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Created using the "ModernCV" template from LaTeXTemplates.com.

Latex template to quickly write author response letters to review comments. Based on @mschroen's review_response_letter. https://github.com/zhangks98/author-response-letter

This is a template for Howard University Dissertation/Thesis documents. Revision 1 which adds some corrections to the format to match the HU style guide. Made some updates to the formatting to better align with the HU Style Guide

Abstract template for submissions for the 2021 Around-the-Clock Around-the-Globe Magnetics Conference. Based on the IEEE Transactions on Magnetics Format

Template Ibracon (english)

Este ejemplo representa los cuatro diferentes modelos de amplificadores existentes: amplificador de tensión, de corriente, de trasnconductancia y de transresistencia. Cualquier amplificador puede ser convertido en cualquier otro modelo. Las notaciones son las siguientes: vi: tensión de entrada. ii: corriente de entrada. Ri: resistencia de entrada. vo: tensión de salida. io: corriente de salida. Ro: resistencia de salida. Avo: Ganancia de tensión en vacío. Aisc: Ganancia de corriente en cortocircuito. Gmsc: Ganancia de transconductancia en cortocircuito, en Siemens. Rmoc: Ganancia de resistencia en circuito abierto, en Ohms. Las figuras con forma de diamante representan fuentes controladas por las tensiones o corrientes de entrada de cada una de los amplificadores. Los esquemas son una adaptación de los que se encuentran en el Capítulo 1 del texto "Electrónica, 2da Edición" de Allan R. Hambley, publicado en idioma español por la editorial Pearson Educación.

A template for design project reports in MCHE201: Introduction to Mechanical Design at the University of Louisiana at Lafayette. For more information on the class, see: http://www.ucs.louisiana.edu/~jev9637/MCHE201.html

This paper addresses both the efficiency and the portability of a computer program in charge of the baseband signal processing of a GNSS receiver. Efficiency, in this context, refers to optimizing the speed and memory requirements of the software receiver. Specifically, the interest is focused on how fast the software receiver can process the incoming stream of raw signal samples and, in particular, if signal processing up to the position fix can be executed in real-time (and how many channels the host computer executing the receiver application can sustain in parallel). This is achieved by applying the concept of parallelization at different abstraction levels. The paper describes strategies based on task, data and instruction-level parallelism, as well as actual implementations released under an open source license and the results obtained with different commercially available computing platforms. At the same time, the proposed solution also addresses portability, understood as the usability of the same software in different computing environments.

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