN100 +/- 100mA @ 125°C Class II, Level A LA4128V-TN100 +/- 100mA @ 125°C Class II, Level A LA4128ZC-TN100 +/- 100mA @ 125°C Class II, Level A LA4128V-TN144 +/- 100mA @ 125°C Class II, Level A Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 24 4.0 PACKAGE QUALIFICATION DATA FOR ispMACH 4000 FAMILIES The ispMACH 4000 product family is offered in ftBGA, csBGA, and TQFP packages. To cover the range of die in the largest package types for this product family, different package and die combinations were chosen as the generic qualification vehicles for all the package qualification tests including, Temperature Cycling (T/C), Un-biased HAST (UHAST)and Biased HAST (BHAST). Mechanical evaluation tests include Scanning Acoustic Tomography (SAT) and visual inspection. The generation and use of generic data is applied across a family of products or packages emanating from one base wafer foundry or assembly process is a Family Qualification, or Qualification By Extension. For the package stresses BHAST and UHAST, these are considered generic for a given Package Technology. T/C is considered generic up to an evaluated die size + package size + 10%, for a given Package Technology. Surface Mount Pre-Conditioning (SMPC) is considered generic up to an evaluated Peak Reflow temperature, for a given Package Technology. The following tables demonstrate the package qualification matrix. Table 4.1 ispMACH 4000 Product-Package Qualification-By-Extension Matrix Product LC4512V/B/C LC4384V/B/C LC4256V/B/C/ ZC/ZE LC4128V/B/C/ ZC/ZE LC4064V/B/C/ ZC/ZE LC4032V/B/C/ ZC/ZE Stress Test SMPC T/C BHAST UHAST * HTSL SMPC T/C BHAST UHAST * HTSL SMPC T/C BHAST UHAST * HTSL SMPC T/C BHAST UHAST * HTSL SMPC T/C BHAST UHAST * HTSL SMPC T/C BHAST UHAST * HTSL ASEM / ATK / UNISEM /UTAC Au-Wire Leaded Packages 44TQFP 48TQFP 100TQFP 128TQFP 144TQFP Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered MSL3 1k cyc 96 hrs 96 hrs By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext MSL3 1k cyc By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext MSL3 1k cyc By Ext By Ext By Ext Package not offered 176TQFP MSL3 1k cyc By Ext By Ext By Ext MSL3 1k cyc By Ext By Ext By Ext MSL3 1k cyc 96 hrs 96 hrs 1k hrs MSL3 1k cyc By Ext By Ext By Ext MSL3 1k cyc 96 hrs 96 hrs 1k hrs MSL3 1k cyc 96 hrs 96 hrs 1k hrs Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered ASEM ASEM / ATP / UNISEM / UTAC ASEM / UTAC 64ucBGA 56csBGA 132csBGA Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered Package not offered MSL3 1k cyc By Ext 96 hrs By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext MSL3 1k cyc 96 hrs 96 hrs By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext 256ftBGA MSL3 1k cyc 96 hrs 96 hrs By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext ASEM / ATP ** 256fpBGA * MSL3 1k cyc By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext By Ext 1k hrs Package not offered Package not offered Package not offered Package not offered Package not offered * Package HTSL stress run as HTRX (data retention). Both stresses are 1000 hour 150°C bakes. ** Package no longer offered. Use 256 ftBGA for all new designs. Refer to PCN#14A-07 for 256 fpBGA package discontinuance. Note: All packages are qualified by an extension from the largest package and largest die in that package technology. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 25 Table 4.2 LA-ispMACH 4000 (Automotive) Product-Package Qualification-By-Extension Matrix ASEM / ATK Au-Wire Wire Leaded Packages Product Stress Test 44-TQFP TN44 48-TQFP TN48 100-TQFP TN100 128-TQFP TN128 SMPC T/C “V/ZC” “V” Package not Package not LA4128V/ZC BHAST Qualified by Qualified by offered offered extension extension UHAST HTSL SMPC “V/ZC” T/C “V” “V/ZC” Qualified by Package not LA4064V/ZC BHAST Qualified by Qualified by extension offered extension extension UHAST HTSL 1k hours SMPC T/C “V” “V/ZC” Package not Package not LA4032V/ZC BHAST Qualified by Qualified by offered offered extension extension UHAST HTSL Note: All packages are qualified by an extension from the largest package and largest die in that package technology. 