Explain how to open the Waveform Viewer for Verification ? State how to insert nodes into the Waveform Viewer ? Tell how to assign Stimulus with the Stimulator Selector
标签: Foundation 仿真
上传时间: 2013-11-05
上传用户:gps6888
中文版详情浏览:http://www.elecfans.com/emb/fpga/20130715324029.html Xilinx UltraScale:The Next-Generation Architecture for Your Next-Generation Architecture The Xilinx® UltraScale™ architecture delivers unprecedented levels of integration and capability with ASIC-class system- level performance for the most demanding applications. The UltraScale architecture is the industr y's f irst application of leading-edge ASIC architectural enhancements in an All Programmable architecture that scales from 20 nm planar through 16 nm FinFET technologies and beyond, in addition to scaling from monolithic through 3D ICs. Through analytical co-optimization with the X ilinx V ivado® Design Suite, the UltraScale architecture provides massive routing capacity while intelligently resolving typical bottlenecks in ways never before possible. This design synergy achieves greater than 90% utilization with no performance degradation. Some of the UltraScale architecture breakthroughs include: • Strategic placement (virtually anywhere on the die) of ASIC-like system clocks, reducing clock skew by up to 50% • Latency-producing pipelining is virtually unnecessary in systems with massively parallel bus architecture, increasing system speed and capability • Potential timing-closure problems and interconnect bottlenecks are eliminated, even in systems requiring 90% or more resource utilization • 3D IC integration makes it possible to build larger devices one process generation ahead of the current industr y standard • Greatly increased system performance, including multi-gigabit serial transceivers, I/O, and memor y bandwidth is available within even smaller system power budgets • Greatly enhanced DSP and packet handling The Xilinx UltraScale architecture opens up whole new dimensions for designers of ultra-high-capacity solutions.
标签: UltraScale Xilinx 架构
上传时间: 2013-11-21
上传用户:wxqman
Prakash Rashinkar has over 15 years experience in system design and verificationof embedded systems for communication satellites, launch vehicles and spacecraftground systems, high-performance computing, switching, multimedia, and wirelessapplications. Prakash graduated with an MSEE from Regional Engineering College,Warangal, in India. He lead the team that was responsible for delivering themethodologies for SOC verification at Cadence Design Systems. Prakash is anactive member of the VSIA Functional Verification DWG. He is currently Architectin the Vertical Markets and Design Environments Group at Cadence.
上传时间: 2013-11-19
上传用户:m62383408
