AZ762-1A-5D中文资料

CONTACTSArrangement SPST (1 Form A)SPDT (1 Form C)RatingsForm A and CMax. switched power: 210 W or 2770 VA Max. switched current: 15 A AC, 7 A DCMax. switched voltage: 30 VDC or 300 VAC UL/CUR 1 Form ARatings15 A at 125 VAC, general use10A at 277 VAC, general use, 100,000 cycles TV - 5 120 VAC1 Form C10 A at 277 VAC, general use, 100,000 cyclesMaterial AgSnO 2Resistance< 100 milliohms initally (24 V, 1 A method)ZET TLERelectronicsTelephone +44 (0) 1582 599 600 Fax +44 (0) 1582 599 700Logistic Design (UK) Limited. Unit 3, Eagle Centre Way, Luton LU4 9US sales@ 2000-01-21GENERAL DATALife ExpectancyMechanical 1 x 106Electrical 1 x 105at rated load Operate Time 10 ms max.Release Time5 ms max.(with no coil suppression)Dielectric Strength 1500 Vrms contact to coil (at sea level for 1 min.)1000 Vrms across contacts Insulation Resistance 100 megohms min. at 500 VDC,50% RHDropoutGreater than 10% of nominal coil voltage Ambient TemperatureAt nominal coil voltage Operating -40°C(-40°F) to 95°C(203°F)Storage-40°C(-40°F) to 130°C(266°F)Vibration 0.062" DA at 10–55 Hz Shock10 gEnclosure P.B.T. polyesterTerminalsTinned copper alloy, P.C.Max. Solder Temp.270°C (518°F)Max. Solder Time 5 seconds Max. Solvent Temp.80°C (176°F)Max. Immersion Time 30 seconds Weight10 gCOILPowerAt Pickup Voltage 203 mWMax Continuous 1.0 W at 20°C (68°F)Dissipation Temperature Rise27°C (49°F)(at nominal coil voltage)TemperatureMax. 130°C (266°F)15 AMP MINIATUREPC BOARD RELAYFEATURES •High performance •Low seated height•Flux tight and sealed versions available •UL, CUR file E43203•Class B insulation (130°C) standardNOTES1.All values at 20°C (68°F).2.Relay may pull in with less than “Must Operate” value.3.Unsealed relays should not be dip cleaned.4.Specifications subject to change without notice.2000-01-21ZET TLERelectronicsTelephone +44 (0) 1582 599 600 Fax +44 (0) 1582 599 700Logistic Design (UK) Limited. Unit 3, Eagle Centre Way, Luton LU4 9US sales@ RELAY ORDERING DATASTANDARD RELAYSCOIL SPECIFICATIONSORDER NUMBERNominal CoilMax. ContinuousCoil ResistanceMust OperateUnsealed Sealed VDC VDC ±10%VDC 58.3703.8AZ943–1CH–5D AZ943–1CH–5DE 610.0100 4.5AZ943–1CH–6D AZ943–1CH–6DE 915.0225 6.8AZ943–1CH–9D AZ943–1CH–9DE 1220.04009.0AZ943–1CH–12D AZ943–1CH–12DE 1830.090013.5AZ943-1CH-18D AZ943-1CH-18DE 2440.01,60018.0AZ943–1CH–24D AZ943–1CH–24DE 4867.06,20036.0AZ943–1CH–48DAZ943–1CH–48DESubstitute “1AH” in place of “1CH” to indicate 1 Form A contact.Dimensions in inches with metric equivalents in parentheses. Tolerance: ± .010"。

