Recursive evaluation of interaction forces of unbounded soil in the time domain from dynamic-stiffness coefficients in the frequency domain

Significant differences between the predicted and measured dynamic response of 3D rigid foundations on multi-layered soils in the time domain were identified due to the existence of uncertainties, which makes the issue a complicated one. In this study, a numerical method was developed to determine the dynamic responses of 3D rigid surfaces and embedded foundations of arbitrary shapes that are bonded to a multi-layered soil in the time domain. First, the dynamic stiffness matrices of the rigid foundations in the frequency domain are calculated via integral domain transformation. Secondly, a dynamic stiffness equation for rigid foundations in the time domain is established via the mixed variables formulation, which is based on the discrete dynamic stiffness matrices in the frequency domain. The proposed method can be applied to the treatment of systems with multiple degrees of freedom without losing the true information that concerns the coupling characteristics. Numerical examples are presented to demonstrate the accuracy of the proposed method for predicting the horizontal, vertical, rocking, and torsional vibrations. Further, a parametric study was carried out to provide insight into the dynamic behavior of the soil–foundation interaction (SFI) while considering soil nonhomogeneity. The results indicate that the elastic modulus of the soil has a significant impact on the dynamic responses of the rigid foundation. Finally, a numerical example of a rigid foundation resting on a six-layered, semi-infinite soil demonstrates that the proposed method can be used to deal with multi-layered media in the time domain in a relatively easy way.

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Dynamics of Infinite Beams Described by Fractional Time Derivatives

Volume 5: 19th Biennial Conference on Mechanical Vibration and Noise, Parts A, B, and C ◽

10.1115/detc2003/vib-48400 ◽

2003 ◽

Cited By ~ 3

Author(s):

Peter Ruge ◽

Carolin Trinks

Keyword(s):

Frequency Domain ◽

Time Domain ◽

Dynamic Stiffness ◽

Time Derivative ◽

Low Frequency ◽

Internal Variables ◽

Closed Form Solutions ◽

Rational Polynomial ◽

The Time Domain ◽

Fractional Time Derivative

Closed-form solutions of infinite Bernoulli-Euler beams on a viscoelastic foundation are available for harmonic excitations with frequency Ω. For more general time-dependent loadings and beam-systems with local perturbations, for example caused by non-linear effects an overall treatment of the system in the time-domain is highly appropriated. Here the analytical dynamic stiffness of the infinite beam in the frequency-domain is approximated by a rational polynomial in the low frequency-domain and by an irrational part representing the asymptotic behaviour for Ω tending towards infinity. Thus, the corresponding description in the time-domain contains a fractional time derivative part and additonal internal variables due to splitting the rational polynomial into a linear system with respect to Ω.

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DYNAMIC PARTIAL UPLIFT ANALYSIS OF A STRUCTURE ON A 3-D LAYERED HALF-SPACE BASED ON RECURSIVE EVALUATION OF INTERACTION FORCES USING DYNAMIC STIFFNESS OF THE UNBOUNDED SOIL IN THE FREQUENCY DOMAIN

Journal of Structural and Construction Engineering (Transactions of AIJ) ◽

10.3130/aijsx.451.0_79 ◽

1993 ◽

Vol 451 (0) ◽

pp. 79-88 ◽

Cited By ~ 2

Author(s):

Masato MOTOSAKA ◽

Masayuki NAGANO

Keyword(s):

Frequency Domain ◽

Half Space ◽

Dynamic Stiffness ◽

Interaction Forces ◽

Recursive Evaluation ◽

Layered Half Space

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Recursive evaluation of interaction forces of unbounded soil in the time domain

Earthquake Engineering & Structural Dynamics ◽

10.1002/eqe.4290180304 ◽

1989 ◽

Vol 18 (3) ◽

pp. 345-363 ◽

Cited By ~ 25

Author(s):

John P. Wolf ◽

Masato Motosaka

Keyword(s):

Time Domain ◽

Interaction Forces ◽

The Time Domain ◽

Recursive Evaluation

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Recursive evaluation of interaction forces of unbounded soil in the time domain

International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts ◽

10.1016/0148-9062(89)91872-x ◽

1989 ◽

Vol 26 (6) ◽

pp. 341

Keyword(s):

Time Domain ◽

Interaction Forces ◽

The Time Domain ◽

Recursive Evaluation

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JOINT INTERPRETATION OF AIRBORNE ELECTROMAGNETIC DATA IN THE TIME DOMAIN AND FREQUENCY DOMAIN

Engineering survey ◽

10.25296/1997-8650-2018-12-7-8-76-83 ◽

2018 ◽

Vol 12 (7-8) ◽

pp. 76-83

Author(s):

E. V. KARSHAKOV ◽

J. MOILANEN

Keyword(s):

