Photon Design的案例
Pea Puffer非球面:周長優化的非球面CCP拋光
參考文獻
1.O.F?hnle, Jens Bliedtner, “Modeling of Freeform Optical Fabrication Chains during Optics Design”, International Conference on Optics-photonics Design & Fabrication (ODF), JSAP (The Japan Society of Applied Physics), July 2024, Tucson, USA
2.J Bliedtner: chapter ?optics fabrication design ?, in the OFT standard werk, book “Optics Technologies”, pp721- 725, ISBN 978-3-446-45850-5 (2022)
3.D.Walker, O.Faehnle, et al. “Bridging the Divide Between Iterative Optical Polishing and Automation”, Journal of Nanomanufacture and Metrology 6, 26 (2023), https://doi.org/10.1007/s41871-023-00197-3
4.https://www.ansys.com/products/optics/ansys-zemax-opticstudio
5.https://www.synopsys.com/optical-solutions/codev.html
6.Robert A.
展開 Pea Puffer非球面:周長優化的非球面CCP拋光
參考文獻
1.O.F?hnle, Jens Bliedtner, “Modeling of Freeform Optical Fabrication Chains during Optics Design”, International Conference on Optics-photonics Design & Fabrication (ODF), JSAP (The Japan Society of Applied Physics), July 2024, Tucson, USA
2.J Bliedtner: chapter ?optics fabrication design ?, in the OFT standard werk, book “Optics Technologies”, pp721- 725, ISBN 978-3-446-45850-5 (2022)
3.D.Walker, O.Faehnle, et al. “Bridging the Divide Between Iterative Optical Polishing and Automation”, Journal of Nanomanufacture and Metrology 6, 26 (2023), https://doi.org/10.1007/s41871-023-00197-3
4.https://www.ansys.com/products/optics/ansys-zemax-opticstudio
5.https://www.synopsys.com/optical-solutions/codev.html
6.Robert A.
展開 實際約束條件下成像系統的初始結構的生成
Thienpont, “Freeform imaging systems: Fermat’s principle unlocks 'first time right' design,” Light Sci. Appl. 10, (2021)
2.Y. Nie, D. R. Shafer, H. Ottevaere, H. Thienpont, and F. Duerr, "Automated freeform imaging system design with generalized ray tracing and simultaneous multi-surface analytic calculation," Opt. Express 29, 17227-17245 (2021)
3.O. F?hnle and I. Livshits, “Modeling of Optical Fabrication Chains during Optics Design”, International Conference on Optics-photonics Design & Fabrication (ODF), JSAP (The Japan Society of Applied Physics), Sapporo, Japan, August 2022
4. O. F?hnle and I.
展開 實際約束條件下成像系統的初始結構的生成
Thienpont, “Freeform imaging systems: Fermat’s principle unlocks 'first time right' design,” Light Sci. Appl. 10, (2021)
2.Y. Nie, D. R. Shafer, H. Ottevaere, H. Thienpont, and F. Duerr, "Automated freeform imaging system design with generalized ray tracing and simultaneous multi-surface analytic calculation," Opt. Express 29, 17227-17245 (2021)
3.O. F?hnle and I. Livshits, “Modeling of Optical Fabrication Chains during Optics Design”, International Conference on Optics-photonics Design & Fabrication (ODF), JSAP (The Japan Society of Applied Physics), Sapporo, Japan, August 2022
4. O. F?hnle and I.
展開 
十大工業軟件供應商市場規模及市場預測2019-2024
Earlier, Synopsys acquired QTronic GmbH for its simulation, test tools, and services for automotive industry.
5
Ansys Inc.
13.2%
In March 2020, Ansys has acquired Lumerical Inc., a developer of photonic design and simulation tools. The acquisition will add best-in-class photonics products to the Ansys multiphysics portfolio, providing customers with a full set of solutions to solve their next-generation product challenges.
6
Cadence
Design
Systems
9.3%
In August 2020 Cadence Design Systems introduced the Cadence XceliumTM Logic Simulator, enhanced with machine learning technology (ML), called Xcelium ML, to increase verification throughput.