贴片3个脚C001A06M073QFN-6封装IC表面编码CCQ09KE7E0AR982 SOT-14361HL SOT-143B83 4脚10A1022A15F5H3 F5HE222 SOT-23MARK为ECIG,封装为SOT-23BU1H SOT-32339BBAEAO4MQU，封装为SOT-23的ICB8SN7 SOT-23封装,丝印:B8TX4 SOT-23封装,丝印:W2H SOT-23封装,丝印:ZTW SOT-23封装,丝印:L231 SOT-23封装,丝印:EA2 SOT-23封装,丝印:8F SOT-23封装M762SCD7BE30CN61110 8ZFJKB1 FJJK5TFT 3H0015BA7sot-23封装的，上标是X1YV与他垂直是10，标有A1FV与他垂直是16的是什么管子贴片二极管上写着ZE20J贴片二极管CCD MZ贴片二极管第一行03A 第2行F6 5D 贴片二极管ACXK7JA SOT-23C251A5V的稳压芯片，贴片封装,印字为8C032NCSN36WD.PS3J7P03BXPD:P62ZA7S3KW8C032J727EIWCAFPLAFPLE601 E60528C26XBLYAP2ABNJKS5RSOT23封装的丝印28G2GBAs87 BAs88 BAs89W3W贴片二极管封装是1206的丝印是T72是什么型号SOT－23的上面标有OOOI贴片二极管标有16LE400BC，封装SOT-23丝印Txw3F，这个x看不清，像0也像U，用x代替了与二极管上面写着D写或5.5SOT-89的，上面丝印为：BD S2L 和DD S3F 2314贴片三极管印字76ee,8626贴片三极管标HG18SSD73W SOT-2312W SOT-23Y6W SOT-23CB2C22A15 22B12 10A10BAT99 BAT98 BAT97 BAT9A BAT9B BAT9C BATA1 BATA2 BATA3 丝印BAU6X,BAU72.BAU79.BAU61 BAU62 BAU63 BAU64 BAU65 BAU66 BAU67 C2F G535A 0MN010TC28PC30AC33BC33MDGHGE36LEC11EIJFE33UE33JE33NE30BE30AE30HE33H7KFG7KFDE50HE50AMD5-3070FB7DEKE50HE50A65Z5662K59GC59I6D3GK6337AJAEDJGEDJJA08TA07TC28JC33B65XB65X865X265ZD2108B501CAPJA65E965K5C22AC33AC27HC28JA5GVE33HE33JE50TE33QE33VE33NE33LL56TL50TL40TL50EL36TL33TL45TM153BAt88 BAt89 BAt8A BAt8B BAT99 BAT98 BAT97BAT9A BAT9B BAT9CBATA1 BATA2 BATA3BAUA7 BAUA8 BAUA9 BAUAA BAs84 BAs83 BAs82BAP66 BAP76 BAP86A006/A007/A00X 009x 00AXC34BAB75EDT72X31N5JI54HH3A08GAPJA5AGJ5CFK5BHJ5BGJ5BFE5BJC65Z5662K54FKXD2859GC59I6AAB66S65265T365XB65X865X2662166226337AJADGHG7KFG7KFD70FB7DEKE50HE50AE50G13HGB6WL50PL33D75FE7AIK DBILE28NE30NE33U 21008 0622-50 501C501DE50N 853050189 RM06 8805/50 8806 2100BC22AC33AC33BE5SAR113BM7SE2HTB17064A65AT8A4sS1gZBBF3A03B85212ZK7M4K7B01FP8A8U9VW0843WMos W04 A7N Y2K N28 N29 33W LD3 M36 B3 HT56 6CW 15H M6G2 LEY2 W2W W1P 1PK NB46 NB43 ACA30 W2D 518A ND55 PD54 618 L6HN 501 GTF 6T1AK 007F NS65 5Ct V30 A6t WV5 NF DM CEQ P11DFRD KQ49 BJT2G PC55 NU79 E33M CFRE OK59 3I38 AZO X1YV A1FV A1YQ 113N M43B 1301 1FW A43Ft 303 A7W Z3W 304 DB3 1FT 5CW J3076 M4B S401 A2SM U1J 6.7Y NB30 WUS ADW63 SAW AAX M5C LC99K 024W T1a88 6Dt3EEt0635K462FN KYZ-U5 TS52FV GJ-YQ2 12PKJXHA6N8UN ZCW14 ZDW05 L05W2T GLV18E119AB 3515 D2E02 2F5R31E HD2K DV5D019I A4W14 K72x7 1A15 W1AK1NM6 J6YA013 HY30L33 076A S2AD K6LD310M43tH2FH1P BWAMPA09TA1215 A3WKA12A09RAR8A2BVA2BNL4WYDHR5A DBRV KYZ-U5 UPRX DKQG CY DKRNALBLBDS2L DDS3F KA Bon IYAQY39 46 47 64 BEQEYL 9X AE RW BQ028C621 GY721 DJ 56NS 13 39 97 93 78 501C4B 0C FL 38 8A 109 M0NKZ1Z58A1YQN502 JStN6I0N N019N 358A08K TIA13 016JK46662L65ZB SO-1R KK9 SOIBB 20952 A7HG13WB56M13KK9008C WT8 8512 8525 431M HH85 sSNW6WW6YS6P3C S4K7C507723K30AJHJM425 T2 955E 6TMAA21K52116APK72 V1W32JA6SUBFS00BM0ZM15B252X4YAEL15N620IM2603WM6450 W13460 WA3453 WK1450 WL2AHA60DSAGHSAGFA7v9G7ZGGGB3t8BVBGGA006ESALAZP2247HA69w1702A7XK8CM3YXOBVAN51CP2HD55A09EO1V015C 015G TACUVLRCJ4BW2X1PVC01ABJLDSTs12WPDTC114TK1CW 1Cp511BKD JFBHDN81YAEAL0.138S72XF8W1KY 8B6A1SSHA2SSHK20BD RKC019V2GBFA1y396yxR12R52 CEDARB B1YU B2YV 702X F36 H6L1xVC N019Q AMA C8M5W MSW H7 BBVAA A91A 318032012-03-05,15:54:08资料邮件回复↑↑“05645”或者“05646”的5脚IC 05619N153C54SOT23-5封装的，丝印是7NH1 JSAREL33，封装“SOT-23-5”A7CAAGAAPH4KJVY6WF SC70-5A18uB02GK11F SOT-23-5BF65 SC70-5A15358BWVC 11 66M117M305芯片表面打“15”，SOT23-5封装表面打“16”，SOT23-5A5485BUWMDJX sot-23-573JU73GJ73JE5个脚上面印的是90B27LDARAAR91G122背光IC,丝印是506CA25EFJ59AVMR 或者VMKH1JE7EFAT2DP T2FFB48Y51EJSARA4AA12ASC20AA16A805 封装:SOT23-5TF06LB21H237XB 37XAF2CA45CBBCSACDPdaacm 五脚15THC397H2A63AMDJXDAG1H DAGOZE30E30/BJXB1YAB1UDSACG9R表面印字C6PH和C6SF丝印打FVG SOT23-55脚标记FANT电源的芯片一个是SOT23-5的，丝印是A60yE；8JAA8JAB8JAC8JB18JB28JB38JB48JB58JB6B3A,sot-25;AASOT-23-5 印字:THHD芯片丝印CR0810-AIC上面丝印是20A32和32A22，SOT25封装芯片上印BES灯控IC 上面写着LTYN丝印：AYAC ,封装:SC70丝印为ICPDAS ST-01 数I6GBHODO 0D0AD4RDZLWAABAADDABONADKQBLHAB10A 23-5HIJEBUF60B8E SOT23-5AAF33SA8JTE6TLTH72YL6ACA90A772A777A773丝印名为L30L或L30K,封装为SOT-23-55脚电源贴片IC（SOT-23-5）丝印4XX9;4XX5 丝印D1924的SOT-23-5封装的元件BPSQ SOT-23-5UQRW sot-23-5电源贴片IC型号（IC上丝印ID97N）丝印代码为co - sow的5脚IC印字112HX 封装为SOT23-5的ic丝印为1A2G的,封装为SOT23-5,31R5 SOT-23-590B16 SOT-23-5.芯片上丝印psri,SOT-23-5321YCXBSOT-25封装的管子，上面印着EDZ JRJXC3EGDJ-8111128CA103印字ACCL SOT-23-5EQ6JT30TX50TU18HC2KLU50ACWWETF83S2A63334XK1 SOT-23-54XX1 SOT-23-54XZ1 SOT-23-54B21 SOT-23-5DG SOT-353-5(SC70)EG SOT-353-5(SC70)CG SOT-353-5(SC70)HG SOT-353-5(SC70)PSREGCLR,是五个脚的双排,ED2F DE9R ED4USOT23-5封装代码G85SOT23-5丝印为HA041F21 sot-23-5封装的IC型号LXZ6A2JBA1VRRT6C2YL7 SOT-23-59Aa1J，封装为TSOT23-5，9AaOb9Aa0N9AaRg贴片器件上面标着9Aa0Z9Aa3S SOT-23-59AaBJ9Aa0W9Aa0y9Aa0M5336FIN69DAWCO贴片5脚33R1摄像头用的电源IC，SOT-23-5, 丝印BQJV，1D2G 23-5封装M3KEM3KK5283EEQ6JLTNDC32F016m017T 017bBG2N5JR N5WOTF83Y52M 706IA87GMU7268116301263105AADLB71ADC31665DB50DB65UA50UAM1GHM1IJM3JGM3JAATX09ATX49印记：AAK80 封装：SOT-353 LTAFAL82M9B23F9DT SOT-23-5M073 SOT-23-3L113X113T113FR33H9Ab2xX733M530FA7K15THA307IT214IN6AEIC75BID9BBIC25KID7YWID8YWIC6YWIP39NA3XXB3YWC56AIN69DID99HID98AIP37CIC27CG3YWL33FCATBA207A2HIKDCWVFQ8CAW9X32JVAJL EACRSS 7Z25D 7Z08D LTIZ LTKH LTXZ LTBHT LTYNE5FM 1335x 135Ax 135x 13dxB7AL8A118A128A138A14 LB24 BDV72 BDV73 BDV74 5509FLM A2HJA207 A2IKH10R 30BC F10LS28GF20GE50EE50HE50G2YL62YL42YL22YLA 5358A 5351A 7NIKH10r30BC H10G HX-NG L36H L50P L50U L50T DCJE 75FE L33S 7A22 L50H 7HJC L33H DDGH 73HB 75KG H1JH UN8HX 54B4 4XZ1A107 A19B H1JCH1IE 8A65 8A93 7NH1 8A74 8A6C KIHLA30L A37A HX-UG K103 H1KA HXN-HX HXN-AP HIHI XH8NU A3114XK3A2HJA207A2IK 5509BLM HX-NG KIHLH1JHS9VRN5RK F10VAJ16 YJAA ACA0C A18A30B4C104C103B6W70JC DHJBA311A71CA7JHB19D AA22 AA23 BAU72 BAU77 BAU75 M3JAM3JGK19J 016FK103C0210 CO-TOC 7AIK DBIL7A22L33S 5509BLMF18LHX-UGFILEC00XBCy618A8473FBDDGDBCy62BCy63BCy6473KD90B1790B189AaNYGGt313ID99CA11Y9AAONEQB9RBAA8LCGA0GBA3C BA3D BA3G G3AHG3JW5136A311A5IKA71CA7HJ5509BLM5509BLG4XK35509FLMA2HJA207A2IK7NHH8JA48JA68JAAHXN-XhF18EF10V4XZ1A17HA107HX-VG30B4CI04HX-NGKIHLA37aB19d2YL62YL42YL22YLAH1JCUN8HX54B4S9VHIIEK19jHIJH55B7016QN1CKHA2EHA2KG1-P1FB7G2N933R2SYS25SE.2E.57ZGGG, 是sot23-5的。

接近开关科技名词定义中文名称：接近开关英文名称：proximity switch定义：一种用于工业自动化控制系统中以实现检测、控制并与输出环节全盘无触点化的新型开关元件。

当开关接近某一物体时，即发出控制信号。

应用学科：机械工程（一级学科）；仪器仪表元件（二级学科）；仪器仪表机电元件-仪器仪表开关（三级学科）以上内容由全国科学技术名词审定委员会审定公布求助编辑百科名片接近开关原理图接近开关又称无触点行程开关，它除可以完成行程控制和限位保护外，还是一种非接触型的检测装置，用作检测零件尺寸和测速等，也可用于变频计数器、变频脉冲发生器、液面控制和加工程序的自动衔接等。

特点有工作可靠、寿命长、功耗低、复定位精度高、操作频率高以及适应恶劣的工作环境等。

目录性能特点1种类1、无源接近开关12、涡流式接近开关13、电容式接近开关14、霍尔接近开关15、光电式接近开关16、热释电式接近开关17、其它型式的接近开关主要用途选用注意事项1接近开关的选型和检测1、接近开关的选型12、接近开关技术指标检测展开编辑本段性能特点在各类开关中，有一种对接近它物件有“感知”能力的元件——位移传感器。

