STD165中文资料

New ProductUH1B, UH1C & UH1DVishay General Semiconductor Document Number: 89111For technical questions within your region, please contact one of the following:Surface Mount Ultrafast RectifiersFEATURES•Low profile package•Ideal for automated placement•Oxide planar chip junction•Ultrafast recovery times for high frequency•Meets MSL level 1, per J-STD-020, LF maximumpeak of 260 °C•Solder dip 260 °C, 40 s•Component in accordance to RoHS 2002/95/ECand WEEE 2002/96/ECTYPICAL APPLICATIONSFor use in secondary rectification and freewheeling forultrafast switching speeds ac-to-ac and dc-to-dcconverters in high temperature conditions for bothconsumer and automotive applications.MECHANICAL DATACase: DO-214AC (SMA)Epoxy meets UL 94V-0 flammability ratingTerminals: Matte tin plated leads, solderable perJ-STD-002 and JESD22-B102E3 suffix for consumer grade, meets JESD 201 class1A whisker test, HE3 suffix for high reliability grade(AEC Q101 qualified), meets JESD 201 class 2whisker testPolarity:Color band denotes cathode endPRIMARY CHARACTERISTICSI F(AV)1.0 AV RRM100 V, 150 V, 200 VI FSM30 At rr25 nsV F at I F = 1.0 A0.76 VT J max.175 °CDO-214AC (SMA)MAXIMUM RATINGS (T A = 25°C unless otherwise noted)PARAMETER SYMBOL UH1B UH1C UH1D UNITDevice marking code HB HC HDMaximum repetitive peak reverse voltage V RRM 100150200VMaximum average forward rectified current (Fig. 1)I F(AV) 1.0 A Peak forward surge current 8.3 ms single half sine-wavesuperimposed on rated loadI FSM 30 AOperating junction and storage temperature range T J, T STG- 55 to + 175 °C元器件交易网New ProductUH1B, UH1C & UH1DVishay General Semiconductor For technical questions within your region, please contact one of the following:Document Number: 89111Notes:(1) Pulse test: 300 µs pulse width, 1 % duty cycle (2) Pulse test: Pulse width ≤ 40 msNote:(1) Free air, mounted on recommended copper pad area. Thermal resistance R θJA - junction to ambient, R θJM - junction to mountNote:(1) Automotive grade AEC Q101 qualifiedELECTRICAL CHARACTERISTICS (T A = 25°C unless otherwise noted)PARAMETERTEST CONDITIONSSYMBOLTYP.MAX.UNITInstantaneous forward voltage (1)I F = 0.6 A I F = 1.0 A T A = 25 °CV F0.900.96 -1.05VI F = 0.6 A I F = 1.0 A T A = 125 °C 0.700.76 -0.90Reverse current (2)rated V RT A = 25 °C T A = 125 °CI R -7.5 1.025µAMaximum reverse recovery time I F = 0.5 A, I R = 1.0 A,I rr = 0.25 AT A = 25 °Ct rr1325ns Typical reverse recovery time I F = 1.0 A, dI/dt = 50 A/µs,V R = 30 V , I rr = 0.1 I RM 2130Typical softness factor (t b /t a )I F = 1.0 A, dI/dt = 200 A/µs,V R = 200 V T A = 125 °CS0.8--Typical reverse recovery current I RM 2.7 4.0A Typical stored charge Q rr35-nCTypical junction capacitance4.0 V , 1 MHzC J 17-pFTHERMAL CHARACTERISTICS (T A = 25°C unless otherwise noted)PARAMETERSYMBOL UH1BUH1C UH1DUNIT Typical thermal resistance (1)R θJA R θJM12020°C/WORDERING INFORMATION (Example)PREFERRED P/N UNIT WEIGHT (g)PREFERRED PACKAGE CODEBASE QUANTITYDELIVERY MODEUH1D-E3/61T 0.06461T 18007" diameter plastic tape and reel UH1D-E3/5AT 0.0645AT 750013" diameter plastic tape and reel UH1DHE3/61T (1)0.06461T 18007" diameter plastic tape and reel UH1DHE3/5AT (1)0.0645AT750013" diameter plastic tape and reel元器件交易网New ProductUH1B, UH1C & UH1DVishay General Semiconductor Document Number: 89111For technical questions within your region, please contact one of the following: RATINGS AND CHARACTERISTICS CURVES(T A = 25 °C unless otherwise noted)Figure1. Maximum Forward Current Derating CurveFigure2. Forward Power Loss CharacteristicsFigure3. Typical Instantaneous Forward CharacteristicsFigure4. Typical Reverse CharacteristicsFigure5. Typical Junction CapacitanceFigure6. Typical Transient Thermal Impedance元器件交易网New ProductUH1B, UH1C & UH1DVishay General Semiconductor For technical questions within your region, please contact one of the following:Document Number: 89111PACKAGE OUTLINE DIMENSIONS in inches (millimeters)元器件交易网Disclaimer Legal Disclaimer NoticeVishayAll product specifications and data are subject to change without notice.Vishay Intertechnology, Inc., its affiliates, agents, and employees, and all persons acting on its or their behalf (collectively, “Vishay”), disclaim any and all liability for any errors, inaccuracies or incompleteness contained herein or in any other disclosure relating to any product.Vishay disclaims any and all liability arising out of the use or application of any product described herein or of any information provided herein to the maximum extent permitted by law. The product specifications do not expand or otherwise modify Vishay’s terms and conditions of purchase, including but not limited to the warranty expressed therein, which apply to these products.No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document or by any conduct of Vishay.The products shown herein are not designed for use in medical, life-saving, or life-sustaining applications unless otherwise expressly indicated. Customers using or selling Vishay products not expressly indicated for use in such applications do so entirely at their own risk and agree to fully indemnify Vishay for any damages arising or resulting from such use or sale. Please contact authorized Vishay personnel to obtain written terms and conditions regarding products designed for such applications.Product names and markings noted herein may be trademarks of their respective owners.元器件交易网Document Number: 。

J-STD-033B(中文版)资料编辑整理：尊敬的读者朋友们：这里是精品文档编辑中心，本文档内容是由我和我的同事精心编辑整理后发布的，发布之前我们对文中内容进行仔细校对，但是难免会有疏漏的地方，但是任然希望（J-STD-033B(中文版)资料）的内容能够给您的工作和学习带来便利。

同时也真诚的希望收到您的建议和反馈，这将是我们进步的源泉，前进的动力。

本文可编辑可修改，如果觉得对您有帮助请收藏以便随时查阅，最后祝您生活愉快业绩进步，以下为J-STD-033B(中文版)资料的全部内容。

SMD温湿度敏感元件作业，运输，储存，包装标准1.前言SMD零件的出现直接带来了新的挑战,而这些挑战的重心又在于包装的品质和可靠性.本文讲述了floor life 在作业,包装，运输，的等级标准。

