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PICMG microTCA.0 Specification RC1.0ContentsIntroduction and objectives1.1 Overview1.2 Introduction1.2.1S1.2.2 MicroTCa implementation options1画1-21.2.3 Design goals1-21.2.4 Elements of microtca1-312.5 Theory of operation……着1国面1面日正1-81.3 Micro TCA enclosure types191.3.1 Single Shelf implementation191.3.2 TWo Tier mⅸ ed Width Shelf implementation.…….….….….….….….…....1-101.3.3 Two-Tier fixed Single Width Shelf implementation ....................1-101.3.4 Back-to-Back Shelf implementation.1-101.3.5 Cube Shelf implementation..1-101.3.6 Pico Shelf implementations1111.3.7 Other implementation options1111.4 Application examples1-1114.1 Base station…1-111.42 Router1-121.4.3∨ olP node.….1-121.4.4 Other Telecom Network applicationsE画1-121.4.5 Enterprise applications1-131.4.6 Other applications.....1-131.4.7 Consumer applications1-131.5 Special word usage1-131.6 Conformance1-141.7 Dimensions1-141.8 Regulatory guidelines1-141.9 Reference specifications1.10 MicroTCA0 Specification contributor……1-151-161.11 Name and logo usage1-161.12 Intellectual property……1-171.12.1 Necessary claims1,,面,国国,,国面正∴1-181.12.2 Unnecessary claims11181.12. 3 Third party disclosures1-181.13 Glossary1-192Mechanical2-12.1 Mechanical overview∴………….2-12.1.1 Terminology…2-22.1.2 Typical arrangement examples2-22.2 Dimensions, tolerances, drawing symbols, and nomenclature2-62.3 Mechanical concept2-82.4 AdvancedMC Module orientation, location, and positioning2-1624.1 Module orientation.2-162.4.2 Module positioning, horizontal--mandatory2-172.4.3 Module positioning, vertical-mandatoryU.882-192. 4. 4 Module positioning, depth--mandatory,.42-21PICMG( Micro TCAO Specification Draft RC1. 0, May 26, 2006Do not specify or claim compliance with this Draft Specification2.5 Slot detail dimensions2-222.5.1S|ot..2-222.5.2 Slot configurations, subdividing Slots2-222.5.3 Card guide, Strut, and Card Guide Support Plate(CGSP)…………2232.5.4 Optional Subrack attachment plane2-322.5.5 AdvancedMC Module--optional locking………………………2-342.6 Backplane2-3627 Subrack dimensions2-412.7.1 Mandatory Subrack2-422.8 Shelf2-472.8. 1 Shelf types.2-482.8.2 Shelf width and height…...…2-492.8.3 Shelf depth2-492.8.4 Air filter provision2-502.8.5 ESD wrist strap interface2-502.8.6 Shelf alarm LEDs2-512.9 Cable management2-522. 10 Power entry /Power Module2-562.10.1 Power Module pcb dimensions2-582.10.2 Power Module component height1·面2-632.10.3 Power module face plate2-642.10. 4 Power Module handle/Latch mechanism.2672.10.5 Power module lEDs2-672. 10.6 Power Module EMc gasketing2-672.10.7 Power Module satety covers2-672.10 8 Power module labels2-682.10. 9 Power Module Backplane Connector2-682.11 MCH Module2-692.11.1 Module types2-692.11.2 MCH PCB dimensions.2-702.11.3 MCH Subrack slot details2-772.11. 4 Plug Connector.2-792.11.5 Sequencing and contact area2-812.11.6 MCH positioning2-812. 12 Air flow management面2-822.13 Auxiliary Connector(Zone 2 and zone 3)keying2-832.13.1 Component keep- in height2-842.13.2 Connector keep-in height2-842.133 Keying block…2-852.13.5 AMC0 electrically compatible keying block2.13. 4 Keying block with electrical connections2-86.2-872.14 MicroTCa cube2892.15 MicroTCA Pico2.16 Microtca filler pane的∵面1面面,面2-902-902.17 Cooling Units(CUs)2-912.18 Subrack/Shelf/Cube/Pico performance.2922. 18.1 Load carrying2-922.18.2 Insertion cycles2922.18.3ESD2-922.18.4EMC2-93PICMG MicroTCA. 0 Specification Draft RC1.O, May 26, 2006Do not specify or claim compliance with this Draft Specification2. 