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Seismic noise analysis and isolation concepts for the ALPS II experiment at DESY (2020)

Miller, Dominik [VerfasserIn] 1991- ; Flury, Jakob [AkademischeR BetreuerIn] ; Neumann, Ingo [AkademischeR BetreuerIn] ; [et al.]

Hannover : Fachrichtung Geodäsie und Geoinformatik der Leibniz Universität Hannover

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Call number: S 99.0139(351)

In: Wissenschaftliche Arbeiten der Fachrichtung Geodäsie und Geoinformatik der Leibniz Universität Hannover, Nr. 351

Type of Medium: Series available for loan

Pages: xxix, 177 Seiten , Illustrationen, Diagramme

ISSN: 0174-1454

Series Statement: Wissenschaftliche Arbeiten der Fachrichtung Geodäsie und Geoinformatik der Leibniz Universität Hannover Nr. 351

URL: https://www.repo.uni-hannover.de/handle/123456789/9921

URL: Table of Contents

Language: English , German

Note: Dissertation, Gottfried Wilhelm Leibniz Universität Hannover, 2019 , Contents 1. Introduction 1.1. Motivations and background 1.2. Research hypotheses and aims 1.3. Outline of this work 2. Fundamentals and theory of seismic noise 2.1. Fundamentals of mechanical vibration 2.1.1. Theory of oscillation 2.1.1.1. Oscillation and waves 2.1.1.2. Standing waves and resonance 2.1.1.3. Types of noise 2.1.1.4. Signal-to-Noise Ratio 2.1.2. The oscillatory systems 2.1.2.1. Mass-Spring-Damper model 2.1.2.2. Equation of motion 2.1.2.3. Free damped oscillation 2.1.2.4. Forced damped oscillation 2.1.3. Modal analysis 2.1.3.1. Fourier transform 2.1.3.2. Windowing 2.1.3.3. Averaging and overlapping 2.1.4. Data evaluation 2.1.4.1. Presenting spectra and spectral densities 2.1.4.2. RMS value in the frequency domain 2.1.4.3. Transfer function 2.1.4.4. Spectrogram 2.2. Seismic noise sources 2.2.1. Natural sources 2.2.1.1. Geodynamical aspects 2.2.1.2. Geological aspects at Hamburg, DESY 2.2.2. Human-made sources 2.2.2.1. Impact by stationary objects 2.2.2.2. Impact by traffic on site, machines and human work 2.2.2.3. Technical devices in the laboratory 2.3. Methods of seismic isolation 2.3.1. Passive constructions 2.3.1.1. Principle of a simple pendulum 2.3.1.2. Principle of a spring pendulum 2.3.1.3. The inverted pendulum concept 2.3.1.4. The anti-spring concept 2.3.1.5. The harmonic oscillator as transfer function 2.3.2. Control theory 2.3.2.1. Simple controller 2.3.2.2. Feed-forward controller 2.3.2.3. Feedback controller 2.3.2.4. Combined controller 3. The Any Light Particle Search experiment 3.1. ALPS and its seismic noise requirements 3.1.1. The physics of ALPS 3.1.2. Optical resonators 3.1.3. Control loop design 3.1.4. Frequency region and absolute length requirements 3.1.5. Infrastructure and status 3.2. Tools and techniques used for seismicmeasurements, analyses, and isolations 3.2.1. Seismic measuring instruments 3.2.1.1. Seismometers 3.2.1.2. Acquisition devices 3.2.1.3. Selected measurement chain 3.2.2. Data management and analyses 3.2.2.1. Notations for documentation 3.2.2.2. Analysing procedure 3.2.3. Finite Element Method simulation 3.2.3.1. Simple isolation simulations 3.2.3.2. Over-determined isolation systems 3.2.3.3. Selected FEM tools 4. Seismic noise analysis 57 4.1. Method of frequency-weighted and averaged FFT 4.1.1. Problem definition and motivation 4.1.2. The solution approaches 4.1.2.1. Stitching 4.1.2.2. LPSD 4.1.2.3. New solution approach 4.1.3. The MfwaFFT algorithm 4.1.3.1. Data preparation 4.1.3.2. FFT generation 4.1.3.3. Windowing of the iteration steps 4.1.3.4. Weighting 4.1.3.5. Summing up 4.1.4. Advantages and disadvantages 4.1.5. Discussion in the field of geodesy 4.2. Measurement Preparation 4.2.1. Calibration of seismic devices 4.2.1.1. Single instruments 4.2.1.2. Cross-calibration 4.2.2. Accuracy analysis 4.2.2.1. Measuring device accuracy and precision 4.2.2.2. Digital uncertainties and errors 4.3. Seismic measurements on-site 4.3.1. On-site noise conditions (HERA) 4.3.1.1. ALPS IIa laboratory (HERA West) 4.3.1.2. ALPS IIc site (HERA North) 4.3.1.3. Reference (HERA South) 4.3.2. Optic-related components of the ALPS II experiment 4.3.2.1. Optical tables 4.3.2.2. CBB and mirror mountings 4.3.3. Associated noise sources 4.3.3.1. Dipole magnet girders 4.3.3.2. Filter Fan Units 4.4. Filtering of signal 4.4.1. Spatial transfer functions 4.4.2. Low-pass filter due to the cavity pole frequency 4.4.3. Filter by the control loop 4.5. Data evaluation 4.5.1. Specifications for the ALPS IIa isolation 4.5.2. Specifications for an ALPS IIc isolation 4.5.3. Specifications for a JURA isolation 5. Development of seismic isolation systems 5.1. Procedure for handling seismic noise and isolation problems 5.2. State-of-the-art seismic isolation concepts 5.2.1. The LIGO system 5.2.2. The VIRGO system 5.3. Development of a seismic isolation system 5.3.1. CAD draft of a test model 5.3.2. FEM simulations 5.3.3. Design drawing 5.3.4. Evaluation and validation 5.4. Seismic isolation concept for ALPS IIc and JURA 6. Conclusion 6.1. Summary 6.2. Outlook , Sprache der Zusammenfassungen: Englisch, Deutsch

