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参数资料
| 型号: | IDT70V26L35G |
| 厂商: | IDT, Integrated Device Technology Inc |
| 文件页数: | 15/17页 |
| 文件大小: | 0K |
| 描述: | IC SRAM 256KBIT 35NS 84PGA |
| 标准包装: | 3 |
| 格式 - 存储器: | RAM |
| 存储器类型: | SRAM - 双端口,异步 |
| 存储容量: | 256K(16K x 16) |
| 速度: | 35ns |
| 接口: | 并联 |
| 电源电压: | 3 V ~ 3.6 V |
| 工作温度: | 0°C ~ 70°C |
| 封装/外壳: | 84-BPGA |
| 供应商设备封装: | 84-PGA(27.94x27.94) |
| 包装: | 托盘 |
| 其它名称: | 70V26L35G |
��
�
�IDT70V26S/L�
�High-Speed� 16K� x� 16� Dual-Port� Static� RAM�
�standard� Static� RAM.� Each� of� the� flags� has� a� unique� address� which�
�can� be� accessed� by� either� side� through� address� pins� A� 0� –� A� 2� .� When�
�accessing� the� semaphores,� none� of� the� other� address� pins� has� any�
�effect.�
�When� writing� to� a� semaphore,� only� data� pin� D� 0� is� used.� If� a� LOW�
�level� is� written� into� an� unused� semaphore� location,� that� flag� will� be� set�
�to� a� zero� on� that� side� and� a� one� on� the� other� side� (see� Truth� Table� IV).�
�That� semaphore� can� now� only� be� modified� by� the� side� showing� the�
�zero.� When� a� one� is� written� into� the� same� location� from� the� same� side,�
�the� flag� will� be� set� to� a� one� for� both� sides� (unless� a� semaphore� request�
�from� the� other� side� is� pending)� and� then� can� be� written� to� by� both� sides.�
�The� fact� that� the� side� which� is� able� to� write� a� zero� into� a� semaphore�
�subsequently� locks� out� writes� from� the� other� side� is� what� makes�
�semaphore� flags� useful� in� interprocessor� communications.� (A� thor-�
�ough� discussion� on� the� use� of� this� feature� follows� shortly.)� A� zero�
�written� into� the� same� location� from� the� other� side� will� be� stored� in� the�
�semaphore� request� latch� for� that� side� until� the� semaphore� is� freed� by�
�the� first� side.�
�When� a� semaphore� flag� is� read,� its� value� is� spread� into� all� data� bits�
�so� that� a� flag� that� is� a� one� reads� as� a� one� in� all� data� bits� and� a� flag�
�containing� a� zero� reads� as� all� zeros.� The� read� value� is� latched� into� one�
�side’s� output� register� when� that� side's� semaphore� select� (� SEM� )� and�
�output� enable� (� OE� )� signals� go� active.� This� serves� to� disallow� the�
�semaphore� from� changing� state� in� the� middle� of� a� read� cycle� due� to� a�
�write� cycle� from� the� other� side.� Because� of� this� latch,� a� repeated� read�
�of� a� semaphore� in� a� test� loop� must� cause� either� signal� (� SEM� or� OE� )� to�
�go� inactive� or� the� output� will� never� change.�
�A� sequence� WRITE/READ� must� be� used� by� the� semaphore� in�
�order� to� guarantee� that� no� system� level� contention� will� occur.� A�
�processor� requests� access� to� shared� resources� by� attempting� to� write�
�a� zero� into� a� semaphore� location.� If� the� semaphore� is� already� in� use,�
�the� semaphore� request� latch� will� contain� a� zero,� yet� the� semaphore�
�flag� will� appear� as� one,� a� fact� which� the� processor� will� verify� by� the�
�subsequent� read� (see� Truth� Table� IV).� As� an� example,� assume� a�
�processor� writes� a� zero� to� the� left� port� at� a� free� semaphore� location.� On�
�a� subsequent� read,� the� processor� will� verify� that� it� has� written� success-�
�fully� to� that� location� and� will� assume� control� over� the� resource� in�
�question.� Meanwhile,� if� a� processor� on� the� right� side� attempts� to� write�
�a� zero� to� the� same� semaphore� flag� it� will� fail,� as� will� be� verified� by� the�
�fact� that� a� one� will� be� read� from� that� semaphore� on� the� right� side� during�
�subsequent� read.� Had� a� sequence� of� READ/WRITE� been� used�
�instead,� system� contention� problems� could� have� occurred� during� the�
�gap� between� the� read� and� write� cycles.�
�It� is� important� to� note� that� a� failed� semaphore� request� must� be�
�followed� by� either� repeated� reads� or� by� writing� a� one� into� the� same�
�Industrial� and� Commercial� Temperature� Ranges�
�semaphore� is� requested� and� the� processor� which� requested� it� no�
�longer� needs� the� resource,� the� entire� system� can� hang� up� until� a� one�
�is� written� into� that� semaphore� request� latch.�
�The� critical� case� of� semaphore� timing� is� when� both� sides� request�
�a� single� token� by� attempting� to� write� a� zero� into� it� at� the� same� time.� The�
�semaphore� logic� is� specially� designed� to� resolve� this� problem.� If�
�simultaneous� requests� are� made,� the� logic� guarantees� that� only� one�
�side� receives� the� token.� If� one� side� is� earlier� than� the� other� in� making�
�the� request,� the� first� side� to� make� the� request� will� receive� the� token.� If�
�both� requests� arrive� at� the� same� time,� the� assignment� will� be� arbitrarily�
�made� to� one� port� or� the� other.�
�One� caution� that� should� be� noted� when� using� semaphores� is� that�
�semaphores� alone� do� not� guarantee� that� access� to� a� resource� is�
�secure.� As� with� any� powerful� programming� technique,� if� semaphores�
�are� misused� or� misinterpreted,� a� software� error� can� easily� happen.�
�Initialization� of� the� semaphores� is� not� automatic� and� must� be�
�handled� via� the� initialization� program� at� power-up.� Since� any� sema-�
�phore� request� flag� which� contains� a� zero� must� be� reset� to� a� one,� all�
�semaphores� on� both� sides� should� have� a� one� written� into� them� at�
�initialization� from� both� sides� to� assure� that� they� will� be� free� when�
�needed.�
�Using� Semaphores—Some� Examples�
�Perhaps� the� simplest� application� of� semaphores� is� their� applica-�
�tion� as� resource� markers� for� the� IDT70V26’s� Dual-Port� RAM.� Say� the�
�16K� x� 16� RAM� was� to� be� divided� into� two� 8K� x� 16� blocks� which� were�
�to� be� dedicated� at� any� one� time� to� servicing� either� the� left� or� right� port.�
�Semaphore� 0� could� be� used� to� indicate� the� side� which� would� control�
�the� lower� section� of� memory,� and� Semaphore� 1� could� be� defined� as� the�
�indicator� for� the� upper� section� of� memory.�
�To� take� a� resource,� in� this� example� the� lower� 8K� of� Dual-Port� RAM,�
�the� processor� on� the� left� port� could� write� and� then� read� a� zero� in� to�
�Semaphore� 0.� If� this� task� were� successfully� completed� (a� zero� was�
�read� back� rather� than� a� one),� the� left� processor� would� assume� control�
�of� the� lower� 8K.� Meanwhile� the� right� processor� was� attempting� to� gain�
�control� of� the� resource� after� the� left� processor,� it� would� read� back� a� one�
�in� response� to� the� zero� it� had� attempted� to� write� into� Semaphore� 0.� At�
�this� point,� the� software� could� choose� to� try� and� gain� control� of� the�
�second� 8K� section� by� writing,� then� reading� a� zero� into� Semaphore� 1.�
�If� it� succeeded� in� gaining� control,� it� would� lock� out� the� left� side.�
�Once� the� left� side� was� finished� with� its� task,� it� would� write� a� one� to�
�Semaphore� 0� and� may� then� try� to� gain� access� to� Semaphore� 1.� If�
�Semaphore� 1� was� still� occupied� by� the� right� side,� the� left� side� could�
�location.� The� reason� for� this� is� easily� understood� by� looking� at� the�
�simple� logic� diagram� of� the� semaphore� flag� in� Figure� 4.� Two� sema-�
�phore� request� latches� feed� into� a� semaphore� flag.� Whichever� latch� is�
�first� to� present� a� zero� to� the� semaphore� flag� will� force� its� side� of� the�
�L� PORT�
�SEMAPHORE�
�REQUEST� FLIP� FLOP�
�R� PORT�
�SEMAPHORE�
�REQUEST� FLIP� FLOP�
�semaphore� flag� low� and� the� other� side� HIGH.� This� condition� will�
�continue� until� a� one� is� written� to� the� same� semaphore� request� latch.�
�Should� the� other� side’s� semaphore� request� latch� have� been� written� to�
�D� 0�
�WRITE�
�D�
�Q�
�Q�
�D�
�D� 0�
�WRITE�
�a� zero� in� the� meantime,� the� semaphore� flag� will� flip� over� to� the� other�
�side� as� soon� as� a� one� is� written� into� the� first� side’s� request� latch.� The�
�SEMAPHORE�
�READ�
�SEMAPHORE�
�READ�
�second� side’s� flag� will� now� stay� low� until� its� semaphore� request� latch�
�is� written� to� a� one.� From� this� it� is� easy� to� understand� that,� if� a�
�15�
�6.42�
�Figure� 4.� IDT70V26� Semaphore� Logic�
�2945� drw� 17�
�,�
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相关代理商/技术参数 |
参数描述 |
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| IDT70V26L35J | 功能描述:IC SRAM 256KBIT 35NS 84PLCC RoHS:否 类别:集成电路 (IC) >> 存储器 系列:- 标准包装:1,000 系列:- 格式 - 存储器:RAM 存储器类型:SRAM - 双端口,同步 存储容量:1.125M(32K x 36) 速度:5ns 接口:并联 电源电压:3.15 V ~ 3.45 V 工作温度:-40°C ~ 85°C 封装/外壳:256-LBGA 供应商设备封装:256-CABGA(17x17) 包装:带卷 (TR) 其它名称:70V3579S5BCI8 |
| IDT70V26L35J8 | 功能描述:IC SRAM 256KBIT 35NS 84PLCC RoHS:否 类别:集成电路 (IC) >> 存储器 系列:- 标准包装:1,000 系列:- 格式 - 存储器:RAM 存储器类型:SRAM - 双端口,同步 存储容量:1.125M(32K x 36) 速度:5ns 接口:并联 电源电压:3.15 V ~ 3.45 V 工作温度:-40°C ~ 85°C 封装/外壳:256-LBGA 供应商设备封装:256-CABGA(17x17) 包装:带卷 (TR) 其它名称:70V3579S5BCI8 |
| IDT70V26L55G | 功能描述:IC SRAM 256KBIT 55NS 84PGA RoHS:否 类别:集成电路 (IC) >> 存储器 系列:- 标准包装:3,000 系列:- 格式 - 存储器:EEPROMs - 串行 存储器类型:EEPROM 存储容量:8K (1K x 8) 速度:400kHz 接口:I²C,2 线串口 电源电压:1.7 V ~ 5.5 V 工作温度:-40°C ~ 85°C 封装/外壳:8-SOIC(0.154",3.90mm 宽) 供应商设备封装:8-SOIC 包装:带卷 (TR) |
| IDT70V26L55J | 功能描述:IC SRAM 256KBIT 55NS 84PLCC RoHS:否 类别:集成电路 (IC) >> 存储器 系列:- 标准包装:1,000 系列:- 格式 - 存储器:RAM 存储器类型:SRAM - 双端口,同步 存储容量:1.125M(32K x 36) 速度:5ns 接口:并联 电源电压:3.15 V ~ 3.45 V 工作温度:-40°C ~ 85°C 封装/外壳:256-LBGA 供应商设备封装:256-CABGA(17x17) 包装:带卷 (TR) 其它名称:70V3579S5BCI8 |
| IDT70V26L55J8 | 功能描述:IC SRAM 256KBIT 55NS 84PLCC RoHS:否 类别:集成电路 (IC) >> 存储器 系列:- 标准包装:1,000 系列:- 格式 - 存储器:RAM 存储器类型:SRAM - 双端口,同步 存储容量:1.125M(32K x 36) 速度:5ns 接口:并联 电源电压:3.15 V ~ 3.45 V 工作温度:-40°C ~ 85°C 封装/外壳:256-LBGA 供应商设备封装:256-CABGA(17x17) 包装:带卷 (TR) 其它名称:70V3579S5BCI8 |
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