Publications

(2023). Review and Scientific Objectives of Spaceborne Gravitational Wave Detection Missions. Chinese Journal of Space Science.

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(2023). Notes on Gravitational Physics. arXiv.

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(2023). Cosmology with the Laser Interferometer Space Antenna. Living Reviews in Relativity.

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(2023). Observational Evidence for Primordial Black Holes: A Positivist Perspective. arXiv.

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(2023). Cosmic Explorer: A Submission to the NSF MPSAC ngGW Subcommittee. arXiv.

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(2023). A Survey of Gravitational Waves. arXiv.

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(2023). The Physics of Gravitational Waves. arXiv.

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(2023). Dark Stars and Gravitational Waves: Topical Review. arXiv.

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(2023). Strong Gravitational Lensing of Gravitational Waves: A Review. Universe.

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(2023). Gravitational Waves Propagation as a Probe of New Fundamental Physics. Proceedings of 41st International Conference on High Energy Physics — PoS(ICHEP2022).

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(2022). Overview and Progress on the Laser Interferometer Space Antenna Mission. Nature Astronomy.

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(2022). Gravitational Waves from the Early Universe. arXiv.

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(2022). A Roadmap of Gravitational Wave Data Analysis. Nature Astronomy.

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(2022). The Galactic Center as a Laboratory for Theories of Gravity and Dark Matter. arXiv.

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(2022). Seeing the Gravitational Wave Universe. Science.

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(2022). Quantum Cosmological Gravitational Waves?. arXiv.

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(2022). Pulsar Glitches: A Review. Universe.

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(2022). Primordial Black Holes. arXiv.

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(2022). Gravitational-Wave Event Validation by Advanced LIGO and Advanced Virgo Detectors. Procedures and Challenges for the Upcoming Observing Runs. Proceedings of 41st International Conference on High Energy Physics — PoS(ICHEP2022).

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(2022). Gravitational-Wave Cosmology with Dark Sirens: State of the Art and Perspectives for 3G Detectors. Proceedings of 41st International Conference on High Energy Physics — PoS(ICHEP2022).

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(2022). Gravitational Wave Astronomy: Astrophysical and Cosmological Inferences. arXiv.

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(2022). Stochastic Gravitational Wave Background: Methods and Implications. arXiv.

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(2022). Modified Gravity Approaches to the Cosmological Constant Problem. arXiv.

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(2022). Modified Gravity Approaches to the Cosmological Constant Problem. arXiv.

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(2022). Six Textbook Mistakes in Data Analysis. arXiv.

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(2022). Cadabra and Python Algorithms in General Relativity and Cosmology II: Gravitational Waves. arXiv.

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(2022). Cadabra and Python Algorithms in General Relativity and Cosmology I: Generalities. arXiv.

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(2022). Cosmology with Gravitational Waves: A Review. Annalen der Physik.

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(2022). Strongly Lensed Transient Sources: A Review. arXiv.

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(2022). New Horizons for Fundamental Physics with LISA. Living Reviews in Relativity.

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(2022). Compact Binary Coalescences: Astrophysical Processes and Lessons Learned. Galaxies.

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(2022). The Dawn of Black Holes. arXiv.

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(2022). Parameter Estimation with Gravitational Waves. Rev. Mod. Phys..

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(2022). Modified Theories of Gravity: Why, How and What?. arXiv:2204.06533 [astro-ph, physics:gr-qc, physics:hep-th].

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(2022). Cosmology with the Laser Interferometer Space Antenna. arXiv:2204.05434 [astro-ph].

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(2022). Detection of Early-Universe Gravitational Wave Signatures and Fundamental Physics. arXiv:2203.07972 [gr-qc, physics:hep-ph, physics:hep-th].

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(2022). Astrophysics with the Laser Interferometer Space Antenna. arXiv:2203.06016 [astro-ph, physics:gr-qc].

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(2022). Status and Perspectives of Continuous Gravitational Wave Searches. arXiv:2202.01088 [gr-qc].

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(2022). Review of the Advanced LIGO Gravitational Wave Observatories Leading to Observing Run Four. arXiv:2202.00847 [astro-ph, physics:gr-qc, physics:physics].

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(2022). Quantum Gravity Phenomenology at the Dawn of the Multi-Messenger Era—A Review. Progress in Particle and Nuclear Physics.

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(2022). Quantum Gravity Phenomenology at the Dawn of the Multi-Messenger Era—A Review. Progress in Particle and Nuclear Physics.