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International Combination Service for Time-variable Gravity Fields (COST-G) Monthly GRACE-FO Series (2020)

Meyer, Ulrich ; Lasser, Martin ; Jaeggi, Adrian ; [et al.]

GFZ Data Services

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Publication Date: 2023-12-01

Description: Abstract

Description: Operationally combined monthly gravity fields of the GRACE-FO satellite mission in spherical harmonic representation (Level-2 product) generated by the Combination Service for Time-variable Gravity Fields (COST-G; Jäggi et al. (2020):http://dx.doi.org/10.1007/1345_2020_109), a product center for time-variable gravity fields of IAG's International Gravity Field Service (IGFS). COST-G_GRACE-FO_RL01_OP is a combination of AIUB-GRACE-FO_op, GFZ-RL06 (GFO), GRGS-RL05 (unconstrained solution), ITSG-Grace_op, LUH-GRACE-FO, CSR-RL06 (GFO) and JPL-RL06 (GFO). The original time-series were provided by the analysis centers (ACs) and partner analysis centers (PCs) of COST-G.

Description: Methods

Description: COST-G performs a harmonization and quality control of the individual input solutions of the COST-G ACs and PCs. The combination of COST-G_GRACE-FO_RL01_OP is then performed applying variance component estimation on the solution level (Jean et al., 2018): https://doi.org/10.1007/s00190-018-1123-5). The resulting COST-G combined gravity fields are validated assessing their signal and noise content in the spectral and spatial domain (Meyer et al., 2019: https://doi.org/10.1007/s00190-019-01274-6) and by the COST-G Product Evaluation Group (PEG).

Keywords: COST-G ; IGFS Product Center ; Combined solutions ; Time variable gravity ; EARTH SCIENCE 〉 SOLID EARTH 〉 GRAVITY/GRAVITATIONAL FIELD 〉 GRAVITATIONAL FIELD ; EARTH SCIENCE 〉 SOLID EARTH 〉 GRAVITY/GRAVITATIONAL FIELD 〉 GRAVITY

Type: Dataset , Dataset

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