144-TQFP TN144 MSL3/260C 1k cycles 96 hours 96 hours By extension Package not offered Package not offered Table 4.3 ispMACH 4000ZE Copper (Cu) Bond Wire Product-Package Qualification-ByExtension Matrix ASEM / UTAC Cu-Wire Leaded Packages Product LC4256ZE LC4128ZE LC4064ZE Stress Test SMPC T/C BHAST UHAST HTSL SMPC T/C BHAST UHAST HTSL SMPC T/C BHAST UHAST HTSL 44-TQFP TCN44 48-TQFP TCN48 100-TQFP TCN100 144-TQFP TCN144 Package not offered Package not offered Qualified by extension MSL3/260C 1k cycles 96 hours 96 hours 1k hours Package not offered Package not offered Qualified by extension Qualified by extension Qualified by extension Qualified by extension Package not offered Package not offered Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 26 4.1 ispMACH 4000 Product Family Surface Mount Preconditioning Testing The Surface Mount Preconditioning (SMPC) Test is used to model the surface mount assembly conditions during component solder processing. All devices stressed through Temperature Cycling, Un-biased HAST and Biased HAST were preconditioned. This preconditioning is consistent with JEDEC JESD22-A113 “Preconditioning Procedures of Plastic Surface Mount Devices Prior to Reliability Testing”, Moisture Sensitivity Level 3(MSL3) package moisture sensitivity and dry-pack storage requirements. Surface Mount Preconditioning (MSL3) (10 Temperature Cycles between -55°C and 125°C, 24 hours bake @ 125°C, 30°C/60% RH, soak 192 hours, 225/245/250/260 °C Reflow Simulation, 3 passes) performed before all EE9 package tests. MSL3 Packages: TQFP, fpBGA, ftBGA, csBGA, ucBGA Surface Mount Preconditioning (MSL2) (10 Temperature Cycles between -55°C and 125°C, 24 hours bake @ 125°C, 85°C/60% RH, soak 168 hours, 260°C Reflow Simulation, 3 passes) performed before all EE9 package tests. MSL2 Packages: csBGA Method: Lattice Procedure # 70-103467, J-STD-020 and JESD22-A113 Table 4.1.1 Surface Mount Precondition Data Product Name Package Assembly Site Lot Number LC4032ZC 48 TQFP Amkor Lot #1 47 0 260°C LC4032ZC 48 TQFP Amkor Lot #2 47 0 260°C LC4032ZE 48 TQFP Amkor Lot #1 45 0 260°C LC4032ZE 48 TQFP Amkor Lot #2 45 0 260°C LC4064ZC 100 TQFP Amkor Lot #1 45 0 260°C LC4064ZC 100 TQFP Amkor Lot #2 45 0 260°C LC4064ZE 64 ucBGA ASEM Lot #1 154 0 260°C LC4064ZE 64 ucBGA ASEM Lot #2 154 0 260°C LC4128 128 TQFP Amkor Lot #1 45 0 260°C LC4128 128 TQFP Amkor Lot #2 45 0 260°C LC4256 176 TQFP Amkor Lot #1 135 0 260°C LC4256 176 TQFP Amkor Lot #2 135 0 260°C LC4256 176 TQFP Amkor Lot #3 135 0 260°C LC4032 44 TQFP ASEM Lot #1 45 0 260°C LC4064 44 TQFP Amkor Lot #1 45 0 260°C LC4064 100 TQFP Amkor Lot #2 45 0 260°C LC4128 128 TQFP Amkor Lot #1 45 0 260°C LC4256 176 TQFP Amkor Lot #1 141 0 260°C LC4256 176 TQFP Amkor Lot #2 141 0 260°C LC4256 176 TQFP Amkor Lot #3 141 0 260°C LC4256 256 fpBGA Amkor Lot #1 45 0 260°C LC4384 176 TQFP Amkor Lot #1 45 0 260°C Quantity # of Fails Reflow Temperature Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 27 Product Name Package Assembly Site Lot Number LC4512 176 TQFP Amkor Lot #1 45 0 260°C LC4512 176 TQFP Amkor Lot #2 45 0 260°C LC4256 132 csBGA ASEM Lot #1 100 0 240°C LC4256 132 csBGA ASEM Lot #2 100 0 240°C LC4256 132 csBGA ASEM Lot #3 100 0 240°C LC4256 132 csBGA ASEM Lot #1 50 0 260°C LC4256 132 csBGA ASEM Lot #2 50 0 260°C LC4256 132 csBGA Quantity # of Fails Reflow Temperature ASEM Lot #3 50 0 260°C 132 csBGA A ASEM Lot #1 50 0 260°C LC4256 132 csBGA A ASEM Lot #2 50 0 260°C LC4512 176 TQFP ASEM Lot #1 150 0 260°C LC4512 176 TQFP ASEM Lot #2 150 0 260°C LC4512 176 TQFP ASEM Lot #3 150 0 260°C LC4512 176 TQFP Amkor Lot #1 150 0 260°C LC4512 176 TQFP Amkor Lot #2 150 0 260°C LC4512 176 TQFP Amkor Lot #3 150 0 260°C LC45256ZC 132 csBGA UNISEM Lot #1 120 0 260°C LC45256ZC 132 csBGA UNISEM Lot #2 120 0 260°C LC45256ZC 132 csBGA UNISEM Lot #3 120 0 260°C LC45256ZC 132 csBGA UNISEM Lot #4 167 0 260°C LC45256ZC 132 csBGA UNISEM Lot #5 167 0 260°C LC45256ZC 132 csBGA UNISEM Lot #6 167 0 260°C LC4064 44 TQFP