J—STD-020说明了湿敏元件级别,JEP113说明了标签要求周围环境中的湿气会通过包装材料渗透到包装内部，并在不同材料的表面聚结。

在组装工艺中，SMD元件贴装在PCB上时会经历超过200℃,在焊接时,湿气的膨胀会造成一些列的焊接品质问题。

2.目的本文旨在为使用,运输,存储，包装SMD湿敏元件提供标准。

通过本文内的方法,可以避免零件受潮和零件在过IR后可靠性下降。

通过本文的各个程序，可以达到无害回焊。

热烘可以使SMD零件得到长达12个月的包装存储寿命。

3.范围3。

1 包装3.1.1 本标准适用于PCBA中无需密封SMD零件的作业，其中包括聚合分子材料和塑胶材料3.1。

2 密封包装大零件无湿气风险，不必作防潮3.2 组装制程3.2。

1本标准适用于PCBA IR，VPR等制程，不适用于波峰焊3.2.2 本标准亦适用于受潮零件的烘烤或重工3。

2.3 本标准不适用于不过回焊炉的零件3。

3 可靠性3.3。

1 内容描述中的方法可以保证PCBA的成品可靠性是可评估的（标准 J-STD-020 和JESD22—A113）3.3。

2 本文不对焊接可靠性作评述4. 涉及文件4。

Pulse is one of the leading manufacturers of magnetic interface transformers, data bus couplers, delay lines, Ethernet transformers, and custom electronic components forMilitary/Aerospace applications. Both catalog and custom designs include a comprehensive range of high-performance solutions and packaging for QPL and non-QPL MIL -STD-1553 interface transformers, various MIL-STD-1553 Data Bus Couplers and QPL and non-QPL active and passive delay lines. In addition, Copperhead transformers and transceivers support a variety of high-speed applications that includes Fibre Channel, Gigabit Ethernet, SONET , HDTV, IEEE1394B, SMTPE, Ethernet and AFDX buses.Pulse's Military/Aerospace products are designed to meet the most demanding requirementsfor military, aerospace and industrial applications. For catalog and/or custom designed products, contact Pulse’s Military/Aerospace Division at 215-781-6400 or find an authorized distributor or representative on the Pulse website. See back cover.1.Web:/products/datasheets/M101.pdf or M102.pdf2.T = Transformer, C = Choke,S = Shunt inductor, SMT = 50 mil pitch leads ,SOIC = 100 mil pitch leads2.Dual Transformers designed specifically for Point-to-Point Coupling to 150 ΩTwinax Cable :Withstands infrared and vapor phase soldering ; Military Temp Range =-55°C to +125°C; Weight = 1.0 grams; Surface Mount = pick-and-place compatible.Applications:Fibre Channel, Gigabit Ethernet, SONET , HDTV, IEEE 1394B, SMTPE.Application Notes : These isolation transformers protect the station from static charges that may develop on the cable and prevent ground loop currents from being transferred between stations. They have also been designed to provide common mode rejection within the transmission band, reducing EMI.MILITARY/AEROSPACE PRODUCTSNon-QPL,Low Profile and Stacked1Part2T urns Ratio Impedance Package*DataNumber(±3%)(ΩMIN)L/W/H (in.)SheetPart2T urns Ratio Impedance Package*DataNumber(±3%)(ΩMIN)L/W/H (in.)Sheet FL1553-11CT:1CT/1CT:.707CT4,000.630 / .630 / .155NQPLC22,3GL1553-11CT:1CT/1CT:.707CT4,000.630 / .630 / .155NQPLC22,3TL1553-11CT:1CT/1CT:.707CT4,000.630 / .630 / .155NQPLC22,3FL1553-2 1.4CT:1CT/2CT:1CT7,200.630 / .630 / .155NQPLC22,3GL1553-2 1.4CT:1CT/2CT:1CT7,200.630 / .630 / .155NQPLC22,3TL1553-2 1.4CT:1CT/2CT:1CT7,200.630 / .630 / .155NQPLC22,3FL1553-3 1.25CT:1CT/1.66CT:1CT4,000.630 / .630 / .155NQPLC22,3GL1553-3 1.25CT:1CT/1.66CT:1CT4,000.630 / .630 / .155NQPLC22,3TL1553-3 1.25CT:1CT/1.66CT:1CT4,000.630 / .630 / .155NQPLC22,3FL1553-51CT:2.12CT/1CT:1.5CT4,000.630 / .630 / .155NQPLC22,3GL1553-51CT:2.12CT/1CT:1.5CT4,000.630 / .630 / .155NQPLC22,3TL1553-51CT:2.12CT/1CT:1.5CT4,000.630 / .630 / .155NQPLC22,3FL1553-451CT:2.5CT/1CT:1.79CT4,000.630 / .630 / .155NQPLC22,3GL1553-451CT:2.5CT/1CT:1.79CT4,000.630 / .630 / .155NQPLC22,3TL1553-451CT:2.5CT/1CT:1.79CT4,000.630 / .630 / .155NQPLC22,3DFL1553-11CT:1CT/1CT:.707CT4,000.930 / .630 / .155NQPLC22,3DGL1553-11CT:1CT/1CT:.707CT4,000.930 / .630 / .155NQPLC22,3DTL1553-11CT:1CT/1CT:.707CT4,000.930 / .630 / .155 NQPLC22,3DFL1553-2 1.4CT:1CT/2CT:1CT7,200.930 / .630 / .155NQPLC22,3DGL1553-2 1.4CT:1CT/2CT:1CT7,200.930 / .630 / .155NQPLC22,3DTL1553-2 1.4CT:1CT/2CT:1CT7,200.930 / .630 / .155NQPLC22,3DFL1553-3 1.25CT:1CT/1.66CT:1CT4,000.930 / .630 / .155NQPLC22,3DGL1553-3 1.25CT:1CT/1.66CT:1CT4,000.930 / .630 / .155NQPLC22,3DTL1553-3 1.25CT:1CT/1.66CT:1CT4,000.930 / .630 / .155NQPLC22,3DFL1553-51CT:2.12CT/1CT:1.5CT4,000.930 / .630 / .155NQPLC22,3DGL1553-51CT:2.12CT/1CT:1.5CT4,000.930 / .630 / .155NQPLC22,3DTL1553-51CT:2.12CT/1CT:1.5CT4,000.930 / .630 / .155NQPLC22,3DFL1553-451CT:2.5CT/1CT:1.79CT4,000.930 / .630 / .155NQPLC22,3DGL1553-451CT:2.5CT/1CT:1.79CT4,000.930 / .630 / .155NQPLC22,3DTL1553-451CT:2.5CT/1CT:1.79CT4,000.930 / .630 / .155NQPLC22,32,3STQ1553-51CT:2.12CT/1CT:1.5CT4,000.630 / .630 / .340NQPLC22,3STQ1553-451CT:2.5CT/1CT:1.79CT4,000.630 / .630 / .340NQPLC22,3SFQ1553-11CT:1CT/1CT:.707CT4,000.630 / .630 / .340NQPLC22,3SGQ1553-11CT:1CT/1CT:.707CT4,000.630 / .630 / .340NQPLC22,3SFQ1553-2 1.4CT:1CT/2CT:1CT7,200.630 / .630 / .340NQPLC22,3SGQ1553-2 1.4CT:1CT/2CT:1CT7,200.630 / .630 / .340NQPLC22,3SFQ1553-3 1.25CT:1CT/1.66CT:1CT4,000.630 / .630 / .340NQPLC22,3SGQ1553-3 1.25CT:1CT/1.66CT:1CT4,000.630 / .630 / .340NQPLC22,3SFQ1553-51CT:2.12CT/1CT:1.5CT4,000.630 / .630 / .340NQPLC22,3SGQ1553-51CT:2.12CT/1CT:1.5CT4,000.630 / .630 / .340NQPLC22,3SFQ1553-451CT:2.5CT/1CT:1.79CT4,000.630 / .630 / .340NQPLC22,3SGQ1553-451CT:2.5CT/1CT:1.79CT4,000.630 / .630 / .340NQPLC22,3SLQG1553-11CT:1CT/1.4CT:1CT4,000.630 / .630 / .280M1042SLQG1553-2 1.4CT:1CT/2CT:1CT7,200.630 / .630 / .280M1042SLQG1553-3 1.25CT:1CT/1.66CT:1CT4,000.630 / .630 / .280M1042SLQG1553-51CT:2.12CT/1CT:1.5CT4,000.630 / .630 / .280M1042SLQG1553-451CT:2.5CT/1CT:1.79CT4,000.630 / .630 / .280M1042SLQT1553-11CT:1CT/1.4CT:1CT4,000.630 / .630 / .280M1042SLQT1553-2 1.4CT:1CT/2CT:1CT7,200.630 / .630 / .280M1042SLQT1553-3 1.25CT:1CT/1.66CT:1CT4,000.630 / .630 / .280M1042SLQT1553-51CT:2.12CT/1CT:1.5CT4,000.630 / .630 / .280M104222.Web:/products/datasheets/N_QPL_Cat2_links.pdfor M104.pdf3.Prefix / Operating Temperature :xxxC1553-xx/ 0°C to +70°C ; xxxN1553-xx/-40°C to +85°C; xxx1553-xx / -55°C to +125°CMIL-STD-1553x1553-11CT:1CT/1CT:.707CT4,000.625 / .625 / .250NQPLC2x1553-2 1.4CT:1CT/2CT:1CT7,200.625 / .625 / .250NQPLC2x1553-3 1.25CT:1CT/1.66CT:1CT4,000.625 / .625 / .250NQPLC2x1553-51CT:2.12CT/1.5CT:1CT4,000.625 / .625 / .250NQPLC2x1553-451CT:2.5CT/1CT:1.79CT4,000.625 / .625 / .250NQPLC21.Designed and built to conform to MIL-PRF-21038/272.Prefix / Operating T emperature:C / 0°Cto +70°C; N/ -40°C to +85°C;TQ / -55°C to +125°C3.Web:/pdf/N_QPL_Cat2_links.pdfInterface T ransformers:COTS Series1Part2T urns Ratio Impedance Package*Data3Number(±3%)(W MIN)(L/W/H) in.SheetMILITARY/AEROSPACE PRODUCTS1.Web:/products/datasheets/M106.pdf2.0.99mm(.039") pitch leads3.T = Transformer, C = Choke,S = Shunt inductor, SMT= 50 mil pitch leads,SOIC = 100 mil pitch leadsGigabitMILITARY/AEROSPACE ETHERNET/AFDX (continued)*Mounting:FP = Flat Pack TH= Through Hole SM= Surface MountQ1553-5M21038/27-101CT:2.12CT/1CT:1.5CT 4,000.625 / .625 / .250QPL6Q1553-45M21038/27-261CT:2.5CT/1CT:1.79CT 4,000.625 / .625 / .275QPL6Q1553-81M21038/27-211CT:1CT/1CT:.707CT 4,000.625 / .625 / .275QPL6Q1553-82M21038/27-22 1.4CT:1CT/2CT:1CT 7,200.625 / .625 / .275QPL6Q1553-83M21038/27-23 1.25CT:1CT/1.66CT:1CT 4,000.625 / .625 / .275QPL6Q1553-84M21038/27-241CT:2.12CT/1CT:1.5CT 4,000.625 / .625 / .275QPL6Q1553-85M21038/27-251CT:2.5CT/1CT:1.79CT 4,000.625 / .625 / .275QPL6M21038/27-xxC, M21038/27-xxT).2.Web:/products/datasheets/QPL6.pdf3.Summary Performance Specifications:Droop = 20%; Overshoot = ±1 VMAX;Common Mode Rejection = 45 dB; Frequency Range (no load) = 75 kHz to 1 MHz; Operating Temperature Range = -55°C to +130°C; Weight = 5 grams;Insulation Resistance = 10 kM Ω@ 250 V DC ; Dielectric Withstanding Voltage = 100 VrmsPulse offers off-the-shelf inductors and transformers for modern military and aerospace power applications--the SLED™, the SLIC,and the POGO™ series. The SLED series consists of rail-mount inductors with a ruggedized header for durable board connections,utilizing two rails for board mounting and cores bonded to high temperature headers for durability and mechanical strength. The SLIC series, self-leaded transformers and inductors,have ruggedized construction. The structural header is bonded to the cores and lead wires,increasing mechanical durability. The POGO series are pad-mounted inductors with open construction for robust board mounting with rugged pins used for both surface board-mounting and electrical connection.To locate the current data sheets for these products, go to the Pulse website at the following URL: and click the “Military / Aerospace” tile on the Pulse home page.T oroid Power Inductors - SLED SeriesPart @I RATED I RATED DCR Inductance Package*Data Number (µH)(A)(m ΩMAX)@0A DC (µH)L/W/H (in.)SheetPart @I RATED I RATED DCR Inductance Package*Data Number (µH)(A)(m ΩMAX)@0A DC (µH)L/W/H (in.)Sheet T oroid Power Inductors - SLED Series (continuedOFF-THE-SHELF POWER INDUCTORS & TRANSFORMERSSLED 20PL8100 1.01 3.4011 1.1.400 / .345 / .250M107PL8101 6.2 1.40 707.400 / .345 / .250M107PL810217.6 1.00 12522.7.400 / .345 / .250M107SLED 30PL8110 3.8 4.8017.3 5.2.625 / .525 / .400M107PL81119.4 2.8043.412.3.625 / .525 / .400M107PL811229.7 1.40 16635.3.625 / .525 / .400M107PL81131140.94 380167.625 / .525 / .400M107MILITARY/AEROSPACE PRODUCTSFrequency (MHz)I m p e d a n c e (W )POGO 40PL8400S 43.6 1.130977.725 / .575 / .380M111POGO 50PL8401S 21.9 2.790.539.5.910 / .700 / .510M111PL8402S 4.025 6.423 6.575.910 / .700 / .510M111PL8403P 0.5323.830.88.910 / .700 / .510M111PL8404P 1.1212.5 2.1.910 / .700 / .510M111SMT Power Inductors:T oroid,SLED Series SMT Power Inductors:T oroid,POGO SeriesSMT Common Mode Inductors:T oroid,POGO SeriesPOGO 25PL8600P 2.08.307.6 2.2.625 / .525 / .310M114PL8601P 2.47.2010.9 2.6.625 / .525 / .310M114PL8602P 5.0 5.2019.0 5.5.625 / .525 / .310M114PL8600S 7.0 4.1616.08.75.625 / .525 / .310M114PL8603P 9.3 3.8029.810.4.625 / .525 / .310M114PL8601S 8.4 3.7821.810.4.625 / .525 / .310M114PL8604P 14.1 3.1045.315.7.625 / .525 / .310M114PL8605P 19.8 2.666.322.1.625 / .525 / .310M114PL8602S 17.9 2.638.022.45.625 / .525 / .310M114PL8606P 29.3 2.2010632.8.625 / .525 / .310M114PL8603S 33.8 1.896041.7.625 / .525 / .310M114PL8607P 42.6 1.8015147.6.625 / .525 / .310M114PL8604S 50.9 1.549162.8.625 / .525 / .310M114PL8608P 61.3 1.5022467.5.625 / .525 / .310M114PL8605S 71.5 1.3013388.2.625 / .525 / .310M114PL8609P 84.2 1.2032491.0.625 / .525 / .310M114PL8606S 106.1 1.07202131.0.625 / .525 / .310M114PL8607S 154.20.89302190.3.625 / .525 / .310M114PL8608S 218.90.74444270.2.625 / .525 / .310M114PL8609S 295.00.64636364.0.625 / .525 / .310M114Part Inductance I RATED DCR SRF Impedance Package Data Number (mH ±30%) (A)(m Ω) MAX (MHz)Curve 1L/W/H (in.)SheetPOGO 40PL8801 1.5 1.506022.725 / .575 / .380M116PL880310.0 1.004500.54.725 / .575 / .380M116PL880422.00.508500.35.725 / .575 / .380M1161.The rated current as listed is either the saturation current or the heating current depending on which value is lower.2.Inductance at 0ADC tolerance is ±30%. The tolerance is ±20% on all other parts.Optional Tape and Reel packaging can be ordered by adding a "T"suffix to the end of the part number.SM =Surface MountMILITARY/AEROSPACE PRODUCTS。