展開 Lumerical案例 | INTERCONNECT和photonic Verilog-A緊湊模型的說明和應用
https://optics.ansys.com/hc/en-us/articles/360042910313-Verilog-A-PAM4-Transceiver-Cadence-Interoperability
[7]Enabling Accurate Electronic-Photonic Co-Design with a Synergetic Workflow on GlobalFoundries Fotonix Platform
https://www.ansys.com/resource-center/white-paper/enabling-accurate-electronic-photonic-co-design-with-a-synergetic-workflow
展開 案例分享 | Lumerical助力CompoundTek光柵耦合器面積大幅縮減
采用Photonic Inverse Design設計使面積縮小20倍的光柵耦合器
結合Lumerical行業領先的FDTD納米光子仿真器,Lumerical的光子逆向設計(PID)流程可被用于對新型光柵耦合器進行設計和優化。Lumerical的PID使光子設計人員能夠快速開發出性能更佳、面積更小、制造工藝更為穩健的優化功能。PID幫助光柵耦合器設計人員實現可靠的、具有數百個自由參數的優化設計的自動生成,最大限度地提高設計分辨率。
Lumerical的2020a版中引入了新的功能,加強了對云平臺運行FDTD和PID的支持。該版本包含Job checkpointing、支持Amazon Linux、FDTD Burst Packs的在線自動激活等特性。全局優化功能等其它顯著的PID特性,讓設計人員能夠高效探索廣闊的設計空間,針對工藝和封裝變化開展聯合優化,實現穩健的制造可變性設計。
在兩周的設計時間內,Lumerical的PID流程在亞馬遜云服務(AWS)的EC2平臺上成功運行,充分的發揮了其靈活性、成本效益的優勢和近乎無限的可擴展功能。對于在整個設計周期中具有可變性的工作負載,計算資源可以隨時擴展,而無需像內部平臺那樣預先支付高昂的IT成本。這在設計后期尤其具有吸引力,因為此時需要大幅增強仿真能力,以快速優化和驗證設計的多種變量。
對兩種光柵耦合器的原始設計和新設計的插入損耗進行對比,并采用2D FDTD開展仿真
在AWS EC2上使用Lumerical的PID流程,成功開發的新型SiPh光柵耦合器,其器件面積比CompoundTek的現有耦合器小20倍,性能預計也會有所改善。
展開 案例分享 | Lumerical助力CompoundTek光柵耦合器面積大幅縮減
采用Photonic Inverse Design設計使面積縮小20倍的光柵耦合器
結合Lumerical行業領先的FDTD納米光子仿真器,Lumerical的光子逆向設計(PID)流程可被用于對新型光柵耦合器進行設計和優化。Lumerical的PID使光子設計人員能夠快速開發出性能更佳、面積更小、制造工藝更為穩健的優化功能。PID幫助光柵耦合器設計人員實現可靠的、具有數百個自由參數的優化設計的自動生成,最大限度地提高設計分辨率。
Lumerical的2020a版中引入了新的功能,加強了對云平臺運行FDTD和PID的支持。該版本包含Job checkpointing、支持Amazon Linux、FDTD Burst Packs的在線自動激活等特性。全局優化功能等其它顯著的PID特性,讓設計人員能夠高效探索廣闊的設計空間,針對工藝和封裝變化開展聯合優化,實現穩健的制造可變性設計。
在兩周的設計時間內,Lumerical的PID流程在亞馬遜云服務(AWS)的EC2平臺上成功運行,充分的發揮了其靈活性、成本效益的優勢和近乎無限的可擴展功能。對于在整個設計周期中具有可變性的工作負載,計算資源可以隨時擴展,而無需像內部平臺那樣預先支付高昂的IT成本。這在設計后期尤其具有吸引力,因為此時需要大幅增強仿真能力,以快速優化和驗證設計的多種變量。
對兩種光柵耦合器的原始設計和新設計的插入損耗進行對比,并采用2D FDTD開展仿真
在AWS EC2上使用Lumerical的PID流程,成功開發的新型SiPh光柵耦合器,其器件面積比CompoundTek的現有耦合器小20倍,性能預計也會有所改善。
展開 