[1] [1] ABRAMOVICI A, ALTHOUSE W E, DREVER R W P, et al.. LIGO: The laser interferometer gravitational-wave observatory ［J］. Science, 1992, 256(5055): 325-333.

[2] [2] ARAIN M A, MUELLER G. Design of the advanced LIGO recycling cavities ［J］. Optics Express, 2008, 16(14): 10018-10032.

[3] [3] ACERNESE F, ANTONUCCI F, AOUDIA S, et al.. Performances of the Virgo interferometer longitudinal control system［J］. Astroparticle Physics, 2010, 33(2): 75-80.

[4] [4] BEKER M G, BLOM M, BRAND J F J, et al.. Seismic attenuation technology for the advanced Virgo gravitational wave detector ［J］. Physics Procedia, 2012, 37: 1389-1397.

[5] [5] HEWITSON M, AUFMUTH P, AULBERT C, et al.. A report on the status of the GEO 600 gravitational wave detector ［J］. Classical & Quantum Gravity, 2003, 20(17): S581-S591.

[6] [6] GROTE H. The status of GEO 600［J］. Classical and Quantum Gravity, 2008, 25(11): 114043-114051.

[7] [7] ANDO M, COLLABORATION T T. Current status of the TAMA300 gravitational-wave detector ［J］. Classical and Quantum Gravity, 2005, 22(18): S881-S889.

[8] [8] KAWAMURA S, COLLABORATION T T. Laser Interferometer gravitational wave detector ［J］. Progress of Theoretical Physics Supplement, 1999, 136: 72-86.

[9] [9] PATEL J, WOOLLEY A, ZHAO C, et al.. Vacuum control system for the AIGO gravitational wave detector［J］. Vacuum, 2010, 85(2): 176-179.

[10] [10] BARRIGA P, BLAIR D G, COWARD D, et al.. AIGO: a southern hemisphere detector for the worldwide array of ground-based interferometric gravitational wave detectors ［J］. Classical and Quantum Gravity, 2010, 27(8): 084005-1-12.

[11] [11] ABBOTT B P, ABBOTT R, ABBOTT T D, et al.. Observation of gravitational waves from a binary black hole merger ［J］. Physical Review Letters, 2016, 116: 061102-1-061102-16.

[12] [12] DANZMANN K, STUDY TEAM T L. LISA: Laser interferometer space antenna for gravitational wave measurements ［J］. Classical and Quantum Gravity, 1996, 13(11A): A247-A250.

[13] [13] CORNISH N J. Detecting a stochastic gravitational wave background with the laser interferometer space antenna ［J］. Physical Review D, 2001, 65(2): 022004.

[14] [14] AMARO-SEOANE P, AOUDIA S, BABAK S, et al.. Low-frequency gravitational-wave science with eLISA/NGO ［J］. Classical and Quantum Gravity, 2012, 29(12): 124016.

[15] [15] PIJNENBURG J, RIJNVELD N, HOGENHUIS H. Extremely stable piezo mechanisms for the new gravitational wave observatory ［J］. SPIE, 2013, 8450: 84500C-1-84500C-15.

[16] [16] CORBIN V, CORNISH N J. Detecting the cosmic gravitational wave background with the big bang observer ［J］. Classical and Quantum Gravity, 2006, 23(7): 2435-2446.

[17] [17] CUTLER C, HARMS J. Big bang observer and the neutron-star-binary subtraction problem ［J］. Physical Review D, 2006, 73(4): 042001-1-21.

[18] [18] KAWAMURA S, NAKAMURA T, ANDO M, et al.. The Japanese space gravitational wave antenna—DECIGO ［J］. Classical Quantum Gravity, 2006, 23(3): S125-S131.

[19] [19] ANDO M, KAWAMURA S, SETO N, et al.. DECIGO and DECIGO pathfinder ［J］. Classical & Quantum Gravity, 2010, 27(8): 084010.

[20] [20] GONG X F, XU S N, BAI S, et al.. A scientific case study of an advanced LISA mission［J］. Classical Quantum Gravity, 2011, 28(9): 094012.

[21] [21] CYRANOSKI D. Chinese gravitational-wave hunt hits crunch time［J］. Nature, 2016, 531(7593): 150-151.

[22] [22] HU W R, WU Y L. The Taiji Program in space for gravitational wave physics and the nature of gravity ［J］. National Science Review, 2017, 4(5): 685-686.

[23] [23] LUO J, CHEN S, DUAN H Z, et al.. TianQin: a space-borne gravitational wave detector ［J］. Classical and Quantum Gravity, 2016, 33(3): 035010.

[24] [24] NI W T. Gravitational wave detection in space［J］. International Journal of Modern Physics D, 2016, 25(14): 163001.

[25] [25] LI Y Q, LUO Z R, LIU H S, et al.. Laser interferometer for space gravitational waves detection and earth gravity mapping ［J］. Microgravity-Science and Technology, 2018, 30(6): 817-829.

[26] [26] YAO D, LI Y P, ZHAO Y, et al.. Tolerance assurance of interferometer for optical HCB process ［J］. Opt. Precision Eng., 2018, 26(8): 1945-1953.(in Chinese)

[27] [27] DONG Y H, LIU H S, LUO Z R, et al.. A comprehensive simulation of weak-light phase-locking for space-borne gravitational wave antenna［J］. Science China Technological Sciences, 2016, 59(5): 730-737.

[28] [28] DONG Y H, LIU H S, LUO Z R, et al.. Methodological demonstration of laser beam pointing control for space gravitational wave detection missions［J］. Review of Scientific Instruments, 2014, 85(7): 074501.

[29] [29] LI Y Q, LUO Z R, LIU H S, et al.. Path-length measurement performance evaluation of polarizing laser interferometer prototype［J］. Applied Physics B, 2015, 118(2): 307-317.

[30] [30] JOSHI A M, DATTA S, PRASAD N, et al.. Reliability testing of ultra-low noise InGaAs quad photoreceivers ［J］. SPIE, 2018, 10526: 105261J-1-10.

[31] [31] JOSHI A M, DATTA S. Space qualification of InGaAs photodiodes and photoreceivers ［J］. SPIE, 2018, 10641: 106410K-1-8.

[32] [32] JOSHI A, DATTA S, RUE J, et al.. Ultra-low noise, large-area InGaAs quad photoreceiver with low crosstalk for laser interferometry space antenna ［J］. SPIE, 2012, 8453: 84532G-1-10.

[33] [33] LIU H S, LUO Z R, JIN G. The development of phasemeter for taiji space gravitational wave detection ［J］. Microgravity-Science and Technology, 2018, 30(6): 775-781.