UNISEM Lot #1 145 0 260°C LC4064 44 TQFP UNISEM Lot #2 145 0 260°C LC4064 44 TQFP UNISEM Lot #3 145 0 260°C LC4512 176 TQFP UNISEM Lot #1 99 0 260°C LC4512 176 TQFP UNISEM Lot #2 98 0 260°C LC4512 176 TQFP LC4256 UNISEM Lot #3 75 0 260°C 256 ftBGA C ASEM Lot #1 45 0 260°C 256 ftBGA C ASEM Lot #2 45 0 260°C 256 ftBGA C ASEM Lot #1 77 1 256 ftBGA C ASEM Lot #2 77 0 260°C 256 ftBGA C UTAC Lot #1 199 0 260°C 256 ftBGA C UTAC Lot #2 199 0 260°C isplSI 5384VE 256 ftBGA C UTAC Lot #3 231 0 260°C LA4128V 144 TQFP ASEM Lot #1 234 0 260°C LA4128V 144 TQFP ASEM Lot #2 231 0 260°C LA4128V 144 TQFP ASEM Lot #3 234 0 260°C LA4128V 144 TQFP Amkor Lot #1 81 0 260°C LA4128V 144 TQFP Amkor Lot #2 82 0 260°C LCMXO2280 LCMXO2280 ispLSI 5384VE isplSI 5384VE isplSI 5384VE isplSI 5384VE B 260°C Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 28 Product Name Package Assembly Site Lot Number LA4128V 144 TQFP Amkor Lot #3 78 0 260°C LA4128V 144 TQFP Amkor Lot #4 162 0 260°C LA4128V 144 TQFP Amkor Lot #5 200 0 260°C LA4128V 144 TQFP LC4256ZE LC4256ZE LC4256ZE LC4256ZE LC4256ZE LC4256ZE Quantity # of Fails Reflow Temperature Amkor Lot #6 200 0 260°C TN 144 D UTAC Lot #1 319 0 260°C TN 144 D UTAC Lot #2 319 0 260°C TN 144 D UTAC Lot #3 319 0 260°C TCN 144 E UTAC Lot #1 319 0 260°C TCN 144 E UTAC Lot #2 319 0 260°C TCN 144 E UTAC Lot #3 319 0 260°C A: MSL-2 packages Cumulative SMPC Failure Rate = 1 / 9,167 B: Functional failure after SMPC CAR# 2700 C: The LCMXO2280 and ispLSI 5384VE were the qualification vehicles for ASEM & UTAC 256 ftBGA packages. The other ASEM & UTAC Mach4K 256 ftBGA packages are qualified by extension. D: The LC4256ZE, TN144 bill-of-materials includes 0.8mil Gold (Au) bond wires. E: The LC4256ZE, TCN144 bill-of-materials includes 0.8mil Copper (Cu) bond wires. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 29 4.2 ispMACH 4000 Product Family Temperature Cycling Data The Temperature Cycling test is used to accelerate those failures resulting from mechanical stresses induced by differential thermal expansion of adjacent films, layers and metallurgical interfaces in the die and package. Devices are tested at 25°C after exposure to repeated cycling between -55°C and +125°C in an air environment consistent with JEDEC JESD22-A104 “Temperature Cycling”, Condition B temperature cycling requirements. Prior to Temperature Cycling testing, all devices are subjected to Surface Mount Preconditioning. MSL3 Packages: TQFP, fpBGA, ftBGA, csBGA, ucBGA Stress Duration: 1000 cycles Stress Conditions: Temperature cycling between -55°C to 125°C Method: Lattice Procedure # 70-101568 and JESD22-A104C Table 4.2.1: Temperature Cycling Data 48 TQFP Assembly Site Amkor Lot Number Lot #1 47 250 Cycles 0 500 Cycles 0 1000 Cycles 0 48 TQFP Amkor Lot #2 47 0 0 0 LC4032ZE 48 TQFP Amkor Lot #1 45 0 0 0 LC4032ZE 48 TQFP LC4064ZC 10 TQFP Amkor Lot #2 45 0 0 0 Amkor Lot #1 45 0 0 0 LC4064ZC LC4064ZE 100 TQFP Amkor Lot #2 45 0 0 0 64 ucBGA ASEM Lot #1 77 0 0 0 LC4064ZE 64 ucBGA ASEM Lot #2 77 0 0 0 LC4128 128 TQFP Amkor Lot #1 45 0 0 0 LC4128 128 TQFP Amkor Lot #2 45 0 0 0 LC4256 176 TQFP Amkor Lot #1 45 0 0 0 LC4256 176 TQFP Amkor Lot #2 45 0 0 0 LC4256 176 TQFP Amkor Lot #3 45 0 0 0 LC4032 44 TQFP Amkor Lot #1 45 0 0 0 LC4064 100 TQFP Amkor Lot #2 45 0 0 0 LC4128 128 TQFP Amkor Lot #1 45 0 0 0 LC4256 176 TQFP Amkor Lot #1 45 0 0 0 LC4256 176 TQFP Amkor Lot #2 45 0 0 0 LC4256 176 TQFP Amkor Lot #3 45 0 0 0 LC4256 256 fpBGA Amkor Lot #1 45 0 0 0 LC4384 176 TQFP Amkor Lot #1 45 0 0 0 LC4512 176 TQFP Amkor Lot #1 45 0 0 0 LC4512 176 TQFP Amkor Lot #2 45 0 0 0 LC4256 132 csBGA ASEM Lot #1 50 0 0 0 LC4256 132 csBGA ASEM Lot #2 50 0 0 0 LC4256 132 csBGA ASEM Lot #3 48 0 0 0 LC4256 132 csBGA ASEM Lot #1 48 0 0 0 LC4256 132 csBGA ASEM Lot #2 50 0 0 0 LC4256 132 csBGA ASEM Lot #3 50 0 0 0 LC4256 132 csBGAA ASEM Lot #1 50 0 0 0 LC4256 A ASEM Lot #2 50 0 0 0 Product Name Package LC4032ZC LC4032ZC 132 csBGA Quantity Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 30 176 TQFP Assembly Site ASEM Lot Number Lot #1 50 250 