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ANSYS 17.0网络培训
我们在开发ANSYS 17.0时有一个愿景：让用户的工程仿真体验和产品开发结果改善10倍。为延续这一主题，我们提供了10场网络研讨会，重点介绍了ANSYS解决方案在各领域中的重要发展，其能够帮助您更快速方便地解决产品设计挑战。尽快报名参加其中1场或全部网络培训吧！
Advanced Wireless Communications - February 3, 2016
The Internet of Things & also known as the Industrial Internet and Industry 4.0 & is the network of wireless systems that is rapidly connecting all our electronic devices through the internet. Wireless communication between devices requires a variety of antennas that must work together without interference, even when in close proximity to each other. To be successful, design engineers need to quickly converge on the right system design for a particular set of devices, and validate their performance in real-world operating conditions. The system architecture, including antenna design, is just as important as the signal processing algorithm in this scenario.
Attend this webinar to learn how a communications systems engineering platform based on ANSYS Electronic Desktop with ANSYS HFSS can help you solve your toughest wireless challenges, whether you are designing LTE, 5G, or 802.11xx devices. With a 60 GHz WiGig (802.11ad) MIMO system as an example, we will demonstrate how you can quickly go from initial concept to working high-fidelity models.
Turbomachinery Simulation Productivity Advances with ANSYS 17.0 - February 17, 2016
Today&s turbomachinery designers must improve all aspects of turbomachinery performance, and do it faster than ever. Improvements in simulation productivity based on enhanced software capabilities and increased computing power play a critical role in ensuring that turbomachines operate reliably over a wider range of conditions.
Attend this webinar to learn how you can improve your engineering simulation productivity using our latest software release, ANSYS 17.0. Discover how the new, advanced features of our computational fluid dynamics, structural mechanics and turbomachinery design simulation tools can help you meet the increasingly challenging product design requirements of this field.
10x More Reliable Electronic Systems - February 18, 2016
Once you&ve put in all the hard work of optimizing the design of your electronic system to perform
its required functions, you want it to last as long as possible. But stress, vibration and heat can cause
mechanical failure through breaking of connections, loosening of components or cracking of a circuit
board. Excellence in mechanical as well as electronic design is necessary to ensure the success of
your electronics system.
Attend this webinar to learn how ANSYS Mechanical simulations can significantly increase the
reliability of your electronics systems through mechanical Finite Element Analysis (FEA) models.
Discover how spending a little time performing thermal, stress and vibration simulations can lead to
more robust structural properties, protecting your optimized
electronic system from premature
failure due to mechanical reasons.
HFSS 3D Component：全新的模型建立、保护与使用方式大幅提升仿真效率 - 日
HFSS近两个版本新增并不断完善的3D Component将大幅提升您的仿真效率。该功能可以将任意仿真模型保存为3D Component，包括完备的属性及设置，可帮助工程师与企业积累仿真数据、分享仿真模型、以及复杂模型的快速装配。HFSS 2016版本新增的加密功能，更能帮助您保护知识产权，并实现更方便的协作式仿真。此外，随着3D Component带来的网格装配、网格复用等高级功能将极大提升您的仿真效率。
Toward Virtual System Prototyping: Challenges and Enablers in Modeling Systems - February 23, 2016
As companies strive to advance their modeling and simulation capabilities toward realizing full virtual prototypes of their complex systems, they face a number of challenges associated with assembling multi-domain system models. Beyond the inherent time and budget pressures, companies interact and collaborate with a variety of departments, suppliers, and manufacturers a they must deal with a diverse mixture of tools, modeling formats and conventions
and they must preserve and repurpose an often decades-old legacy of modeling knowledge and assets.
Attend this webinar to learn how modeling languages, reduced-order modeling, and interoperability
standards can help companies to meet these challenges. Standardized interface specifications like the
Functional Mock-up Interface can help departments and supply chains to exchange models and
communicate more effectively. Discover how multi-domain modeling languages, including Modelica and
VHDL-AMS, can combine with ANSYS solutions for more effective system-level simulations.