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(2022). Lectures on Classical and Quantum Cosmology. arXiv:2202.13875 [astro-ph, physics:gr-qc, physics:hep-th].

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(2022). The Current Status and Future Prospects of KAGRA, the Large-Scale Cryogenic Gravitational Wave Telescope Built in the Kamioka Underground. Galaxies.

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(2022). Stochastic Gravitational-Wave Backgrounds: Current Detection Efforts and Future Prospects. arXiv:2202.00178 [gr-qc].

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(2022). Research Facilities for Europe's Next Generation Gravitational-Wave Detector Einstein Telescope. Galaxies.

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(2022). Gravitational Waves in Full, Non-Linear General Relativity. arXiv:2201.11634 [astro-ph, physics:gr-qc, physics:hep-th].

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(2022). Gravitational Waves from~Cosmic Strings. Beyond the Standard Model Cocktail: A Modern and Comprehensive Review of the Major Open Puzzles in Theoretical Particle Physics and Cosmology with a Focus on Heavy Dark Matter.

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(2021). Testing General Relativity with Gravitational Waves: An Overview. Universe.

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(2021). Cosmological Tests of Gravity: A Future Perspective. Universe.

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(2021). The Next Generation Global Gravitational Wave Observatory: The Science Book. arXiv:2111.06990 [gr-qc].

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(2021). Legacy of the First Workshop on Gravitational Wave Astrophysics for Early Career Scientists. arXiv:2111.15596 [astro-ph, physics:gr-qc].

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(2021). Gravitational Wave Data Analysis: Computing Challenges in the 3G Era. arXiv:2111.06987 [astro-ph, physics:gr-qc].

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(2021). Future Ground-Based Gravitational-Wave Observatories: Synergies with Other Scientific Communities. arXiv:2111.06988 [astro-ph, physics:gr-qc].

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(2021). Expanding the Reach of Gravitational Wave Astronomy to the Edge of the Universe: The Gravitational-Wave International Committee Study Reports on Next Generation Ground-based Gravitational-Wave Observatories. arXiv:2111.06986 [astro-ph, physics:gr-qc].

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(2021). An Exploration of Possible Governance Models for the Future Global Gravitational-Wave Observatory Network. arXiv:2111.06989 [astro-ph, physics:gr-qc].

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(2021). Sensitivity of Present and Future Detectors across the Black-hole Binary Gravitational Wave Spectrum. Classical and Quantum Gravity.

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(2021). Coalescence of Black Hole--neutron Star Binaries.

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(2021). Principles, Detections and Applications of Cosmological Gravitational Waves. Journal of Physics: Conference Series.

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(2021). Concepts and Status of Chinese Space Gravitational Wave Detection Projects. Nature Astronomy.

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(2021). A Horizon Study for Cosmic Explorer: Science, Observatories, and Community.

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(2021). LISA Sensitivity and SNR Calculations.

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(2021). Gravitational-wave Searches in the Era of Advanced LIGO and Virgo.

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(2021). Rates of Compact Object Coalescences.

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(2021). The Gravitational-wave physics II: Progress. Science China Physics, Mechanics & Astronomy.

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(2021). Intuition in Einsteinian Physics.

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(2021). Best Practices for Data Publication in the Astronomical Literature.

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(2021). The Missing Link in Gravitational-wave Astronomy: A Summary of Discoveries Waiting in the Decihertz Range. Experimental Astronomy.

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(2021). Gravitational Waves from Isolated Neutron Stars.

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(2021). Gravitational Wave Physics and Astronomy in the Nascent Era.

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(2021). Reproducing GW150914: The First Observation of Gravitational Waves from a Binary Black Hole Merger. Comput. Sci. Eng..

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(2021). Recent LIGO-Virgo Discoveries. Mod. Phys. Lett. A.

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(2021). Non-linear Effects in Emri Dynamics and Their Imprints on Gravitational Waves. arXiv preprint arXiv:2103.06724.

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(2021). Introduction to Numerical Relativity. Frontiers in Astronomy and Space Sciences.

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(2021). A Brief Overview of Black Hole-neutron Star Mergers. Frontiers in Astronomy and Space Sciences.

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(2021). A Needle in (many) Haystacks: Using the False Alarm Rate to Sift Gravitational Waves from Noise. Significance.

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(2021). 引力波数据处理技术. 中山大学学报(自然科学版).

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(2021). 天琴计划简介. 中山大学学报(自然科学版).

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(2021). Testing General Relativity with Gravitational Waves. Handbook of Gravitational Wave Astronomy.

