Time delay interferometry and principal component analysis for noise cancellation of TianQin

doi:10.1088/1674-1056/ae12d4

Abstract TianQin is a proposed space-borne laser interferometer which aims to detect gravitational waves in the low frequency band ($10^{-4}$ Hz-$10^{0}$ Hz). However, for space-borne interferometry detectors the laser phase noise is expected to be 7-8 orders of magnitude higher than the gravitational wave signals, due to unequal and time-varying arm lengths. Time delay interferometry (TDI) is an effective method to cancel laser phase noise by synthesizing virtual equal arm interferometric measurements with time delayed Doppler data combinations. In previous work it has been shown that TDI variables can also be understood within the context of principal component analysis (PCA), as combinations of eigenvectors of the total noise covariance matrix. It is therefore possible to generate the same TDI variables using a PCA approach - by computing the eigenvectors of the noise covariance matrix at a specific time. In this paper we extend significantly the previous work on a PCA approach to generating TDI variables by presenting TDI sensitivity curves for TianQin approximated as both a static and moving constellation of satellites. We compare the covariance matrix for the static and moving case, from the point of view of performing statistical inference using PCA. We also demonstrate the equivalency between the `conventional' second generation TDI variables and those obtained using PCA.

Keywords: gravitational waves time delay interferometry principal component analysis

Received: 27 July 2025
Revised: 24 September 2025
Accepted manuscript online: 14 October 2025

PACS:	04.30.-w	(Gravitational waves)
	04.80.Nn	(Gravitational wave detectors and experiments)
	04.20.Cv	(Fundamental problems and general formalism)

Fund: Project supported by “GrEAT network” in School of Physics and Astronomy, University of Glasgow. Wang Y gratefully acknowledges support from the National Key Research and Development Program of China (Grant Nos. 2023YFC2206702 and 2022YFC2205201), and the Major Science and Technology Program of Xinjiang Uygur Autonomous Region of China (Grant No. 2022A03013-4). Hu X C is supported by the Tongling University Talent Program (Grant No. 2021tlxyrc26) and Tongling University Natural Science Research Project (Grant No. 2024tlxykjZD10).

Corresponding Authors: Xinchun Hu
E-mail: 030261@tlu.edu.cn

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Xinchun Hu(胡新春) and Yan Wang(王炎) Time delay interferometry and principal component analysis for noise cancellation of TianQin 2026 Chin. Phys. B 35 050401