利用位移传感器对接近物体的敏感特性达到控制开关通或断的目的，这就是接近开关。

MICROSONAR系列接近开关当有物体移向接近开关，并接近到一定距离时，位移传感器才有“感知”，开关才会动作。

通常把这个距离叫“检出距离”。

但不同的接近开关检出距离也不同。

有时被检测验物体是按一定的时间间隔，一个接一个地移向接近开关，又一个一个地离开，这样不断地重复。

不同的接近开关，对检测对象的响应能力是不同的。

这种响应特性被称为“响应频率”。

编辑本段种类因为位移传感器可以根据不同的原理和不同的方法做成，而不同的位移传感器对物体的“感知”方法也不同，所以常见的接近开关有以下几种：1、无源接近开关这种开关不需要电源，通过磁力感应控制开关的闭合状态。

当磁或者铁质触发器靠近开关磁场时，和开关内部磁力作用控制闭合。

招标参数*一、探测器(进口品牌）1、探测器结构与材料：整板非晶硅；2、采集像素矩阵：＞3000*3000；3、极限空间分辨率：≥3.5 Lp/mm;4、图像输出灰阶：≥14BIT；二．高频高压发生器*1、高压发生器：与整机品牌一致，提供证明材料；2、最大输出功率：≥50KW；3、最大输出电压：≥150KV；4、最大毫安量：≥630mA；*5、最短曝光容积率：≤0.4mAS；三．X光球管组件（进口球管）*1、焦点：0.6mm/1.2mm；2、焦点最大功率：≥50KW；3、阳极热容量：≥300KHU；*4、阳极最高转速：＞9000转/min；5、球管最高输出管电压：150KV；四．直臂机架1、探测器中心距地距离最小距离：≤465mm；2、焦点到影像接收面距离：1000mm、1500mm；3、横臂的轴向旋转范围：0°～ +90°；4、出于匹配性考虑，机架、高压、软件、整机注册属于同一厂家；五．滤线栅及限束器1、滤线栅栅格比为10:1；2、限束器：功率：150W、24VAC自动关闭时间：30S亮度：焦片距100cm时≥160lux六．工作站硬件1、CPU双核Dual-Core≥2.8GHz，2M缓存，内存≥2GB，通讯网卡≥1000M网卡；2、CD/DVD刻录：DVD光驱，CD/DVD刻录，硬盘容量≥500GB；3、显示器≥24英寸液晶显示器；七．医生登记采集诊断工作站软件功能系统软件应能对患者和图像信息进行管理。

具体功能如下：①病人管理：手工登记，WORKLIST自动查询；②图像采集：自动调窗，自动裁剪，自动发送；③图像处理：图像校正，图像翻转，EAE图像处理增强，IEQ图像处理；④图像观察：查看静态图像、窗宽窗位调整，图像翻转，图像旋转，图像缩放、还原；⑤病历报告：病人信息自动加载；⑥胶片打印：支持DICOM3.0标准激光相机打印；⑦DICOM传输：可发送图像到任何遵循DICOM3.0标准的PACS及工作站。

GENERAL DATALife ExpectancyMinimum operations Mechanical 3 x 107Electrical1.7 x 105at 10 A 230 VAC res.(ohmic load at2.8 x 105at 8 A 230 VAC res.105°C / 221°F)3.2 x 105at 6 A 230 VAC res.Operate Time (typical)7 ms at nominal coil voltage Release Time (typical)3 ms at nominal coil voltage (with no coil suppression)Dielectric Strength 5000 Vrms coil to contact(at sea level for 1 min.)1000 Vrms between open contactsInsulation105megohms min. at 500 VDC,Resistance 20°C, 50% RHInsulation C250(according to Overvoltage category: III DIN VDE 0110, Pollution degree: 3IEC 60664-1)Nominal voltage: 250 VACDropout DC coilsGreater than 10% of nominal coil voltage AC coilsGreater than 15% of nominal coil voltage Ambient TemperatureAt nominal coil voltageOperating-40°C (-40°F) to 105°C (221°F) - DC sens.-40°C (-40°F) to 85°C (185°F) - DC std.-40°C (-40°F) to 70°C (158°F) - AC coils Storage-40°C (-40°F) to 105°C (221°F)Vibration 20 g at 30…500 Hz Shock 30 gEnclosure P.B.T. polyester, UL-94 : V0TerminalsTinned copper alloy P.C. and quick connect Max. Solder Temp.270°C (518°F)Max. Solder Time 5 seconds Weight16 gramsPacking unit in pcs12 per carton tube / 600 per carton box20 AMP HIGH TEMPERATURE MINIATURE POWER RELAYFEATURES •Quick connect Faston and PCB terminals •Ambient Temperature up to 105°C (221°F)•Dielectric strength 5000 Vrms •Low height: 15.7 mm•20 Amp switching (18 A over Faston)•AC and DC (standard and sensitive) coils •Isolation spacing greater than 10 mm •Proof tracking index (PTI/CTI) 250•Reinforced insulation, EN 60730-1 (VDE 0631, part 1)EN 60335-1 (VDE 0700, part 1)•UL, CUR pending•VDE file 40012572 (sensitive DC coils only)CONTACTSArrangement SPST (1 Form A)RatingsResistive load:Max. switched power:600 W or 5000 VA Max. switched current:20 AMax. switched voltage:300 VDC* or 400 VAC* Note: If switching voltage is greater than 30VDC,special precautions must be taken.Please contact the factory.Rated Load UL, CUR 20 A at 250 VAC general useVDE10 A at 250 VAC resistive, 105 °C, 150k cycles 16 A at 250 VAC resistive, 105 °C, 10k cycles 20 A at 250 VAC resistive, 85 °C, 10k cycles Material Silver tin oxide Resistance< 100 milliohms initiallyCOILPowerAt Pickup Voltage 140 mW (sensitive DC coil)(typical)200 mW (standard DC coil).422 VA (AC coil)Max. Continuous 2.2 W at 20°C (68°F) ambient (DC coil)Dissipation1.7 VA at 20°C (68°F) ambient (AC coil)Temperature Rise 16°C (29°F) (sensitive DC coil)(at nominal voltage)26°C (47°F) (standard DC coil)26°C (47°F) (AC coil)Max. Temperature155°C (311°F)NOTES1.All values at 20°C (68°F).2.Relay may pull in with less than “Must Operate” value.3.Specifications subject to change without notice.4. Allow suitable slack on leads when wiring and do not subject the terminals to excessive force.https://https://https://https://httpshttps://https://https://wwwhttps:// :// https://www.ichunhttps://www.ichun://https://https://wwwhttps://https://httpshttps://* Substitue “FV” for “FH” for vertical quick connect terminals.COIL SPECIFICATIONS - AC COILORDER NUMBER*Nominal CoilMust OperateMax. ContinuousNominal CurrentCoil Resistance VACVACVACmA ± 10%Ohm ± 10%129.018.063.0100AZ764FH–1AE–12A 2418.036.031.3400AZ764FH–1AE–24A 11586.3172.5 6.59,600AZ764FH–1AE–115A 230172.5345.03.338,500AZ764FH–1AE–230A 240180.0360.03.142,500AZ764FH–1AE–240ARELAY ORDERING DATACOIL SPECIFICATIONS - DC COILORDER NUMBER*Nominal CoilMust OperateMax. ContinuousCoil Resistance VDCVDCVDCOhm ±10%5 3.512.760 AZ764FH–1AE–5D6 4.215.390AZ764FH–1AE–6D9 6.322.9200AZ764FH–1AE–9D128.430.6360 AZ764FH–1AE–12D1812.645.9710AZ764FH–1AE–18D 2416.861.21,440 AZ764FH–1AE–24D4833.6122.05,700AZ764FH–1AE–48D 6042.0153.07,500AZ764FH–1AE–60D11077.0280.025,200AZ764FH–1AE–110DCOIL SPECIFICATIONS - DC COIL SENSITIVE VERSIONORDER NUMBER*Nominal CoilMust OperateMax. ContinuousCoil Resistance VDCVDCVDCOhm ±10%5 3.7515.0102 AZ764FH–1AE–5DS6 4.518.0144AZ764FH–1AE–6DS 9 6.7527.0330 AZ764FH–1AE–9DS 107.530.0400AZ764FH–1AE–10DS129.036.0580 AZ764FH–1AE–12DS 2418.072.02,300 AZ764FH–1AE–24DShttps://https://https://https://httpshttps://https://www://https://www.ichunhttps:// https://httpshttpshttps://https://https://www.ichunhttps://wwwhttps。