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(2021). Space-Based Gravitational Wave Observatories. arXiv:2201.10593 [gr-qc].

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(2021). Reduced Order and Surrogate Models for Gravitational Waves.

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(2021). Recent Observations of Gravitational Waves by LIGO and Virgo Detectors. Universe.

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(2021). Pulsar Timing Array Experiments.

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(2021). Ground-based Gravitational Wave Detection and Its Implications. Journal of the Korean Physical Society.

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(2021). Gravitational-wave Physics and Astronomy in the 2020s and 2030s. Nature Reviews Physics.

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(2021). Detection of Low-frequency Gravitational Waves. Journal of the Korean Physical Society.

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(2021). Computational Challenges in Numerical Relativity in the Gravitational-wave Era. Nature Computational Science.

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(2021). Advanced Virgo: Status of the Detector, Latest Results and Future Prospects. Universe.

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(2020). Getting Ready for LISA: The Data, Support and Preparation Needed to Maximize Us Participation in Space-based Gravitational Wave Science.

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(2020). First Multimessenger Observations of a Neutron Star Merger.

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(2020). Gravitational Waves and Multi-messenger Astronomy: The New Exploration of the Universe. Particle Physics at the Year of 150th Anniversary of the Mendeleev’s Periodic Table of Chemical Elements.

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(2020). Frequency Estimation of Gravitational Waves from a Binary Black Hole Merger.

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(2020). Formation, Propagation and Detection of Gravitational Waves. Journal of Mechanical and Energy Engineering.

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(2020). Electromagnetic Counterparts of Compact Binary Mergers.

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(2020). The Missing Link in Gravitational-wave Astronomy: Discoveries Waiting in the Decihertz Range. Classical and Quantum Gravity.

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(2020). Probing Fundamental Physics with Gravitational Waves: The Next Generation.

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(2020). Discovering Gravitational Waves with Advanced LIGO. Contemporary Physics.

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(2020). Gravitational-wave Astronomy Still in Its Infancy. Physics.

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(2020). Computational Techniques for Parameter Estimation of Gravitational Wave Signals. WIREs Comput Stat.

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(2020). Inferring the Properties of a Population of Compact Binaries in Presence of Selection Effects.

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(2020). GW190412: Gravitational Wave from an Unequal Mass Binary Black Hole with Precession. Science China Physics, Mechanics & Astronomy.

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(2020). Binary Black Hole Mergers: Formation and Populations. Front. Astron. Space Sci..

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(2020). The First Three Seconds: A Review of Possible Expansion Histories of the Early Universe. Open J. Astrophys. Vol. 4, 2021.

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(2020). Nonparametric Score Estimators.

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(2020). Gravitational Waves, 100 Years Later.

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(2020). O3 Highlights. Nature Reviews Physics.

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(2020). Gravitational Waves from Coalescing Binaries. Synthesis Lectures on Wave Phenomena in the Physical Sciences.

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(2020). Vflow: More Expressive Generative Flows with Variational Data Augmentation.

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(2020). Handbook of Gravitational Wave Astronomy. Springer Singapore.

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(2020). Gravity’s Songs. Scientific Journeys: A Physicist Explores the Culture, History and Personalities of Science.

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(2020). Gravitational-wave Parameter Estimation with Autoregressive Neural Network Flows.

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(2020). Discovering Gravitational Waves with Advanced LIGO. LIGO Document P2000530-v1.

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(2019). Gravitational wave observations and future detectors. Rendiconti Lincei. Scienze Fisiche e Naturali.

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(2019). Parameterized and Consistency Tests of Gravity with Gravitational Waves: Current and Future. Multidisciplinary Digital Publishing Institute Proceedings.

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(2019). Gradient Descent Finds Global Minima of Deep Neural Networks. PMLR.

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(2019). Black Holes, Gravitational Waves and Fundamental Physics: A Roadmap. Classical and Quantum Gravity.

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(2019). Black Holes in General Relativity and Beyond. Proceedings.

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(2019). The New Frontier of Gravitational Waves. Nature.

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(2019). The Architecture of the LISA Science Analysis. Keck Institute for Space Studies.

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(2019). Lecture Notes on Gravitational Waves. Proceedings, 18th International Baikal Summer School on Physics of Elementary Particles and Astrophysics: Exploring the Universe through multiple messengers (ISAPP-Baikal 2018): Bolshie Koty, Lake Baikal, Russia, July 12-21, 2018.

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(2019). Gravitational Waves. IOP Publishing.

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(2018). Cosmological Backgrounds of Gravitational Waves. Classical and Quantum Gravity.