POWER: 600Wa t VOLTAGE RANGE: 6.8 - 440VP6KE6.8A(CA)-P6KE440A(CA)Classification Rating 94V-OFeaturesGlass Passivated Die ConstructionUni- and Bi-Directional Versions Available Excellent Clamping Capability Fast Response TimePlastic Case Material has UL Flammability Mechanical DataCase: JEDEC DO-15 Low Profile Molded Plastic Terminals: Axial Leads, Solderable per MIL-STD-202, Method 208Polarity: Cathode Band or Cathode Notch Weight: 0.40 grams (approx.)Maximum Ratings and Electrical Characteristics@T A =25°C unless otherwise specifiedCharacteristicSymbol ValueUnit Peak Pulse Power Dissipation at T A = 25°C (Note 1, 2, 5) Figure 3P PPM 600 MinimumW Peak Forward Surge Current (Note 3)I FSM 100A Peak Pulse Current on 10/1000µS Waveform (Note 1) Figure 1I PPM See Table 1A Steady State Power Dissipation (Note 2, 4)P M(AV) 5.0W Operating and Storage Temperature RangeT j , T STG-65 to +175°CNote: 1. Non-repetitive current pulse, per Figure 1 and derated above T A = 25°C per Figure 4.2. Mounted on 40mm 2 copper pad.3. 8.3ms single half sine-wave duty cycle = 4 pulses per minutes maximum.4. Lead temperature at 75°C = T L .5. Peak pulse power waveform is 10/1000µS.AXIAL LEADED TRANSIENT VOLTAGE SUPPERSSOR DIODE!!!!!!!!P6KE440CA10.5 14.513.412.186.577.971.364.658.953.248.544.740.934.231.428.525.722.820.919.017.115.214.312.49.508.657.797.136.45(uA)R RMW RMW@V leakage Reverse CurrentPulse Peak (A)Vc(V)(mA)BR MAX CurrentMax.BR MIN @I Min.Volgtage Breakdown (V)(BI)(Uni)Voltage Stand-Off Reverse Maximum Clamping V T PP(V)V @I Volgtage Breakdown Test (V)V T Volgtage @I PP P6KE6.8A P6KE6.8CA 5.80 7.14 10.0 57.1 1000.0P6KE7.5A P6KE7.5CA 6.40 7.88 10.0 11.3 53.1 500.0 P6KE8.2A P6KE8.2CA 7.028.61 10.0 49.6 200.0 P6KE9.1A P6KE9.1CA 7.78 9.55 1.0 44.8 50.0 P6KE10A P6KE10CA 8.55 10.5 1.0 41.4 10.0P6KE11A P6KE11CA 9.40 10.5 11.6 1.0 15.6 38.5 5.0 P6KE12A P6KE12CA10.2 11.412.6 1.0 16.7 35.9 5.0P6KE13A P6KE13CA11.1 13.7 1.0 18.2 33.0 5.0 P6KE15A P6KE15CA 12.8 15.8 1.0 21.2 28.3 5.0 P6KE16A P6KE16CA 13.6 16.8 1.0 22.5 26.7 5.0P6KE18A P6KE18CA 15.3 18.9 1.0 25.2 23.8 5.0 P6KE20A P6KE20CA 17.1 21.0 1.0 27.7 21.7 5.0 P6KE22A P6KE22CA 18.8 23.1 1.0 30.6 19.6 5.0 P6KE24A P6KE24CA 20.5 25.2 1.0 33.2 18.1 5.0 P6KE27A P6KE27CA 23.1 28.4 1.0 37.5 16.0 5.0 P6KE30A P6KE30CA 25.6 31.5 1.0 41.4 14.5 5.0 P6KE33A P6KE33CA 28.2 34.7 1.0 45.7 13.1 5.0P6KE36A P6KE36CA 30.8 37.8 1.0 49.9 12.0 5.0P6KE39A P6KE39CA 33.3 37.1 41.0 1.0 53.9 11.1 5.0 P6KE43A P6KE43CA 36.8 45.2 1.0 59.3 10.1 5.0 P6KE47A P6KE47CA 40.2 49.4 1.0 64.8 9.3 5.0 P6KE51A P6KE51CA 43.6 53.6 1.0 70.1 8.6 5.0P6KE56A P6KE56CA 47.8 58.8 1.077.0 7.8 5.0P6KE62A P6KE62CA 53.0 65.1 1.0 85.07.1 5.0 P6KE68A P6KE68CA 58.1 71.4 1.0 92.06.5 5.0 P6KE75A P6KE75CA 64.1 78.81.0 103 5.8 5.0P6KE82A P6KE82CA70.1 86.1 1.0 1135.3 5.0P6KE91A P6KE91CA 77.8 95.5 1.0 1254.85.0 P6KE100A P6KE100CA 85.5 95.0 105 1.0 137 4.4 5.0 P6KE110AP6KE110CA 94.0 105 116 1.0 1523.9 5.0 P6KE120AP6KE120CA102 114 126 1.0 165 3.6 5.0 P6KE130A P6KE130CA 111 124 137 1.0 179 3.4 5.0 P6KE150A P6KE150CA 128 143 158 1.0 207 2.9 5.0 P6KE160A P6KE160CA 136 152168 1.0 219 2.7 5.0 P6KE170A P6KE170CA 145 162 179 1.0 234 2.6 5.0 P6KE180A P6KE180CA 154 171 189 1.0 246 2.4 5.0 P6KE200A P6KE200CA 171 190 210 1.0 274 2.2 5.0 P6KE220A P6KE220CA 185 209 231 1.0 328 1.8 5.0 P6KE250A P6KE250CA 214 237 263 1.0 344 1.7 5.0 P6KE300A P6KE300CA 256 285 315 1.0 414 1.4 5.0 350 310 380 P6KE350A P6KE350CA 1.0 482 1.2 5.0 P6KE400A P6KE400CA 342 380 420 1.0 548 1.1 5.0 P6KE440A 3764184621.06021.05.0TYPERating at = 25 °C ambient temperature unless otherwise specified255075100125150175200100755025T ,AMBIENT TEMPERATURE (°C)Fig.4Pulse Derating CurveA P K P U L S E D E R A T I N G (%P K P W R O R C U R R E N T )25507510012515017520002.55.0T ,LEAD TEMPERATURE (°C)Fig.5,Steady State Power DeratingLP ,S T E A D Y S T A T E P O W E R D I S S I P A T I O N (W )d 0.11.0T ,PULSE WIDTH (µs)Fig.3Pulse Rating Curvep 0.1101001.010100100010000P ,P E A K P U L S E P O W E R (k W )P0123I ,P E A K P U L S E C U R R E N T (%)P p pt,TIME (ms)Fig.1Pulse Waveform110100100010100100010,000V ,REVERSE STANDOFF VOLTAGE (V)Fig.2Typical Junction CapacitanceRWM C ,C A P A C I T A N C E (p F )j。