250 kSPS 、六通道、同步采样、双极性16/14/12-位 ADCAD7656/AD7657/AD7658Rev. D Information furnished by Analog Devices is believed to be accurate and reliable. However , no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Speci cations subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. T rademarks and registered trademarks are the property of their respective owners.One Technology Way, P.O.Box 9106, Norwood, MA 02062-9106, U.S.A.Tel: 781.329.4700 Fax: 781.461.3113 2006–2012 Analog Devices, Inc. All rights reserved.功能框图V SSDGNDV DDREFCONVST ACONVST B CONVST C OUTPUT DRIVERSOUTPUT DRIVERSOUTPUT DRIVERSOUTPUT DRIVERSCONTROL LOGICBUFBUFBUFAGNDT/HT/H T/H T/HT/HT/HCLK OSCAV CCDV CCV1V2V3V4V5V6SER/PAR CSV DRIVE STBYDOUT ADOUT BDOUT C SCLKRD WRDATA/CONTROL LINES 05020-001AD7656/AD7657/AD765816-/14-/12-BIT SAR16-/14-/12-BIT SAR16-/14-/12-BIT SAR16-/14-/12-BIT SAR16-/14-/12-BIT SAR16-/14-/12-BIT SAR图1.-1受美国专利第6,731,232号保护。

POWER RELAYFEATURES •Dielectric strength 5000 Vrms •Low cost•Epoxy sealed version available •16 Amp switching•Isolation spacing greater than 10 mm•Reinforced insulation, EN 60730-1 (VDE 0631, part 1),EN 60335-1 (VDE 0700, part 1)•UL, CUR file E44211•VDE 40006031ZET TLERelectronics GmbHFax +49 89 800 97 200 office@ 0 97 800 89 +49 Tel. GermanyPuchheim, D-82178 Junkersstrasse 3, 2004-09-27GENERAL DATALife ExpectancyMinimum operations Mechanical 1 x 107Electrical 1 x 105at 16 A 250 VAC Res.Operate Time (typical)7 ms at nominal coil voltage Release Time (typical)3 ms at nominal coil voltage (with no coil suppression)Dielectric Strength 5000 Vrms coil to contact(at sea level for 1 min.)1000 Vrms between open contacts Insulation 1000 megohms min. at 20°C Resistance 500 VDC 50% RH InsulationC250(according to Overvoltage category: III DIN VDE 0110, Pollution degree: 3IEC 60664-1)Nominal voltage: 250 VACDropoutGreater than 10% of nominal coil voltage Ambient TemperatureAt nominal coil voltageOperating -40°C (-40°F) to 85°C (185°F)Storage -40°C (-40°F) to 105°C (221°F)Vibration 0.062" (1.5 mm) DA at 10–55 Hz Shock10 gEnclosure P .B.T. polyesterTerminalsTinned copper alloy, P.C.Max. Solder Temp.270°C (518°F)Max. Solder Time 5 seconds Max. Solvent Temp.80°C (176°F)Max. Immersion Time 30 Seconds Weight14 gramsPacking unit in pcs20 per plastic tube / 1000 per carton boxCONTACTSArrangement SPDT (1 Form C)SPST (1 Form A, 1 Form B)RatingsResistive load:Max. switched power:480 W or 4432 VA Max. switched current:16 AMax. switched voltage:150 VDC* or 440 VAC* Note: If switching voltage is greater than 30VDC,special precautions must be taken.Please contact the factory.Rated Load UL, CUR16 A at 277 VAC resistive, 100k cycles [3]16 A at 277 VAC resistive, 50k cycles [1]1 HP at 250 VAC (1 Form A) [1]1/2HP at 125 VAC (1 Form A) [1]TV-5 at 125 VAC (1 Form A) [1]16 A at 277 VAC resistive, 75k cycles [2]B300 Pilot Duty [2]R300 Pilot Duty [2]VDE 16 A at 250 VAC resistive, [1] [2] and [3]9 A at 250 VAC, inductive (Form A) [1] [2] and [3]Material Silver cadmium oxide [1] or silver tin oxide [2]or silver nickel [3]. Gold plating available Resistance< 50 milliohms initiallyCOILPowerAt Pickup Voltage 196 mW(typical)Max. Continuous 1.7 W at 20°C (68°F) ambient Dissipation Temperature Rise 26°C (47°F) at nominal coil voltage Max. Temperature130°C (266°F)NOTES1.All values at 20°C (68°F).2.Relay may pull in with less than “Must Operate” value.3.Specifications subject to change without notice.2004-09-27ZET TLERelectronics GmbHFax +49 89 800 97 200 office@ 0 97 800 89 +49 Tel.GermanyPuchheim, D-82178 Junkersstrasse 3,RELAY ORDERING DATACOIL SPECIFICATIONS – DC COILORDER NUMBER*Nominal CoilMust OperateMax. ContinuousCoil Resistance1 Form C 1 Form AVDC VDC VDC Ohm ± 10%53.510.262 AZ762–1A–5DAZ762–1C–5D 6 4.212.390AZ762–1A–6D AZ762–1C–6D 9 6.318.3200AZ762–1A–9D AZ762–1C–9D 128.424.7360 AZ762–1A–12D AZ762–1C–12D 1812.637.0810AZ762–1A–18D AZ762–1C–18D 2416.849.41,440 AZ762–1A–24DAZ762–1C–24D 4833.698.05,760AZ762–1A–48D AZ762–1C–48D 6042.0112.97,500AZ762–1A–60D AZ762–1C–60D 11077.0206.925,200AZ762–1A–110DAZ762–1C–110D* “1A” or “1C” denote silver cadmium oxide contacts.Substitute “1B” in place of “1A” for 1 Form B contact.Add suffix “E” to “1A” or “1B” or “1C” for silver tin oxide contacts. Add suffix “B” to “1A” or “1B” or “1C” for silver nickel contacts. Add suffix “E” at the end of order number for sealed version.Add suffix “A” at the end of order number for gold plated contacts.。