可穿戴设备及其对人体的影响 - 日
可穿戴设备是整合到用户的衣服或配件的一种便携式设备。可穿戴设备通过软件支持以及数据交互、云端交互来实现强大的功能，例如进行健康跟踪，如血压、脉搏、生命体征和睡眠状况等；亦可通过蓝牙、无线等通信协议查看信息与邮件、接听电话，实现日常健康和娱乐的交互。可穿戴设备将会对我们的生活、感知带来极大的转变。Ansys R16在可穿戴研发过程中考虑在工作过程中可能遇到的各种工况，包括：电子系统中天线、PCB、无线充电，机械系统中可靠性分析、跌落测试、散热、结构强度和疲劳问题，以及芯片及PCB散热分析等全面多物理场分析解决方案。
Get Better, Faster CFD Results with ANSYS Fluent - February 25, 2016
ANSYS 17.0 greatly enhances the ANSYS Fluent user experience, improving the workflow so you can make better, faster decisions to overcome your most difficult product design challenges. ANSYS Fluent
makes it easier than ever for every engineer in your organization to create well-validated CFD simulation
Attend this webinar to receive an overview of the key advances in ANSYS 17.0, including improvements
to workflow and meshing that allow novice users to become productive quickly, along with new tools
that greatly expand opportunities for experienced users to excel. Learn from Andrew Hobbs, Chief
CFD/DEM Engineer at Astec, Inc., a manufacturer of continuous and batch-process plants, how his team
has been using ANSYS Fluent simulation parametric studies to optimize the performance and reduce the
cost of a new hot mix asphalt burner design.
ANSYS SCADE 17.0新特性介绍 - 日
本次网络培训将介绍SCADE 17.0支持专门针对航空、汽车、轨道等行业领域的解决方案，支持FACE, AUTOSAR等下一代开放系统架构，以及ARINC 653、ARINC 429、ARINC 664等行业标准。大大提高了生成代码的性能，显示代码基于OpenGL/ES的渲染速度可提高至十倍。提供了基于模型的自动化测试环境，支持新的人机交互界面自动化测试。R17版本提供了更友好的用户界面，更好的使用体验。同时支持新的FMI 2.0标准，易于将模型嵌入到任何兼容FMI的系统仿真平台中。
Transient Blade Row Enhancements Advance State-of-the-Art for Fluid and Aeromechanical Simulation - March 2, 2016
Improving the aerodynamic or hydrodynamic properties of the blading & the heart of all types of turbomachinery & is essential for enhancing performance and durability of pumps, fans, compressors, turbines, etc. While separate, steady-state fluid and structural performance analyses were the norm, more comprehensive transient simulation, including aeromechanical interactions, is now possible through software advances and increased computing power.
Attend this webinar and learn how the latest enhancements in ANSYS 17.0 advance the state-of-the-art of CFD and aeromechanical simulations. Discover how these powerful new capabilities can be used to effectively improve your designs by better simulating and understanding advanced flow and structural phenomena, as well as the interaction between the two.
TBR模型在叶轮机械三维流场仿真中的应用 - 日
叶轮机械瞬态仿真一直以来被认为是有必要但代价昂贵的。由于转静子的相对运动，前排叶片的尾迹区对后排叶片形成周期性扰动。由于是非定常现象，故一般来说无法在稳态计算中进行模拟。进行稳态计算时，一般处理方法是将前排出口流场进行平均后再赋予后排流场。经历这样的处理后，虽然可实现稳态计算，却丢失了前排尾迹周期性扰动这一重要现象，给稳态计算带来较大误差。而由于叶轮机械单排叶片数为避免共振往往设置成质数，使得通常的周期性边界设置失效，瞬态计算必须对整圈叶片进行仿真，因此需要耗费大量计算资源。ANSYS CFX的TBR模型解决了这一难题，使得用户可对转静子的单叶片通道进行瞬态仿真，从而大大降低了叶轮机械瞬态分析的计算资源与时间花费，使得瞬态分析能够成为叶轮机常规设计的有力工具。
10x Faster Insight for Structural Analysis with ANSYS 17.0 - March 3, 2016
High-performance computing (HPC) is increasing speed in all areas of simulation, including
static and dynamic structural analysis. ANSYS 17.0, provides you with even more HPC speed
than before from multiple enhancements to our core solver capabilities.
