STBK568中文资料

DS04-28203-4EFUJITSU SEMICONDUCTORDATA SHEETASSP Image ProcessingBIPOLARA/D Converter(1-channel, 8-bit low-power model with built-in clamp circuit)MB40568s DESCRIPTIONThe MB40568 is an all-parallel (flash type) A/D converter for 8-bit video applications, and uses high-speed bipolar process technology for low-power consumption and high-speed conversion.This A/D converter is capable of converting analog signals into digital signals at a rate of DC to 20 MSPS (megasamples per second). Additional circuitry including a clamp circuit and reference voltage generator circuits are build in, to make the MB40568 ideally suited for video signal processing.s FEATURES•Resolution: 8 bits•Linearity error: ±0.15 % typ.•Maximum conversion rate: 20 MSPS min.•Analog input voltage:0 to 3 V in 2 V P-P (clamp circuit)3 to 5 V (without clamp circuit)•Digital input/output level: TTL Levels•Power supply voltage: +5 V single power supply •Power dissipation: 200 mW typ.2MB40568s PIN ASSIGNMENTSs PIN DESCRIPTIONS(Continued)Pin no.Symbol FunctionDIP SOP 1, 111, 11 D.GND Ground pinShould be connected to the analog system ground.2 to 9 2 to 9D 8 to D 1Digital signal output pin 1010CLK Clock input pin12, 2212, 24 A.GND Ground pinShould be connected to the analog system ground.13, 2113, 23V CCDPower supply voltage input pinAlso functions as V CCA power supply, and should be in the same voltage level as V CCA pin.14, 2014, 22V CCAPower supply voltage input pinAlso functions as V CCD power supply, and should be in the same voltage level as V CCD pin.1515V INCClamp circuit input pinThe clamp circuit is a diode-clamp type sync chip clamp circuit.Should be shorted to ground if the clamp circuit is not used.1616V OUTCClamp circuit output pinA capacitor of at least 1 µF should be connected between this pin and the V CLMP pin.Should be left open if the clamp circuit is not used.MB40568(Continued)Pin no.Symbol FunctionDIP SOP1717V CLMP Clamp voltage output pinA capacitor of at least 1 µF should be connected between this pinand the V OUTC pin.Should be left open if the clamp circuit is not used.1818V INA Analog signal input pin19—V RB Analog reference voltage pinIn the DIP model, this pin is internally connected to the referencecircuit.Always be sure that a capacitor is connected immediately next to theIC, between this pin and the ground. The capacitor must be at least1 µF with excellent frequency characteristics.—19V RM Reference voltage monitor pinSet to the midpoint of resistance between V CCA and V RB.Should be left open in normal use.—20V REF Reference voltage output pinShould be left open when no reference voltage source is used.—21V RB Analog reference voltage input pinWhen an internal reference voltage source is used, this pin shouldbe shorted to the V REF pin. In this case, always be sure that acapacitor is connected immediately next to the IC, between this pinand the ground. The capacitor must be at least 1 µF with excellentfrequency characteristics.When an external reference voltage source is used, this pin willcarry a current of up to 8.5 mA, therefore it is necessary to use avoltage source with sufficient sync capacity.A capacitor connection should also be used similar to that used withinternal reference voltage sources.3MB40568s BLOCK DIAGRAMS 1.SK-DIP4MB40568 2.SOP56MB40568s ABSOLUTE MAXIMUM RATINGS (See WARNING)* :Package : SOPV CCA = 2.0 ± 0.1 V , V RB = 2.0 ± 0.1 VWARNING:Permanent device damage may occur if the above Absolute Maximum Ratings are exceeded.Functional operation should be restricted to the conditions as detailed in the operational sections of this data sheet. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.s RECOMMENDED OPERATING CONDITIONS*1:V CCA and V CCD must be used in the same voltage level.*2:Package : SOPV CCA = 2.0 ± 0.1 V , V RB = 2.0 ± 0.1 V*3:V INC must have an amplitude of V CCA – V CLMP .ParameterSymbol Rating Unit Power supply voltage V CCA , V CCD –0.5 to +7.0V Digital input voltage V IND –0.5 to +7.0V Analog input voltage V INA –0.5 to V CC + 0.5V Analog reference voltage*V RB –0.5 to V CC + 0.5V Clamp circuit input voltage V INC –0.5 to V CC + 0.5V Storage temperatureTstg–55 to +125°CParameterSymbol ValueUnit Min.Typ.Max.Power supply voltage*1V CCA , V CCD 4.75 5.00 5.25V Analog input voltage V INA V RB —V CCA V Analog reference voltage*2V RB 2.753 3.25V Clamp circuit input voltage*3V INC 0—3V Clamp capacitanceC CLMP 1——µF Digital high-level output voltage I OH –400——µA Digital low-level output voltage I OL —— 1.6mA Clock pulse width at high-level t W +22.5——ns Clock pulse width at low-level t W –22.5——ns