ZET TLERelectronics GmbHFax +49 89 800 97 200 office@ 0 97 800 89 +49 Tel. GermanyPuchheim, D-82178Junkersstrasse 3, 2003-03-12GENERAL DATALife ExpectancyMinimum operations Mechanical 1 x 107Electrical 1 x 105at 30 A 120 VAC Res. (N.O.)Operate Time (max.)Max. 12 ms Typical: 8 ms Release Time (max.)Max. 5 ms Typical: 3.5 msDielectric Strength 2500 Vrms contact to coil(at sea level for 1 min.)1500 Vrms between open contacts Insulation Resistance 1000 megohms min. at 500 VDC, 20°C 50% RHDropoutGreater than 10% of nominal coil voltage Ambient TemperatureAt nominal coil voltageOperating -55°C (-67°F) to 85°C (185°F)Storage -55°C (-67°F) to 105°C (221°F)Vibration 0.062" (1.5 mm) DA at 10–55 Hz Shock 20 gEnclosure P .B.T. polyester TerminalsTinned copper alloy Max. Solder Temp.270°C (518°F)Max. Solder Time 5 seconds Max. Solvent Temp.80°C (176°F)Max. Immersion Time30 seconds Weight25 gramsMINIATURE POWER RELAYFEATURES•30 Amp switching capability for both N.O. and N.C. contacts•1 Form A, B and C contacts available •DC coils to 120 VDC•Life expectancy to 10 million operations •Class B insulation standard•Class F (155°C) version available•Available with an epoxy seal for automatic wave soldering and immersion cleaning •Proof Tracking Index (PTI/CTI) 175•UL, CUR file E44211 including versions meeting UL 508 and UL 873 spacing and contact rating requirements; VDE 132710 ÜG (some models)CONTACTSArrangement SPDT (1 Form C)SPST (1 Form A and 1 Form B)RatingsResistive load:Max. switched power:900 W or 7200 VA Max. switched current: 30 AMax. switched voltage: 30 VDC or 300 VAC UL Rating:See chart for UL contact ratings.AZ2150 Series meets UL 508 Group A spacing and UL 873 refrigeration and safety control requirements. AZ2151 Series meets UL 508Group B spacing requirements.VDE Rating:AZ2150-1A - 25 A at 250 VAC, 1 x 104, resistive AZ2150-1C - 20 A at 250 VAC, 1 x 104, resistiveMaterial Silver cadmium oxideResistance< 20 milliohms initially(at rated current, voltage drop method)COILPowerAt Pickup Voltage 500 mW(typical)Max. Continuous 2.2 W at 20°C (68°F) ambient Dissipation 1.8 W at 40°C (104°F) ambient Temperature Rise 43°C (77°F) at nominal coil voltage TemperatureMax. 130°C (266°F) Class B Max. 155°C (311°F) Class FNOTES1.All values at 20°C (68°F).2.Relay may pull in with less than “Must Operate” value.3.Unsealed relays should not be dip cleaned.4.Other coil resistances and sensitivities available upon request.Please call the factory.5.Specifications subject to change without notice.2003-03-12ZET TLERelectronics GmbHFax +49 89 800 97 200 office@ 0 97 800 89 +49 Tel. GermanyPuchheim, D-82178 Junkersstrasse 3, RELAY ORDERING DATASTANDARD RELAYS: 1 Form A (SPST); 508 Group A; UL 873 VersionCOIL SPECIFICATIONS ORDER NUMBER*Nominal Max.CoilMust Coil Continuous Resistance Operate Unsealed SealedVDC VDC±10%VDC57.327 3.75AZ2150–1A–5D AZ2150–1A–5DE 68.940 4.5AZ2150–1A–6D AZ2150–1A–6DE 913.997 6.75AZ2150–1A–9D AZ2150–1A–9DE 1217.51559.0AZ2150–1A–12D AZ2150–1A–12DE 1522.525611.25AZ2150–1A–15D AZ2150–1A–15DE 1827.438013.5AZ2150–1A–18D AZ2150–1A–18DE 2436.166018.0AZ2150–1A–24D AZ2150–1A–24DE 4868.42,56036.0AZ2150–1A–48D AZ2150–1A–48DE 70104.45,50052.5AZ2150–1A–70D AZ2150–1A–70DE 110163.213,45082.5AZ2150–1A–110D AZ2150–1A–110DESTANDARD RELAYS: 1 Form A (SPST); UL 508 Group B VersionCOIL SPECIFICATIONS ORDER NUMBER*57.327 3.75AZ2151–1A–5D AZ2151–1A–5DE 68.940 4.5AZ2151–1A–6D AZ2151–1A–6DE913.997 6.75AZ2151–1A–9D AZ2151–1A–9DE1217.51559.0AZ2151–1A–12D AZ2151–1A–12DE1522.525611.25AZ2151–1A–15D AZ2151–1A–15DE1827.438013.5AZ2151–1A–18D AZ2151–1A–18DE2436.166018.0AZ2151–1A–24D AZ2151–1A–24DE4868.42,56036.0AZ2151–1A–48D AZ2151–1A–48DE70104.45,50052.5AZ2151–1A–70D AZ2151–1A–70DE 110163.213,45082.5AZ2151–1A–110DAZ2151–1A–110DE * Substitute “1B” or “1C” in place of the “1A” to indicate 1 Form B and 1 Form C respectively.To indicate Class F version, add suffix “F”.MECHANICAL DATA。

