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ANSYS in ACTION: Analog and Mixed Signal Workflows for Power and Reliability Signoff for SerDes IP and PMIC - Webinar

Analog and mixed signal IPs are very complex and require significant time to design, verify and validate. With increasing mask costs and tighter design cycles, first time silicon success is key to accelerate time to market and beat the competition. Watch this 20-minute webinar to learn how AMS workflows based on ANSYS Totem, a layout-based transistor level power and reliability signoff platform, can enable you to design the next generation of SerDes IP or PMIC for cutting-edge applications.

Author: ANSYS Type: Webinar Date:
Product Name: ANSYS Totem
Sub Industry: Semiconductors


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High Capacity Power Signoff Using Big Data - Webinar

In this webinar, learn how NVIDIA has developed a workflow to run a flat, full-chip power integrity and reliability signoff analysis using a fully distributed compute and big data solution with ANSYS RedHawk-SC. They achieved a turn-around time of well under 24 hours for full-chip flat power signoff analysis on NVIDIA’s largest GPU – Volta, which contains around 21 billion transistors. Additionally, silicon correlation exercises performed on the Volta chip using RedHawk-SC produced simulated voltage values that were within 10 percent of silicon measurement results. This methodology was published in the Design Automation Conference 2017 (DAC 2017) Designer/IP track poster session. Discover how NVIDIA’s most powerful GPU uses ANSYS’ next generation SoC power signoff solution based on big data to deliver the best performance for cutting-edge AI and machine learning applications.

Author: ANSYS Type: Webinar Date:
Product Name: ANSYS RedHawk


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Concept Modeling and Simulation with ANSYS SpaceClaim - Webinar

Watch this webinar to explore ANSYS SpaceClaim's 3-D concept modeling capabilities. We’ll demonstrate the power that direct modeling brings to various workflows, such as design, manufacturing, 3-D printing, reverse engineering, sheet metal fabrication and engineering simulation. You’ll learn how SpaceClaim can be used for rapid concept development starting from a blank screen or imported file; how it creates and edits assemblies; and how rapidly it can make detailed 2-D drawings.

Finally, we’ll demonstrate SpaceClaim technology in the context of an engineering simulation using a new product called ANSYS Discovery Live, a revolutionary solution that rewards you with instantaneous simulation results as soon as you change the geometry or other parameters of your model. Attend this webinar and you’ll walk away more confident in your ability to perform concept modeling and true upfront simulation.

Author: ANSYS Type: Webinar Date:
Product Name: ANSYS SpaceClaim


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ANSYS Discovery Live and Geometry Modeling - Webinar

ANSYS SpaceClaim, which allows you to create and edit virtually any 3-D CAD file, provides the geometry backbone for this application. As fast as you can make changes to models, Discovery Live provides instant engineering simulation answers. This combination empowers true upfront simulation. Join us for this webinar and learn about several ANSYS concept modeling tools along with the power of direct modeling in SpaceClaim. You'll walk away being able to edit models as fast as Discovery Live solves them.

Author: ANSYS Type: Webinar Date:


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初级读本:利用CFD解决无人机(UAV)空气动力学问题

作为一位工程经理或分析人员,您的任务是解决与无人飞行系统(UAS)的空气动力学有关的一些问题。您使用CFD(计算流体动力学)的经验比较有限,而您所在公司的无人机(UAV)项目却时间紧迫。本白皮书将向您介绍一些通常可利用CFD软件求解的空气动力学问题,以指导您进行决策。此白皮书中还包含了一系列案例研究,并且每个案例都解释了应用流体工程来解决该特定问题的具体原因。