POWER: 1500Wa t VOLTAGE RANGE: 6.8 - 440 VAXIAL LEADED TRANSIENT VOLTAGE SUPPRESS DIODE1.5KE6.8A(CA) - 1.5KE440A(CA)6.8V – 440V Standoff VoltageCase: JEDEC DO-201AD Molded Plastic FeaturesGlass Passivated Die Construction Uni- and Bi-Directional Versions Available Excellent Clamping Capability Fast Response TimePlastic Case Material has UL FlammabilityMechanical DataTerminals: Axial Leads, Solderable per MIL-STD-202, Method 208 Polarity: Cathode Band or Cathode Notch Marking:Unidirectional – Device Code and Cathode Band Bidirectional – Device Code OnlyMaximum Ratings and Electrical Characteristics@T A =25°C unless otherwise specifiedCharacteristicSymbol ValueUnit Peak Pulse Power Dissipation at T A = 25°C (Note 1, 2, 5) Figure 3P PPM 1500 MinimumW Peak Forward Surge Current (Note 3)I FSM 200A Peak Pulse Current on 10/1000µS Waveform (Note 1) Figure 1I PPM See Table 1A Steady State Power Dissipation (Note 2, 4)P M(AV) 5.0W Operating and Storage Temperature RangeT j , T STG-65 to +175°CNote: 1. Non-repetitive current pulse, per Figure 1 and derated above T A = 25°C per Figure 4.2. Mounted on 40mm 2 copper pad.3. 8.3ms single half sine-wave duty cycle = 4 pulses per minutes maximum.4. Lead temperature at 75°C = T L .5. Peak pulse power waveform is 10/1000µS.!!!!!!!Weight: 1.20 grams (approx.)!94.085.57.0211.4510.513.4 1.5KE440CA1.5KE400CA 1.5KE350A 1.5KE220CA 1.5KE170CA 1.5KE150A 1.5KE82CA (uA)R RMW RMW@V leakage Reverse CurrentPulse Peak (A)Vc(V)(mA)BR MAX CurrentMax.BR MIN @I Min.Volgtage Breakdown (V)(BI)(Uni)Voltage Stand-Off Reverse Maximum Clamping V T PP(V)V @I Volgtage Breakdown Test (V)V T Volgtage @I PP 1.5KE62CA 1.5KE56CA 1.5KE51CA 1.5KE47CA 1.5KE43CA 1.5KE39CA 1.5KE36CA 1.5KE33CA 1.5KE30CA 1.5KE27CA 1.5KE24CA 1.5KE22CA 1.5KE20CA 1.5KE18CA 1.5KE16CA 1.5KE15CA 1.5KE13CA 1.5KE12CA 1.5KE11CA 1.5KE10CA 1.5KE9.1CA 1.5KE8.2CA 1.5KE7.5CA 1.5KE6.8CA 1.5KE6.8A 1.5KE7.5A 1.5KE8.2A 1.5KE9.1A 1.5KE10A 1.5KE11A 1.5KE12A 1.5KE13A 1.5KE15A 1.5KE16A 1.5KE18A 1.5KE20A 1.5KE22A 1.5KE24A 1.5KE27A 1.5KE30A 1.5KE33A 1.5KE36A 1.5KE39A 1.5KE43A1.5KE47A 1.5KE51A 1.5KE56A 1.5KE300CA 1.5KE250CA 1.5KE200CA 1.5KE180CA 1.5KE160CA 1.5KE150CA 1.5KE130CA 1.5KE120CA 1.5KE110CA 1.5KE100CA 1.5KE91CA 1.5KE75CA 1.5KE68CA 1.5KE62A 1.5KE68A 1.5KE75A 1.5KE82A 1.5KE91A 1.5KE100A 1.5KE110A 1.5KE120A 1.5KE130A 1.5KE160A 1.5KE170A 1.5KE180A 1.5KE200A 1.5KE220A 1.5KE250A 1.5KE300A 1.5KE400A 1.5KE440A1.5KE350CA 5.80 6.45 7.14 10 144.8 1000.06.407.13 7.88 10 11.3 134.5 500.0 7.79 8.61 10 12.1 125.6 200.0 7.78 8.65 9.55 1.0 113.4 50.0 8.55 9.50 10.5 1.0 14.5 104.8 10.0 9.40 10.11.6 1.0 15.6 97.4 5.0 10.212.6 1.0 16.7 91.0 5.011.1 12.4 13.7 1.0 18.2 83.5 5.0 12.8 14.3 15.8 1.0 21.2 71.75.013.615.2 16.8 1.0 22.5 67.6 5.0 15.3 17.1 18.9 1.0 25.2 60.3 5.0 17.1 19.0 21.0 1.0 27.7 54.9 5.0 18.820.923.1 1.0 30.6 49.7 5.020.5 22.8 25.2 1.0 33.2 45.8 5.023.1 25.7 28.4 1.0 37.5 40.5 5.0 25.6 28.5 31.5 1.0 41.4 36.7 5.0 28.2 31.4 34.7 1.0 45.7 33.3 5.030.8 34.2 37.8 1.0 49.9 30.5 5.033.3 37.1 41.0 1.0 53.9 28.2 5.0 36.8 40.9 45.2 1.0 59.3 25.6 5.0 40.2 44.7 49.4 1.0 64.8 23.5 5.0 43.648.553.6 1.0 70.1 21.7 5.047.8 53.2 58.8 1.0 77.0 19.7 5.053.0 58.9 65.1 1.0 85.0 17.9 5.058.1 64.6 71.4 1.0 92.0 16.5 5.0 64.1 71.3 78.8 1.0 103 14.8 5.0 70.1 77.9 86.1 1.0 113 13.5 5.0 77.8 86.5 95.5 1.0 125 12.2 5.095.0 105 1.0 137 11.1 5.0105 116 1.0 152 10.0 5.0102 114 126 1.0 165 9.2 5.0 111 124 137 1.0 179 8.5 5.0128 143 158 1.0 207 7.3 5.0136 152 168 1.0 219 6.9 5.0 145 162 179 1.0 234 6.5 5.0 154 171 189 1.0 246 6.2 5.0 171 190 210 1.0 274 5.5 5.0 185 209 231 1.0 328 4.6 5.0 214 237 263 1.0 344 4.4 5.0256 285 315 1.0 414 3.7 5.0300 333 368 1.0 482 3.2 5.0 342 380 420 1.0 548 2.8 5.0 376 418 462 1.0 600 2.5 5.0TYPE255075100125150175200100755025T ,AMBIENT TEMPERATURE (°C)Fig.4Pulse Derating CurveA P K P U L S E D E R A T I N G (%P K P W R O R C U R R E N T )25507510012515017520002.55.0T ,LEAD TEMPERATURE (°C)Fig.5,Steady State Power DeratingLP ,S T E A D Y S T A T E P O W E R D I S S I P A T I O N (W )d 0.11.0T ,PULSE WIDTH (µs)Fig.3Pulse Rating Curvep 0.1101001.010100100010000P ,P E A K P U L S E P O W E R (k W )P 0123I ,P E A K P U L S E C U R R E N T (%)P p pt,TIME (ms)Fig.1Pulse Waveform110100100010100100010,000V ,REVERSE STANDOFF VOLTAGE (V)Fig.2Typical Junction CapacitanceRWM C ,C A P A C I T A N C E (p F )j。

POWER: 1500Wa t VOLTAGE RANGE: 6.8 - 440 VAXIAL LEADED TRANSIENT VOLTAGE SUPPRESS DIODE1.5KE6.8A(CA) - 1.5KE440A(CA)6.8V – 440V Standoff VoltageCase: JEDEC DO-201AD Molded Plastic FeaturesGlass Passivated Die Construction Uni- and Bi-Directional Versions Available Excellent Clamping Capability Fast Response TimePlastic Case Material has UL FlammabilityMechanical DataTerminals: Axial Leads, Solderable per MIL-STD-202, Method 208 Polarity: Cathode Band or Cathode Notch Marking:Unidirectional – Device Code and Cathode Band Bidirectional – Device Code OnlyMaximum Ratings and Electrical Characteristics@T A =25°C unless otherwise specifiedCharacteristicSymbol ValueUnit Peak Pulse Power Dissipation at T A = 25°C (Note 1, 2, 5) Figure 3P PPM 1500 MinimumW Peak Forward Surge Current (Note 3)I FSM 200A Peak Pulse Current on 10/1000µS Waveform (Note 1) Figure 1I PPM See Table 1A Steady State Power Dissipation (Note 2, 4)P M(AV) 5.0W Operating and Storage Temperature RangeT j , T STG-65 to +175°CNote: 1. Non-repetitive current pulse, per Figure 1 and derated above T A = 25°C per Figure 4.2. Mounted on 40mm 2 copper pad.3. 8.3ms single half sine-wave duty cycle = 4 pulses per minutes maximum.4. Lead temperature at 75°C = T L .5. Peak pulse power waveform is 10/1000µS.!!!!!!!Weight: 1.20 grams (approx.)!94.085.57.0211.4510.513.4 1.5KE440CA1.5KE400CA 1.5KE350A 1.5KE220CA 1.5KE170CA 1.5KE150A 1.5KE82CA (uA)R RMW RMW@V leakage Reverse CurrentPulse Peak (A)Vc(V)(mA)BR MAX CurrentMax.BR MIN @I Min.Volgtage Breakdown (V)(BI)(Uni)Voltage Stand-Off Reverse Maximum Clamping V T PP(V)V @I Volgtage Breakdown Test (V)V T Volgtage @I PP 1.5KE62CA 1.5KE56CA 1.5KE51CA 1.5KE47CA 1.5KE43CA 1.5KE39CA 1.5KE36CA 1.5KE33CA 1.5KE30CA 1.5KE27CA 1.5KE24CA 1.5KE22CA 1.5KE20CA 1.5KE18CA 1.5KE16CA 1.5KE15CA 1.5KE13CA 1.5KE12CA 1.5KE11CA 1.5KE10CA 1.5KE9.1CA 1.5KE8.2CA 1.5KE7.5CA 1.5KE6.8CA 1.5KE6.8A 1.5KE7.5A 1.5KE8.2A 1.5KE9.1A 1.5KE10A 1.5KE11A 1.5KE12A 1.5KE13A 1.5KE15A 1.5KE16A 1.5KE18A 1.5KE20A 1.5KE22A 1.5KE24A 1.5KE27A 1.5KE30A 1.5KE33A 1.5KE36A 1.5KE39A1.5KE43A 1.5KE47A 1.5KE51A 1.5KE56A 1.5KE300CA 1.5KE250CA 1.5KE200CA 1.5KE180CA 1.5KE160CA 1.5KE150CA 1.5KE130CA 1.5KE120CA 1.5KE110CA 1.5KE100CA 1.5KE91CA 1.5KE75CA 1.5KE68CA 1.5KE62A 1.5KE68A 1.5KE75A 1.5KE82A 1.5KE91A 1.5KE100A 1.5KE110A 1.5KE120A 1.5KE130A 1.5KE160A 1.5KE170A 1.5KE180A 1.5KE200A 1.5KE220A 1.5KE250A 1.5KE300A 1.5KE400A 1.5KE440A1.5KE350CA 5.80 6.45 7.14 10 144.8 1000.06.407.13 7.88 10 11.3 134.5 500.0 7.79 8.61 10 12.1 125.6 200.0 7.78 8.65 9.55 1.0 113.4 50.0 8.55 9.50 10.5 1.0 14.5 104.8 10.0 9.40 10.11.6 1.0 15.6 97.4 5.0 10.212.6 1.0 16.7 91.0 5.011.1 12.4 13.7 1.0 18.2 83.5 5.0 12.8 14.3 15.8 1.0 21.2 71.75.013.615.2 16.8 1.0 22.5 67.6 5.0 15.3 17.1 18.9 1.0 25.2 60.3 5.0 17.1 19.0 21.0 1.0 27.7 54.9 5.0 18.820.923.1 1.0 30.6 49.7 5.020.5 22.8 25.2 1.0 33.2 45.8 5.023.1 25.7 28.4 1.0 37.5 40.5 5.0 25.6 28.5 31.5 1.0 41.4 36.7 5.0 28.2 31.4 34.7 1.0 45.7 33.3 5.030.8 34.2 37.8 1.0 49.9 30.5 5.033.3 37.1 41.0 1.0 53.9 28.2 5.0 36.8 40.9 45.2 1.0 59.3 25.6 5.0 40.2 44.7 49.4 1.0 64.8 23.5 5.0 43.648.553.6 1.0 70.1 21.7 5.047.8 53.2 58.8 1.0 77.0 19.7 5.053.0 58.9 65.1 1.0 85.0 17.9 5.058.1 64.6 71.4 1.0 92.0 16.5 5.0 64.1 71.3 78.8 1.0 103 14.8 5.0 70.1 77.9 86.1 1.0 113 13.5 5.0 77.8 86.5 95.5 1.0 125 12.2 5.095.0 105 1.0 137 11.1 5.0105 116 1.0 152 10.0 5.0102 114 126 1.0 165 9.2 5.0 111 124 137 1.0 179 8.5 5.0128 143 158 1.0 207 7.3 5.0136 152 168 1.0 219 6.9 5.0 145 162 179 1.0 234 6.5 5.0 154 171 189 1.0 246 6.2 5.0 171 190 210 1.0 274 5.5 5.0 185 209 231 1.0 328 4.6 5.0 214 237 263 1.0 344 4.4 5.0256 285 315 1.0 414 3.7 5.0300 333 368 1.0 482 3.2 5.0 342 380 420 1.0 548 2.8 5.0 376 418 462 1.0 600 2.5 5.0TYPE255075100125150175200100755025T ,AMBIENT TEMPERATURE (°C)Fig.4Pulse Derating CurveA P K P U L S E D E R A T I N G (%P K P W R O R C U R R E N T )25507510012515017520002.55.0T ,LEAD TEMPERATURE (°C)Fig.5,Steady State Power DeratingLP ,S T E A D Y S T A T E P O W E R D I S S I P A T I O N (W )d 0.11.0T ,PULSE WIDTH (µs)Fig.3Pulse Rating Curvep 0.1101001.010100100010000P ,P E A K P U L S E P O W E R (k W )P 0123I ,P E A K P U L S E C U R R E N T (%)P p pt,TIME (ms)Fig.1Pulse Waveform110100100010100100010,000V ,REVERSE STANDOFF VOLTAGE (V)Fig.2Typical Junction CapacitanceRWM C ,C A P A C I T A N C E (p F )j。