16-Bit, 6MSPS PulSARDifferential ADC Preliminary Technical Data AD7625Rev. PrBInformation furnished by Analog Devices is believed to be accurate and reliable. However, noresponsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. T rademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 Fax: 781.461.3113 ©2008 Analog Devices, Inc. All rights reserved.FEATURESThroughput: 6 MSPSSAR architecture16-bit resolution with no missing codes SNR: 92 dB Typ, 90dB Min @ 1MHzINL: ±1 LSB Typ, ±2 LSB MaxDNL: ±0.3 LSB Typ, ±1 LSB MaxDifferential input range: ± 4.096VNo latency/no pipeline delay (SAR architecture) Serial LVDS interface:Self-clocked modeEchoed-clock modeReference:Internal 4.096 VExternal (1.2V) buffered to 4.096 VExternal 4.096 VPower dissipation 150 mW32-Lead LFCSP package (5 mm x 5 mm)APPLICATIONSHigh dynamic range telecommunications ReceiversDigital imaging systemsHigh-speed data acquisitionSpectrum analysisTest equipmentTable 1. Fast PulSAR ADC SelectionInput Type Res(Bits)≥1 MSPSto< 2MSPS≥ 2 MSPSto≤ 3 MSPS6 MSPS10MSPSDifferential (ground sense) 16 AD7653AD7667AD7980AD7983AD7985True Bipolar 16 AD7671Differential (anti-phase) 16 AD7677AD7623AD7621AD7622AD7625AD7626Differential (anti-phase) 18 AD7643AD7982AD7984AD7641AD7986FUNCTIONAL BLOCK DIAGRAMIN-IN+CNVVIODDCOCLKFigure 1.GENERAL DESCRIPTIONThe AD7625 is a 16-bit, 6MSPS, charge redistribution successiveapproximation register (SAR) architecture, analog-to-digitalconverter (ADC). SAR architecture allows unmatchedperformance both in noise – 92dB SNR - and in linearity –1LSB. The AD7625 contains a high speed 16-bit sampling ADC,an internal conversion clock, and an internal buffered reference.On the CNV edge, it samples the voltage difference betweenIN+ and IN− pins. The voltages on these pins swing in oppositephase between 0 V and REF. The 4.096V reference voltage, REF,can be generated internally or applied externally.All converted results are available on a single LVDS self-clockedor echoed-clock serial interface reducing external hardwareconnections.The AD7625 is housed in a 32-lead LFCSP (5mm by 5mm) withoperation specified from −40°C to +85°C.AD7625Preliminary Technical DataRev. PrB | Page 2 of 11TABLE OF CONTENTSFeatures..............................................................................................1 Applications.......................................................................................1 Functional Block Diagram..............................................................1 General Description.........................................................................1 Specifications.....................................................................................3 Timing Specifications..................................................................4 Absolute Maximum Ratings............................................................5 Thermal Resistance.......................................................................5 ESD Caution...................................................................................5 Pin Configuration and Function Descriptions..............................6 Terminology.......................................................................................8 Theory of Operation.........................................................................9 Outline Dimensions.. (11)Preliminary Technical DataAD7625Rev. PrB | Page 3 of 11SPECIFICATIONSVDD1 = 5 V; VDD2 = 2.5 V; VIO = 2.5 V; V REF = 4.096 V; all specifications T MIN to T MAX , unless otherwise noted. Table 2.Parameter Conditions Min Typ Max Unit RESOLUT ON 16 Bits ANALOG INPUT Voltage Range V IN+ − V IN− −V REF +V REF V Operating Input Voltage V IN+, V IN− to AGND −0.1 +V REF + 0.1 V Common Mode Input Range V REF /2 – 0.1 V REF /2 V REF /2 + 0.1 V Analog Input CMRR f IN = 1 MHz 60 dB Input Current 6 MSPS throughput 350 μA THROUGHPUT SPEED Complete Cycle 166 ns Throughput Rate 0.001 6 MSPS DC ACCURACY Integral Linearity Error -2 ±1 +2 LSB No Missing Codes 16 Bits Differential Linearity Error -1 ±0.3 +1 LSB Transition Noise 0.6 LSB Zero Error, T MIN to T MAX ±100 μV Zero Error Drift 1 ppm/°C Gain Error, T MIN to T MAX 50 ppm of FS Gain Error Drift 1 ppm/°C Power Supply Sensitivity VDD1 = 5 V ± 5% TBD LSB VDD2 = 2.5 V ± 5% TBD LSB AC ACCURACY Dynamic Range 90 92 dB Signal-to-Noise f IN = 250 kHz 90 92 dB Spurious-Free Dynamic Range f IN = 250 kHz 110 dB f IN = TBD 90 dB Total Harmonic Distortion f IN = 250 kHz -110 dB f IN = TBD -90 dB Signal-to-(Noise + Distortion) f IN = 250 kHz 92 dB −3 dB Input Bandwidth 100 MHz Aperture Delay ns Aperture jitter 5 ps rms Transient Response Full-Scale Step 50 ns INTERNAL REFERENCE Output Voltage REFIN @ 25°C 1.2 V Temperature Drift −40°C to +85°C ±7 ppm/°C REFERENCE BUFFER REFIN Input Voltage Range 1.2 V REF Output Voltage range 4.096 V EXTERNAL REFERENCE Voltage Range REF 4.096 V VCM @ 25°C Output Voltage V REF /2 V REF /2 Output Impedance 4 5 6 kΩAD7625Preliminary Technical DataRev. PrB | Page 4 of 11Parameter Conditions Min Typ Max Unit LVDS I/O, (ANSI-644) Data Format Serial LVDS Two’s complement V ODDifferential Output Voltage,R L =100 Ω247 350 454 mV V OCM Common mode Output Voltage,R L =100Ω1125 1250 1375 mV V ID Differential Input Voltage 100 650 mV V ICM Common mode Input Voltage 800 1575 mV POWER SUPPLIES Specified Performance VDD1 4.75V 5 5.25V V VDD2 2.37 2.5 2.63 V V O 2.3 2.5 2.7 V Operating Currents VDD1 10 mA VDD2 25 mA V O Self-clocked mode 14 mA V O Echoed-clock mode 18 mA Power Dissipation 1 With Internal Reference 6 MSPS throughput 140 mW Without Internal Reference 6 MSPS throughput 120 mW Energy per conversion 6 MSPS throughput 10 nJ/sample TEMPERATURE RANGESpecified Performance T MIN to T MAX −40 +85 °C1Power dissipation is for the AD7626 only. In self-clocked interface, 9mW is dissipated in the 100 ohm terminator. In echoed-clock interface, 18mW is dissipated in (2) 100 ohm terminators.TIMING SPECIFICATIONSVDD1 = 5 V; VDD2 = 2.5 V; VIO = 2.3V to 2.7 V; V REF = 4.096 V; all specifications T MIN to T MAX , unless otherwise noted. Table 3.Parameter Symbol Min Typ Max Unit Time between conversion t CYC 100 ns Acquisition time t ACQ 40 10000 ns CNV high time t CNVH 10 40 ns CNV to D (MSB) delay t MSB 166 ns CNV to last CLK (LSB) delay t CLKL 120 ns CLK period t CLK TBD 4 ns CLK frequency f CLK 250 400 MHz CLK to DCO delay (echoed-clock mode) t DCO 0 4 7 ns DCO to D delay (echoed-clock mode) t D -1 0 1 ns CLK to D delay t CLKD 0 4 7 nsPreliminary Technical DataAD7625Rev. PrB | Page 5 of 11ABSOLUTE MAXIMUM RATINGSTable 4.Parameter With Respect toRatingAnalog Inputs/Outputs CAP1, REFIN GND -0.3V to 2.7VIN+, IN-, REF, REF/2,CAP2GND -0.3V to 6V Digital Inputs/Outputs GND -0.3V to 2.7V Supply Voltage VDD1 GND -0.3V to 6V VDD2, VIO GND -0.3V to 2.7VStresses above those listed under Absolute Maximum Ratingsmay cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operationalsection of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.THERMAL RESISTANCEθJA is specified for the worst-case conditions, that is, a devicesoldered in a circuit board for surface-mount packages. Table 5. Thermal ResistancePackage Type θJA θJC UnitESD CAUTIONAD7625Preliminary Technical DataRev. PrB | Page 6 of 11PIN CONFIGURATION AND FUNCTION DESCRIPTIONS1VDD12VDD23CAP14REFIN 5EN06EN17VDD28CNV-24GND 23IN+22IN-21REF/220VDD119VDD118VDD217CLK+9C N V +10D -11D +12V I O 13G N D 14D C O -15D C O +16C L K -32R E F 31G ND 30REF 29R E F 28C A P 227G N D 26C A P 225C A P 200000-000Figure 2.Table 6. Pin Function DescriptionsPin No. Mnemonic Type 1 Description 1VDD1P Analog 5V Supply.Decouple with 10uF and 100nF capacitors.2 VDD2 P Analog 2.5V Supply.The system 2.5V supply should supply this pin first, decoupled with 10uF and 100nF capacitors, then starred off to other VDD2 pins.3 CAP1 AO Connect to a 10nF capacitor.4 REF I N A I/O Pre-Buffer Reference Voltage.When using the internal reference, this pin outputs the band-gap voltage and is nominally at 1.2V. It can be overdriven with an external reference voltage like the ADR280.In either mode, a 10uF capacitor is required. If using an external 4.096V reference (connected to REF), this pin is a no connect and does not require any capacitor.5, 6 EN0, EN1 DI Enable Pins.EN1 EN0 Operation0 0 Power down all; ADC, internal reference and reference buffer.0 1 Enable internal buffer, disable internal reference. An external 1.2V referenceconnected to REFIN pin is required.1 0 Disable internal reference and buffer. An external reference connected to the REFpin is required.11 Enable all; ADC, internal reference and reference buffer. 7 VDD2 P Digital 2.5V supply. 8, 9 CNV-, CNV+ DI Convert Input.This input has multiple functions. On its rising edge, it samples the analog inputs and initiates aconversion cycle. CNV+ works as a CMOS input when CNV- is grounded otherwise CNV+, CNV- are LVDS inputs.10, 11 D-, D+ D0 LVDS Data Outputs.The conversion data is output serially on these pins.12 VIO P Input/Output Interface Supply. Nominally 2.5V. 13 GND P Ground. 14, 15 DCO-, DCO+ DI/O LVDS Buffered Clock Outputs.When DCO+ is grounded, the self-clock interface mode is selected. In this mode, the 16 bit results on D is preceded by a three bit header (010) to allow synchronization of the data by the digital host with simple logic.When DCO+ is not grounded, the echoed clock interface mode is selected. In this mode, DCO± is a copy of CLK±. The data bits are output on the falling edge of DCO+ and can be latched in the digital host on the next rising edge of DCO+.16, 17 CLK-, CLK+ DI LVDS Clock Inputs.This clock shifts out the conversion results on the negative edge of CLK+.Preliminary Technical DataAD7625Rev. PrB | Page 7 of 11Pin No. Mnemonic Type 1 Description 18 VDD2 P Analog 2.5V Supply. 