Transposer systems for digital terrestrial television

Electronics & Communication Engineering Journal Pub Date : 2001-02-01 DOI:10.1049/ECEJ:20010102

P. Kenington, K. Hayler, P. Moss, D. Edwards, A. Jenkins, M. Johnstone

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引用次数: 1

Abstract

The UK digital terrestrial television (DTT) network has completed its first phase of roll-out, with over 70% of the population now able to receive all six digital multiplexes. Whilst this is an impressive achievement, the current analogue TV network can cover 99.7% of the UK population and digital satellite systems can boast virtually 100% coverage, so DTT still has some way to go. DTT coverage must improve in order to make analogue switch-off a politically acceptable reality and to compete directly with satellite in value-added services, such as shopping or banking. Analogue switch-off is a particularly desirable goal, as it would release a significant amount of valuable spectrum for use by other commercial services (e.g. mobile telephony). This paper addresses the use of transposers, in a manner similar to that of the current analogue TV network, in order to extend coverage cost-effectively to those viewers currently unable to receive all of the digital multiplexes. A number of transposer designs are considered, employing both DSP and high-temperature superconducting (HTS) techniques, and results presented on some of the technologies employed.

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数字地面电视转发器系统

英国数字地面电视(DTT)网络已经完成了第一阶段的推广，超过70%的人口现在可以接收所有6个数字多路复用。虽然这是一个令人印象深刻的成就，但目前的模拟电视网络可以覆盖99.7%的英国人口，数字卫星系统几乎可以覆盖100%的人口，所以数字地面电视还有一段路要走。为了使关闭模拟信号成为政治上可以接受的现实，并在诸如购物或银行等增值服务方面与卫星直接竞争，数字地面电视的覆盖范围必须得到改善。模拟关闭是一个特别理想的目标，因为它将释放大量有价值的频谱供其他商业服务(例如移动电话)使用。本文以类似于当前模拟电视网络的方式讨论了转座的使用，以便经济有效地将覆盖范围扩大到目前无法接收所有数字多路复用的观众。考虑了一些转座设计，采用DSP和高温超导(HTS)技术，并给出了一些采用技术的结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Electronics & Communication Engineering Journal

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