Attend this webinar to learn how faster solve times in ANSYS Mechanical using HPC can help
you achieve results quicker and run more models to gain even faster insight into your designs.
Discover how hardware considerations in HPC can impact your structural simulations.
10x Faster Transient Electromagnetic Field Simulation - March 8, 2016
The patent-pending Time Decomposition Method for ANSYS Maxwell, now available in ANSYS 17.0,
delivers a minimum 10x speed and 10x capacity improvement for transient electromagnetic field
simulations. A new algorithm from ANSYS that allows engineers to solve time steps simultaneously as
opposed to sequentially, together with an advanced symmetric multiprocessing (SMP) computer from
SGI, combine to produce these unprecedented simulation enhancements.
Attend this joint ANSYS&SGI webinar to learn how SGI&s UV 3000 advanced SMP computer system
eliminates the risk of simulation failure and lost time due to insufficient computing memory. Discover
ANSYS Maxwell&s Time Decomposition Method leverages SGI&s Hybrid High-Performance
Computing (HPC) architecture by distributing time steps to multiple nodes where multiple cores are
engaged to provide a second layer of computational speed.
ANSYS 17.0结构分析新产品介绍 - 日
ANSYS 17.0产品线全线更新，提供给客户更多更全的结构仿真功能，让客户在结构仿真的能力进一步提升。如果您想了解全新的ANSYS结构仿真产品，请参加这个讲座。
ANSYS 17.0 Advances for Pump Simulation - March 11, 2016
Pumps are used in almost every industry & oil and gas, water, transportation, manufacturing, chemical processing, etc. & as well as in many household appliances. Experts have estimated that pumps consume up to 10 percent of the electricity generated worldwide, producing a significant load on the grid. This major power drain has caused some jurisdictions to establish pump standards requiring high durability and efficiency.
Attend this webinar to discover the latest advances available to pump engineers in the ANSYS pump design and CFD simulation tools included in ANSYS 17.0. Learn how you can increase the fidelity of your simulations and increase design and simulation throughput, enabling you to develop better pumps faster.
Three Advanced Technologies for Faster, More Accurate Turbomachinery Simulation - March 17, 2016
ANSYS 17.0 incorporates the latest advances in turbomachinery engineering simulation to provide
increased efficiency, reliability and durability, as well as reduced noise and emissions (when combustion
is involved). These advances include innovations in blade row modeling, combustion physics, and
turbulence calculations.
Attend this webinar to discover the most important advances for turbomachinery simulation in ANSYS
17.0. Learn how you can obtain a full wheel solution by calculating as few
advances in scale-resolving turbulence methods provide higher fidelity results for combustion
and how a breakthrough, one-equation intermittency-based turbulence transition model
substantially decreases the complexity and solution time of boundary layer simulations.
HFSS 2016混合算法与HPC的新功能与实例演示 - 日
HFSS的算法改进与高性能计算（HPC）性能的增强一直是每个版本更新的重点。本次网络培训将介绍：最新的HFSS 2016版本中，HFSS推出了业界最强的混合算法功能，用户可在同一模型中将FEM、IE、PO三种算法按照需要完全混合使用，从而以最佳的灵活性实现仿真效率、精度的平衡。新版本的HPC增加了对频域算法的GPU加速支持，可进一步发挥硬件的性能，提升仿真速度。本专题将详细介绍HFSS 2016在算法和HPC两方面的新功能改进，并演示实际的仿真案例。
Ten New Advancements in Automotive Simulation with ANSYS 17.0 - March 23, 2016
Engineering simulation is needed more than ever to develop advanced driver assistance systems and, eventually, the autonomous vehicles that are coming extremely close to reality. At the same time as these futuristic designs are being explored, automotive engineers cannot avoid the always pressing need to improve powertrain efficiency, body and chassis systems, and passenger comfort and safety.
Attend this webinar to discover the numerous advances in ANSYS 17.0 that will enable you to meet these design challenges using engineering simulation. Learn how enhancements to ANSYS simulation solutions in our latest release will simplify and accelerate your product development efforts for radar antennas, fuel cells, IC engines, thermal management systems and other components of your next line of automotive vehicles.