Cycles 0 500 Cycles 0 1000 Cycles 0 LC4512 176 TQFP ASEM LC4512 176 TQFP ASEM Lot #2 50 0 0 0 Lot #3 50 0 0 0 LC4512 176 TQFP Amkor Lot #1 45 0 0 0 LC4512 LC4512 176 TQFP Amkor Lot #2 45 0 0 0 176 TQFP Amkor Lot #3 45 0 0 0 LC45256ZC 132 csBGA UNISEM Lot #1 120 0 0 0 LC45256ZC 132 csBGA UNISEM Lot #2 120 0 0 0 LC45256ZC 132 csBGA UNISEM Lot #3 120 0 0 0 LC4064 44 TQFP UNISEM Lot #1 45 0 0 0 LC4064 44 TQFP UNISEM Lot #2 45 0 0 0 LC4064 44 TQFP UNISEM Lot #3 45 0 0 0 LC4512 176 TQFP UNISEM Lot #1 50 0 0 0 LC4512 176 TQFP UNISEM Lot #2 49 0 0 0 Product Name Package LC4512 Quantity LC4512 176 TQFP UNISEM Lot #3 45 0 0 0 LCMXO2280 256 ftBGAB ASEM Lot #1 45 0 0 0 LCMXO2280 256 ftBGA B ASEM Lot #2 45 0 0 0 ispLSI 5384VE 256 ftBGAB ASEM Lot #1 76 0 0 0 isplSI 5384VE 256 ftBGA B ASEM Lot #2 77 0 0 0 isplSI 5384VE 256 ftBGA B UTAC Lot #1 77 0 0 0 isplSI 5384VE 256 ftBGAB UTAC Lot #2 77 0 0 0 isplSI 5384VE 256 ftBGA B UTAC Lot #3 77 0 0 0 LA4128V 144 TQFP ASEM Lot #1 77 0 0 0 LA4128V 144 TQFP ASEM Lot #2 77 0 0 0 LA4128V 144 TQFP ASEM Lot #3 77 0 0 0 LA4128V 144 TQFP Amkor Lot #1 81 0 0 0 LA4128V 144 TQFP Amkor Lot #2 82 0 0 0 LA4128V 144 TQFP Amkor Lot #3 78 0 0 0 TN 144 C UTAC Lot #1 83 0 0 0 LC4256ZE TN 144 C UTAC Lot #2 83 0 0 0 LC4256ZE TN 144C UTAC Lot #3 83 0 0 0 LC4256ZE TCN 144 D UTAC Lot #1 83 0 0 0 LC4256ZE TCN 144D UTAC Lot #2 83 0 0 0 LC4256ZE D UTAC Lot #3 83 0 0 0 LC4256ZE A: MSL-2 packages TCN 144 Cumulative Temp Cycle Failure Rate = 0 / 3,867 B: The LCMXO2280 and ispLSI 5384VE were the qualification vehicles for ASEM & UTAC 256 ftBGA packages. The other ASEM & UTAC Mach4K 256 ftBGA packages are qualified by extension. C: The LC4256ZE, TN144 bill-of-materials includes 0.8mil Gold (Au) bond wires. D: The LC4256ZE, TCN144 bill-of-materials includes 0.8mil Copper (Cu) bond wires. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 31 4.3 ispMACH 4000 Product Family Unbiased HAST Data Unbiased Highly Accelerated Stress Test (HAST) testing uses both pressure and temperature to accelerate penetration of moisture into the package and to the die surface. The Unbiased HAST test is designed to detect ionic contaminants present within the package or on the die surface, which can cause chemical corrosion. Consistent JEDEC JESD22-A118, “Accelerated Moisture Resistance Unbiased HAST,” for which the conditions are 96 hour exposure at 130°C and 85% relative humidity. Prior to Unbiased HAST testing, all devices are subjected to Surface Mount Preconditioning. MSL3 Packages: TQFP, fpBGA, ftBGA, csBGA, ucBGA Stress Duration: 96 Hrs Stress Conditions: 130°C, 15psig, 85% RH Method: Lattice Procedure # 70-104285 and JESD22-A118 Table 4.3.1: Unbiased HAST Data Product Name Package Assembly Site Lot Number Quantity # of Fails Stress Duration LC4064ZE 64 ucBGA ASEM Lot #1 77 0 96 Hrs LC4064ZE 64 ucBGA ASEM Lot #2 77 0 96 Hrs LC4256 176 TQFP ASEM Lot #1 45 0 96 Hrs LC4256 176 TQFP ASEM Lot #2 45 0 96 Hrs LC4256 176 TQFP ASEM Lot #3 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #1 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #2 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #3 45 0 96 Hrs LC45256ZC 132 csBGA UNISEM Lot #4 45 0 96 Hrs LC45256ZC 132 csBGA UNISEM Lot #5 45 0 96 Hrs LC45256ZC 132 csBGA UNISEM Lot #6 45 0 96 Hrs LC4512 176 TQFP Amkor Lot #1 45 0 96 Hrs LC4512 176 TQFP Amkor Lot #2 45 0 96 Hrs LC4512 176 TQFP Amkor Lot #3 45 0 96 Hrs LC4064 44 TQFP UNISEM Lot #1 50 0 96 Hrs LC4064 44 TQFP UNISEM Lot #2 50 0 96 Hrs LC4064 44 TQFP UNISEM Lot #3 50 0 96 Hrs LC4512 176 TQFP UNISEM Lot #1 49 0 96 Hrs LC4512 176 TQFP UNISEM Lot #2 49 0 96 Hrs LC4512 176 TQFP UNISEM Lot #3 30 0 96 Hrs 256 ftBGA A UTAC Lot #1 77 0 96 Hrs 256 ftBGA A UTAC Lot #2 77 0 96 Hrs isplSI 5384VE 256 ftBGA A UTAC Lot #3 77 0 96 Hrs LA4128V 144 TQFP ASEM Lot #1 77 0 96 Hrs LA4128V 144 TQFP ASEM Lot #2 75 0 96 Hrs LA4128V 144 TQFP ASEM Lot #3 77 0 96 Hrs LA4128V 144 TQFP Amkor Lot #4 81 0 96 Hrs LA4128V 144 TQFP Amkor Lot #5 100 0 96 Hrs isplSI 5384VE isplSI 5384VE Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 