18.5 Safety2-932.18.6 Physical Slot and Tier numbering2932.19 Subrack/Shelf environmental2-962.19. 1 Subrack shock and vibration2-962.19.2 Earthquake.........2-962.19.3 Flammability2-962.19.4 Atmospheric2-962. 19.5 Thermal2-972.19.6 Acoustic∴…………………2972.19.7 Surface temperatures2-972.20 References2-973 Hardware platform management3-13.1 Overview3.1.1 Micro Tca Carrier model3-13.1.3 Relationship with IPMI, AdvancedMC, and AdvancedTCA.3.1.2 MicroTCA management architecture3-23-73.1.4 Key differences from PICMG 3.0 and AMC.0 specifications..........3-73.1.5 PICMG properties and FRU Device ID assignments3-93.2 Management-related interconnects3-113.2.1 AdvancedMc interconnects3-113.2.2 Power Module and Cooling Unit interconnects3.2.3 Guidelines for OEM Module interconnects and management3-133-143.2.4 Carrier FRU Information device requirements.3-153.25 Microtca carrier interconnects3-193.3 Carrier Manager.…….…..…...…3-203.3.1 MCH Face Plate indicators3-223.3.2 Payload Interface3-223.3.3 Carrier Manager IP address3-223.3.4 IPM event support∴3-243.3.5 Redundant MCH operation3-253.3.6 Addressing3-263.3.7 Carrier number3-293.3.8 Location information34 Shelf Manager…3-383. 4.1 Shelf Manager configuration options383.4.2 Differences from the AdvancedTca shelf Manager3-403.4.3 Shelf-Carrier Manager Interface翻套国画1面,国面,1面D国画面国3-423.4.4 Shelf Manager IP addre3-433.5 MCMC requirements3453.6 EMMC requirements3-463.7 Operational state management3-483.7.1 Carrier Manager start up……….….….….………..……3483.7.2 Shelf Manager actions on Carrier detection3-483.7.3 Normal Shelf operation1B面面国B3-483.7.4 Abnormal situation handling3-4938 Power management.……3-493.8.1 Power clapping国面3-503.8.2 Micro T CA Carrier Power Management records.3-513.8.3 Early power management356PICMG( Micro TCAO Specification Draft RC1. 0, May 26, 2006Do not specify or claim compliance with this Draft Specification3.8.4 Normal power management.3-573.8.5 Power management commands and sensors3-593.8.6 Abnormal power condition handling3-673.9 Cooling management3-693.9.1 Fan geography.…3-703.9.2 Cooling control…3-713.9.3 Normal cooling operation3-723.9.4 Abnormal cooling operation3-733.9.5 Fan tachometer sensors3-733.9.6 Temperature sensors翻画1国翻B1B…3-733.10 Electronic Keying3-743.10.1 Micro TCA Carrier point-to-point connectivity information3-753.10.2 Module point-to-point connectivity information.3-773.10.3 AMC Port state commands3-783.10.4 Clock b- Keying……3-783.11 Telco alarm management3-73. 12 System Event log…………3-863.13 Sensor management3-863.13.1 Guidelines and requirements for fru sensor events3-863.13.2 MCMC SDR requirements.3-873.13.3 EMMC SDR requirements3-883.13.4 Carrier Manager SDR requirements3-883.14 fru Information.3-913. 14.1 EMMC FRU Information3-913. 14.2 MCMC FRU Information3-913.143 Carrier FRu Information3-923. 14.4 Shelf fru information面国面国面3-923.15 PMI message bridging……….3-933.15.1 Message bridging process3-933.16 PMI functions and command3-943. 16.1 Required IPMI functions..3-953.16.2 Command assignments3-973.17 FRU records, sensors and entity Ids∴3-1084 Power…4-14.1 Overview4-14.2 Loads on the Power Subsystem4-24.2.1 Microtca carrier hub(MCH),………,………………………24-24.2.2 Cooling Units4-74.2.3 Advanced mezzanine cards4-104.3 Power architecture4-134.3.1 Basic functionality4-134.3.2 Partitioning of the Power Subsystem:.::a:.4-154.3.3 Power sources4-154.3. 