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1. Diffraction Line Imaging

   Sheinin, Mark; Reddy, Dinesh N.; O'Toole, Matthew; Narasimhan, Srinivas G. (October 2020, European Conference on Computer Vision)
2. Borel line graphs

   https://doi.org/10.1017/jsl.2024.50  

   ANDERSON, JAMES; BERNSHTEYN, ANTON (November 2024, The Journal of Symbolic Logic)

   Abstract We characterize Borel line graphs in terms of 10 forbidden induced subgraphs, namely the nine finite graphs from the classical result of Beineke together with a 10th infinite graph associated with the equivalence relation$$\mathbb {E}_0$$on the Cantor space. As a corollary, we prove a partial converse to the Feldman–Moore theorem, which allows us to characterize all locally countable Borel line graphs in terms of their Borel chromatic numbers. 

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3. Filtered lifting line theory and application to the actuator line model

   https://doi.org/10.1017/jfm.2018.994  

   Martínez-Tossas, Luis A.; Meneveau, Charles (March 2019, Journal of Fluid Mechanics)

   Lifting line theory describes the cumulative effect of shed vorticity from finite span lifting surfaces. In this work, the theory is reformulated to improve the accuracy of the actuator line model (ALM). This model is a computational tool used to represent lifting surfaces, such as wind-turbine blades in computational fluid dynamics. In ALM, blade segments are represented by means of a Gaussian body force distribution with a prescribed kernel size. Prior analysis has shown that a representation of the blade using an optimal kernel width $$\unicode[STIX]{x1D716}^{opt}$$ of approximately one quarter of the chord size results in accurate predictions of the velocity field and loads along the blades. Also, simulations have shown that use of the optimal kernel size yields accurate representation of the tip-vortex size and the associated downwash resulting in accurate predictions of the tip losses. In this work, we address the issue of how to represent the effects of finite span wings and tip vortices when using Gaussian body forces with a kernel size larger than the optimal value. This question is relevant in the context of coarse-scale large-eddy simulations that cannot afford the fine resolutions required to resolve the optimal kernel size. For this purpose, we present a filtered lifting line theory for a Gaussian force distribution. Based on the streamwise component of the vorticity transport equation, we develop an analytical model for the induced velocity resulting from the spanwise changes in lift force for an arbitrary kernel scale. The results are used to derive a subfilter-scale velocity model that is used to correct the velocity along the blade when using kernel sizes larger than $$\unicode[STIX]{x1D716}^{opt}$$ . Tests are performed in large-eddy simulation of flow over fixed wings with constant and elliptic chord distributions using various kernel sizes. Results show that by using the proposed subfilter velocity model, kernel-size independent predictions of lift coefficient and total lift forces agree with those obtained with the optimal kernel size. 

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4. Electric Field Comparison of Conventional Transmission Line With Unconventional Transmission Line

   https://doi.org/10.1109/TPEC60005.2024.10472238  

   Arafat, Easir; Porkar, Babak; Ghassemi, Mona (February 2024, IEEE)
5. Bayesian Estimates of Transmission Line Outage Rates That Consider Line Dependencies

   https://doi.org/10.1109/TPWRS.2020.3012840  

   Zhou, Kai; Cruise, James R.; Dent, Chris J.; Dobson, Ian; Wehenkel, Louis; Wang, Zhaoyu; Wilson, Amy L. (March 2021, IEEE Transactions on Power Systems)