32 Product Name Package Assembly Site Lot Number Quantity # of Fails Stress Duration LA4128V 144 TQFP LC4256ZE LC4256ZE LC4256ZE LC4256ZE LC4256ZE LC4256ZE Amkor Lot #6 100 0 96 Hrs TN 144 B UTAC Lot #1 77 0 96 Hrs TN 144 B UTAC Lot #2 77 0 96 Hrs TN 144 B UTAC Lot #3 77 0 96 Hrs TCN 144 C UTAC Lot #1 77 0 96 Hrs TCN 144 C UTAC Lot #2 77 0 96 Hrs TCN 144 C UTAC Lot #3 77 0 96 Hrs Cumulative Unbiased HAST failure Rate = 0 / 2,175 A: The LCMXO2280 and ispLSI 5384VE were the qualification vehicles for ASEM & UTAC 256 ftBGA packages. The other ASEM & UTAC Mach4K 256 ftBGA packages are qualified by extension. B: The LC4256ZE, TN144 bill-of-materials includes 0.8mil Gold (Au) bond wires. C: The LC4256ZE, TCN144 bill-of-materials includes 0.8mil Copper (Cu) bond wires. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 33 4.4 ispMACH 4000 Product Family THB: Biased HAST Data Highly Accelerated Stress Test (HAST) testing uses both pressure and temperature to accelerate penetration of moisture into the package and to the die surface. The Biased HAST test is used to accelerate threshold shifts in the MOS device associated with moisture diffusion into the gate oxide region as well as electrochemical corrosion mechanisms within the device package. Consistent with JEDEC JESD A110-B “Highly-Accelerated Temperature and Humidity Stress Test (HAST)”, the biased HAST conditions are with Vcc bias and alternate pin biasing in an ambient of 130°C and 85% relative humidity. Prior to Biased HAST testing, all devices are subjected to Surface Mount Preconditioning. MSL3 Packages: TQFP, fpBGA, ftBGA, csBGA, ucBGA Stress Conditions: Vcc= 1.95V/ 3.6V, 130°C / 85% RH, 15 psig Stress Duration: 96 hours Method: Lattice Procedure # 70-101571 and JESD22-A101B Table 4.4.1: Biased HAST Data Product Name Package Assembly Site Lot Number Quantity # of Fails Stress Duration LC4256 176 TQFP Amkor Lot #1 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #2 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #3 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #1 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #2 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #3 45 0 96 Hrs LC4256 132 csBGA ASEM Lot #1 45 0 96 Hrs LC4256 132 csBGA ASEM Lot #2 45 0 96 Hrs LC4256 132 csBGA ASEM Lot #3 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #1 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #2 45 0 96 Hrs LC4256 176 TQFP Amkor Lot #3 45 0 96 Hrs LC45256ZC 132 csBGA UNISEM Lot #4 45 0 96 Hrs LC45256ZC 132 csBGA UNISEM Lot #5 45 0 96 Hrs LC45256ZC 132 csBGA UNISEM Lot #6 45 0 96 Hrs LC4064 44 TQFP UNISEM Lot #1 50 0 96 Hrs LC4064 44 TQFP UNISEM Lot #2 50 0 96 Hrs LC4064 44 TQFP UNISEM Lot #3 50 0 96 Hrs 256 ftBGA B UTAC Lot #1 45 0 96 Hrs 256 ftBGA B UTAC Lot #2 45 0 96 Hrs isplSI 5384VE 256 ftBGA B LA4128V LA4128V isplSI 5384VE isplSI 5384VE A UTAC Lot #3 77 1 96 Hrs 144 TQFP ASEM Lot #1 80 0 96 Hrs 144 TQFP ASEM Lot #2 77 0 96 Hrs LA4128V 144 TQFP ASEM Lot #3 80 0 96 Hrs LA4128V 144 TQFP Amkor Lot #4 81 0 96 Hrs Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 34 Product Name Package Assembly Site Lot Number Quantity # of Fails Stress Duration LA4128V 144 TQFP Amkor Lot #5 100 0 96 Hrs LA4128V 144 TQFP LC4256ZE LC4256ZE LC4256ZE LC4256ZE LC4256ZE LC4256ZE Amkor Lot #6 100 0 96 Hrs TN 144 C UTAC Lot #1 77 0 96 Hrs TN 144 C UTAC Lot #2 77 0 96 Hrs TN 144 C UTAC Lot #3 77 0 96 Hrs TCN 144 D UTAC Lot #1 77 0 96 Hrs TCN 144 D UTAC Lot #2 77 0 96 Hrs TCN 144 D UTAC Lot #3 77 0 96 Hrs Cumulative BHAST failure Rate EE9 = 1 / 1,972 A: Failed for open. CAR # 2699 B: The LCMXO2280 and ispLSI 5384VE were the qualification vehicles for ASEM & UTAC 256 ftBGA packages. The other ASEM & UTAC Mach4K 256 ftBGA packages are qualified by extension. C: The LC4256ZE, TN144 bill-of-materials includes 0.8mil Gold (Au) bond wires. D: The LC4256ZE, TCN144 bill-of-materials includes 0.8mil Copper (Cu) bond wires. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 35 4.5 ispMACH 4000 Product Family High Temperature Storage Life (HTSL) High Temperature storage test is typically used to determine the effect of time and temperature, under storage conditions, for thermally activated failure mechanisms of solid state electronic devices. Units were stressed per JESD22-A103C, High Temperature Storage Life. For the original ispMACH 4000 non-volatile based products, the HTRX and HTSL stress and test conditions condition were the same. Therefore in many cases the HTSL test was covered by HTRX. Prior to HTSL testing, all devices are subjected to Surface Mount Preconditioning. The High Temperature Storage Life units were stressed at 150°C. High Temperature Storage Life (HTSL) Conditions: Stress Duration: 168, 500, 1000, 1500 hours. Temperature: 150°C Method: Lattice Document # 87-101925 and JESD22-A103C / JESD22-A117A Table 3.2.2: High Temperature Storage Life Results Product Name Package Assembler Lot # Qty 168 Hrs Result 500 Hrs Result LA4064V 100 TQFP ASEM Lot #1 78 0 0 0 78,000 LA4064V 100 TQFP ASEM Lot #2 77 0 0 0 77,000 LA4064V 100 TQFP ASEM Lot #3 78 0 0 0 78,000 LA4064V 100 TQFP LC4256ZE LC4256ZE LC4256ZE LC4256ZE LC4256ZE LC4256ZE 1000 Hrs 1500 Hrs Cumulative Result Result Hours Amkor Lot #2 79 0 0 0 TN 144 A 0 118,500 UTAC Lot #1 83 0 0 0 83,000 TN 144 A UTAC Lot #2 83 0 0 0 83,000 TN 144 A UTAC Lot #3 83 0 0 0 83,000 TCN 144 B UTAC Lot #1 77 0 0 0 77,000 TCN 144 B UTAC Lot #2 77 0 0 0 77,000 TCN 144 B UTAC Lot #3 77 0 0 0 77,000 EE9 Cumulative HTSL Failure Rate = 0 / 792 EE9 Cumulative HTSL Device Hours = 831,500 A: The LC4256ZE, TN144 bill-of-materials includes 0.8mil Gold (Au) bond wires. B: The LC4256ZE, TCN144 bill-of-materials includes 0.8mil Copper (Cu) bond wires. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 36 5.0 ispMACH 4000 Process Reliability Wafer Level Review Several key fabrication process related parameters have been identified by the foundry that would affect the Reliability of the End-Product. These parameters are tested during the Development Phase of the Technology. Passing data (a 10yr lifetime at the reliability junction temperature) must be obtained for three lots minimum for each parameter before release to production. Normal operating conditions are defined in the Electrical Design Rules (EDR). These parameters are: Hot Carrier Immunity (HCI): Effect is a reduction in transistor Idsat. Worst case is low temperature. Time Dependent Dielectric Breakdown (TDDB): Transistor and capacitor oxide shorts or leakage. Negative Bias Temperature Instability (NBTI): Symptom is a shift in Vth (also a reduction in Idsat). Electromigration Lifetime (EML): Symptom is opens within, or shorts between, metal conductors. Stress Migration (SM): Symptom is a void (open) in a metal Via due to microvoid coalescence. SM is not an issue for the EE9 BEOL (etched Al lines, W plug Vias, SiO IMD). Table 5.1 – Wafer Level Reliability Results for Seiko EE9 (180nm) Process Technology Device delta Ids Celsius Vgstress Vds TTF LVN -10% 25 Vd/2 2 5 lots>23yr TDDB Device Celsius Vg Area 0.1% TTF LVPwell 130 2 8000um² 5 lots>133yr EML Layer Celsius delta R Jmax M1 130 20% M2 130 20% M3 130 20% M4 130 20% M5 130 20% .573mA/um² .705mA/um² .705mA/um² .705mA/um² 1.233mA/um² 0.1%TTF 4 lots>41yr 4 lots>32yr 4 lots>33yr 4 lots>16yr 5 lots>15yr HCI Note: Reliability life times are based on listed temperature and used conditions. Detailed WLR test conditions are available upon request. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 37 Table 5.2 – Wafer Level Reliability Results for UMC EE9 (180nm) Process Technology HCI TDDB EML Device delta Ids Celsius Vgstress Vds TTF LVN -10% 25 Vd/2 2 12 lots>15yr LVP -10% 25 0 -2 6 lots>1200yr HVN -10% 25 Vd/2 3.6 6 lots>28yr Device Celsius Vg Area LVPwell 130 2 8000um² 0.1% TTF 6 lots>110000yr LVNwell 130 -2 8000um² 6 lots>2300yr HVPwell 130 3.6 8000um² 6 lots>76yr 6 lots>70yr Layer Celsius delta R Jmax M1 130 +20% M2 130 +20% M3 130 +20% M4 130 +20% M5 130 +20% .573mA/um² .705mA/um² .705mA/um² .705mA/um² 1.233mA/um² 0.1%TTF 7 lots>70yr 6 lots>77yr 4 lots>65yr 4 lots>173yr 3 lots>316yr HVNwell 130 -3.6 8000um² Note: Reliability life times are based on listed temperature and used conditions. Detailed WLR test conditions are available upon request. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 38 6.0 ispMACH 4000V/B/C/ZC/ZE Soft Error Rate Data Soft Error Rate (SER) testing is conducted to characterize the sensitivity of EECPLD storage and device registered logic elements to High Energy Neutron and Alpha Particle radiation. Charge induced by the impact of these particles can collect at sensitive nodes in the device, and result in changes in the internal electrical states of the device. While these changes do not cause physical damage to the device, they can cause a logical error in device operation. All testing conforms to JEDEC JESD-89. Table 6.1 ispMACH 4000 MEASURED FITs / Mb Stress / Structure Neutron Alpha REGISTERED LOGIC 0.6 N/A EECLPD 0 0 Note: Detailed SER data is available upon request. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 39 7.0 ispMACH 4000 PACKAGE ASSEMBLY INTEGRITY TESTS 7.1 Wire Bond Shear Test This procedure is used to measure the wire bond strength at the ball joints. Thirty bonds from a minimum of five devices were used for Wire Bond Shear. WIRE BOND SHEAR TEST RESULTS: All observations > 15 grams for TQFP and fTBGA. The average measured bond shear results for TQFP were Cpk of > 3.7 and Ppk of > 3.7. The average measured bond shear results for 256 ball ftBGA were Cpk of > 3.5 and Ppk of > 3.5 7.2 Wire Bond Pull This procedure is used to measure the wire bond strength at the ball joints and stitch bonds. For products evaluation thirty bonds from a minimum of five devices were used for and Wire Bond Pull. Test conditions for these tests were 6 grams minimum for 1.0 mil gold wire WIRE BOND PULL RESULTS: All observations >6 grams for TQFP and ftbGA packages tested. The average measured wire bond pull results for TQFP were Cpk of > 2.0 and Ppk of > 2.1. The average measured wire bond pull results for 256 ball ftBGA were Cpk of > 2.4 and Ppk of > 2.4. 7.3 Solderability This procedure is used to evaluate the solderability of device terminals normally joined by a soldering operation. An accelerated aging test is included in this test method, which simulates natural aging under a combination of various storage conditions that have deleterious effects. Units are exposed to a 8 hour steam preconditioning followed a flux exposure for 7 seconds and a dip in Pb-free solder alloy @ 245 °C ± 5°C for 5 seconds. Minimum of 22 leads from 3 devices per lot were tested with zero failure acceptance. No failures were observed for ispMACH 4000 devices in TQFP packages. All the tested units passed. There was less than 5% pitting and dewetting on the solder covered area. 7.4 Physical Dimensions Devices were measured using the appropriate Lattice Semiconductor case outline drawings. The 10 devices of TQFP from 3 different lots were measured with no failures found. The calculated Cpk on this small sample is Cpk > 9.6. The 10 devices 256 ftBGA from 3 different lots were measured with no failures found. The calculated Cpk on this small sample is Cpk > 2.0. 7.5 Solder Ball Shear For the 256 ball ftBGA ten devices from three lots were tested. All units were exposed to two surface mount reflow simulations. The 256 ball ftBGA package use a 0.40 mm barrier metal diameter. All ball shear observations were > 800 grams. The average measured ball shear results for 256 ball ftBGA packages post reflow stress were Cpk of >2.0. Note: Mach4K 256 ftBGA packages are qualified by extension from MachXO and ispLSI devices. Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 40 8.0 ispMACH 4000 ADDITIONAL FAMILY DATA Table 8.1: ispMACH 4000 Package Assembly Data – csBGA/ ftBGA Package Attributes / Assembly Sites Die Family (Product Line) Fabrication Process Technology Package Assemble Site Package Type Ball Counts Die Preparation/ Singulation Die Attach Material Mold Compound Supplier/ID Wire Bond Material Wire Bond Methods Substrate Material L/F Plating or BGA Ball Lead Finish Marking ASEM Amkor UNISEM UTAC ispMACH 4000 ispMACH 4000 ispMACH 4000 ispMACH 4000 EE9 (180nm CMOS) EE9 (180nm CMOS) EE9 (180nm CMOS) Malaysia Philippines Singapore Singapore csBGA/ucBGA/ ftBGA 56/64/132/144/ 256 csBGA/caBGA/ ftBGA csBGA csBGA/ftBGA 56/132/256/324 56/132 56/132/256 wafer saw, full cut wafer saw, full cut wafer saw, full cut wafer saw, full cut Ablebond 2100 Series Sumitomo / G770 Series Ablebond 2300 Series Sumitomo / G770 Series Ablebond 2100 Series Sumitomo / G760 Series Ablebond 2300 Series Sumitomo / G770 Series Gold (Au) Gold (Au) Gold (Au) Gold (Au) Thermosonic Ball Thermosonic Ball Thermosonic Ball Thermosonic Ball Bismaleimide Triazine HL83X Series Sn96.5/Ag3.0/ Cu0.5 SnAgCu solder ball Bismaleimide Triazine HL83X Series Sn95.5/Ag4.0/ Cu0.5 SnAgCu solder ball Bismaleimide Triazine HL83X Series Sn96.5/Ag3.0/ Cu0.5 SnAgCu solder ball Bismaleimide Triazine HL83X Series Sn95.5/Ag4.0/ Cu0.5 SnAgCu solder ball Laser Laser Laser Laser EE9 (180nm CMOS) Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 41 Table 8.2: ispMACH 4000 Package Assembly Data – Au-Wire TQFP Package Attributes / Assembly Sites Die Family (Product Line) Fabrication Process Technology Package Assembly Site Package Type Pin Count Die Preparation/ Singulation Die Attach Material Mold Compound Supplier/ID Wire Bond Material Wire Bond Methods Lead frame Material Lead Finish Marking ASEM Amkor UNISEM UTAC ispMACH 4000 ispMACH 4000 ispMACH 4000 ispMACH 4000ZE EE9 (180nm CMOS) EE9 (180nm CMOS) EE9 (180nm CMOS) EE9 (180nm CMOS) Malaysia Korea Singapore Singapore TQFP TQFP TQFP TQFP 44/48/100/144/176 44/48/100/144/176 44/48/100/128/144 100/144 wafer saw, full cut wafer saw, full cut wafer saw, full cut wafer saw, full cut Ablebond 3230 Ablebond 3230 CRM1076NS Ablebond 3230 Hitachi 9220HF Series KTMC 5700TQ Series Sumitomo G700 Series CEL9510HF10-U Gold (Au) Gold (Au) Gold (Au) 0.8mil Gold (Au) Thermosonic Ball Thermosonic Ball Thermosonic Bball Thermosonic Bball Cu Alloy Cu Alloy Cu Alloy Cu Alloy Matte Sn (annealed) Matte Sn (annealed) Matte Sn (annealed) Matte Sn (annealed) Laser Laser Laser Laser Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 42 Table 8.3: ispMACH 4000 Package Assembly Data – Cu-Wire TQFP Package Attributes / Assembly Sites Die Family (Product Line) Fabrication Process Technology Package Assembly Site Package Type Pin Count Die Preparation/ Singulation Die Attach Material Mold Compound Supplier/ID UTAC ispMACH 4000ZE EE9 (180nm CMOS) Singapore TQFP 100/144 wafer saw, full cut Ablebond 3230 CEL8240HF10G Wire Bond Material 0.8mil Copper (Cu) Wire Bond Methods Thermosonic Bball Lead frame Material Cu Alloy Lead Finish Marking Matte Sn (annealed) Laser Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 43 9.0 Revision History Table 9.1: Lattice ispMACH 4000 V/B/C/ZC/ZE Product Family Qualification Summary revisions Date July 2003 Revision A Section --3.1 HTOL & 4.0 Package July 2008 B August 2009 C Whole document May 2011 July 2011 D E 3.4 ESD/LU 3.1 HTOL November 2011 F 4.0 Package Qual Data October 2012 G 3.4 ESD/LU Change Summary Initial document release. Added Seiko LC4032ZE & LC4064ZE qual data to this Product Family Qual Summary New qualification summary reporting format. Also added UMC and Seiko foundry WLR; SER data; ESD/LU; and Package assembly integrity & BOM Updated Seiko LC4064ZE HBM-ESD data Added UMC LC4032ZE & LC4064ZE ELFR data Added UTAC package qual for LC4000ZE: TN144 bill-of-materials includes 0.8mil Gold (Au) bond wires; and TCN144 bill-of-materials includes 0.8mil Copper (Cu) bond wires. Added UMC LC4128ZE HBM, CDM & LU data Lattice Semiconductor Corporation 5555 NE Moore Court Hillsboro, Oregon 97124 U.S.A. Telephone: (503) 268-8000, FAX: (503) 268-8556 www.latticesemi.com © 2012 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are listed at www.latticesemi.com/legal. All other brand or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice. www.latticesemi.com Lattice Semiconductor Corporation Doc. #25-105900 Rev. G 44