Seven Segment Displays—10mm (0.40 inch), 10mm Slim Font,10.9mm (0.43 inch), 14.2mm (0.56inch),13mm Slim FontReliability DataDescriptionThe following cumulative test results have been obtained from testing performed at HP Optoelec-tronics Division in accordance with the latest revision of MIL- STD-883.Hewlett-Packard tests parts at the absolute maximum rated condi-tions recommended for the device. The actual performance you obtain from HP parts depends on the electrical and environmen-tal characteristics of your applica-Point Typical PerformanceStress Test Total DeviceUnits Total Failure Rate ColorsConditionsHoursTestedFailedMTBF(% /1 K Hours)HER T A = 55°C, I F = 30 mA 420,000630420,000≤0.23 %AlGaAs T A = 55°C, I F = 30 mA 378,000630378,000≤0.26 %Green T A = 55°C, I F = 30 mA 252,000840252,000≤0.40 %Orange T A = 55°C, I F = 30 mA 147,000210147,000≤0.26 %YellowT A = 55°C, I F = 20 mA147,00021147,000≤0.26 %Table 1. Life TestsDemonstrated PerformanceFailure Rate PredictionThe failure rate of semiconductor devices is determined by the junction temperature of thedevice. The relationship between ambient temperature and actual junction temperature is given by the following:T J (°C) = T A (°C) + θJA P AVG where T A = ambient temperature in °CθJA = thermal resistance of junction-to-ambient in °C/wattHDSP-Exxx, HDSP-Fxxx,HDSP-Gxxx, HDSP- Hxxx,HDSP-Kxxx, HDSP-3xxx,HDSP-4xxx, HDSP-5xxx,HDSP-6xxx, HDSP-7xxxtion but will probably be better than the performance outlined in Table 1.P AVG = average power dissipated in wattsThe estimated MTBF and failure rate at temperatures lower than the actual stress temperature can be determined by using anArrhenius model for temperature acceleration. Results of such calculations are shown in the table below using an activation energy of 0.43 eV (reference MIL-HDBK-217).Table 2.Point Typical Performance in Time[2]Performance[1] in Time(90%Confidence) Ambient Temp.Junction Temp.Failure Rate Failure Rate I F(°C)(°C)MTBF[1](%/1K Hours)MTBF[2](%/1K Hours) 3085115457,0000.219%118,0000.850% 751056430000.156%165,0000.605%6595920,0000.109%237,0000.423%55851,344,0000.074%346,0000.289%45752,006,0000.050%516,0000.194%35653,066,0000.033%788,0000.127%25554,809,0000.021%1,236,0000.081% Notes:1.The point typical MTBF (which represents 60% confidence level) is the total device hours divided by the number offailures. In the case of zero failures, one failure is assumed for this calculation.2.The 90% confidence MTBF represents the minimum level of reliability performance which is expected from 90% of allsamples. This confidence interval is based on the statistics of the distribution of failures. The assumed distribution of failures is exponential. This particular distribution is commonly used in describing useful life failures. Refer toMIL-STD-690B for details on this methodology.3. A failure is any LED which does not emit light.Example of Failure Rate Calculation:Assume a device operating 8 hours/day, 5 days a week. The utilization factor, given 168 hours/week is:(8 hours/day) x (5 days/week) ÷ (168 hours/week) = 0.25The point failure rate per year (8760 hours) at 25°C ambient temperature is:(0.021%/1K hours) x 0.25 x (8760 hours/year) = 0.045% per yearSimilarly, 90% confidence level failure rate per year at 25°C:(0.081%/1K hours) x 0.25 x (8760 hours/year) = 0.177% per yearTable 3. Environmental TestsUnits Units Test Name Reference Test Conditions Tested Failed Solder Heat Resistance MIL-STD-883 Method 2003260°C, 3 seconds100 Temperature Cycle MIL-STD-883 Method 1010-55°C to 100°C, 15 min. dwell,260015 min. transfer, 20 cyclesHumidity Storage JIS C 7021 Method B-1185°C, 85% RH, 168 Hours2520Solderability MIL-STD-883 Method 200316 Hours steam aging followed by100solder dip at 260°C for 5 secondsSalt Atmosphere MIL-STD-883 Method 100935°C, 24 Hours100Table 4. Mechanical TestsUnits Units Test Name Reference Test Conditions Tested Failed Terminal Strength MIL-STD-883 Method 2004 Cond. A 1 lb. for 30 sec.110 Lead Strength MIL-STD-883 Method 2004 Cond. B 3 X 90 degree bend, 8 oz.110 Vibration Variable MIL-STD-883 Method 2007 2 Hours for each X, Y, Z axis at220 Frequency20 Gs, 10 to 2k Hz; 20 min. sweep/go/ledFor technical assistance or the location of your nearest Hewlett-Packard sales office, distributor or representative call: Americas/Canada: 1-800-235-0312 or 408-654-8675 • Far East/Australasia: Call your local HP sales office. Japan: (81 3) 3335-8152 • Europe: Call your local HP sales office. • Data subject to change. • Copyright © 1999 Hewlett-Packard Co.5968-7071E (8/99)。