[1] Harry G M and LIGO Scientific Collaboration 2010 Classical and Quantum Gravity 27 084006
[2] LIGO Scientific Collaboration, Aasi J, Abbott B P, Abbott R, Abbott T, Abernathy M R, Ackley K, et al. 2015 Classical and Quantum Gravity 32 074001
[3] Acernese F, Agathos M, Agatsuma K, Aisa D, Allemandou N, et al. 2015 Classical and Quantum Gravity 32 024001
[4] Somiya K 2012 Classical and Quantum Gravity 29 124007
[5] Amaro-Seoane P, Audley H, Babak S, Baker J, Barausse E, Bender P, Berti E, Binetruy P, Born M, Bortoluzzi D, Camp J, Caprini C, et al 2017 arXiv e-prints arXiv: 1702.00786
[6] eLISA Consortium, Amaro Seoane P, Aoudia S, Audley H, Auger G, Babak S, Baker J, Barausse E, Barke S, Bassan M, Beckmann V, Benacquista M, Bender P L, Berti E, et al. 2013 arXiv e-prints arXiv: 1305.5720
[7] Armano M, Audley H, Auger G, Baird J T, Bassan M, Binetruy P, Born M, Bortoluzzi D, Brandt N, Caleno M, Carbone L, Cavalleri A, et al. 2016 Phys. Rev. Lett. 116 231101
[8] Luo J, Chen L S, Duan H Z, Gong Y G, Hu S, Ji J, Liu Q, Mei J, Milyukov V, Sazhin M, Shao C G, Toth V T, Tu H B, Wang Y, Wang Y, Yeh H C, Zhan M S, Zhang Y, Zharov V and Zhou Z B 2016 Classical and Quantum Gravity 33 035010
[9] Conklin J W, Buchman S, Aguero V, Alfauwaz A, Aljadaan A, Almajed M, Altwaijry H, Al-Saud T, Balakrishnan K, Byer R L, Bower K, Costello B, Cutler G D, DeBra D B, Faied D M, Foster C, Genova A L, Hanson J, Hooper K, Hultgren E, Jaroux B, Klavins A, Lantz B, Lipa J A, Palmer A, Plante B, Sanchez H S, Saraf S, Schaechter D, Sherrill T, Shu K L, Smith E, Tenerelli D, Vanbezooijen R, Vasudevan G, Williams S D, Worden S P, Zhou J and Zoellner A 2011 arXiv e-prints arXiv: 1111.5264
[10] Tinto M, de Araujo J C N, Aguiar O D and AlvesME S 2013 Astroparticle Physics 48 50
[11] Tinto M, DeBra D, Buchman S and Tilley S 2015 Rev. Sci. Instrum. 86 014501
[12] Hiscock B and Hellings R W 1997 OMEGA: A space gravitational wave MIDEX mission. Vol. 29
[13] Ni W T 2002 Int. J. Mod. Phys. D 11 947
[14] Ni W T, Cao J, Dittus H, Dong P, Guo J, Lämmerzahl C, Mei X, Shaul D, Sumner T J, Wang G, Hou X, Huang C G, Meng J, Wang H, Zhang C and Zhang Y 2010 38th COSPAR Scientific Assembly 38 11
[15] Gong X, Lau Y K, Xu S, Amaro-Seoane P, Bai S, Bian X, Cao Z, Chen G, Chen X, Ding Y, Dong P, Gao W, Heinzel G, Li M, Li S, Liu F, Luo Z, Shao M, Spurzem R, Sun B, Tang W, Wang Y, Xu P, Yu P, Yuan Y, Zhang X and Zhou Z 2015 J. Phys.: Conf. Ser. 610 012011
[16] Cutler C and Harms J 2006 Phys. Rev. D 73 042001
[17] Crowder J and Cornish N J 2005 Phys. Rev. D 72 083005
[18] Sato S, Kawamura S, Ando M, et al. 2009 J. Phys.: Conf. Ser. 154 012040
[19] Ni W T 2016 Int. J. Mod. Phys. D 25 1630001
[20] Bender P, Brillet A, Ciufolini I, Cruise A, Cutler C, Danzmann K, Fidecaro F, et al. 1998 LISA Mission Concept Study, Laser Interferometer Space Antenna for the Detection and Observation of Gravitational Waves, Vol. 233 (MPQ)
[21] Tinto M and Dhurandhar S V 2014 Living Reviews in Relativity 17 6
[22] Tinto M and Armstrong J W 1999 Phys. Rev. D 59 102003
[23] Armstrong J W, Estabrook F B and Tinto M 1999 The Astrophysical Journal 527 814
[24] Estabrook F B, Tinto M and Armstrong J W 2000 Phys. Rev. D 62 042002
[25] Armstrong J W, Estabrook F B and Tinto M 2001 Classical and Quantum Gravity 18 4059
[26] Tinto M, Armstrong JWand Estabrook F B 2001 Classical and Quantum Gravity 18 4081
[27] Prince T A, Tinto M, Larson S L and Armstrong J W 2002 Phys. Rev. D 66 122002
[28] Zhang C, Gao Q, Gong Y, Liang D, Weinstein A J and Zhang C 2019 Phys. Rev. D 100 064033
[29] Tinto M and Hartwig O 2018 Phys. Rev. D 98 042003
[30] Vallisneri M 2005 Phys. Rev. D 71 022001
[31] Nayak K R and Vinet J Y 2004 Phys. Rev. D 70 102003
[32] Shaddock D A 2004 Phys. Rev. D 69 022001
[33] Shaddock D A, Tinto M, Estabrook F B and Armstrong J W 2003 Phys. Rev. D 68 061303
[34] Tinto M, Shaddock D A, Sylvestre J and Armstrong J W 2003 Phys. Rev. D 67 122003
[35] Dhurandhar S V, Nayak K R and Vinet J Y 2002 Phys. Rev. D 65 102002
[36] Tinto M, Estabrook F B and Armstrong J W 2002 Phys. Rev. D 65 082003
[37] Romano J D and Woan G 2006 Phys. Rev. D 73 102001
[38] Abdi HervéWL J 2010 Principal Component Analysis, Vol. 2 (WIREs Comp Stat)
[39] Leighton M D 2016 A principal component approach to space-based gravitational wave astronomy Thesis (phd) University of Glasgow
[40] Baghi Q, Thorpe J I, Slutsky J and Baker J 2021 Phys. Rev. D 103 042006
[41] Baghi Q, Baker J, Slutsky J and Thorpe J I 2021 Phys. Rev. D 104 122001
[42] Wang G and NiWT 2012 Chinese Astronomy and Astrophysics 36 211
[43] Armstrong J W, Estabrook F B and Tinto M 2001 Classical and Quantum Gravity 18 4059
[44] Hu X C, Li X H, Wang Y, Feng W F, Zhou M Y, Hu Y M, Hu S C, Mei J W and Shao C G 2018 Classical and Quantum Gravity 35 095008
[45] Vallisneri M 2005 Phys. Rev. D 72 042003
[46] Ye B B, Zhang X, ZhouMY,Wang Y, Yuan H M, Gu D, Ding Y, Zhang J, Mei J and Luo J 2019 Int. J. Mod. Phys. D 28 1950121

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