Ten New Advancements in Aerospace Simulation with ANSYS 17.0 - March 23, 2016
From improving fuel efficiency to innovating unmanned aerial vehicles to designing the latest components for the private space industry, ANSYS engineering solutions are helping to revolutionize the way we fly. ANSYS 17.0 has many new features to meet the toughest challenges of the rapidly evolving aerospace industry.
Attend this webinar to discover the 10 major advances in core technology areas of aerospace simulation incorporated in ANSYS 17.0. Learn how these simulation enhancements support the industry&s key business initiatives, such as designing aircraft with less environmental impact and improving passenger comfort and safety. We will also discuss the technology behind advances such as composite material curing, integrated icing simulation and a new system avionics package.
ANSYS17.0高科技领域新技术介绍 - 日
ANSYS长期以来不断的致力于新技术的开发,尤其是电、热、应力等多领域的新技术整合，在本此网络培训中,您将可以看到ANSYS在多重领域技术的进步与突破。
芯片封装联合仿真加速电源功耗设计流程 - 日
本次网络培训将介绍ANSYS开发的SoC芯片功耗、噪声及可靠性分析平台RedHawk设计芯片封装联合仿真加速电源功耗设计流程。RedHawk可以实现准确的静态和动态电源噪声分析，电源地和信号电子迁移分析，低功耗设计分析，静电防护分析，基于动态电源噪声的时序抖动分析，自动修复优化，定位电源完整性问题，为系统级分析提供芯片级功耗模型以及3D-IC的功耗分析建模和仿真等功能。同时RedHawk支持封装和板级的抽取模型，使得芯片级的分析更加准确。
ANSYS Savant：电大载体天线布局仿真软件功能介绍与实例演示 - 日
ANSYS Savant是ANSYS的新产品之一，它是一款电大载体天线布局计算软件，采用弹跳射线（SBR）渐进算法，能够快速且精确地预测安装在几十至上千电波长尺寸平台上的装载天线性能，获得多天线之间的互耦效应、空间近/远场分布、辐射场与散射场等结果，并可以与HFSS全波求解器的混合求解，支持CPU及GPU加速。本次网络培训将介绍ANSYS Savant的功能，并展示众多电大尺寸问题的求解案例。
Advances in Turbomachinery Design by Coupling ANSYS and Advanced Design Technology Tools - April 1, 2016
Faced with ever-increasing goals for performance, reliability, cost and time-to-market, turbomachinery designers need enhanced design and analysis tools. Integrating Turbodesign 1 inverse design software from Advanced Design Technology (ADT), based in London, U.K., into ANSYS Workbench has resulted in a major simulation software enhancement for turbomachinery designers.
Attend this webinar to learn how the integrated software enables faster and better aerodynamic or hydrodynamic design of turbomachinery blading. Discover how the software enables execution of parametric studies, response surface and direct optimization within ANSYS Workbench, with seamless data transfer exchange between Turbodesign 1, TurboGrid and CFX.
Ten New Advancements in High Tech Simulation with ANSYS 17.0 - April 6, 2016
Engineering simulation has played a large role in making possible many of the electronic conveniences we take for granted & communication through Internet-enabled phones, electronic payments, and digital streaming, to name just a few. By helping engineers to understand the physics behind the electronics, ANSYS simulation solutions have enabled continuous engineering improvements to be delivered through cheaper, faster, more precise electronics.
Attend this webinar to learn about the advances in our latest release, ANSYS 17.0, which will help you improve product reliability and performance, while reducing design cost and time. Discover how ANSYS electronics and semiconductor simulation solutions can simplify and accelerate your development of secure IP, wireless system and Chip-Package-System designs, along with many other electronic devices.