GS9001EDH CoprocessorGENLINX™GENNUM CORPORATION P.O. Box 489, Stn A, Burlington, Ontario, Canada L7R 3Y3 tel. (905) 632-2996 fax: (905) 632-5946 Japan Branch: A-302, Miyamae Village, 2-10-42, Miyamae, Suginami-ku, Tokyo 168, Japan tel. (03) 3247-8838 fax. (03) 3247-8839Document No. 521 - 38 - 02DATA SHEETControlLogicCompareErroredFieldCounterSerial Clock& DataDevice AddressAncillaryCheck Error Flags&FormatCRCExtractionTransmit/ReceiveData InClockReset CRCCalculationAutomaticStandardsDetectionDataOutInterruptTransmissionError FlagsHSync, VBlank,Ancillary Data, TRS-ID,TRS Absence IndicationField Signals/Standard IndicationMuxI CInterface2APPLICATIONSThe GS9001 implements error detection and handling (EDH)functions according to SMPTE RP165. Interfacing to theparallel port of either the GS9002/GS9022 serial digitalencoders or GS9000 decoder, the GS9001 provides EDHinsertion and extraction for 4ƒsc NTSC, 4ƒsc PAL and 4:2:2component standards up to 18 MHz luminance sampling.The GS9001 also generates timing signals such as horizontalsync, vertical blanking, field ID and ancillary data identification.The ancillary data identification aids the extraction of ancillarydata from the data stream.The device has an I2C (Inter-Integrated Circuit) serial interfacebus for communication with a microcontroller. The devicecan be programmed as an I2C slave transmitter or receiver bythe microcontroller. This interface can be used to read thecomplete set of error flags and override the flag status prior tore-transmission. The device automatically determines theoperating standard which can be overridden through the I2Cinterface. Timing signals and transmission error flags are alsoavailable on dedicated outputs.FEATURES DESCRIPTION• 4ƒsc, 4:2:2 and 360 Mb/s serial digital interfaces• Source and destination equipment• Distribution equipment• Test equipment•Error Detection and Handling (EDH) according toSMPTE RP165•EDH insertion and extraction in one device•autostandard operation•I2C Serial communications interface for access toerror flags and device configuration•available stand alone mode•error flags available on dedicated outputs•field, vertical, horizontal timing signals, ancillary dataindication and TRS indication•video standard and invalid data indication•reserved words readable and writeable•21 bit Errored Fields counter•passthrough mode to bypass EDH packet insertion•true 8-bit compatibility•40 MHz operating frequencyPart Number Package TemperatureGS9001-CQM44 PQFP O°C to 70°CORDERING INFORMATIONBLOCK DIAGRAMRevision Date: February 1996I2C is a registered Trademark of Philips2521 - 38 - 02ELECTRICAL CHARACTERISTICS DC Parameters @ V DD = 5V, V SS = 0V, T A = 0o C - 70o C unless otherwise shown Parameter Symbol Conditions Min Typ Max Units Supply Voltage V S Operating range 4.755.00 5.25V Supply Current I S Operating range -85100mA TTL Compatible V IHmin T A =25o C 2.00--V CMOS Inputs V ILmax T A =25o C --0.80V Input Leakage I IN V IN =V DD or V SS --±10µA TTL Compatible V OHmin T A =25o C 2.40 4.50-V CMOS OutputsV OLmax T A =25o C -0.200.40V I OL T A =25o C ---4mA I OHT A =25o C--4mAAC Parameters @ V DD = 5V, V SS = 0V, T A = 0o C - 70o C unless otherwise shown ParameterSymbol Conditions Min Typ Max Units Input Clock Frequency ƒclk --40MHz Input & Output Data Rates ƒdata--40Mb/sInput Data & Clock Rise Time t ir -1-ns Setup Time t set T A =25o C2--ns Hold Timet hold 2--ns Input Clock to Output data t P C L < 30pF 3 5.58.5(1)ns Output data rise/fall time t or T A =25o C 234ns SCL Clock FrequencyƒSCL-100400(2)kHz(1)T A = 70°c, V DD = 4.75V(2)Determined by I 2C bus specificationABSOLUTE MAXIMUM RATINGSPARAMETERVALUE/UNITSSupply Voltage (V s =V DD -V ss)7VInput Voltage Range (any input)-0.3 to (VDD+0.3) V DC Input Current (any one input)±10 µAPower Dissipation800 mW Operating Temperature Range 0°C to 70°C Storage Temperature Range-65°C to +150°CLead Temperature (soldering, 10 seconds)260°CCAUTIONELECTROSTATIC SENSITIVE DEVICESDO NOT OPEN PACKAGES OR HANDLE EXCEPT AT A STATIC-FREE WORKSTATION3521 - 38 - 02DIN9(MSB)(MSB)(LSB)(LSB)DIN8DIN7DIN6DIN5DIN4DIN3DIN2DIN1DIN0 CLKDOUT9DOUT8DOUT7DOUT6DOUT5DOUT4DOUT3DOUT2DOUT1DOUT0INTERRUPTV D DV D DV S SF 2/N T S C _P A LN O T R SF 0/H D 1F 1/D 1_D 2V B L A N K H S Y N CF L 0A N C _D A T AF L 1F I E L D /S T D R /TA 0A 1S C LV S SS 0S 1R S T N S D AFig. 1 GS9001 EDH Coprocessor Pin ConnectionsInput S1 Input S0Output FL1Output FL000EDA Full Field EDH Full Field 01UES (See Note) EDH Active Picture 10EDA Ancillary EDH Ancillary 11IDA (See Note)IDH (See Note)NOTE:The UES, IDH and IDA flags that appear on pins FL0 and FL1 as shown in Table 2, represent the sum of each corresponding flag for active picture, full field and ancillary. UES indication can also be used to identify the absence of EDH implementation in the upstream equipment.Table 1. Selection of Field and Video standard signals on F2, F1, F0 pinsTable 2. Selection of Error status flags to displayInput Output F2 Output F1Output F0Field/Std 0 NTSC (0) / PAL (1)D1 (0) / D2 (1)*13.5 MHz Y (0) / 18 MHz Y (1) 1Field Bit 2 Field Bit 1Field Bit 0*D1: 4:2:2 samplingD2: 4ƒsc samplingPIN NO. SYMBOL TYPE DESCRIPTION1-10DIN[9..0]I Parallel digital video data inputs11CLK I Parallel clock input.12R/T I Receive or Transmit mode select. High - CRC extraction, recalculation, comparison, errorindication, re-insertion. Low - CRC calculation, insertion, clears error flags13FIELD/STD I Field or Standard indication select. High - Field signals on F0, F1, F2. Low - Standardindication on F0, F1,F2. (Refer to Table 1)14,15S0, S1I Error flag select inputs. Select type of error flag to output on FL0, FL1. (Refer to Table 2) 16RSTN I Master Reset. Active low input, which provides option to initialise internal circuitry. TheGS9001 contains power on reset circuitry that automatically initialises all internalstates including the I2C Interface.19,20A0,A1I Device address select pins for I2C interface bus. (Refer to Table 3)21SCL I Serial Clock for I2C Interface bus. SCL and SDA must be connected to GND if there is noI2C interface connected to the device.22SDA I/O Serial Data for I2C Interface bus.23INTERRUPT O Programmable interrupt for error flag indication. Active low, open drain output. Interruptcan be made sensitive to specific or all error flags (described in I2C WRITE formatsection). Default is sensitive to all error flags. This output stays active until a word is readfrom the device.24-33DOUT[0..9]O Parallel digital video data outputs34NO TRS O Indicates presence of invalid input data, containing no timing reference signal (TRS).Active high output which signals absence of seven consecutive valid TRSs in theincoming data. Returns to low state after seven consecutive valid TRSs occur. A validinput CLK must be present for this to operate.35ANC DATA O Ancillary data presence indication. Active high output, indicates data presence fromANC data header word to checksum word. Can be programmed through the I2Cinterface to also indicate presence of TRS-ID (3FF,000,000) blocks. In this mode, outputstays high for 5 words during composite video TRS-ID and 4 words during componentEAV, SAV. In stand alone operation mode without I2C Interface, this feature can beforced on ANC DATA pin by selecting address 0,1 on A1,A0 pins. (NOTE: SCL and SDAmust be connected to GND when I2C Interface is not used)36HSYNC O Horizontal sync indication. Active high, extends from EAV to SAV for component video,indicates TRS-ID location for composite video.37V BLANK O Vertical blanking interval indication. Active high during this period.40-42F0/HD1O Field or standard indication pins. Field signals output when FIELD/STD pin is high, Video F1/D1_D2,standard when FIELD/STD is low.F2/NTSC_PAL43,44FL1,FL0O Error Flag Status. Active high outputs programmed via S0, S1 to indicate varioustransmission and hardware related error flags. Output flags stay active for one field. 17,39VDDP Power Supply. Most positive power supply connection. (+5V)18,38VSS P Power Supply. Most negative power supply connection. (GND)GS9001 PIN DESCRIPTIONS4 521 - 38 - 02GS9001 - DETAILED DEVICE DESCRIPTION.The GS9001 contains all functional blocks required to implement Error Detection and Handling according to SMPTE RP165. It also provides Field, Vertical, and Horizontal timing information as well as Ancillary Data and TRS-ID indication. The device offers standard independent operation and an I2C serial communications interface to allow reading/writing of error flags, device configuration and video standards format. The device can also be operated in stand alone mode without the I2C interface with error flags available on dedicated output pins. In all modes, the device latency is four clock cycles.Automatic Standards DetectionThis block analyses the incoming 8 or 10 bit data to determine whether it is component or composite. In total, six standards are automatically detected. For composite data conforming to SMPTE 259M, the Timing Reference Signal and Identification (TRS-ID) packet contains line and field information used to detect the format. For component data conforming to SMPTE 125M, the TRS-ID packets for End of Active Video (EAV)and Start of Active Video (SAV) are used to determine the format. The TRS information is then used to determine whether the composite signal is NTSC or PAL, or whether the component signal has 13.5 MHz or 18 MHz luminance samples.Noise immunity has also been included, to ensure that momentary signal interruption does not affect the auto-standards detection function. This built in noise immunity results in delayed switching time between standards. Delays range from as little as eight lines when switching between component standards to as much as four frames when switching between PAL and NTSC composite standards. The latter delay is due to the method used to differentiate PAL and NTSC, which counts the number of lines per frame and requires four sequential frames before switching standards. Manual override of the auto-standard feature is provided via the I2C interface, for applications where the standards recognition delay is intolerable. Standards indication is provided on multiplexed output pins or via the I2C interface.Control LogicThe control logic coordinates operation and extracts timing signals such as vertical blanking, horizontal sync, field ID, ancillary data indication and TRS-ID indication.The vertical blanking interval signal is active during the digital vertical blanking period for all signal formats. The horizontal sync signal is provided as a pulse with a duration of one clock period for every TRS-ID occurrence in composite video. For component video, the horizontal sync is a positive going pulse which starts at EAV and ends at SAV. Three field ID bits (pins 40, 41, 42) indicate the two fields for component video standards, the four colour fields for composite NTSC or eight colour fields for composite PAL.The ancillary data indication allows external circuitry to identify ancillary data in the data stream for extraction or masking.The presence of ancillary data is indicated by a logic high that extends from the Data ID word to the Checksum word of each ancillary packet. These timing signals are available ondedicated output pins and through the I2C communications interface.The control logic also verifies incoming data validity by checking the occurrence of consecutive TRS-IDs. If the absence of seven consecutive TRS-IDs is detected, a “NO TRS” flag is output on pin 34. This flag is reset once seven consecutive TRS-IDs occur.CRC CalculationA cyclic redundancy check (CRC) is calculated for each video field according to the CRC-CCITT polynomial X16+X12+X5+1. Separate CRCs are calculated for active picture and full field to provide an indication that active video is still intact despite possible full field errors. This allows the user to distinguish between different classes of data errors, which yields the best compromise in error detection for all types of equipment. In order to provide compatibility between 8 bit and 10 bit systems, all data words with values between 3FCHand 3FFHinclusive,are recoded as 3FFHat the input of the polynomial generator. Start and end points for the CRC calculation are as defined in RP165 and depend on the standard and check field being calculated. Calculated CRC words can be read through the I2C interface.CRC ComparisonThe GS9001 can be configured for transmit or receive mode. In receive mode, the calculated CRC is checked against the incoming CRC embedded in the error data packet. Any mismatch will generate status error flags to indicate transmission related error flags in either active picture, full field or both. The error flags resulting from CRC mismatch are full field error detected here (EDH) and active picture EDH.Ancillary Checksum VerificationThe ancillary data checksums are also verified to ensure data integrity. Ancillary data is preceded by the Data Header, Data ID, Block Number and Data Count. The Data Count shows the number of ancillary words contained in each ancillary data packet. A checksum is calculated for each incoming ancillary data packet and compared with the transmitted checksum. Any difference is reported as an error via the ancillary EDH error flag. A separate ANC EXT error flag is also provided to indicate corruption of the EDH data packet.Error Flags and FormattingThis block performs the functions of error flag reporting and recoding, EDH data packet construction, programmable interrupt generation and interface with the I2C communication block.5521 - 38 - 026521 - 38 - 027.UES for AP, FF and AncillaryUES i s s e t i f th e i n c o m i n g UES i s s e t. A l s o,i f th e incoming data does not have an error data packet, this flag is set. This is to inform the down-stream devices that the data being sent has not been previously checked for data errors.In addition to error flag access through the I 2C interface,selected EDH , EDA , IDH , IDA and UES flags are available on two user programmable output pins. Table 2 (on page 3)shows these error flags and the corresponding input addresses.These flags are available for applications where access to the I 2C interface via microcontroller is not possible or cost effective.These flags give the user immediate warning of transmission related errors either locally or from upstream equipment.In situations where the upstream equipment does not support EDH, a new error data packet is inserted in the data stream as specified in RP165. In this case the UES flag is set for active picture, full field and ancillary data. The EDH , EDA and IDA flags are reset for active picture and full field. For ancillary data, the EDH flag is still reported if there are any checksum errors and the EDA and IDA flags are reset. This is done since the checksums for ancillary data may still be valid without the presence of an error data packet in the data stream.Transmit vs Receive ModesThe preceding description refers to the device in Receive mode. In Transmit mode, valid CRC-check words for active picture and full field are inserted and all error flags are reset.Flag MaskingAny of the fifteen error flags can be set/reset or made transparent using the I 2C interface. Transparent flags are updated on the occurrence of data errors. Flag masking can be done only when the device is in the receive mode. During transmit mode all error flags are reset. The transmit mode would be used for source equipment and equipment that modifies or processes the data before re-serializing.Programmable InterruptThe interrupt output can be made sensitive to any specific or all error flags. This function is programmed using the sensitivity flags SANC, SFF and SAP as described in the section for I 2C interface WRITE format.Errored Field CounterThis 21 bit counter can be used to count the number of fields in which data errors occur. The same set of sensitivity flags used for the programmable interrupt, also control the incrementing of this counter. This counter can be made to increment on the occurrence of any specific type of error flag in a field.Error ReportingError reporting is meant to provide the information necessary to allow system diagnostics. There are fifteen error flags in total, which are used to identify specific error types. All flags are available to be read or overwritten via the I 2C interface.The definition of these flags and an explanation of how the device handles these flags are described below.The acronyms used are:EDA E rror D etected A lreadyEDH E rror D etected H ere IDH I nternal device error D etected H ere IDA I nternal device error D etected A lready UES U nknown E rror S tatus AP A ctive P icture FF F ull F ield1.EDH for AP and FFIf the incoming CRC checkword is different from the calculated CRC checkword, the EDH flag is set.2.EDH for AncillaryIf the checksum for the ancillary data does not match the calculated checksum, this flag is set.3.EDA for AP and FFThis flag is generated by summing the incoming EDA flag with the product of the incoming EDH fl ag a n d t h e v a li d C R C b it. A s a result, if the incoming EDH flag is set and the EDA flag has not been set, the EDH flag will be recoded to EDA and then cleared. If the incoming CRC is invalid, then the outgoing EDA flag will be determined by the incoming EDA flag only. This is to support devices in the transmission path that do not generate valid CRC,yet pass only the EDA flags.4.EDA for AncillaryThis flag is the sum of the in-coming EDH and EDA flags for ancillary data.5.IDH for AP, FF and AncillaryThese flags are set by the user through the I 2C serial interface. They can be used to indicate any internal device errors in the vicinity of the device.Examples could be local hardware errors such as a RAM failure or a system diagnostics failure on power-up.6.IDA for AP, FF and AncillaryThis flag is the sum of the incoming IDH and IDA flags for AP, FF and ancillary data.7521 - 38 - 02NOTE:If an I 2C interface is not used, address 0, 1 will force TRS-ID indication on the ancillary data pin. This is to facilitate applications in which TRS-ID is desired, but an I 2C interface is not used. In this case, the SCL clock line must be connected to the most negative supply.During the stand-alone mode of operation, flag masking,video standard override and programmable interrupt features are disabled. The user can still monitor the video standard and the error flags through dedicated pins as shown in Table 2.EDH Passthrough ModeAn EDH passthrough mode is available to aid in system diagnostics. This mode is selected by address 1,0 on A1, A0pins. In this mode, the GS9001 will not insert a new EDH packet into the data stream. Input data is bypassed to output without modification. Error flag status available through the I 2C interface and output pins, is now invalid. However, valid CRC words can be read through the I 2C interface every field,for a static picture.The counter can be programmed either to clear automatically when the counter status is read via the interface, or to clear when forced through the interface.I 2C Serial Communications InterfaceThe serial communications interface allows access to all error flags and other internal programmable functions. The Inter-Integrated Circuit (I 2C) protocol is used. For information on the GS9001 I 2C protocol, refer to Document 521 - 59 "Using the GS9001 EDH Coprocessor".The slave addresses for the I 2C interface are given in Table 3.Data formats for the I 2C interface READ and WRITE operations are given in Tables 4 and 5.I 2C Address is 00011A 1 A 0A1A0Function00Available Device Address 01Available Device Address 10EDH Passthrough Mode 11Test ModeTable 3. I 2C Slave AddressesTable 4. I2C - Interface: Data Format for READ 15 WordsWord Databits CommentsAddress B7B6B5B4B3B2B1B01AP AP AP ANC ANC ANC ANC ANC15 Error Flags (according to IDH EDA EDH UES IDA IDH EDA EDH SMPTE RP165) see notebelow for flag ANC EXT 2ANC FF FF FF FF FF AP APEXT UES IDA IDH EDA EDH UES IDA3Error counter NTSC HD1D1Video standard & error counter b20b19b18b17b16PAL D1D24Error counter Error counter 21 bits wide b15b14b13b12b11b10b9b85Error counterb7b6b5b4b3b2b1b06Active Picture CRC Active picture CRC b15b14b13b12b11b10b9b816 bits wide7Active Picture CRCb7b6b5b4b3b2b1b08Full Field CRC Full Field CRC 16 bits wide b15b14b13b12b11b10b9b89Full Field CRCb7b6b5b4b3b2b1b010RW2RW2RW1RW1RW1RW1RW1RW1Bits 2 to 7 for reserved b3b2b7b6b5b4b3b2words 1 to 711RW3RW3RW3RW3RW2RW2RW2RW2b5b4b3b2b7b6b5b4Example:Bit number 4 of reserved 12RW4RW4RW4RW4RW4RW4RW3RW3word 2 is denoted as b7b6b5b4b3b2b7b6RW2 b413RW6RW6RW5RW5RW5RW5RW5RW5b3b2b7b6b5b4b3b214RW7RW7RW7RW7RW6RW6RW6RW6b5b4b3b2b7b6b5b415000000RW7RW7b7b6NOTES:The error counter is 21 bits wide and counts the number of fields that had errors. This counter can be made to increment only upon the occurrence of a specific type of flag in a field. This sensitivity is programmable through SANC,SFF & SAPclass of flags (see WRITE section). ANC EXT is a flag defined to indicate any checksum error in the EDH packet.Reserved Words 1 to 7 in an EDH packet are both readable and writable. Only bits 2 to 7 of each reserved wordare available. During Write operation for every reserved word, Even Parity is added as bit 8 and bit 9 is the logical inverse of bit 8. Bits 0 and 1 are zero to maintain compatibility with 8 bit systems.16 bit Active Picture CRC and Full Field CRC words are available for every field, through the I2C interface.8521 - 38 - 02Word Databits CommentsAddress B7B6B5B4B3B2B1B01AP AP AP ANC ANC ANC ANC ANC15 Error Flags (according to IDH EDA EDH UES IDA IDH EDA EDH SMPTE RPI65)2STICKY FF FF FF FF FF AP APFLAGS UES IDA IDH EDA EDH UES IDA3MAP MAP MAP MANC MANC MANC MANC MANC Mask Status for the 15 Error IDH EDA EDH UES IDA IDH EDA EDH Flags (see Note 1)4MASK MFF MFF MFF MFF MFF MAP MAPRW UES IDA IDH EDA EDH UES IDA5SAP SAP SAP SALL SANC SANC SANC SANC Sensitivity Status for the15 IDH EDA EDH UES IDA IDH EDA EDH Error Flags (see Note 2)6AUTO CLR TRS SFF SFF SFF SFF SAPCLR CNT SEL IDA IDH EDA EDH IDA7RW1RW100SEL NTSC HD1D1Standard Select (see Note 3) b3b2STD PAL D1D28RW2RW2RW2RW2RW1RW1RW1RW1Bits 2 to 7 for reserved words b5b4b3b2b7b6b5b4 1 to 7Example: Bit number 4 of 9RW3RW3RW3RW3RW3RW3RW2RW2reserved word 2 is b7b6b5b4b3b2b7b6denoted as RW2 b410RW5RW5RW4RW4RW4RW4RW4RW4b3b2b7b6b5b4b3b211RW6RW6RW6RW6RW5RW5RW5RW5b5b4b3b2b7b6b5b412RW7RW7RW7RW7RW7RW7RW6RW6b7b6b5b4b3b2b7b6NOTES: 1.Mask status is used for flag masking.MASK RW is 1 to overwrite Reserved Words.Bit STICKY FLAGS will make the flags sticky. (Flag stays set until read by I2C interface)2.Sensitivity status defines the interrupt & error counter sensitivity. Please note for UES flag sensitivity, there is onlyone bit which is the SALL UES bit. This covers the UES bit for Ancillary, Active Picture and Full Field classes.3.Bit SEL STD: 1 to overwrite video standard, 0 for auto standard selectionBit NTSC/PAL: 1 for PAL (625/50) standard, 0 for NTSC (525/60) standardBit HD1/D1: 1 for Component 4:2:2 standard with 18Mhz Luminance, 0 for Component 4:2:2 standardwith 13.5 MHz LuminanceBit D1/D2: 1 for 4ƒsc composite standard, 0 for Component 4:2:2 standardBit TRS SEL: 1 to force TRS-ID indication in addition to ancillary data indication on the Ancillary Data pin, (pin 35)0 to force only ancillary indication on the ancillary data pin (pin 35)Bit CLR CNT: 1 to clear the ‘errored field counter’. 0 to let the counter count the errored fieldsBit AUTO CLR: 1 to automatically clear the ‘errored field counter’ after every reading of the counter status through the interface, 0 to disable this automatic clear featureDefault Status: On power-up all bits are set to zero except for the sensitivity flags which are set to one.Stand-Alone Operation:All bits will stay at power-up initial conditions, as described above, when there is no interfaceconnected to the device, except for the bit TRS-SEL, which can be set to one by connecting the A1and A0 pins to 0,1 respectively.Table 5. I2C - Interface: Data Format for WRITE 12 Words9521 - 38 - 0210521 - 38 - 02PARAMETERSYMBOL MIN MAXUNITSMinimum Rest Pulse Duration tr(min)100 - nS External to Internal Reset Delaytr d1-12nS tr d2-3µS Interrupt Delay after RSTNti d-12nSLine 11/272 - Sample 1456 - NTSC (525/60) 4:2:2Line 11/272 - Sample 1936 - NTSC (525/60) 4:2:2,16 x 9Line 11/272 - Sample 806 - NTSC (525/60) 4ƒsc Line 7/320 - Sample 1456 - PAL (625/50) 4:2:2Line 7/320 - Sample 1936 - PAL (625/50) 4:2:2,16 x 9Line 7/320 - Sample 983 - PAL (625/50) 4ƒscINTERRUPTI 2C READAFTER SECOND WORD(Interrrupt is inactive after second word of the I 2C packet is read)Fig. 2c Interrupt TimingReset and Interrupt Characteristics (V CC = 5V, 0°C < T A < 70°C)RSTNV DDINTERNALRESETINTERRUPTRSTNFig. 2b Reset and Interrupt TimingFig. 2a GS9001 Internal Reset CircuitXXX XXX000H 3FF H 2FE H 202H 200H 100HXXX XXX3FF H 000H 200HXXX XXX CLOCKANC_DATAXXX XXXXXX XXX000H 3FF H 2FE H 202H 200H 100HXXX XXX3FF H 000H 200HXXX XXX DATA INDATA OUTANCILLARY_DATATRS_DATA(IF TRS INDICATION IS ENABLED)Fig. 4 Ancillary Data Indication TimingFig. 5 Component Timing SignalsCLOCKHSYNCVBLANKFIELDDON'T CAREDATA INDATA OUTXXXEAV 000H3FF H XXX XXX3FF H 000H SAV XXX XXXXXXXXXXX EAV 000H3FF H XXX XXX3FF H 000H SAV XXX XXXFig. 3 Error Flag TimingOUTPUT DATA STREAMWITH EDH PACKETANCILLARY ERROR FLAGS ACTIVE PICTURE ERROR FLAGS FULL FIELD ERROR FLAGSX DON'T CAREthe last stage prior to serialization and immediately after deserialization.The nature of the EDH error flags and the flexibility of use with an I 2C interface or in stand alone operation, make the GS9001suitable for most system applications.routing equipment.Complete, System-Wide Implementation of EDH Figure 9 shows a typical system implementation using EDH ,where both equipment fault errors and transmission errors occur.PCLK INPUT10 BIT INPUT CLOCKHSYNCFIELDDATA INDATA OUTXXX000H3FF H TRS-ID XXX XXX XXX XXXXXXXXX000H3FF H TRS-ID XXX Fig. 6 Composite Timing SignalsEDH EDA IDAFig. 9Fig. 10These errors result in the transmission error flags EDH and EDA and the non-transmission related flags IDH and IDA .In Figure 9, the AES/EBU audio encoder has generated an error during the audio formatting process and reported an IDH (Internal device error Detected Here) error.The signal from the audio encoder then experiences degradation from a faulty cable, before it reaches the router.In this case, the cable is marginal and is producing random infrequent errors. A GS9001 device in the router flags these errors as EDH (Error Detected Here) for Active Picture, Full Field or both. Incoming IDH flags are also recoded as IDA(Internal device error Detected Already).UES IDA EDA EDH The next device in the chain is a distribution amplifier (DA)which is receiving its input from the router. The GS9001 device in the DA will recode the incoming EDH flag as EDA (Error Detected Already) and pass the IDA flag.An additional transmission error occurs between the DA and the production switcher which is flagged as EDH . The GS9001in the production switcher now has a list of error flags that can be reported locally or through a communications interface to a central maintenance station.。