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(2018). 贝叶斯引力波多信使天文学. 中国科学(物理学 力学 天文学).

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(2018). 引力波探测检验广义相对论. 中国科学(物理学 力学 天文学).

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(2018). Neural Tangent Kernel: Convergence and Generalization in Neural Networks. Advances in Neural Information Processing Systems.

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(2018). Initial study on the application of deep learning to the Gravitational Wave data analysis. Journal of Henan Normal University.

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(2018). Bayesian astrophysics. Cambridge University Press.

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(2017). Obtaining Gravitational Waves from Inspiral Binary Systems Using LIGO Data. The European Physical Journal Plus.

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(2017). Gravitational Waves without General Relativity: A Tutorial. Am. J. Phys. 86, 186-197 (2018).

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(2017). Zhusuan: A Library for Bayesian Deep Learning.

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(2017). An Analysis of the LIGO Discovery Based on Introductory Physics. Am. J. Phys..

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(2017). The Gravitational-wave Physics. Natl. Sci. Rev..

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(2017). The Expressive Power of Neural Networks: A View from the Width. Advances in Neural Information Processing Systems.

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(2017). The Basic Physics of the Binary Black Hole Merger Gw150914. LIGO Scientific and Virgo Collaborations, Annalen der Physik, Volume 529, Issue 1-2, January 2017, 1600209.

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(2017). Gravitational Wave Theories.

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(2017). Gravitational Wave Simulations.

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(2017). Erratum to: Obtaining Gravitational Waves from Inspiral Binary Systems Using LIGO Data. The European Physical Journal Plus.

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(2017). Detection Methods for Stochastic Gravitational-wave Backgrounds: A Unified Treatment. Living Reviews in Relativity..

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(2016). Understanding Deep Learning Requires Rethinking Generalization. arXiv preprint arXiv:1611.03530.

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(2016). Testing the Black Hole `No-Hair' Hypothesis. Class. Quantum Grav..

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(2016). Dropout As a Bayesian Approximation: Representing Model Uncertainty in Deep Learning. international conference on machine learning.

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(2015). Testing General Relativity with Present and Future Astrophysical Observations. Class. Quantum Grav..

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(2015). Train Faster, Generalize Better: Stability of Stochastic Gradient Descent.

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(2015). An example journal article. Journal of Source Themes, 1(1).

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(2015). 大数据分析中的计算智能研究现状与展望. 软件学报.

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(2014). Nice: Non-linear Independent Components Estimation.

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(2014). Very Deep Convolutional Networks for Large-Scale Image Recognition. arXiv preprint arXiv:1409.1556.

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(2013). Bayes' Theorem in the 21st Century. Science.

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(2012). Improving neural networks by preventing co-adaptation of feature detectors.

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(2012). ImageNet Classification with Deep Convolutional Neural Networks. Advances in Neural Information Processing Systems 25.

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(2012). Bayesian Learning for Neural Networks. Springer Science & Business Media.

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(2011). Riemann Manifold Langevin and Hamiltonian Monte Carlo Methods. Journal of the Royal Statistical Society: Series B (Statistical Methodology).

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(2010). Tree-structured Stick Breaking for Hierarchical Data. Advances in Neural Information Processing Systems.

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(2009). Physics, Astrophysics and Cosmology with Gravitational Waves. Living Reviews in Relativity.

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(2008). Graphical Models, Exponential Families, and Variational Inference. Found. Trends Mach. Learn..

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(2007). An Introduction to General Relativity, Gravitational Waves and Detection Principles. Second VESF School on Gravitational Waves, Cascina, Italy, May 28th–June 1st.

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(2006). Pattern recognition and machine learning. springer.

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(2005). The Basics of Gravitational Wave Theory. New Journal of Physics.

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(2002). Gravitational Wave Physics. Encyclopedia of Physical Science and Technology.

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(2001). New Physics and Astronomy with the New Gravitational-wave Observatories. eConf.

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(1998). Data Analysis of Gravitational-wave Signals from Spinning Neutron Stars: The Signal and Its Detection. Phys. Rev. D.

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(1995). Gravitational Waves. 1994 DPF Summer Study on High-energy Physics: Particle and Nuclear Astrophysics and Cosmology in the Next Millenium (Snowmass 94).

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(1992). Bayesian Methods for Adaptive Models.

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(1989). Approximation by Superpositions of a Sigmoidal Function. Mathematics of Control, Signals and Systems.

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(1963). Gravitational Radiation from Point Masses in a Keplerian Orbit. Phys. Rev..

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