ANSYS EMIT：系统级射频干扰（RFI）仿真平台功能介绍与实例演示 - 日
ANSYS EMIT是ANSYS的另一款新产品，适用于预测复杂射频（RF）环境中电磁干扰（EMI）的仿真。EMIT提供了一个整体框架，从RF系统性能数据管理，共址与共存EMI效应仿真，到EMI问题改善，能够实现多RF系统平台在整个生命周期内的完整模型仿真设计。EMIT采用独特的多保真方法，能很好预测RF共址/共存干扰，从而实现对复杂RF环境中EMI问题的快速定位及&根源&分析。本次网络培训介绍ANSYS EMIT的功能，并展示系统级EMI分析的案例。
Ten Reasons to Be Excited by ANSYS 17.0 for Turbomachinery Simulation - April 8, 2016
When it comes to turbomachinery simulation software, ANSYS 17.0 contains the most powerful advances ever devised. The speed, fidelity and productivity with which turbomachinery designs can be developed will be impacted by the wide range of software improvements included in this release.
Attend this webinar to discover the most significant general and specific advances in ANSYS 17.0 that will benefit turbomachinery engineers. Learn how enhancements in pre- and post-processing, CFD and mechanical simulation tools will make turbomachinery design faster and easier than before.
PCB板极电热耦合分析及对电子设备热设计的影响 - 日
传统的电子热备热设计时，只考虑PCB板上的芯片功耗作为热源，会导致热分析出来的温度结果偏低。真实情况是：PCB板上的大量的电源/地铜皮或网格铜，既是散热结构也是发热结构，也需要作为热源考虑。本次网络培训将介绍ANSYS 17.0中的新版SIwave可以与电子散热分析软件ANSYS Icepak双向耦合，后台自动进行多次电热迭代，充分考虑温度对材料电气属性的影响，得到考虑板外复杂风道情况下PCB板上的准确温度分布。并利用此时正确的板上功率密度分布和芯片功耗，准确的进行电子设备热分析，验证电子设备散热设计的有效性。
FLUENT MESHING革命性网格生成界面及流程 - 日
本次网络培训将介绍ANSYS全新产品FLUENT MESHING，提供了全新的基于Ribbon风格的界面，提高了操作的便捷性，改善了用户的体验，同时提供了基于包面方法的全自动脚本生成网格、基于ANSA集成FLUENT MESHING的网格生成、基于SCDM结合FLUENT MESHING等多种网格生成流程。
DDR系统虚拟验证平台 - 日
DDR系统的市场应用越来越广泛，其传输速率已经超2Gbps，而随之带来的设计挑战也越来越大，时序裕量变不断变小，系统电平降低，DDR本身的并行传输特性使得信号间的串扰耦合不断加大，设计者必须小心的对待系统中每一个设计因素，封装与PCB布线、ODT配置等。本次网络培训将介绍ANSYS最新发布的电磁仿真软件中集成了全新的DDR系统虚拟验证平台，可以帮助设计者提取封装/PCB等结构的无源传输模型，完成瞬态分析，并通过集成的DDR4/LPDDR5等DDR标准，自动对仿真结果进行测量分析，直接得到DDR系统的Pass/Fail指标，大大提高仿真设计效率，帮助设计者在有限的设计周期内尽可能提高DDR系统的可靠性与稳定性。
嵌入Workbench系统的Forte内燃机流场分析 - 日
自从收购了专注于详细化学反应模拟的专业公司&Reaction Desgin之后，ANSYS将其内燃机仿真产品Forte集成到Workbench内，使得ANSYS对内燃机的缸内仿真能力得到进一步的加强，并为发动机完整仿真流程提供了平台基础。Forte采用KIVA作为内核，并采用了先进的雾化、蒸发、燃烧计算模型，可在不显著增加计算时间的前提下，对几百种组分的燃烧现象进行准确模拟。从而可在较少调试的情况下对压燃和敲缸现象进行精确模拟。其先进的烟气生成机理，完全遵循实际烟气生成机理，从而做到对污染物排放的准确预测。嵌入到workbentch里的Forte计算流程，继承了原来的几何处理、面网格划分及与其他模块无缝对接的优点，使得其仿真能力极大加强。本次网络培训将为您介绍以上课程。
在HFSS 3D Layout中完成PCB版图与三维器件联合仿真 - 日
本次网络培训介绍了ANSYS HFSS 3D Layout产品，ANSYS HFSS 3D Layout产品为PCB版图的仿真提供了全新的网格技术和流程界面，在显著缩短仿真时间的同时也改善了用户操作体验。为了进一步提升HFSS 3D Layout的应用范围，实现对PCB与其他三位器件的联合仿真，在ANSYS 17.0本中增加了三维器件组装的功能，允许用户在HFSS 3D Layout界面中放置连接器等三维部件，从而更好地实现全信号链路的仿真和优化。
Delcross：车载天线布局、车载雷达系统仿真新技术 - 日