1/9L165July 2003 s OUTPUT CURRENT UP TO 3A s LARGE COMMON-MODE AND DIFFERENTIAL MODE RANGES s SOA PROTECTIONs THERMAL PROTECTION s± 18V SUPPLYDESCRIPTIONThe L165 is a monolithic integrated circuit in Pen-tawatt® package, intended for use as power oper-ational amplifier in a wide range of applications,including servo amplifiers and power supplies. The high gain and high output power capability provide superiore performance wherever an operational amplifier/power booster combination is required.3A POWER OPERATIONAL AMPLIFIERAPPLICATION CIRCUITS Figure 1. Gain > 10.Figure 2. Unity gain configuration.L1652/9ABSOLUTE MAXIMUM RATINGSPIN CONNECTION (Top view)SCHEMATIC DIAGRAMTHERMAL DATASymbol ParameterValue Unit V S Supply voltage± 18V V 5 V4Upper power transistor V CE 36V V 4V 3Lower power transistor V CE 36VV i Input voltageV S V j Differential input voltage± 15V I o Peak output current (internally limited) 3.5A P tot Power dissipation at T case = 90°C 20W T stg , T jStorage and junction temperature-40 to 150°C Symbol ParameterValue Unit R th-j-caseThermal resistance junction-casemax3°C/WL165ELECTRICAL CHARACTERISTCS (V S = ± 15 V, T j = 25 °C unless otherwise specified)Symbol Parameter Test Condition Min. Typ.Max.Unit V S Supply Voltage± 6± 18VI d Quiescent Drain Current V S = ±18 V4060mAI b Input Bias Current0.21µAV os Input Offset Voltage± 2± 10mVI os Input Offset Current± 20± 200nASR Slew-rate G v= 108V/µsG v = 1 (°)6V o Output Voltage Swing f = 1kHzI p = 0.3AI p = 3A 2724V ppf = 10kHz I p = 0.3A I p = 3A 2724V ppR Input Resistance (pin 1) f = 1 KHz100500KΩG v Voltage Gain (open loop)80dB e N Input Noise Voltage B = 10 to 10 000 Hz2µV i N Input Noise Current f = 1 KHz100pA CMR Common-mode Rejection R g≤ 10 KΩ; G V = 30 dB70dB SVR Supply Voltage Rejection R g = 22 KΩ; V ripple = 0.5 Vrmsf ripple = 100 HzG v= 10G v= 1006040dBdBEfficiency f = 1 kHz; R L = 4ΩI p = 1.6 A; P o = 5W I p = 1.6 A; P o = 18W 7060%%T sd Thermal Shut-down Case Temperature P tot = 12 W110°CP tot = 6 W130°C3/9L1654/9Figure 3. Open loop frequency response.Figure 4. Closed loop frequency response(circuit of figure 2).Figure 5. Large signal frequency response.Figure 6. Maximum output current vs. voltage[VCE] across each output transistor.Figure 7. Safe operating area and collectorcharacteristics of the protected power transistor.Figure 8. Maximum allowable powerdissipation vs. ambient temperature.5/9L165Figure 9. Bidirectional DC motor control with TTL/CMOS/µP compatible inputs.Figure 10. Motor current control circuit with external power transistors (I motor > 3.5A).Must be V S2 ≥V S1; E1, E2 = logic inputs; V S1 = logic supply voltageD1 to D4:V F ≤ 1.2 @ I = 4At rr ≤ 500nsNote : The inputvoltage level is compatible with L291 (5-BIT D/A converter).The transfer function is: IM V i-----R4Rx R3------------------=L1656/9Figure 11. High current tracking regulator.Figure 12. Bidirectional speed control of DC motor (Compensation networks not shown).A: for ± 18 ≤ Vi ± 32Note: V z must be chosen in order to verify2 V i - V z ≤ 36V B: for V i ≤ ±18VD1 to D4:V F ≤ 1.2 @ I = 2At rr ≤ 500ns7/9L165Figure 13. Split power supply.Figure 14. Power squarewave oscillator with independent adjustments for frequency and duty-cycle.P1 : duty-cycle adjustP2 : frequency adjust (f = 700 Hz with C1 = 10 nF , P2 = 100K Ω, f = 25 Hz with C1 = 10 nF , P2 = 0)L1658/9L165 Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is grantedby implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are notauthorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.STMicroelectronics acknowledges the trademarks of all companies referred to in this document.The ST logo is a registered trademark of STMicroelectronics©2003 STMicroelectronics - All Rights ReservedSTMicroelectronics GROUP OF COMPANIESAustralia - Brazil - Canada - China - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan -Malaysia - Malta - Morocco - Singapore - Spain - Sweden - Switzerland - United Kingdom - United States.9/9。