Operating temperatureT op—70°C7MB40568s ELECTRIC CHARACTERISTICS1.DC Characteristics(1)Analog DC Characteristics(V CCA = V CCD = 4.75 to 5.25 V , T a = 0°C to +70°C)* :V CCA = V CCD = 5.00 V , T a = +25°C (2)Digital DC Characteristics(V CCA = V CCD = 4.75 to 5.25 V , T a = 0°C to +70°C)* :V CCA = V CCD = 5.00 V , T a = +25°CParameterSymbol ValueUnit RemarksMin.Typ.Max.Resolution ———8bits Linearity error*LE —±0.15±0.3%DC Accuracy Equivalent analog input resistance R INA 300——k ΩAnalog input capacitance C INA —4050pF f INA = 1MHz Analog high-level input current I IHA ——45µA V INA = V CCA Analog low-level input current I ILA ——40µA V INA = V RB Clamp circuit input currentI INC –600–200—µAV INC = 0 V Reference voltageV RB0.6 × V CC–0.10.6 × V CC0.6 × V CC+0.1VSK-DIP22P packageV REFSOP24P package Short between V REF and V RB Clamp voltage V CLMP —V RB + 0.2—V Reference currentI RB–8.5–5.5–3.0mASOP24P packageParameterSymbol ValueUnit Remarks Min.Typ.Max.Digital high-level output voltage V OH 2.7——V I OH = –400 µA Digital low-level output voltage V OL ——0.4V I OL = 1.6 mADigital high-level input voltage V IHD 2.0——V Digital low-level input voltage V ILD ——0.8V Maximum input current I ID ——100µA V ID = 7 V High-level input current I IHD —020µA V IHD = 2.7 V Digital low-level input current I ILD –100–10—µA V ILD = 0.4 VPower supply currentI CC—40*85mAR INA =V CCA – V RB I IHA – I ILA8MB405682.Switching Characteristics(V CCA = V CCD = 4.75 to 5.25 V , T a = 0°C to +70°C)s TIMING DIAGRAMParameterSymbol ValueUnit Min.Typ.Max.Maximum conversion rate f S 20——MSPS Digital output delay timet pd81530nsMB40568 s TYPICAL CHARACTERISTIC CURVES(Continued)9MB40568(Continued)(Continued) 10(Continued)s EQUIVALENT CIRCUIT1.Analog Input Equivalent Circuit2.Equivalent Circuit of Clamp Circuit Block3.Equivalent Circuit of Reference Circuit Block4.Digital Input Equivalent Circuit5.Load Circuit for Output Buffers LINEARITY ERROR1.Ideal Conversion CharacteristicsThe values for V ZT and V FT are typical values under conditions that V CCA = V CCD = 5.000 V and V RB = 3.000 V.2.Actual Conversion Characteristicss CLAMP CIRCUIT OPERATIONThe MB40568’s internal clamp circuit is a peak-detection type circuit, which clamps compound synchronized signals using the lowest sync point as clamp voltage (V CLMP ) (see illustration below).The clamp voltage is set at 0.6 × V CC + 0.2 V (typical).If the clamp circuit is not used, the signal pins should be handled as follows:•ClampCircuitPin name Description V INC Connect to GND V OUTC Leave open V CLMPLeave opens TYPICAL CONNECTION EXAMPLES 1.On-Chip Input PNP Transistor Utilized2.Input PNP Transistor of Clamp Circuit is Put Externallys ORDERING INFORMATIONPart number Package Remarks MB40568P-SK20 pin Plastic SK-DIP(DIP-20P-M04)MB40568PF24 pin Plastic SOP(FPT-24P-M02)s PACKAGE DIMENSIONS(Continued)21MEMO 22MEMO2324FUJITSU LIMITEDFor further information please contact:JapanFUJITSU LIMITEDCorporate Global Business Support DivisionElectronic DevicesKAWASAKI PLANT, 4-1-1, KamikodanakaNakahara-ku, Kawasaki-shiKanagawa 211-88, JapanT el: (044) 754-3763Fax: (044) 754-3329North and South AmericaFUJITSU MICROELECTRONICS, INC.Semiconductor Division3545 North First StreetSan Jose, CA 95134-1804, U.S.A.T el: (408) 922-9000Fax: (408) 432-9044/9045EuropeFUJITSU MIKROELEKTRONIK GmbHAm Siebenstein 6-1063303 Dreieich-BuchschlagGermanyT el: (06103) 690-0Fax: (06103) 690-122Asia PacificFUJITSU MICROELECTRONICS ASIA PTE. LIMITED#05-08, 151 Lorong ChuanNew T ech ParkSingapore 556741T el: (65) 281-0770Fax: (65) 281-0220F9702©FUJITSU LIMITED Printed in JapanAll Rights Reserved.Circuit diagrams utilizing Fujitsu products are included as ameans of illustrating typical semiconductor applications. Com-plete information sufficient for construction purposes is not nec-essarily given.The information contained in this document has been carefullychecked and is believed to be reliable. However, Fujitsu as-sumes no responsibility for inaccuracies.The information contained in this document does not convey anylicense under the copyrights, patent rights or trademarks claimedand owned by Fujitsu.Fujitsu reserves the right to change products or specificationswithout notice.No part of this publication may be copied or reproduced in anyform or by any means, or transferred to any third party withoutprior written consent of Fujitsu.The information contained in this document are not intended foruse with equipments which require extremely high reliabilitysuch as aerospace equipments, undersea repeaters, nuclear con-trol systems or medical equipments for life support.*DS04-28203。