车载高频系统广泛应用在车辆的通信,导航,娱乐,遥控,自动驾驶等方面,是车辆系统非常核心的组成部分,多个系统之间的相互兼容工作,直接关系到设备系统的性能甚至安全,在设计之初需要对这些系统的重要电磁辐射单元,即天线系统进行精细的设计和性能仿真评估,最优化天线布局设计,以及天线系统相关的电磁兼容要求.ANSYS提供了从全波电磁算法到高频近似算法的全系完备算法,旗下HFSS软件系列及Delcross软件系列,能解决车载系统从部件,如天线,线缆,车体,到系统级,如车载雷达系统,车载通信系统,车载自动导航系统,等系统级的仿真分析功能. 本次网络培训主要侧重于Delcross系列技术在车载系统级仿真中的应用介绍。
ANSYS17.0在无线传输的新技术发表 - 日
无线传输系统的仿真设计,因为涉及到复杂的3D电磁场耦合技术,所以模拟技术门坎相对高,如何快速、有效、准确的模拟出设计结果是ANSYS长期以来非常专注的问题,本次网络培训中，将介绍ANSYS最新、最有效的无线系统设计方案。
ANSYS17.0在芯片、封装与系统整合的新技术介绍 - 日
芯片的设计微小精密属于micrometer等级,封装的设计需要同时考虑电性耦合、散热与机构强度,结构属于millimeter等级,系统的设计必须考虑功能性与外观,属于centimeter等级,如何将这三个不同领域的技术相结合,设计出更好的产品,一直是高科技设计努力的目标,在本次的训练课程,您将可以看到居于世界领先技术的ANSYS如何有效整合所有的相关技术,带领客户进一步的突破。
ANSYS Fluent & CFX 17.0 新功能介绍 - 日
本次网络培训将介绍全面更新的ANSYS CFD产品。并行计算速度与16.0相比，提升了20%-85%。并行扩展性得到极大提高，12万核并行效率高达90%，可计算20亿网格模型。对于差质量网格的处理功能，使得CFD计算鲁棒性获得显著提高。在操作流程方面，通过对软件界面和功能的修改，极大提升了CFD前后处理的效率和可视性。为了实现更高的精度，ANSYS CFD进一步改进和开发了各个领域的物理模型，显著提高了ANSYS CFD在普通流动、旋转机械、多相流、燃烧、辐射、多孔介质等各个领域内的仿真能力与精度。为提高设计人员的设计效率，ANSYS CFD更开发了锂电池热管理、燃料电池电化学等多个专门模块，使得这些专业的使用者可更方便的进行仿真。
ANSYS CFD 17.0的全新燃烧解决方案 - 日
自从收购了专注于详细化学反应模拟的专业公司&Reaction Desgin之后，ANSYS 在燃烧和化学反应方面的解决方案得到了巨大提升：首先是ANSYS Fluent 17.0的用户，可以使用集成的CHEMKIN-CFD功能，实现详细化学反应和燃烧计算与Fluent的流场模拟相耦合；其次，针对内燃机等专业客户，可以使用专用模拟工具Forte来完成快捷而精确的内燃机燃烧仿真；最后，ENERGICO是专注于污染物排放模拟的产品，可以有效解决燃气轮机、航空发动机和锅炉等燃烧设备的污染物排放难题。本次网络培训将为您介绍以上功能。
Mapping技术助力Fluent轻松解决Underhood共轭换热问题 - 日
发动机舱内大量的复杂结构件给工程师进行热管理仿真带来了很大的挑战，传统的基于流体-结构网格共节点的求解方式存在网格生成难度大，网格量不容易控制等问题，本次网络培训给您介绍基于FLUENT最新的Mapping技术，工程师可以分别生成结构网格及流体网格，仅通过指定界面Mapping关系即可完成复杂结构的共轭换热分析，大大提高了发动机舱及整车热管理分析的效率。
利用时间分解算法（TDM）提高瞬态电磁场仿真速度 - 日
瞬态电磁场有限元分析因涉及仿真过程长而导致较长的求解时间，尤其是模型复杂、求解规模大，时间步长多、稳定时间长的模型。传统的仿真方法是按照时间顺序逐步求解。ANSYS 17.0推出的时间分解算法可以将瞬态求解过程分成多个部分，通过调用多线程并行求解，实现各计算节点多个时间步长并行求解，从而大大加速瞬态电磁场有限元求解进程，特别适合电机、变压器、作动器等电磁设备的仿真设计。本次网络培训将为您演示此功能。
一键式ECE模型生成和多层次机电系统仿真
继ANSYS 16.0推出旋转运动设备一键式ECE模型生成后，ANSYS 17.0将该功能扩展到变压器和直线运动设备。ANSYS用户可以通过简单的软件设置，即可一键式启动定制化开发的脚本程序，自动设置参数化扫描模型、自动求解并输出ECE模型，供机电系统仿真设计使用。该功能不仅大大提高旋转电机、直线电机、变压器、作动器等设备的系统仿真精度，而且加速机电设备从部件到系统的仿真设计流程，特别适合复杂模型的集成化系统设计。本次网络培训将给您介绍和演示此功能。
ANSYS燃烧仿真模型介绍与应用 - 日
新版本的ANSYS CFD对多种燃烧模型进行了代码重构工作并对求解器进行了大量改进，从而显著提升了仿真效率和精度。在实际的仿真工作中，不同的仿真案例需采用不同的燃烧模型及设置。本研讨会对多种燃烧现象、燃烧仿真任务和燃烧模型进行探讨，为不同仿真案例燃烧模型的选择和设置提供依据。
利用交互调试和自动优化技术提高RTL设计功耗效率 - 日
当今的芯片设计集成度越来越高，工艺越来越先进，而随之而来的功耗问题也越来越凸现出来。众所周知，在RTL级设计阶段更早的考虑功耗问题可以得到更好的功耗优化结果。芯片设计中的功耗缺陷不同于真正的功能缺陷，仿真过程中一般没有办法进行验证和定位。本次网络培训将介绍基于ANSYS PowerArtist平台的功耗设计缺陷定位方法可以帮助前端设计人员有效地定位设计中潜在的冗余功耗，进而提升芯片的整体性能。
子产品可靠性仿真(ECAD数据直接读取、跌落、热、密封、断裂等) - 日
