Multiplexed binary offset carrier: Difference between revisions

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Multiplexed binary offset carrier (MBOC) modulation ^[1]^[2]^[3] is a modulation proposed for Galileo^[2] and modernized GPS signals, which combines a sine binary offset carrier SinBOC(1,1) signal with a SinBOC(6,1) signal, either via weighted sum/difference (the CBOC implementation) or via time-multiplexing (the TMBOC implementation).

The main objective of the common GPS and Galileo signal design activity was that the power spectral density (PSD) of the proposed solution would be identical for GPS L1C and Galileo E1 OS when the pilot and data components are computed together.^[1] This assures high interoperability between both signals. Its power spectral density $\Phi (f)$ is defined by ^[4]

$\Phi (f)={\frac {10}{11}}BOC(1,1)+{\frac {1}{11}}BOC(6,1)$

MBOC has two main implementations, the Composite Binary Offset Carrier (CBOC) implementation, currently used in Galileo and the Time-Multiplexed Binary Offset Carrier (TMBOC), currently used in modernized GPS L1C signal.

References

^ ^a ^b Navipedia information on MBCO Modulation
^ ^a ^b Galileo Open Service Signal In Space Interface Control Document (OS SIS ICD) Archived 2014-06-11 at the Wayback Machine, GSA, Issue 1.1, September 2010
^ [Hoult, N.; Aguado, L. E. and Xia, P. MBOC and BOC(1,1) Performance Comparison. Journal of Navigation, Volume 61, No. 4, pp613–627, 2008 (NaviJournal08)]
^ Agreement06 Archived 2011-07-25 at the Wayback Machine

[NAVIPEDIA_MBOC-1] Navipedia information on MBCO Modulation

[GAL_ICD-2] Galileo Open Service Signal In Space Interface Control Document (OS SIS ICD) Archived 2014-06-11 at the Wayback Machine, GSA, Issue 1.1, September 2010

[3] [Hoult, N.; Aguado, L. E. and Xia, P. MBOC and BOC(1,1) Performance Comparison. Journal of Navigation, Volume 61, No. 4, pp613–627, 2008 (NaviJournal08)]

[4] Agreement06 Archived 2011-07-25 at the Wayback Machine

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-'''Multiplexed binary offset carrier''' ('''MBOC''') modulation <ref name="NAVIPEDIA_MBOC">[http://www.navipedia.org/index.php/MBOC_Modulation Navipedia information on MBCO Modulation]</ref><ref name="GAL_ICD">[http://ec.europa.eu/enterprise/policies/satnav/galileo/files/galileo-os-sis-icd-issue1-revision1_en.pdf Galileo Open Service Signal In Space Interface Control Document (OS SIS ICD)], GSA, Issue 1.1, September 2010</ref><ref>[Hoult, N.; Aguado, L. E. and Xia, P. MBOC and BOC(1,1) Performance Comparison. Journal of Navigation, Volume 61, No. 4, pp613–627, 2008 (NaviJournal08)]</ref> is a modulation proposed for [[Galileo (satellite navigation)|Galileo]]<ref name="GAL_ICD"/> and modernized [[Global Positioning System|GPS]] signals, which combines a sine [[binary offset carrier]] SinBOC(1,1) signal with a SinBOC(6,1) signal, either via weighted sum/difference (the CBOC implementation) or via time-multiplexing (the TMBOC implementation).
+'''Multiplexed binary offset carrier''' ('''MBOC''') modulation <ref name="NAVIPEDIA_MBOC">[http://www.navipedia.org/index.php/MBOC_Modulation Navipedia information on MBCO Modulation]</ref><ref name="GAL_ICD">[http://ec.europa.eu/enterprise/policies/satnav/galileo/files/galileo-os-sis-icd-issue1-revision1_en.pdf Galileo Open Service Signal In Space Interface Control Document (OS SIS ICD)] {{webarchive|url=https://web.archive.org/web/20140611093741/http://ec.europa.eu/enterprise/policies/satnav/galileo/files/galileo-os-sis-icd-issue1-revision1_en.pdf |date=2014-06-11 }}, GSA, Issue 1.1, September 2010</ref><ref>[Hoult, N.; Aguado, L. E. and Xia, P. MBOC and BOC(1,1) Performance Comparison. Journal of Navigation, Volume 61, No. 4, pp613–627, 2008 (NaviJournal08)]</ref> is a modulation proposed for [[Galileo (satellite navigation)|Galileo]]<ref name="GAL_ICD"/> and modernized [[Global Positioning System|GPS]] signals, which combines a sine [[binary offset carrier]] SinBOC(1,1) signal with a SinBOC(6,1) signal, either via weighted sum/difference (the CBOC implementation) or via time-multiplexing (the TMBOC implementation).
-The main objective of the common GPS and Galileo signal design activity was that the power spectral density (PSD) of the proposed solution would be identical for GPS L1C and Galileo E1 OS when the pilot and data components are computed together.<ref name="NAVIPEDIA_MBOC"/> This assures high interoperability between both signals. Its [[power spectral density]] <math>\Phi(f)</math> is defined by <ref>[http://www.losangeles.af.mil/shared/media/document/AFD-070803-061.pdf Agreement06]</ref>
+The main objective of the common GPS and Galileo signal design activity was that the power spectral density (PSD) of the proposed solution would be identical for GPS L1C and Galileo E1 OS when the pilot and data components are computed together.<ref name="NAVIPEDIA_MBOC"/> This assures high interoperability between both signals. Its [[power spectral density]] <math>\Phi(f)</math> is defined by <ref>[http://www.losangeles.af.mil/shared/media/document/AFD-070803-061.pdf Agreement06] {{webarchive|url=https://web.archive.org/web/20110725125416/http://www.losangeles.af.mil/shared/media/document/AFD-070803-061.pdf |date=2011-07-25 }}</ref>
 <math>\Phi(f)=\frac{10}{11}BOC(1,1)+\frac{1}{11}BOC(6,1)</math>