Author: ANSYS Type: White Paper Date:
Product Name: ANSYS CFD


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制动尖叫预测的突破有助于在设计流程中尽早消除噪声问题

工程师近年来成功地降低了众多类型的汽车噪声。但是汽车制动时,因摩擦引起的尖叫正越来越多地遭到客户投诉。目前制动噪声是汽车原始设备制造商(OEM)和供应商面临的最大质保问题之一。近期推出了制动尖叫预测集成方法,是一项重大突破:它融合了双向计算机辅助设计(CAD)连接、自动网格划分和连接功能、灵活使用线性和/或非线性求解器、参数化和敏感性研究以及多种类型的图形输出。这种集成方法可显著缩短设置时间,与物理测试良好关联,让模型与生产及供应链保持同步,能够自动评估大量设计备选方案,迅速地找出最佳设计。与常规方法相比,这种新方法能在短得多的时间内一次性完成用于多种平台的低成本、低噪声制动系统的虚拟设计。

Author: ANSYS Type: White Paper Date:
Industry: Automotive


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设计最佳产品:利用仿真工具进行创新,并缩短产品上市时间

世界化妆品和盥洗用品市场2003年市场估值超过2000亿美元,年增长率约5%¹,²。在西方世界,根据每个细分市场中的目标年龄层、性别、种族、肤色和发质制定的产品差异化等策略对增长起到了促进作用。最近,北美的全国连锁零售商一直积极地开办广告活动,以吸引特定的消费群体。更重要的是,技术创新以及上游大众细分市场的持续发展对增长产生了影响。

Author: ANSYS Type: White Paper Date:
Product Name: ANSYS CFD


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研发智能低成本情报、监视与侦查技术:五大趋势值得关注

行业对于情报、监视和侦查(ISR)技术和基础设施的需求正在显著增长。例如,从2002年到2011年的10年间,美国在ISR技术上的国防开支增长了六倍,而同期国防开支总体相对平稳[国会众议院情报委员会(House Permanent Select Committee on Intelligence),2012年]。类似的经费开支模式在全球相当普遍。从无人系统到天线,再到系统和嵌入式软件,仿真工程在推进ISR技术研发方面一直发挥着重要作用。其价值主张早已经过实践验证。

Author: ANSYS Type: White Paper Date:
Industry: High Tech


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在32核高性能计算集群上将ANSYS Maxwell DSO提速16倍,通用汽车实现牵引电机设计生产力翻番

在设计电动车(EV)和混合动力车(HEV)的牵引电机时,设计优化工作充满了挑战,因为汽车制造商在这个领域经验不足。电磁仿真在评估设计概念的性能方面起着关键作用,如计算机器的扭矩参数等。过去单次设计迭代上的电磁仿真需耗时数百小时,工程师不得不等待结果,严重影响生产力。通用汽车(GM)研发出一种高性能计算(HPC)环境,它使用32核计算机集群的多余硬件为电磁仿真带来16倍加速,将求解时间缩短到不足5小时。

Author: ANSYS Type: White Paper Date:
Product Name: ANSYS Maxwell
Industry: Automotive


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体育的巨变: 工程仿真技术的贡献

专业运动员、教练和业余体育参与者不懈地探索各种方法,以提高成绩、确保舒适度、并最大限度降低受伤风险。同时,运动器材制造商也必须开展技术研发,以加快创新速度,而且对于时常面临极端条件挑战的产品,也需要最大限度提高可靠性。长期以来,业界一直采用包括工程等在内的工具。但在过去几年里,体育工程领域对工程仿真投入了更为密切的关注。

工程仿真是一项经实践验证的技术,能预测特定条件下设备、运动员的行为,或由运动员、装备和设备组成的系统的行为。通过基于计算机的建模,可以判断并了解相关参数如何影响运动员的成绩,或是掌握它们将如何减轻或增大受伤的风险;通过变更各种影响条件并预测修改产生的结果,运动器材设计人员能够选择出既能优化成绩,又能降低受伤风险的最佳条件组合。此外,体育用品制造商还能以更快的速度、更低的成本将这些改良后的产品投放市场。

Author: ANSYS Type: White Paper Date:


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