4 Power Subsystem redundancy4-164.3.5 System Grounding considerations4-214.3.6 Power distribution and backplane considerations4-234.4 Control and monitoring of the Power Subsystem4-2444.1 PM-EMMCs4-244.4.2 Geographic Address4-24PICMG MicroTCA. 0 Specification Draft RC1.O, May 26, 2006Do not specify or claim compliance with this Draft Specification4.4.3|PMB-04-2444.4Ps1[S|o#4-254.4.5EN[Slof]#,…4-2544.6 PWRON_[Sot]…4-254.4.7PSPM#4-2644.8 PM-EMMC watchdog timer……4264.4.9 Power Module oK4-2744.10 Power module reset4-274.4.11 System power-up4-274.4.12 Input voltage sensors1国面面量面1国面4-294.4.13 Temperature sensors4-294414 Power module extraction switch4-304,415 Blue lED4-304.4.16LED14-314 4.17 Other leds4-314.5 Connectors4-314.5. 1 Power Module Output Connector4-324.5.2 Power Module Input Connectors81国面面4-324.6 Single-Width,Fu‖- Height Power Module…∴4-334.6.1 Inputs4-344.6.2 Outputs4-354.6.3 Bulk supply current limit4-384.6.4 Control and monitoring………………………4-384.6.5 Redundancy4-384.6.6 Mechanical4-4546.7 Thermals.8...8.88.84-45画·面4.6.8 Regulatory.4-4547 Other mechanical considerations…4-464.7.1 Double-Width form factor4-464.7.2 Form factors other than Full-Height4-464.8 Power source considerations.4-464.8.1 DC power feeds4-474.8.2 AC power feeds4-554.9 References4-605 Thermal5.1 Overview5-15.2 AMC. 0 Modules and microtCa国着画5-15.3 AMC.0 Carriers and microtca5.4 Subrack slot5-25.5 Airflow path5.6 AMC.0 Modules and power dissipation.5-35-35.7 MicroTCA system cooling configuration……….….….…....545. 8 Air distribution in a slot5-45.9 Air inlet and exhaust5-55. 10 Slot cooling capability5-55. 11 Module cooling requirements●5.12 Standard air.5-75.12.1 Derivatie5.122 Barometric changes due to weather....…...……….57PICMG( Micro TCAO Specification Draft RC1. 0, May 26, 2006Do not specify or claim compliance with this Draft Specification5.13 Slot impedance curve.5-85.14 Slot fan flow curve5.15 Cooling Unit failure5-85.16 Filters5.17 System sensors….…….….……5-95.18 Thermal and operating environment5-105.19 Thermal and cabling5-105.20 Simulation and impedance testing5-105.20.1 AdvancedMC/MCH reference Module..5-115.20.2 Power Unit reference module∴5-125.21 Simulation environment5.22 Thermal dynamic modeling5-135.23 Fluid networking modeling5.24 Acoustic noise5-135.25 Surface temperature5-145.26 Design recommendations5-155.27 Cooling limitations and examples..5-175.28 References1面5-226 Interconnect6-16.1 Introduction.…6-16.2 Fabric interface6.2.1 Backplane fabric interface support requirements6-26.2.2 MCH fabric interface support requirements6.3 MCH Specific Interfaces6-46.3.1 MCH update Channel interface6-46.3.2 MCH cross-over Channel interface.6-56. 3. 3 MCH PWR ON interface6-66.3.4 Inter-MCH IPMB-L interface6.4 Synchronization clock interface6.4.1 Signal descriptions6-86. 4.2 Clock architectures6-96.4.3 Non-Telecom and Telecom clocks6-136.5 JTAG interface.…6-136.5.1 JSM Overview6-146.5.2 JSM Signaling Overview6-166.5.3 JSM Interface to mch16.54 JSM Interface to mch2.……6-186.5.5 JSM Interface to Advancedmcs.6-196.5.6 JSM Interface to Power modules.6-226.5.7 JSM Master mode selection6-236.5.8 JSM Interface to External tester..6-246.5.9 MCH JTAG6-266.5. 10 Power module jtAG6-276.6 MicroTCA Interface topologies1画6-276.6. 1 Topology models6-286.6.2 Correlation to AdvancedMc fabric regions6-296.7 MCH Connector pin allocation6-306.7.1 Pin naming conventions6-316.7.2 Fabric interface naming conventions6-31PICMG MicroTCA. 