scholarly journals Spin separation based on-chip optical polarimeter via inverse design

Nanophotonics ◽  
2021 ◽  
Vol 0 (0) ◽  
Author(s):  
Changyu Zhou ◽  
Youpeng Xie ◽  
Jianxin Ren ◽  
Zepeng Wei ◽  
Luping Du ◽  
...  

Abstract Polarimetry has been demonstrated essential in various disciplines, such as optical communications, imaging, and astronomy. On-chip nanostructures for polarization measurements are most expected to replace the conventional bulk elements, and hence minimize the polarimeter for integrated applications. Some on-chip nanophotonic polarimeter via polarization detection has been implemented, in which the separation of two spin polarized states is needed. However, due to the relatively low coupling efficiency or complicated photonic silicon circuits, on-chip polarimetry using a single device still remains challenging. Here, we introduce and investigate an on-chip polarimeter with nanostructures using the inverse design method. The developed device shows the ability to detect the four polarization components of light, two of which are the spin polarizations, and the other two are the linear polarizations. The retrieved Stokes parameters with experimentally tested data are in close agreement with the numerical results. We also show the proof of concept demonstration for high-speed Stokes vector optical signals detection. In the high-speed communication experiment with data rate up to 16 GBd, the detected optical signals via polarization measurements at multiple wavelengths in the C-band were recovered with the bit error rate below the 20% forward error correction threshold. The proposed on-chip polarimeter shows promising performance both in Stokes polarimetry and high-speed optical communication applications.

Author(s):  
June Chung ◽  
Jeonghwan Shim ◽  
Ki D. Lee

A three-dimensional (3D) CFD-based design method for high-speed axial compressor blades is being developed based on the discrete adjoint method. An adjoint code is built corresponding to RVC3D, a 3D turbomachinery Navier-Stokes analysis code developed at NASA Glenn. A validation study with the Euler equations indicates that the adjoint sensitivities are sensitive to the choice of boundary conditions for the adjoint variables in internal flow problems and constraints may be needed on internal boundaries to capture proper physics of the adjoint system. The design method is demonstrated with inverse design based on Euler physics, and the results indicate that the adjoint design method produces efficient 3D designs by drastically reducing the computational cost.


Author(s):  
Kosuke Ashihara ◽  
Akira Goto ◽  
Shijie Guo ◽  
Hidenobu Okamoto

In this paper, a new aerodynamic design procedure is presented for a centrifugal compressor stage of a microturbine system. To optimize the three-dimensional (3-D) flows and the performance, an inverse design method, which numerically generates the 3-D blade geometry for specified blade loading distribution, has been applied together with the numerical validation using CFD (Computational Fluid Dynamics) and FEM (Finite Element Method). The blade profile along the shroud surface of the impeller was optimized based on the 3-D inverse design and CFD. However, the blade profile towards the hub surface was modified geometrically to achieve a nearly radial blade element especially at the inducer part of the impeller, in order to meet the required structural strength. The modified impeller successfully kept similar aerodynamic performance as that of a blade with a fully 3-D shape, whilst showing improved structural reliability. So, the proposed method to adopt the blade profile designed by the inverse method along the shroud, and to geometrically modify the blade profile towards the hub, was confirmed to be effective to design a high-speed compressor impeller. The vaned diffuser has also been re-designed using the inverse design method. The corner separation in the conventional wedge-type diffuser channel was suppressed in the new design. The stage performance improvements were confirmed by stage calculations using CFD.


2015 ◽  
Vol 19 (2) ◽  
pp. 119-122 ◽  
Author(s):  
Bomin Li ◽  
Knud J. Larsen ◽  
Darko Zibar ◽  
Idelfonso Tafur Monroy

2011 ◽  
Vol 2011 (1) ◽  
pp. 000044-000060
Author(s):  
Pervez M. Aziz ◽  
Adam Healey ◽  
Cathy Liu ◽  
Freeman Zhong ◽  
Alex Zabroda

In this paper, signal integrity challenges for high speed serial link at 25 Gb/s, such as lossy channels and noisy environments are discussed. A few solution spaces to address those challenges are investigated, such as advanced equalization schemes, alternative signaling formats and forward error correction. It demonstrates that advanced signal processing enables long reach and extra long reach serial link performance at 25 Gb/s in next generation systems. Modeling methodologies used in SerDes behavioral models to ensure good correlation with transistor level circuit simulation are also discussed.


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