19, 20 VDD1P Analog 5V supply. Isolate from Pin 1 with a ferrite bead. 21 VCMAO Common Mode Output.When using any reference scheme, this pin produces ½ of the voltage present on the REF pin which can be useful for driving the common mode of the input amplifiers.22 IN- AI Differential Negative Analog Input.Referenced to and must be driven 180° out of phase with IN+.23 IN+ AI Differential Positive Analog Input.Referenced to and must be driven 180° out of phase with IN-.24 GND P Ground.25, 26, 28 CAP2 AO Connect all three pins to a single 10uF X5R capacitor with the shortest distance. The other side of thecapacitor must be placed close to pin 27 (GND). 27 GND P Ground.Return path for 10uF capacitor connected to pins 25, 26, and 28.29, 30,32 REF AI/O Buffered Reference Voltage. When using the internal reference or 1.2V external reference (REFIN input), the 4.096V system referenceis produced at this pin.When using an external reference, like the ADR434 or ADR444, the internal reference buffer must be disabled.In either case, connect all three pins to a single 10uF X5R capacitor with the shortest distance. The other side of the capacitor must be placed close to pin 31 (GND)31 GND P Ground.Return path for 10uF capacitor connected to pins 29, 30, and 32.1AI = analog input; AI/O = bidirectional analog; AO = analog output; DI = digital input; DI/O = bidirectional digital; DO = digital output; P = power.AD7625Preliminary Technical DataRev. PrB | Page 8 of 11TERMINOLOGYLeast Significant Bit (LSB)The least significant bit, or LSB, is the smallest increment that can be represented by a converter. For a fully differential input ADC with N bits of resolution, the LSB expressed in volts isNINp-p V V LSB 2)(=Integral Nonlinearity Error (INL)Linearity error refers to the deviation of each individual code from a line drawn from negative full scale through positive full-scale. The point used as negative full scale occurs a ½ LSB before the first code transition. Positive full scale is defined as a level 1½ LSBs beyond the last code transition. The deviation is meas-ured from the middle of each code to the true straight line. Differential Nonlinearity Error (DNL)In an ideal ADC, code transitions are 1 LSB apart. Differential nonlinearity is the maximum deviation from this ideal value. It is often specified in terms of resolution for which no missing codes are guaranteed. Zero ErrorThe difference between the ideal midscale input voltage (0 V) and the actual voltage producing the midscale output code. Gain ErrorThe first transition (from 100 ... 00 to 100 ... 01) should occur at a level ½ LSB above nominal negative full scale (−4.095938 V for the ±4.096V V range). The last transition (from 011 … 10 to 011 … 11) should occur for an analog voltage 1½ LSB below the nominal full scale (+4.095813 V for the ±4.096V range). The gain error is the deviation of the difference between the actual level of the last transition and the actual level of the first transition from the difference between the ideal levels. Dynamic RangeDynamic range is the ratio of the rms value of the full scale to the rms noise measured for an input typically at −60 dB. The value for dynamic range is expressed in decibels. Signal-to-Noise Ratio (SNR)SNR is the ratio of the rms value of the actual input signal to the rms sum of all other spectral components below the Nyquist frequency, excluding harmonics and dc. The value for SNR is expressed in decibels. Total Harmonic Distortion (THD)THD is the ratio of the rms sum of the first five harmonic components to the rms value of a full-scale input signal and is expressed in decibels.Signal-to-(Noise + Distortion) Ratio (SINAD)SINAD is the ratio of the rms value of the actual input signal to the rms sum of all other spectral components below the Nyquist frequency, including harmonics but excluding dc. The value for SINAD is expressed in decibels. Spurious-Free Dynamic Range (SFDR)The difference, in decibels (dB), between the rms amplitude of the input signal and the peak spurious signal. Effective Number of Bits (ENOB)ENOB is a measurement of the resolution with a sine wave input. It is related to SINAD and is expressed in bits byENOB = [(SINAD dB − 1.76)/6.02] Aperture DelayAperture delay is a measure of the acquisition performance measured from the falling edge of the CNVST input to when the input signal is held for a conversion. Transient ResponseThe time required for the AD7634 to achieve its rated accuracy after a full-scale step function is applied to its input. Reference Voltage Temperature CoefficientReference voltage temperature coefficient is derived from the typical shift of output voltage at 25°C on a sample of parts at the maximum and minimum reference output voltage (V REF ) measured at T MIN , T(25°C), and T MAX . It is expressed in ppm/°C as610C 25((C ppm/××°=°)T –T ()(V )Min V –)Max V )(TCV MIN MAX REF REF REF REFwhere:V REF (Max ) = maximum V REF at T MIN , T(25°C), or T MAX . V REF (Min ) = minimum V REF at T MIN , T(25°C), or T MAX . V REF (25°C ) = V REF at 25°C. T MAX = +85°C. T MIN = –40°C.Preliminary Technical DataAD7625Rev. PrB | Page 9 of 11THEORY OF OPERATIONEchoed-Clock Interface ModeThe AD7626 digital operation in “echoed-clock interface mode” is shown in Figure 3. This interface mode, requiring just a shift register on the digital host, can be used with many digital hosts (FPGA, shift register, microprocessor, etc.). It requires 3 LVDS pairs (D±, CLK±, and DCO±) between each AD7626 and the digital host.The clock DCO is a buffered copy of CLK and synchronous to the data, D, which is updated on DCO+ falling edge (t D ). By keeping good propagation delay matching between D and DCO through the board and the digital host, DCO can be can be used to latch D with good timing margin for the shift register. Conversions are initiated by a CNV pulse. The CNV must be returned low ≤ t CNVH (max) for valid operation. Once aconversion has begun, it continues until completion. Additional CNV pulses are ignored during the conversion phase. After the time t MSB elapses, the host should begin to burst the CLK. Note that t MSB is the maximum time for the MSB of the newconversion result and should be used as the gating device for CLK. The echoed clock, DCO, and data, D, will be driven in phase with D being updated on the DCO+ falling edge and the host should use the DCO+ rising edge to capture D. The only requirement is that the 16 CLK pulses finish before the time t CLKL elapses of the next conversion phase or the data will be lost. From the time t CLKL to t MSB , D and DCO will be driven to 0’s.CLK+CNV+DCO+D+SAMPLE ND-CLK-CNV-DCO-Figure 3. Echoed-Clock Interface Mode Timing DiagramAD7625Preliminary Technical DataRev. PrB | Page 10 of 11Self Clocked ModeThe AD7626 digital operation in “self-clocked interface mode” is shown in Figure 4. This interface mode reduces the number of wires between ADCs and the digital host to 2 LVDS pairs per AD7626, CLK± and D± or a single pair if sharing a common CLK using multiple AD7626’s. This considerably eases the design of a system using multiple AD7626’s since the interface can tolerate several CLK cycles of propagation delay mismatch between the different AD7626 devices and the digital host. The “self-clocked interface mode” consists of preceding each ADC word results by a header of 2 bits on the data, D This header is used to synchronize D of each conversion in the digital host. Synchronization is accomplished by one simple state machine per AD7626 device. The state machine is running, for instance, at the same speed as CLK with 3 phases. The state machine measures when the first “one” of the header occurs. This provides the value of the actual propagation delay delta between the state machine clock and D including any board propagation time allowing to use the best clock signal to latch the following bits of the conversion result.Conversions are initiated by a CNV pulse. The CNV must be returned low ≤ t CNVH (max) for valid operation. Once aconversion has begun, it continues until completion. Additional CNV pulses are ignored during the conversion phase. After the time t MSB elapses, the host should begin to burst the CLK. Note that t MSB is the maximum time for the first bit of the header and should be used as the gating device for CLK. CLK is also used internally on the host to begin the internal synchronization state machine. The next header bit and conversion results are output on subsequent falling edges of CLK. The onlyrequirement is that the 18 CLK pulses finish before the time t CLKL elapses of the next conversion phase or the data will be lost.CNV+SAMPLE NSAMPLE N+1CNV-Figure 4. Self-Clocked Interface Mode Timing Diagram 11This timing is for silicon rev 1 or above. For silicon rev 0, there is an extra bit (a zero) in front on the bit with value 1. Therefore, silicon rev 0 needs 19 clock pulses.Preliminary Technical DataAD7625OUTLINE DIMENSIONSCOMPLIANT TO JEDEC STANDARDS MO-220-VHHD-2PLANECOPLANARITY0.08Figure 5.32-Lead Lead Frame Chip Scale package [LFCSP_VQ]5 mm × 5 mm Body, Very Thin Quad(CP-32-3)©2008 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. PR07652-0-6/08(PrB)元器件交易网。