GA165-2016《防弹透明材料》标准解析邱日祥;杨杰【摘要】本文通过修订前后标准的对比分析,介绍了GA165-2016《防弹透明材料》中材料防护性能的分级与分类、环境适应性分级、代号、标识、透光率和尺寸偏差等主要内容.【期刊名称】《中国安全防范认证》【年(卷),期】2017(000)003【总页数】4页(P52-55)【关键词】防弹透明材料;分级;分类;透光率【作者】邱日祥;杨杰【作者单位】公安部检测中心;公安部检测中心【正文语种】中文GA165-1997《防弹复合玻璃》标准于1997年首次颁布实施,已经运行18年，该标准在促进产品发展、规范产品质量等方面起到了积极作用。

但随着科学技术的发展，新材料、新工艺不断涌现，防弹透明材料的种类得到了扩展；同时，枪弹的品种、威力也在不断发展,所以，现行标准已经不能适应产品发展和实际使用的需要。

为此，公安部组织相关单位修订了标准，修订后的标准名称为《防弹透明材料》，并于2016年10月8日发布，2016年11月1日正式实施。

新旧标准主要内容发生了较大的变化。

2.1 标准名称由《防弹复合玻璃》变成了《防弹透明材料》玻璃在常温下是一种透明的固体，在熔融时形成连续网络结构，冷却过程中粘度逐渐增大并硬化而不结晶的硅酸盐类非金属材料，普通玻璃的化学组成是Na2O・CaO・6SiO2，主要成分是二氧化硅。

人们一直将透明材料称为玻璃，其实，透明种类很多，除无机玻璃外，常见的还有：聚甲基丙甲酸甲酯（俗称有机玻璃，PMMA，PolymethylMethacrylate）、聚碳酸酯（PC，Polycarbonate）、将聚乙烯醇缩丁醛胶（PVB，polyvinyl butyral）、PU胶（聚氨酯，Polyurethane）、玻璃安全膜（一种叠层膜片，膜片的高抗张强度赋予玻璃内张应力）等有机材料。

常见的防弹复合玻璃是上述材料的复合，如玻璃和玻璃安全膜；玻璃、胶以及PC或PMMA等。