电路的集成规模越来越大，I/O数越来越多，使得PCB互连密度不断加大，随之带来许多PCB可靠性问题。ANSYS 17.0版本集成针对PCB的Trace Mapping强大功能，可以快速从EACD中直接导入PCB热物参数，从而能在Mechanical中进行准确的PCB板热力、疲劳、随机振动、跌落等可靠性问题的仿真。本此网络培训将介绍Trace Mapping功能，并演示ANSYS解决PCB板可靠性问题的案例。
ANSYS 17.0工作流程和求解器进展（HPC、CMS+RBD、梁、子模型技术等） - 日
本次网络培训将为您介绍ANSYS 17.0工作流程和求解器进展，具体如下：
模型网格处理技术又有很大的进展，涵盖几何、网格、复杂截面梁单元、复合材料建模，以及变形后的网格生成几何。
ANSYS通过收购MultiPlas，岩土材料极大丰富，涵盖Cam-clay、Mohr-Coulomb、Jointed Rock、Drucker-Prager concrete等岩土本构，从而更加有效解决土壤、岩石、颗粒、混凝土、砌体等非线性结构力学问题，对于众多的土木行业用户是最大的福音。
新的分布式并行求解技术全面支持Lanczos特征求解器，使得动力学求解规模和速度大幅提升，加速10倍以上。
ANSYS HPC计算效率大幅提升，有效使用更多的计算机内核参与计算。
CMS技术用于刚体动力学，使得刚柔混合动力学求解规模和速度大幅提升。
最佳工程仿真前处理工具SpaceClaim - 日
如果您是一名仿真工程师，曾经为网格划分不成功而苦恼，曾经耗费大量时间在几何模型的检查和修复上，曾经为简化几何而苦于没有一个快速的工具，那么请您关注ANSYS的几何前处理先进解决方案。本次网络培训主要介绍：
基于直接建模技术SpaceClaim，帮助工程师提高各类仿真分析中的几何处理能力，让网格划分更快更好。直接几何建模技术，使几何模型处理更加直观、高效。SpaceClaim让您处理几何如鱼得水，所见即所要，再也不用为复杂的几何处理而烦恼。
SCADE System Avionics Package: How to Design Comprehensive ICDs - XX X, 2016
Ensuring robust system management and control of the thousands of signals that are transmitted aboard an aircraft every second is one of the most complex and critical jobs of today&s avionics engineers. With so many systems and signals, how can engineers manage them all with 100 percent reliability and confidence? Creating a well-integrated systems architecture, and expressing that architecture in Interface Control Documents (ICDs), is an incredibly challenging, time-consuming exercise.
Join us for this webinar to learn how the new ANSYS SCADE System Avionics Package can help you to streamline your avionics systems architecture process with the creation of ICDs. Discover how ANSYS solutions can assist you in understanding and meeting the requirements of many standard protocols, including ARINC 653, ARINC 429, CAN and ARINC 664, to ensure the integrity of all your safety-critical avionics systems.
Register 9am Session & Register 4pm Session
10x Faster Time to Analysis with ANSYS SpaceClaim - XX X, 2016
ANSYS 17.0 contains extensive improvements to ANSYS SpaceClaim Direct Modeler, which provides
speed of design, conceptualization, editing and preparing geometry for simulation. New functionality
has been added, including scripting capabilities, edge repair tools and a weld creation tool for shell
models. Existing analysis tools, such as imprinting, midsurfacing and beam support, have also been
Attend this webinar and learn about two major enhancements to SpaceClaim Direct Modeler (in