QB568油墨耐乙醇、耐碱、耐酸、耐水检验方法
1、检验原理
经干燥的油墨与规定浓度的酸、碱、醇和水溶液浸透的滤纸接触，在一定压力下，经过一定时间，根据油墨刮样变化情况及渗透染色滤纸张数评级并以之表示油墨耐酸、碱、乙醇及水的性能。

2、工具及材料
(1)调墨刀。

(2)刮墨刀。

(3)小玻璃板(9.5cm×6cm)。

(4)1000g砝码。

(5)定性滤纸(直径11cm)。

(6)1000ml蒸发皿。

(7)蒸馏水。

(8)1%氢氧化钠溶液。

(9)1%盐酸溶液。

(10)95%乙醇溶液。

(11)小镊子。

3、检验方法
（1）将受检测油墨用调墨刀调少量放于刮样纸中上方，持刮墨刀自上而下用力刮于刮样上，使之均匀分布在刮样上，剪去黑色部分。

然后，在常温条件下放置、干燥24h(个别品种可适当延长)。

（2）取小玻璃板置于平面工作台上，将刮样的1/2平放于玻璃板。

（3）在100ml蒸发皿中注入溶液，取定性滤纸10张，将镊子夹在滤纸一端浸入溶液至完全浸透，取出，覆盖于油墨刮样1/2部分.
（4）将另一块玻璃压在滤纸上，并加一个砝码静置24h后取下砝码及玻璃板，稍干后，检验刮样变色情况及染渗滤纸张数，按下列规定平定等级。

4、注意事项
①接触油墨刮样的第一张滤纸不计在内。

②试验中加滤纸不染色，可根据下表中刮样变化程度评级。

③耐乙醇试验因试剂挥发较快，所以测试时要放到可封闭之盒内，其他操作相同。

④做空白试验对比，以便观察纸张在溶液中的变化，定级时应减除纸张变化因素。

油墨耐抗性级别。

TIA/EIA-568-B理解标准568A：绿白-1，绿-2，橙白-3，蓝-4，蓝白-5，橙-6，褐白-7，褐-8；标准568B：橙白-1，橙-2，绿白-3，蓝-4，蓝白-5，绿-6，褐白-7，褐-8。