The LogiCORE™ GTP Wizard automates the task of creating HDL wrappers to configure the high-speed serial GTP transceivers in Virtex™-5 LXT and SXT devices. The menu-driven interface allows one or more GTP transceivers to be configured using pre-definedtemplates for popular industry standards, or from scratch, to support a wide variety of custom protocols.The Wizard produces a wrapper, an example design, and a testbench for rapid integration and verification of the serial interface with your custom function Features• Creates customized HDL wrappers to configureVirtex-5 RocketIO™ GTP transceivers• Users can configure Virtex-5 GTP transceivers toconform to industry standard protocols usingpredefined templates, or tailor the templates forcustom protocols• Included protocol templates provide support for thefollowing specifications: Aurora, CPRI, FibreChannel 1x, Gigabit Ethernet, HD-SDI, OBSAI,OC3, OC12, OC48, PCI Express® (PCIe®), SATA,SATA II, and XAUI• Automatically configures analog settings• Each custom wrapper includes example design, testbench; and both implementation and simulation scripts
标签: Transceiver Virtex Wizar GTP
上传时间: 2013-10-20
上传用户:dave520l
磁芯电感器的谐波失真分析 摘 要:简述了改进铁氧体软磁材料比损耗系数和磁滞常数ηB,从而降低总谐波失真THD的历史过程,分析了诸多因数对谐波测量的影响,提出了磁心性能的调控方向。 关键词:比损耗系数, 磁滞常数ηB ,直流偏置特性DC-Bias,总谐波失真THD Analysis on THD of the fer rite co res u se d i n i nductancShi Yan Nanjing Finemag Technology Co. Ltd., Nanjing 210033 Abstract: Histrory of decreasing THD by improving the ratio loss coefficient and hysteresis constant of soft magnetic ferrite is briefly narrated. The effect of many factors which affect the harmonic wave testing is analysed. The way of improving the performance of ferrite cores is put forward. Key words: ratio loss coefficient,hysteresis constant,DC-Bias,THD 近年来,变压器生产厂家和软磁铁氧体生产厂家,在电感器和变压器产品的总谐波失真指标控制上,进行了深入的探讨和广泛的合作,逐步弄清了一些似是而非的问题。从工艺技术上采取了不少有效措施,促进了质量问题的迅速解决。本文将就此热门话题作一些粗浅探讨。 一、 历史回顾 总谐波失真(Total harmonic distortion) ,简称THD,并不是什么新的概念,早在几十年前的载波通信技术中就已有严格要求<1>。1978年邮电部公布的标准YD/Z17-78“载波用铁氧体罐形磁心”中,规定了高μQ材料制作的无中心柱配对罐形磁心详细的测试电路和方法。如图一电路所示,利用LC组成的150KHz低通滤波器在高电平输入的情况下测量磁心产生的非线性失真。这种相对比较的实用方法,专用于无中心柱配对罐形磁心的谐波衰耗测试。 这种磁心主要用于载波电报、电话设备的遥测振荡器和线路放大器系统,其非线性失真有很严格的要求。 图中 ZD —— QF867 型阻容式载频振荡器,输出阻抗 150Ω, Ld47 —— 47KHz 低通滤波器,阻抗 150Ω,阻带衰耗大于61dB, Lg88 ——并联高低通滤波器,阻抗 150Ω,三次谐波衰耗大于61dB Ld88 ——并联高低通滤波器,阻抗 150Ω,三次谐波衰耗大于61dB FD —— 30~50KHz 放大器, 阻抗 150Ω, 增益不小于 43 dB,三次谐波衰耗b3(0)≥91 dB, DP —— Qp373 选频电平表,输入高阻抗, L ——被测无心罐形磁心及线圈, C ——聚苯乙烯薄膜电容器CMO-100V-707APF±0.5%,二只。 测量时,所配用线圈应用丝包铜电磁线SQJ9×0.12(JB661-75)在直径为16.1mm的线架上绕制 120 匝, (线架为一格) , 其空心电感值为 318μH(误差1%) 被测磁心配对安装好后,先调节振荡器频率为 36.6~40KHz, 使输出电平值为+17.4 dB, 即选频表在 22′端子测得的主波电平 (P2)为+17.4 dB,然后在33′端子处测得输出的三次谐波电平(P3), 则三次谐波衰耗值为:b3(+2)= P2+S+ P3 式中:S 为放大器增益dB 从以往的资料引证, 就可以发现谐波失真的测量是一项很精细的工作,其中测量系统的高、低通滤波器,信号源和放大器本身的三次谐波衰耗控制很严,阻抗必须匹配,薄膜电容器的非线性也有相应要求。滤波器的电感全由不带任何磁介质的大空心线圈绕成,以保证本身的“洁净” ,不至于造成对磁心分选的误判。 为了满足多路通信整机的小型化和稳定性要求, 必须生产低损耗高稳定磁心。上世纪 70 年代初,1409 所和四机部、邮电部各厂,从工艺上改变了推板空气窑烧结,出窑后经真空罐冷却的落后方式,改用真空炉,并控制烧结、冷却气氛。技术上采用共沉淀法攻关试制出了μQ乘积 60 万和 100 万的低损耗高稳定材料,在此基础上,还实现了高μ7000~10000材料的突破,从而大大缩短了与国外企业的技术差异。当时正处于通信技术由FDM(频率划分调制)向PCM(脉冲编码调制) 转换时期, 日本人明石雅夫发表了μQ乘积125 万为 0.8×10 ,100KHz)的超优铁氧体材料<3>,其磁滞系数降为优铁
