A Lower Bound for the Coherence Block Length in Mobile Radio Channels
A lower bound for the coherence block (ChB) length in mobile radio channels is derived in this paper. The ChB length, associated with a certain mobile radio channel, is of great practical importance in future wireless systems, mainly those based on massive multiple input and multiple output (M-MIMO)...
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MDPI AG
2021-02-01
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| Series: | Electronics |
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| Online Access: | https://www.mdpi.com/2079-9292/10/4/398 |
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doaj-3df6546b54404bfcb0f45128114d60b42021-02-08T00:01:12ZengMDPI AGElectronics2079-92922021-02-011039839810.3390/electronics10040398A Lower Bound for the Coherence Block Length in Mobile Radio ChannelsRafael P. Torres0Jesús R. Pérez1Departamento de Ingeniería de Comunicaciones, Universidad de Cantabria, 39005 Santander, SpainDepartamento de Ingeniería de Comunicaciones, Universidad de Cantabria, 39005 Santander, SpainA lower bound for the coherence block (ChB) length in mobile radio channels is derived in this paper. The ChB length, associated with a certain mobile radio channel, is of great practical importance in future wireless systems, mainly those based on massive multiple input and multiple output (M-MIMO) technology. In fact, it is one of the factors that determines the achievable spectral efficiency. Firstly, theoretical aspects regarding the mobile radio channels are summarized, focusing on the rigorous definition of coherence bandwidth (<i>B<sub>C</sub></i>) and coherence time (<i>T<sub>C</sub></i>) parameters. Secondly, the uncertainty relations developed by B. H. Fleury, involving both <i>B<sub>C</sub></i> and <i>T<sub>C</sub></i>, are presented. Afterwards, a lower bound for the product <i>B<sub>C</sub>T<sub>C</sub></i> is derived, i.e., the ChB length. The obtained bound is an explicit function of easily measurable parameters, such as the delay spread, mobile speed and carrier frequency. Furthermore, and especially important, this bound is also a function of the degree of coherence with which we define both <i>B<sub>C</sub></i> and <i>T<sub>C</sub></i>. Finally, an application example that illustrates the practical possibilities of the bound obtained is presented. As a further conclusion, the need to determine what degree of correlation is required to consider mobile channels as effectively flat-fading and stationary is highlighted.https://www.mdpi.com/2079-9292/10/4/3985G mobile systemsmobile radio channelscoherence bandwidthcoherence timecoherence blockmassive MIMO |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Rafael P. Torres Jesús R. Pérez |
| spellingShingle |
Rafael P. Torres Jesús R. Pérez A Lower Bound for the Coherence Block Length in Mobile Radio Channels Electronics 5G mobile systems mobile radio channels coherence bandwidth coherence time coherence block massive MIMO |
| author_facet |
Rafael P. Torres Jesús R. Pérez |
| author_sort |
Rafael P. Torres |
| title |
A Lower Bound for the Coherence Block Length in Mobile Radio Channels |
| title_short |
A Lower Bound for the Coherence Block Length in Mobile Radio Channels |
| title_full |
A Lower Bound for the Coherence Block Length in Mobile Radio Channels |
| title_fullStr |
A Lower Bound for the Coherence Block Length in Mobile Radio Channels |
| title_full_unstemmed |
A Lower Bound for the Coherence Block Length in Mobile Radio Channels |
| title_sort |
lower bound for the coherence block length in mobile radio channels |
| publisher |
MDPI AG |
| series |
Electronics |
| issn |
2079-9292 |
| publishDate |
2021-02-01 |
| description |
A lower bound for the coherence block (ChB) length in mobile radio channels is derived in this paper. The ChB length, associated with a certain mobile radio channel, is of great practical importance in future wireless systems, mainly those based on massive multiple input and multiple output (M-MIMO) technology. In fact, it is one of the factors that determines the achievable spectral efficiency. Firstly, theoretical aspects regarding the mobile radio channels are summarized, focusing on the rigorous definition of coherence bandwidth (<i>B<sub>C</sub></i>) and coherence time (<i>T<sub>C</sub></i>) parameters. Secondly, the uncertainty relations developed by B. H. Fleury, involving both <i>B<sub>C</sub></i> and <i>T<sub>C</sub></i>, are presented. Afterwards, a lower bound for the product <i>B<sub>C</sub>T<sub>C</sub></i> is derived, i.e., the ChB length. The obtained bound is an explicit function of easily measurable parameters, such as the delay spread, mobile speed and carrier frequency. Furthermore, and especially important, this bound is also a function of the degree of coherence with which we define both <i>B<sub>C</sub></i> and <i>T<sub>C</sub></i>. Finally, an application example that illustrates the practical possibilities of the bound obtained is presented. As a further conclusion, the need to determine what degree of correlation is required to consider mobile channels as effectively flat-fading and stationary is highlighted. |
| topic |
5G mobile systems mobile radio channels coherence bandwidth coherence time coherence block massive MIMO |
| url |
https://www.mdpi.com/2079-9292/10/4/398 |
| work_keys_str_mv |
AT rafaelptorres alowerboundforthecoherenceblocklengthinmobileradiochannels AT jesusrperez alowerboundforthecoherenceblocklengthinmobileradiochannels AT rafaelptorres lowerboundforthecoherenceblocklengthinmobileradiochannels AT jesusrperez lowerboundforthecoherenceblocklengthinmobileradiochannels |
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