0 Specification Draft RC1.o, May 26, 2006Do not specify or claim compliance with this Draft Specification6.7.3 Synchronization clock interface naming convention6-316.7.4 MCH Connector pin list……………6-326.8 System examples.6-386.8. 1 Redundant MicroTCA system6-386.8.2 Variant redundant microtca interconnect6-416.8.3 Non-redundant MicroTCA system6-45Connectors7-17.1 General information7-17.2 AdvancedMC Backplane Connectors7-17.2.1 AdvancedMC Backplane Connector pin list7-27.2.2 AdvancedMC Backplane Connector dimensions7-27.2.3 Advancedmc backplane connector pcb layout∴7-67. 2. 4 AdvancedMC Backplane Connector electrical characteristics7-107.2.5 AdvancedMC Backplane Connector high-speed characteristics7-147.2.6 AdvancedMC Backplane Connector mechanical characteristics7-187.3 Micro TCa Carrier hub connectors7-197.3.1 Micro TCA Carrier Hub Connector pin list7-197.3.2 Micro TCA Carrier Hub mating interface design7-207.3.3 Micro TCA Carrier Hub backplane connector7-227.3. 4 Micro TCA Carrier Hub Connector Backplane PCB layout7-237. 3.5 Micro tca Carrier Hub connector electrical characteristics7-247.3.6 Micro TCA Carrier Hub Connector high-speed characteristics7-2573.7 Micro tCa Carrier hub connector mechanical characteristics7-297.4 Power Module Output Connector7.4.1 Power Module Output Connector pin list and mating sequence7-317.4.2 Power Module Output Connector dimensions7-327. 4.3 Power Module Output Connector Backplane PCb layout7-347.4.4 Electrical characteristics for power Module output connector.7-367.4.5 Power Module Output Connector mechanical characteristics7-397.5 Power Module Input Connector7.5.1 Power Module Input Connector pin list and mating sequence7-417.5.2 Power Module Input Connector dimensions7-427.5.3 Electrical characteristics for Power Module Input Connector7-477.5.4 Power Module Input Connector mechanical characteristics7-517.6 AdvancedMC Auxiliary Connector7-537.7 Test schedule7-547.7.1 Specimen measurement arrangements7-547.7.2 Test schedule tables.7-647. 8 References.7-798 Regulatory requirements and industry standard guidelines8-18.1 Regulatory……8-18.1.1 Safety8-18.1.2 Electromagnetic compatibility..……………8-28.1.3 Ecology standards.8-28.2 Telecommunications industry standards requirements8-38. 2. 1 EMC/safety requirements for the telecommunications industry.......8-38.2.2 Environmental requirements for the telecommunications industry ..............8-48.3 Reliability/MTBF standards8-7PICMG( Micro TCAO Specification Draft RC1. 0, May 26, 2006Do not specify or claim compliance with this Draft Specification8.4 Cross reference list8.5 FRU test guidelines∴8-78.5. 1 FRU safety test8-88.5.2 FRU EMC testing.8-88.5.3 FRU environmental testing8-9a Module mis-insertion considerationsA-1A 1 MCH Module mis-insertion combinationsA-2A 2 AdvancedMc module mis-insertion combinationsA-5A3 Power management implicationsA-8A 4 System management implicationsA-8A.4.1 Optional MMC instance on MCH ModuleA-9A.4.2 Using an AdvancedMC in an MCH SlotA-13A.4.3 Using an mch in an AdvancedMc SlotA-15A.4.4 Detecting mis-insertionsA-16A.5 Hardware implicationsA-1A. 5. 1 GNd pins at same locations........A-20A.5.2 PSO# and PS1# pins at same locationsA-23A.5.3 PWR and MP pins at same locationsA27A.5. 4 PWR ON pinA-29A.5.5 Ga[2: 0] pins at same locations道1面4…A-31A.5.6 ENABLE# pin at same locationA-35A.5.7 SDA L and SCL L pinsA-37A 5.8 JTAG pinsA-38A 5.9 Cross-over pinsA-39A.5. 10 TMREQ#, 12C SDA, and I2C SCL pins…A-39B Requirement list….B-1PICMG MicroTCA. 0 Specification Draft RC1.O, May 26, 2006Do not specify or claim compliance with this Draft Specification