上传时间: 2013-12-15
上传用户:天空说我在
解压密码:www.elecfans.com 随着微电子技术的迅速发展以及集成电路规模不断提高,对电路性能的设计 要求越来越严格,这势必对用于大规模集成电路设计的EDA 工具提出越来越高的 要求。自1972 年美国加利福尼亚大学柏克莱分校电机工程和计算机科学系开发 的用于集成电路性能分析的电路模拟程序SPICE(Simulation Program with IC Emphasis)诞生以来,为适应现代微电子工业的发展,各种用于集成电路设计的 电路模拟分析工具不断涌现。HSPICE 是Meta-Software 公司为集成电路设计中 的稳态分析,瞬态分析和频域分析等电路性能的模拟分析而开发的一个商业化通 用电路模拟程序,它在柏克莱的SPICE(1972 年推出),MicroSim公司的PSPICE (1984 年推出)以及其它电路分析软件的基础上,又加入了一些新的功能,经 过不断的改进,目前已被许多公司、大学和研究开发机构广泛应用。HSPICE 可 与许多主要的EDA 设计工具,诸如Candence,Workview 等兼容,能提供许多重要 的针对集成电路性能的电路仿真和设计结果。采用HSPICE 软件可以在直流到高 于100MHz 的微波频率范围内对电路作精确的仿真、分析和优化。在实际应用中, HSPICE能提供关键性的电路模拟和设计方案,并且应用HSPICE进行电路模拟时, 其电路规模仅取决于用户计算机的实际存储器容量。 The HSPICE Integrator Program enables qualified EDA vendors to integrate their products with the de facto standard HSPICE simulator, HSPICE RF simulator, and WaveView Analyzer™. In addition, qualified HSPICE Integrator Program members have access to HSPICE integrator application programming interfaces (APIs). Collaboration between HSPICE Integrator Program members will enable customers to achieve more thorough design verification in a shorter period of time from the improvements offered by inter-company EDA design solutions.
上传时间: 2013-10-18
上传用户:s363994250
影响汽油发动机排放的最主要因素是混合气的空燃比, 理论上一公斤燃料完全燃烧时需要14.7公斤的空气。这种空气和燃料的比例称为化学当量比。空燃比小于化学当量比时供给浓混合气,此时发动机发出的功率大,但燃烧不完全,生成的CO、HC多;当混合气略大于化学当量比时,燃烧效率最高,燃油消耗量低,但生成的NOx也最多;供给稀混合气时,燃烧速度变慢,燃烧不稳定,使得HC增多。在电控汽油喷射系统中采用闭环控制的方式,将空燃比控制在化学当量比附近,并在排气系统中消声器前安装一个三元催化转化器,对发动机进行后处理,是当前减少汽车排气污染物的最有效方法。在化学当量比附近,转化器的净化效率最高。
上传时间: 2013-11-14
上传用户:bvdragon
Explain how to open the Waveform Viewer for Verification ? State how to insert nodes into the Waveform Viewer ? Tell how to assign Stimulus with the Stimulator Selector
标签: Foundation 仿真
上传时间: 2013-10-29
上传用户:daguogai
基本矩阵运算 : + - *, power, transpose, trace, determinant, minor, matrix of minor, cofactor, matrix of cofactor, adjoint, inverse, gauss, gaussjordan, linear transformation, LU decomposition , Gram-Schmidt process, similarity. b) Basic vectors functions : norm, distance, innerproduct,coldim, rowdim, rank, nullity. *
标签: matrix minor determinant transpose
上传时间: 2013-12-09
上传用户:541657925
This code may be reused for any educational or non-commercial application without further licence Contact the author at BrianLBurns@att.net for any other use.
标签: non-commercial application educational further
上传时间: 2014-07-27
上传用户:jennyzai
