The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
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The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
Na tecnologia de emenda mecânica, a mudança de perda durante o ciclo de temperatura é causada principalmente pelo deslizamento ou deslocamento da fibra na interface entre as fibras e os substratos de fixação da fibra. O limite superior da precisão de fabricação das fibras e substratos restringe o número total de fibras em uma emenda. Para superar isso, propomos um novo método de fixação de fibras utilizando a elasticidade da superfície do substrato. Prendemos as fibras com mais força nas extremidades de fixação das fibras, onde as fibras precisam de uma força de atrito maior do que ao redor da junta de topo, para mantê-las na posição. Tomando o caso de uma emenda de fita de 8 fibras, comparamos marcas lineares nos substratos com as curvas de largura de linha limite para o início do deslizamento. Alcançamos uma mudança na perda de inserção de menos de
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Toshiaki KATAGIRI, Masao TACHIKURA, Yasuji MURAKAMI, "Basic Design for Stable Fiber-Clamping in Multi-Fiber Ribbon Mechanical Splice" in IEICE TRANSACTIONS on Communications,
vol. E84-B, no. 8, pp. 2161-2169, August 2001, doi: .
Abstract: In mechanical splice technology, loss change during temperature cycling is mainly caused by fiber slippage or shift at the interface between fibers and fiber clamping substrates. The upper limit of the fabrication accuracy of the fibers and substrates restricts the total number of fibers in a splice. To overcome this, we propose a novel fiber clamping method using the elasticity of the substrate surface. We clamp the fibers more strongly at the fiber clamping ends, where the fibers need a greater friction force than around the butt-joint, to hold them in position. Taking the case of an 8-fiber ribbon splice, we compared linear marks on the substrates with the boundary linewidth curves for the onset of slippage. We achieved an insertion loss change of less than
URL: https://global.ieice.org/en_transactions/communications/10.1587/e84-b_8_2161/_p
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@ARTICLE{e84-b_8_2161,
author={Toshiaki KATAGIRI, Masao TACHIKURA, Yasuji MURAKAMI, },
journal={IEICE TRANSACTIONS on Communications},
title={Basic Design for Stable Fiber-Clamping in Multi-Fiber Ribbon Mechanical Splice},
year={2001},
volume={E84-B},
number={8},
pages={2161-2169},
abstract={In mechanical splice technology, loss change during temperature cycling is mainly caused by fiber slippage or shift at the interface between fibers and fiber clamping substrates. The upper limit of the fabrication accuracy of the fibers and substrates restricts the total number of fibers in a splice. To overcome this, we propose a novel fiber clamping method using the elasticity of the substrate surface. We clamp the fibers more strongly at the fiber clamping ends, where the fibers need a greater friction force than around the butt-joint, to hold them in position. Taking the case of an 8-fiber ribbon splice, we compared linear marks on the substrates with the boundary linewidth curves for the onset of slippage. We achieved an insertion loss change of less than
keywords={},
doi={},
ISSN={},
month={August},}
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TY - JOUR
TI - Basic Design for Stable Fiber-Clamping in Multi-Fiber Ribbon Mechanical Splice
T2 - IEICE TRANSACTIONS on Communications
SP - 2161
EP - 2169
AU - Toshiaki KATAGIRI
AU - Masao TACHIKURA
AU - Yasuji MURAKAMI
PY - 2001
DO -
JO - IEICE TRANSACTIONS on Communications
SN -
VL - E84-B
IS - 8
JA - IEICE TRANSACTIONS on Communications
Y1 - August 2001
AB - In mechanical splice technology, loss change during temperature cycling is mainly caused by fiber slippage or shift at the interface between fibers and fiber clamping substrates. The upper limit of the fabrication accuracy of the fibers and substrates restricts the total number of fibers in a splice. To overcome this, we propose a novel fiber clamping method using the elasticity of the substrate surface. We clamp the fibers more strongly at the fiber clamping ends, where the fibers need a greater friction force than around the butt-joint, to hold them in position. Taking the case of an 8-fiber ribbon splice, we compared linear marks on the substrates with the boundary linewidth curves for the onset of slippage. We achieved an insertion loss change of less than
ER -