FOX connector10FOX-A1_REFER_ASSY B10-FOXK-LF S10-FOXK-LF CPT connector02CPT-B-2A 04CPT-B1-2A 08CPT-B-2A08CPT-B1-2A 08CPT-B1-2A 12CPT-B-2A 16CPT-B-2A 20CPT-B-2A 24CPT-B-2A BM08B-CPTK-1A-TB SM02B-CPTK-1A-TBSM02B-CPTK-1A-TB SM04B1-CPTK-1A-TBSM08B-CPTK-1A-TB SM08B1-CPTK-1A-TBSM12B-CPTK-1A-TB SM16B-CPTK-1A-TBSM20B-CPTK-1A-TB SM24B-CPTK-1A-TBMEC connector05MEC-B-1A 08MEC-B-1A 10MEC-B-1A 10MEC-B-2A 18MEC-B-2A 20MEC-B-2A2 24MEC-B-2A S05B-MECK-1GA-AS10B-MECK-2GA-A S18B-MECK-1GA-AS18B-MECK-2GA-A SM20B-MECK-2TC2-A-TBSM24B-MECK-2TA-A-TBHIC connector08HIC-P-1A 08HIC-P-2A 08HIC-R-1AHIT connectorHITPB-25-B-S HITPB-25-C-LE HITPB-25-D-K HITPB-25-E-N HITPB-25-F-PK HITPB-27-A-LM HITPB-28-G-HAIT connectorAITPB-C08-1A-K AITWSB-10-2AK S04B1-AIT-A1A-KSS08B1-AIT-A1A-KS S10B-AIT-A1A-KS-(M)(LF)(SN)S20B-AIT-A2A-KS S52B-AIT-A23-SS-(M)(LF)(SN)HCH connectorHCHFB-09-KE HCMPB-04-K SM04B-HCHK-TB SM09B-HCHK-TBHCM connectorB03B-HCMKS B04B-HCMKS-2R B04B-HCMKS-RB04B-HCMKS-RA B05B-AHCMKK B05B-HCMKS-RB05B-HCMSS-R B05B2-AHCMKS-A B06B-HCMKKB06B-HCMSK HCMDPB-08-S HCMDPB-09-K HCMDWPB-04-K HCMDWSB-04-S HCMPB-03-K HCMPB-04-K HCMPB-05-K HCMPB-05-S HCMPB-06-K HCMPB-12-K HCMPB-A05-K HCMPB-A12-K HCMPB-C06A-K HCMWPB-05-K HCMWSB-05-K S03B1-HCMKS S04B1-HCMKSS04B1A-HCMKSEVZ2 connector10EVZ-B-K-1A 10EVZ-B-K-2A 27EVZ-B-K-2A27ZRO-B-1A 36EVZ-B-K-2A 36ZRO-B-1ABU10B-EVZ2K-2A1 BU10B-EVZ2K-2A3 BU27B-EVZ2K-2A1 BU27B-EVZ2K-2A3 BU36B-EVZ2K-2A1 BU36B-EVZ2K-2A3ACA connector32GIT-A1_REFER_ASSY SM32B-ACAK-1A-01MAIT-II connectorAIT2PB-02A-1FS AIT2PB-02G-1AK AIT2PB-03B-1AK AIT2PB-04B-1AK AIT2PB-04G-1AK AIT2PB-06-1AK AIT2PB-07-1BH AIT2PB-07-1FS AIT2PB-10-1AK AIT2PB-10P-2AK AIT2PB-18-2AK AIT2PB-22-2AK AIT2WSB-02A-1AK AIT2WSB-03A-1AK AIT2WSB-06-1AK AIT2WSB-10A-2AK AIT2WSB-10A-2BH AIT2WSB-22-2AK B04BA-AIT2-1AK B06BA-AIT2-1AK-K S02BA-AIT2-1AKS02BA-AIT2-1FS S06B-AIT2-1AK S10B-AIT2-2AKS10B-AIT2G-1AD S10B-AIT2G-2AK S18B-AIT2G-2AD S18B-AIT2G-2BD S18B-AIT2G-2DM S20B-AIT2G-2A2BK S22B-AIT2G-2AKARV connectorARVPB-12-2AK ARVPB-12C12-2AK ARVPB-18-3AK ARVPB-18C18-3AK ARVPB-22-3AK ARVPB-22C22-3AK ARVWSB-12B-2AK ARVWSB-12BC-2AK ARVWSB-18-3AK ARVWSB-18C-3AK ARVWSB-22-3AK ARVWSB-22C-3AKASG connectorASGPB-1547R2A-K ASGPB-2547L2A-K ASGPB-47L1A-K ASGPB-F1947R-3AKASU connectorASU-4RASM-12T1-K1-TRATL connectorATLPB-21-2AK S21BA-ATL-2AKATLC connectorATLCPB-21-2AY ATLCPB-21-2BHATSS connectorATSSCC-08-K ATSSPB-C08C-1AKBCC connectorBCCRB-14-1A-K BCCRB-14-2A-SCIT connector08CIT-B-1A 16CIT-B-1A 16CIT-B-2A23CIT-B-1A S36B-CITYTP-01B S60B-CITYTP-01BCN connector (For automotive)CNB-01AH CNP-01VCPI connector24CPT-B-2A S58B-CPIK-1A (M) S69B-CPIK-1A (M)EA2 connectorEA2-1RAS-12T100-K1-TRFAB connectorFABPB-02-2BA-K FABRB-02-1A-K SABC-02-1A-WGIT connector50GIT-A1_REFER_ASSYGIT connector (18P type)18GIT-A1_REFER_ASSY 18GIT-A2_REFER_ASSY S18B-GIT01-1A-01HIE connectorHIE-N19R-S02AHPS connectorHPSPB-C40C09-AK HPSPB-C40C12-AK HPSPB-C40C21-BH HPSPB-C40C31-BH HPSWC-40-KHSDP connectorB04B-HSDP-2BH B04B-HSDP-2DM B04B-HSDP-2FS HSDPPB-04-2BH HSDPPB-04-2DM HSDPPB-04-2FSHVD connector09HVD6B-EMGF-NRHVGW connector02HVGW-A1_REFER_ASSY B02-HVGT-BS B02-HVGW-AK HVGWPB-G02-BDJIA connector74JIA-RB-2E-K JIAHC-74H-1A-K S132B-JIA-1C-HK S74B-JIA-1C-HKMIO connectorB16B-MIOS MIOPB-16-SSMSA connector20MSA-PB-1A-A-K 20MSA-RBC-1A-A-KMWT connectorMWTPB-06-1A-R MWTPC-06-1A-R MWTRB-06-1A-RNFG connector03NFG-B-1ARAD connectorRADPB-44-1AK S44B-RAD1AKSAB connectorSABC-02-1A-W SABPB-02-1A-Y SABPB-04-1A-Y SABRB-02-1A-Y SABRB-04-1A-YSAC connectorSACWPB-04-K SACWSB-04-KSBO connectorSSBO-0.2SPT-M0.55-L LFSHC connector10SHC-B-1A 14SHC-B-1A 24SHC-B-1A26SHC-B-1A 26SHC-B-2A 32SHC-B-1AS10B-SHCH-1A (M) S14B-SHCH-1A (M) S14B-SHCH-1A RS24B-SHCH-1A (M) S24B-SHCH-1A R S26B-SHCH-1A (M) S26B-SHCH-1A R S26B-SHCH-2A (M) S26B-SHCH-2A RS32B-SHCH-1A (M) S32B-SHCH-1A RSHUNT RING02-SQS-GF-1A-E 02-SQS-GF-1A-K 02-SQS-GF-1A-LP02-SQS-GF-1A-N 02-SQS-GF-1A-Y 02-SQS-GF-1B-M02-SQS-GF-1C-D 02-SQS-GF-2A-E 02-SQS-GF-2A-K02-SQS-GF-2A-LP 02-SQS-GF-2A-R 02-SQS-GF-2A-Y02-SQS-GF-2B-H 02-SQS-GF-2B-M 02-SQS-GF-2C-D02-SQS-GF-2C-MK 02-SQS-GF-2C-PSNA connectorSNAMB-02UN-1AYK SNAMB-05UN-1FYS SNAPB-02UN-1AYK SNAPB-05UN-1FYSSPH2 connector02SPH2-P-1D 02SPH2-R-1KSQB connector02SQB-SGJ-1A-PK_REFER_ASSY 02SQB-SGJ-1B-DV_REFER_ASSY 02SQB-SGJ-1C-H_REFER_ASSY 02SQB-SGJ-1D-M_REFER_ASSYSQF connector02SQF-A1_REFER_ASSYSQM connector02SQM-A1_REFER_ASSY 02SQM-C1_REFER_ASSYSQS connector02SQS-A1_REFER_ASSYSQSK connector02-SQSK-GI-2A-K 02SQSK-A1_REFER_ASSY02SQSK-C1_REFER_ASSY SQSKC-02H-1A-DSQSKL-02H-2A-Y SQSKR-02H-1A-KSQW connector02SQW-A1_REFER_ASSYSQXW connector02SQXW-A1_REFER_ASSY 02SQXW-B1_REFER_ASSY02SQXW-C1_REFER_ASSYSQZ connector02SQZS-SGJ-1A-K_REFER_ASSY 02SQZS-SGJ-1C-Y_REFER_ASSY 02SQZS-SGJ-1B-LM_REFER_ASSYSRV connectorSRVPB-A05-H SRVPB-B04-S SRVPB-C03-N SRVPB-D02-K SRVWSB-02A-DK SRVWSB-03A-CN SRVWSB-04A-BS SRVWSB-05A-AHTRZ connectorS46B-TRZY-D-1B TRZPB-22-A-Y TRZPB-24-A-YWIC connector36WIC-B-1A-01 40WIC-B-1A-01 S22(76)B-WICP05-1AZRO connector36ZRO-B-1A 48ZRO-B-1A S36B-ZROK-2A-RS48B-ZROK-2A-R ZROHC-36H-K-1 ZROHC-48H-K-1。