addition to those mentioned above): an STL-to-solid tool called Skin Surface and a faceted data
simplification called Shrinkwrap. Skin Surface adds more reverse engineering capabilities by building
surface geometry on prismatic or organic shapes, such as scan data from a living organism. Shrinkwrap
couples with Skin Surface to smooth over rough scans (or dirty CAD data) and further solidifies any
faceted model.
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Power Noise Closure With Up to 10x Total Productivity Gain for Advanced Networking ASICs - XX X, 2016
Challenges routinely faced by networking chip designers include extremely big capacity due to growing
more accurate modeling of the system and co-analysis at the top- chip thermal
solution fo comprehensive coverage of different modes of analysis in po and timing impact annotation for jitter analysis and timing closure, just to name a few.
Join us for this webinar and discover how ANSYS RedHawk can help you to meet these challenges, with a
focus on power integrity and reliability of advanced networking application-specific integrated circuits
(ASICs). Learn how RedHawk&s capabilities in DMP (distributed machine processing), CPA (chip package
analysis), CTA (chip thermal analysis) and thermal-aware EM (electromigration) analyses can provide a
total productivity gain of up to 10x in networking chip design.
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10x More Productivity for Chip-Package-System Workflows - XX X, 2016
The Internet of Things (IoT), autonomous vehicles and smart devices have two major components in common:
sensors and antennas. These components collect data and transmit it throughout systems of various sizes,
ranging from inside an automobile to across a country. This has presented engineers with new design
challenges regarding connectivity, performance, power efficiency and achieving first-time success.
Attend this webinar to learn how ANSYS 17.0 has enhanced the Chip-Package-System workflow to address
design challenges in power integrity, signal integrity, ESD, thermal and structural challenges. Discover how
ANSYS solutions provide a unique virtual prototyping flow to simulate the real-world electrical, thermal, and
mechanical behaviors of a product, allowing design engineers to meet their system power and performance
targets, while reducing cost.
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