使用trackball和glm，可以读取和显示obj文件，并进行旋转与缩放。运行环境：vs2010， 运行后用o或者O选择obj文件，+和-进行缩放

C++面向对象的有限元程序设计,空间8结点等参元的分析计算第二章有限元分析计算的理论基础(空间8结点等参元)有限元法进行的前提是满足四个假定:连续性假定、完全弹性假定、均匀与各向同性假定、小变形和小位移假定。有限元法是建立在弹性力学的基础之上的。它是以平衡微分方程(数学上)、变形协调方程(几何方程)、本构方程(物理方程)作为基本的理论方程,同时又有圣维南原理、基于能量形式的虚位移原理作为解决问题的手段。有限元法是依照弹性力学的基本解法进行求解的,不论有限元法的哪种单元类型,在求解的过程和步骤上都是一样的,只不过求解的具体方法和细节处理有所不同。本文就以空间8结点等参元的求解的过程为例来进行编程,别的单元类型可以自己开发。而且,有了面向对象的于段,许多单元类型可以用继承的方式加以实现。2.1自然坐标系与位移模式自然坐标系与直角坐标系,如图(-1,-1,1)58(-1,1,1)X(1,-1,1)67(1,1,14(-1s3(1.1,1)局部自然坐标系与整体直角坐标系之间的关系(2-1)其屮N是关于三个自然坐标系变量;.,t的矩阵,x,y1,21,x2,…,zs是六面体的八个顶点(结点)在直角坐标系下的位置坐标,它们是已知的,xy,z与;s,t就有了对应的关系。N被称为形函数矩阵,N100N0N=0N100NNI小(22)其中N1=N(r,s,t)=(+m)1+.+t11≤i≤8(2-3)整体直角坐标与局部自然坐标的关系又可以表达成:x∑Ny∑N偎定结点间的位移变化是线性的,则位移模式可以表达为:(2-5)其中1,V1,w1,u2,…,ws是八个顶点(结点)的位移。2.2应变与位移间的关系根据变形协调方程,有:OulozAEou Ov(2-6)6×16×24vOw cu其中[B=[B1BB(2-7)ONON0aNB1≤i

做预测的小例子，简单易懂，明了，适合初学者学习使用

TcL Scripting for Cisco IOS.zip TcL Scripting for Cisco IOS.zip TcL Scripting for Cisco IOS.zip TcL Scripting for Cisco IOS.zip TcL Scripting for Cisco IOS.zip TcL Scripting for Cisco IOS.zip TcL Scripting for Cisco IOS.zip TcL Scripting for Cisco IOS.zip

利用xilinx vivado硬件开发套件中的IP核开发的XADC应用，可供参考，也可直接用于FPGA开发中XADC的配置。

蒙特卡罗方法MCMC(里面有应用实例)，个人认为有较强的可读性，还有相应的实例讲解。

java从本地读文件并上传Hbase

【实例简介】使用EMIF将Xilinx_FPGA与TI_DSP平台接口,使用EMIF将Xilinx_FPGA与TI_DSP平台接口

基于LabVIEW的五子棋游戏 目录摘要Abstract第1章  前言  1第2章  LabVIEW简介  22.1 LabVIEW的概念. 22.2 LabVIEW的特点. 2第3章 总体设计方案  33.1五子棋游戏规则. 33.2游戏设计框图. 33.3游戏设计流程图. 43.3.1总体设计流程图. 43.3.2人机对弈模式下的游戏流程图. 43.3.3双人对弈模式下的游戏流程图. 5第4章 各模块程序设计  74.1初始棋盘模块. 74.2多步计算模块. 74.2.1多步计算流程图. 74.2.2多步计算前面板及程序框图. 84.3决定下子方模块. 104.4判定胜负模块. 104.4.1判定胜负模块设计前面板及程序框图. 104.5胜负对话模块. 11第5章 主程序设计  145.1游戏主程序设计. 145.1.1五子棋主程序的程序框图. 145.1.2五子棋的游戏界面. 155.2结果演示. 16第6章  结束语  17参考文献  18答谢辞  19