MODE Solutions
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多功能波导模式求解和传播模拟仿真软件, 可用于波导器件、元件和子系统的设计、分析和优化
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MODE Solutions 概述
MODE Solutions
能够准确模拟支持导模的各种结构。MODE Solutions包括本征模式求解eigensolver和传播计算propagator两个模块。
Eigensolver准确计算传统和非传统的波导结构物理特性,它使产品工程师和研究科学家可以专注于波导设计理念的创新,同时又能完全信赖模拟结果的准确性。计算物理性质,化学性质。 eigensolver技术模式解决方案,允许它真正的任意细节 波导几何结构,从传统的纤维和肋骨波导更复杂的设备,包括表面等离子体波导,光子晶体光纤,坡壁脊波导,上和空间上不同的折射率分布。MODE Solutions 的 eigensolver 技术使它能全面解析真正的任意细节波导结构,从传统的纤维和脊形波导到更复杂的器件,例如表面等离子体波导、光子晶体光纤、斜壁脊形波导和上和空间变折射率波导等。
Propagator 准确地描述了平面集成光学系统中光的传播,从基于脊形波导大的系统到更复杂的几何图形,如光子晶体。Propagator不需要假设任何光轴方向,因此可以更有效地模拟平面传播的复杂结构, 如环形谐振腔和光子晶体微腔等,这些器件传统上一直用三维FDTD软件计算。Propagator可以很快地模拟几百微米的尺寸的器件。
使用MODE Solutions的主要受益
- 通过高精度算法和快速进行虚拟原型试制来降低产品开发成本,缩短产品入市时间;
- 通过量化研究制造允差对设计性能的影响,从而提供稳健的设计;
- 应用灵活易于使用的设计软件实现新的设计理念创新。
MODE Solutions的主要特点
- 真正任意形状波导的自由设计
- 参数化设计和三维层次结构布局
- 包含优化模块
- 先进的网格算法
- 渐变/非均匀和公形网格功能
- 全矢量计算方法
- 多台计算机上并发并行计算
- 色散材料建模
- 强大的文本程式脚本语言
- 近场-远场变换
- MATLAB® 程式集成
Eigensolver
- 高度优化的模式求解引擎
- 模式色散,群速度、和群折射率随频率变化的计算
- 色散和损耗介质
- 弯曲波导和光纤,弯曲损耗
- 模式重叠和功率耦合计算
Propagator
- 2.5D计算方法
- 全方向传播
- 时域计算的一个仿真就可以得到宽谱结果
- 多核和多节点系统分布式并行计算
- 优化的计算引擎
- 模拟动态过程的电影输出
MODE Solutions的典型应用
间隙表面等离子体波导
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在寻找与现有制造技术兼容的超紧凑型波导技术的过程中,研究人员越来越注重表面等离子体波导。
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光子晶体光纤
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学习 MODE Solutions如何帮助光学设计者在设计光子晶体光纤时量化弯曲损耗的影响,远场性能和耦合效率等。
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同轴布拉格光纤
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光学设计师们越来越多地转向不同寻常的纤维几何形状如同轴布拉格光纤来建设下一代通信、娱乐和光谱系统。
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引用MODE Solutions的文献
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| H. Hu, R. Ricken, and W. Sohler, "Lithium niobate photonic wires," Opt. Express 17, 24261-24268 (2009) http://www.opticsinfobase.org/abstract.cfm?URI=oe-17-26-24261 |
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