美国电子工业协会（EIA）美国电信工业协会（TIA）568,应该是标准的序号，就和1394一样。

A，B 应该是标准的具体方案版本序号。

EIA/TIA-568 标准分A 和B打线的标准不一样EIA/TIA的布线标准中规定了两种双绞线的线序568A与568B。

标准568A：绿白，绿，橙白，蓝，蓝白，橙，棕白，棕；标准568B：橙白，橙，绿白，蓝，蓝白，绿，棕白，棕。

EIA/TIA的布线标准中规定了两种双绞线的线序568A与568B。

标准568A：绿白-1，绿-2，橙白-3，蓝-4，蓝白-5，橙-6，棕白-7，棕-8；标准568B：橙白-1，橙-2，绿白-3，蓝-4，蓝白-5，绿-6，棕白-7，棕-8。

在整个网络布线中应用一种布线方式，但两端都有RJ45端头的网络连线无论是采用端接方式A，还是端接方式B，在网络中都是通用的。

实际应用中，大多数都使用T568B的标准，通常认为该标准对电磁干扰的屏蔽更好。

交叉线是指：一端是568A标准，另一端是568B标准的双绞线。

直连线是指：两端都是568A或都是568B标准的双绞线。

顺便说一下，许多朋友在做RJ45头的时候，只是保证线两端的顺序一一对应，却并未按照568A/568B的排线标准去做。

这样虽能连通网络，但这种线的抗干扰性非常差，经常出现诸如传输速度慢、网络时好时坏的情况。

希望大家在做网线的时候一定按照标准去做，并且根据实际的工程经验网线长度最好不小于1.5米，这对提高网络的稳定性是非常必要的！下面让我们看看如何正确选用直连线和双绞线。

当以下设备互联时，需使用直连线：1. 将交换机或HUB与路由器连接；2. 计算机（包括服务器和工作站）与交换机或HUB连接。

而这些设备互联时，则需使用交叉线：1．交换机与交换机之间通过UPLINKS口连接；2． HUB与交换机连接；3． HUB与HUB 之间连接；4．两台PC直接相连；5．路由器接口与其它路由器接口的连接；6． Ethernet接口的ADSL Modem连接到PC机的网卡接口。

标准T568B（正线）白橙、橙、白绿、蓝、白蓝、绿、白棕、棕标准T568A（反线）白绿、绿、白橙、蓝、白蓝、橙、白棕、棕中继器（Repeat）：增加网络节点，放大信号网桥（Bridge）：OSI参考模型第二层，控制广播，维护地址表，只查看MAC地址来过滤网络信息和数据包，不关心协议。

集线器（HUB--共享式集线器）：通过网络传播信号，无过滤功能和路径检测或交换，用于网络集中点Switch（交换式集线器）：第二层数据交换设备，线速交换。

MAC 地址学习；帧过滤，回路避免Router：第三层设备，提供路径选择和数据转发等• 802.1—8 0 2标准的概述。

• 802.2—逻辑链接控制的标准和其他网络连接标准。

• 802.3—带有检测冲突的载波侦听多路存取方法( C S M A / C D )的标准。

• 802.4—传递总线存取的令牌标准。

• 802.5—令牌环存取以及L A N与M A N间通信的标准。

• 802.6—包括高速无连接网络互连在内的L A N和M A N网络标准。

• 802.7—宽带电缆技术标准。

• 802.8—光纤电缆技术标准。

• 802.9—集成网络互连服务(如语音和数据集成)的标准。

• 802.10—L A N和M A N能共同使用的安全性标准。

• 802.11—无线连接标准。

• 802.12—要求优先级存取方法标准。

• 802.14—有线电视宽带通信标准。

常用的网络工具使用熟练使用各种网络工具进行网络分析是每一个数据通信工程师的基本技能*网络的规模越来越大*网络的环境更加复杂*日常网络维护经常使用*深入理解协议的手段课程的目地*熟练使用基本网络命令->ping->tracert->route->arp*掌握路由器升级软件TFTPPing简介*原理：ping向目的主机发出icmp request 报文，目的主机收到后回icmp replay报文，这样就验证了两个节点之间层ip的可达性，网络层是连通的。