Fuzzy Logic Estimator for Variant SNR Environments

Encyclopedia of Artificial Intelligence Pub Date : 1900-01-01 DOI:10.4018/978-1-59904-849-9.CH107

R. A. Pages, C. M. Segura, J. Socoró

{"title":"Fuzzy Logic Estimator for Variant SNR Environments","authors":"R. A. Pages, C. M. Segura, J. Socoró","doi":"10.4018/978-1-59904-849-9.CH107","DOIUrl":null,"url":null,"abstract":"The acquisition system is one of the most sensitive stages in a Direct Sequence Spread Spectrum (DS-SS) receiver (Peterson, Ziemer & Borth, 1995), due to its critical position in order to demodulate the received information. There are several schemes to deal with this problem, such as serial search and parallel algorithms (Proakis, 1995). Serial search algorithms have slow convergence time but their computational load is very low; on the other hand, parallel systems converge very quickly but their computational load is very high. In our system, the acquisition scheme used is the multiresolutive structure presented in (Moran, Socoró, Jové, Pijoan & Tarrés, 2001), which combines quick convergence and low computational load. The decisional system that evaluates the acquisition stage is a key process in the overall system performance, being a drawback of the structure. This becomes more important when dealing with time-varying channels, where signal to noise ratio (called SNR) is not a constant parameter. Several factors contribute to the performance of the acquistion system (Glisic & Vucetic, 1997): channel distorsion and variations, noise and interference, uncertainty about the code phase, and data randomness. The existence of all these variables led us to think about the possibility of using fuzzy logic to solve this complex acquisition estimation (Zadeh, 1973). A fuzzy logic acquisition estimator had already been tested and used in our research group to control a serial search algorithm (Alsina, Morán & Socoró, 2005) with encouraging results, and afterwards in the multiresolutive scheme (Alsina, Mateo & Socoró, 2007), and other applications to this field can be found in bibliography as (Bas, Pérez & Lagunas, 2001) or (Jang, Ha, Seo, Lee & Lee, 1998). Several previous works have been focused in the development of acquisition systems for non frequency selective channels with fast SNR variations (Moran, Socoró, Jové, Pijoan & Tarrés, 2001) (Mateo & Alsina, 2004).","PeriodicalId":320314,"journal":{"name":"Encyclopedia of Artificial Intelligence","volume":"1 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"1900-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"4","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Encyclopedia of Artificial Intelligence","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.4018/978-1-59904-849-9.CH107","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 4

Abstract

The acquisition system is one of the most sensitive stages in a Direct Sequence Spread Spectrum (DS-SS) receiver (Peterson, Ziemer & Borth, 1995), due to its critical position in order to demodulate the received information. There are several schemes to deal with this problem, such as serial search and parallel algorithms (Proakis, 1995). Serial search algorithms have slow convergence time but their computational load is very low; on the other hand, parallel systems converge very quickly but their computational load is very high. In our system, the acquisition scheme used is the multiresolutive structure presented in (Moran, Socoró, Jové, Pijoan & Tarrés, 2001), which combines quick convergence and low computational load. The decisional system that evaluates the acquisition stage is a key process in the overall system performance, being a drawback of the structure. This becomes more important when dealing with time-varying channels, where signal to noise ratio (called SNR) is not a constant parameter. Several factors contribute to the performance of the acquistion system (Glisic & Vucetic, 1997): channel distorsion and variations, noise and interference, uncertainty about the code phase, and data randomness. The existence of all these variables led us to think about the possibility of using fuzzy logic to solve this complex acquisition estimation (Zadeh, 1973). A fuzzy logic acquisition estimator had already been tested and used in our research group to control a serial search algorithm (Alsina, Morán & Socoró, 2005) with encouraging results, and afterwards in the multiresolutive scheme (Alsina, Mateo & Socoró, 2007), and other applications to this field can be found in bibliography as (Bas, Pérez & Lagunas, 2001) or (Jang, Ha, Seo, Lee & Lee, 1998). Several previous works have been focused in the development of acquisition systems for non frequency selective channels with fast SNR variations (Moran, Socoró, Jové, Pijoan & Tarrés, 2001) (Mateo & Alsina, 2004).

查看原文

微信好友朋友圈 QQ好友复制链接

本刊更多论文

变信噪比环境下的模糊逻辑估计

采集系统是直接序列扩频(DS-SS)接收机中最敏感的阶段之一(Peterson, Ziemer & Borth, 1995)，因为它在接收信息的解调中处于关键位置。有几种方案可以处理这个问题，例如串行搜索和并行算法(Proakis, 1995)。串行搜索算法收敛时间慢，但计算量很低;另一方面，并行系统收敛速度快，但计算量大。在我们的系统中，使用的采集方案是(Moran, Socoró， jov， Pijoan & tarr， 2001)中提出的多分辨率结构，它结合了快速收敛和低计算负荷。评估采办阶段的决策系统是整个系统性能的关键过程，也是该结构的一个缺点。当处理时变信道时，这一点变得更加重要，其中信噪比(称为SNR)不是一个常数参数。有几个因素影响着采集系统的性能(Glisic & Vucetic, 1997):信道失真和变化、噪声和干扰、编码相位的不确定性以及数据的随机性。所有这些变量的存在使我们思考使用模糊逻辑来解决这种复杂的获取估计的可能性(Zadeh, 1973)。我们的研究小组已经测试并使用了模糊逻辑获取估计器来控制串行搜索算法(Alsina, Morán & Socoró， 2005)，并取得了令人鼓舞的结果，随后在多分辨率方案(Alsina, Mateo & Socoró， 2007)中，该领域的其他应用可以在参考文献中找到(Bas, prez & Lagunas, 2001)或(Jang, Ha, Seo, Lee & Lee, 1998)。以前的几项工作主要集中在具有快速信噪比变化的非频率选择信道的采集系统的开发上(Moran, Socoró， jov， Pijoan和tarr， 2001) (Mateo和Alsina, 2004)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文去求助