参数资料
| 型号: | DS1862B+T&R |
| 厂商: | Maxim Integrated |
| 文件页数: | 38/43页 |
| 文件大小: | 0K |
| 描述: | IC LASR CTRLR 7CHAN 5.5V 25CSBGA |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 类型: | 激光二极管控制器(光纤) |
| 数据速率: | 10Gbps |
| 通道数: | 7 |
| 电源电压: | 2.9 V ~ 5.5 V |
| 电流 - 电源: | 3mA |
| 工作温度: | -40°C ~ 100°C |
| 封装/外壳: | 25-TFBGA,CSPBGA |
| 供应商设备封装: | 25-BGA(5x5) |
| 包装: | 带卷 (TR) |
| 安装类型: | 表面贴装 |
第1页第2页第3页第4页第5页第6页第7页第8页第9页第10页第11页第12页第13页第14页第15页第16页第17页第18页第19页第20页第21页第22页第23页第24页第25页第26页第27页第28页第29页第30页第31页第32页第33页第34页第35页第36页第37页当前第38页第39页第40页第41页第42页第43页
��
�
�XFP� Laser� Control� and� Digital� Diagnostic� IC�
�The� memory� address� is� always� the� second� byte� trans-�
�mitted� during� a� write� operation� following� the� slave�
�address� byte.�
�I� 2� C� Communication�
�Writing� a� single� byte� to� a� slave:� The� master� must�
�generate� a� START� condition,� write� the� slave� address�
�byte� (R/� W� =� 0),� write� the� memory� address,� write� the�
�byte� of� data,� and� generate� a� STOP� condition.�
�Remember� the� master� must� read� the� slave’s� acknowl-�
�edgement� during� all� byte� write� operations.�
�Writing� multiple� bytes� to� a� slave:� To� write� multiple�
�bytes� to� a� slave,� the� master� generates� a� START� condi-�
�tion,� writes� the� slave� address� byte� (R/� W� =� 0),� writes� the�
�memory� address,� writes� up� to� 4� data� bytes,� and� gener-�
�ates� a� STOP� condition.�
�The� DS1862� is� capable� of� writing� 1� to� 4� bytes� (referred�
�to� as� one� row� or� page)� with� a� single� write� transaction.�
�This� is� internally� controlled� by� an� address� counter� that�
�allows� data� to� be� written� to� consecutive� addresses� with-�
�out� transmitting� a� memory� address� before� each� data�
�byte� is� sent.� The� address� counter� limits� the� write� to� one�
�row� of� the� memory� map.� Attempts� to� write� to� additional�
�memory� rows� without� sending� a� STOP� condition�
�between� rows� results� in� the� address� counter� wrapping�
�around� to� the� beginning� address� of� the� present� row.�
�To� prevent� address� wrapping� from� occurring,� the� mas-�
�ter� must� send� a� STOP� condition� at� the� end� of� the� row,�
�and� then� wait� for� the� bus� free� or� EEPROM� write� time� to�
�elapse.� Then� the� master� can� generate� a� new� START�
�condition,� and� write� the� slave� address� byte� (R/� W� =� 0)�
�and� the� first� memory� address� of� the� next� memory� row�
�before� continuing� to� write� data.�
�Acknowledge� polling:� Any� time� EEPROM� is� written,�
�the� DS1862� requires� the� EEPROM� write� time� (t� W� )� after�
�the� STOP� condition� to� write� the� contents� of� the� row� to�
�EEPROM.� During� the� EEPROM� write� time,� the� DS1862�
�does� not� acknowledge� its� slave� address� because� it� is�
�busy.� It� is� possible� to� take� advantage� of� this� phenome-�
�non� by� repeatedly� addressing� the� DS1862,� which�
�allows� the� next� row� to� be� written� as� soon� as� the� DS1862�
�is� ready� to� receive� the� data.� The� alternative� to� acknowl-�
�edge� polling� is� to� wait� for� the� maximum� period� of� t� W� to�
�elapse� before� attempting� to� write� again� to� the� DS1862.�
�EEPROM� write� cycles:� When� EEPROM� writes� occur,�
�the� DS1862� writes� the� whole� EEPROM� memory� 4-byte�
�row� even� if� only� a� single� byte� on� the� row� was� modified.�
�Writes� that� do� not� modify� all� 4� bytes� on� the� row� are�
�allowed� and� do� not� corrupt� the� remaining� bytes� of�
�memory� on� the� same� row.� Because� the� whole� row� is�
�written,� bytes� on� the� row� that� were� not� modified� during�
�the� transaction� are� still� subject� to� a� write� cycle.� This�
�can� result� in� a� whole� row� being� worn� out� over� time� by�
�writing� a� single� byte� repeatedly.� Writing� a� row� one� byte�
�at� a� time� wears� out� the� EEPROM� four� times� faster� than�
�writing� the� entire� row� at� once.� The� DS1862’s� EEPROM�
�write� cycles� are� specified� in� the� Nonvolatile� Memory�
�Characteristics� table.�
�Reading� a� single� byte� from� a� slave:� Unlike� the� write�
�operation� that� uses� the� memory� address� byte� to� define�
�where� the� data� is� to� be� written,� the� read� operation�
�occurs� at� the� present� value� of� the� memory� address�
�counter.� To� read� a� single� byte� from� the� slave� at� the�
�location� currently� in� the� address� counter,� the� master�
�generates� a� START� condition,� writes� the� slave� address�
�byte� with� R/� W� =� 1,� reads� the� data� byte� with� a� NACK� to�
�indicate� the� end� of� the� transfer,� and� generates� a� STOP�
�condition.�
�Manipulating� the� address� counter� for� reads:� A�
�dummy� write� cycle� can� be� used� to� force� the� address�
�counter� to� a� particular� value.� To� do� this� the� master� gen-�
�erates� a� START� condition,� writes� the� slave� address�
�byte� (R/� W� =� 0),� writes� the� memory� address� where� it�
�desires� to� read,� generates� a� REPEATED� START� condi-�
�tion,� writes� the� slave� address� byte� (R/� W� =� 1),� reads�
�data� with� ACK� or� NACK� as� applicable,� and� generates� a�
�STOP� condition.�
�See� Figure� 15� for� a� read� example� using� the� REPEATED�
�START� condition� to� specify� the� starting� memory� location.�
�Reading� multiple� bytes� from� a� slave:� The� read� opera-�
�tion� can� be� used� to� read� multiple� bytes� with� a� single�
�transfer.� When� reading� bytes� from� the� slave,� the� master�
�simply� ACKs� the� data� byte� if� it� desires� to� read� another�
�byte� before� terminating� the� transaction.� After� the� mas-�
�ter� reads� the� last� byte� it� NACKs� to� indicate� the� end� of�
�the� transfer� and� generates� a� STOP� condition.� This� can�
�be� done� with� or� without� modifying� the� address�
�counter’s� location� before� the� read� cycle.� If� the� address�
�counter� reaches� the� last� physical� address,� the� internal�
�index� pointer� loops� back� to� the� first� memory� location� in�
�a� given� memory� table.� For� example,� if� address� FFh� in�
�Table� 02h� is� read,� the� next� byte� of� data� to� be� returned�
�to� the� master� is� address� 80h� in� Table� 02h,� not� 00h� in�
�lower� memory.�
�38�
�____________________________________________________________________�
�相关PDF资料 |
PDF描述 |
|---|---|
| DS1873T+ | IC CTLR SFP+ ANLG LDD 28-TQFN |
| DS1874T+ | IC CTLR SFP+ ANLG LDD 28-TQFN |
| DS2129S+T&R | IC REGULATOR SCSI 16-SOIC |
| DS2438Z+T&R | IC MONITOR SMART BATTERY 8-SOIC |
| DS2703U+ | IC BATT AUTHENTICATE SHA-1 8UMAX |
相关代理商/技术参数 |
参数描述 |
|---|---|
| DS1863 | 制造商:MAXIM 制造商全称:Maxim Integrated Products 功能描述:Burst-Mode PON Controller With Integrated Monitoring |
| DS1863B+ | 制造商:Maxim Integrated Products 功能描述:PON CONTROLLER 16 LEAD BGA PB FREE - Trays |
| DS1863B+T&R | 制造商:Maxim Integrated Products 功能描述:PON CONTROLLER 16 LEAD BGA PB FREE - Tape and Reel |
| DS1863E+ | 功能描述:激光驱动器 Burst-Mode PON Ctlr w/Integrated Mntr RoHS:否 制造商:Micrel 数据速率:4.25 Gbps 工作电源电压:3 V to 3.6 V 电源电流:80 mA 最大工作温度:+ 85 C 封装 / 箱体:QFN-16 封装:Tube |
| DS1863E+R | 制造商:MAXIM 制造商全称:Maxim Integrated Products 功能描述:Burst-Mode PON Controller With Integrated Monitoring |
发布紧急采购,3分钟左右您将得到回复。