Fourier Transform ◽

Frequency Domain ◽

Time Domain ◽

Frequency Interval ◽

Single Spectrum ◽

Simultaneous Inversion ◽

Homogeneous Half Space ◽

Time Domain Data ◽

The Time Domain

Тhe advantage of combine processing of frequency domain and time domain data provided by the EQUATOR system is discussed. The heliborne complex has a towed transmitter, and, raised above it on the same cable a towed receiver. The excitation signal contains both pulsed and harmonic components. In fact, there are two independent transmitters operate in the system: one of them is a normal pulsed domain transmitter, with a half-sinusoidal pulse and a small "cut" on the falling edge, and the other one is a classical frequency domain transmitter at several specially selected frequencies. The received signal is first processed to a direct Fourier transform with high Q-factor detection at all significant frequencies. After that, in the spectral region, operations of converting the spectra of two sounding signals to a single spectrum of an ideal transmitter are performed. Than we do an inverse Fourier transform and return to the time domain. The detection of spectral components is done at a frequency band of several Hz, the receiver has the ability to perfectly suppress all sorts of extra-band noise. The detection bandwidth is several dozen times less the frequency interval between the harmonics, it turns out thatto achieve the same measurement quality of ground response without using out-of-band suppression you need several dozen times higher moment of airborne transmitting system. The data obtained from the model of a homogeneous half-space, a two-layered model, and a model of a horizontally layered medium is considered. A time-domain data makes it easier to detect a conductor in a relative insulator at greater depths. The data in the frequency domain gives more detailed information about subsurface. These conclusions are illustrated by the example of processing the survey data of the Republic of Rwanda in 2017. The simultaneous inversion of data in frequency domain and time domain can significantly improve the quality of interpretation.

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Time and Frequency Domain Dynamic Analysis of Offshore Mooring

Journal of Marine Science and Engineering ◽

10.3390/jmse9070781 ◽

2021 ◽

Vol 9 (7) ◽

pp. 781

Author(s):

Shi He ◽

Aijun Wang

Keyword(s):

Dynamic Analysis ◽

Frequency Domain ◽

Time Domain ◽

Linearization Method ◽

Euler Method ◽

Single Component ◽

Hydrodynamic Drag ◽

Lumped Mass ◽

Mooring Lines ◽

The Time Domain

The numerical procedures for dynamic analysis of mooring lines in the time domain and frequency domain were developed in this work. The lumped mass method was used to model the mooring lines. In the time domain dynamic analysis, the modified Euler method was used to solve the motion equation of mooring lines. The dynamic analyses of mooring lines under horizontal, vertical, and combined harmonic excitations were carried out. The cases of single-component and multicomponent mooring lines under these excitations were studied, respectively. The case considering the seabed contact was also included. The program was validated by comparing with the results from commercial software, Orcaflex. For the frequency domain dynamic analysis, an improved frame invariant stochastic linearization method was applied to the nonlinear hydrodynamic drag term. The cases of single-component and multicomponent mooring lines were studied. The comparison of results shows that frequency domain results agree well with nonlinear time domain results.

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A Multiple Harmonic Open-Loop Controller for Hydro/Aerodynamic Force Measurements in Rotating Machinery Using Magnetic Bearings

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.1473159 ◽

2002 ◽

Vol 124 (4) ◽

pp. 827-834 ◽

Cited By ~ 3

Author(s):

D. O. Baun ◽

E. H. Maslen ◽

C. R. Knospe ◽

R. D. Flack

Keyword(s):

Frequency Domain ◽

Time Domain ◽

Open Loop ◽

Rotating Machinery ◽

Operating Conditions ◽

Rotor Vibration ◽

Aerodynamic Forces ◽

Analog Input ◽

Input And Output ◽

The Time Domain

Inherent in the construction of many experimental apparatus designed to measure the hydro/aerodynamic forces of rotating machinery are features that contribute undesirable parasitic forces to the measured or test forces. Typically, these parasitic forces are due to seals, drive couplings, and hydraulic and/or inertial unbalance. To obtain accurate and sensitive measurement of the hydro/aerodynamic forces in these situations, it is necessary to subtract the parasitic forces from the test forces. In general, both the test forces and the parasitic forces will be dependent on the system operating conditions including the specific motion of the rotor. Therefore, to properly remove the parasitic forces the vibration orbits and operating conditions must be the same in tests for determining the hydro/aerodynamic forces and tests for determining the parasitic forces. This, in turn, necessitates a means by which the test rotor’s motion can be accurately controlled to an arbitrarily defined trajectory. Here in, an interrupt-driven multiple harmonic open-loop controller was developed and implemented on a laboratory centrifugal pump rotor supported in magnetic bearings (active load cells) for this purpose. This allowed the simultaneous control of subharmonic, synchronous, and superharmonic rotor vibration frequencies with each frequency independently forced to some user defined orbital path. The open-loop controller was implemented on a standard PC using commercially available analog input and output cards. All analog input and output functions, transformation of the position signals from the time domain to the frequency domain, and transformation of the open-loop control signals from the frequency domain to the time domain were performed in an interrupt service routine. Rotor vibration was attenuated to the noise floor, vibration amplitude ≈0.2 μm, or forced to a user specified orbital trajectory. Between the whirl frequencies of 14 and 2 times running speed, the orbit semi-major and semi-minor axis magnitudes were controlled to within 0.5% of the requested axis magnitudes. The ellipse angles and amplitude phase angles of the imposed orbits were within 0.3 deg and 1.0 deg, respectively, of their requested counterparts.

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Time-Domain Nonlinear SSI Analysis of Foundation Sliding Using Frequency-Dependent Foundation Impedance Derived From SASSI

Volume 8: Seismic Engineering ◽

10.1115/pvp2008-61556 ◽

2008 ◽

Author(s):

Mansour Tabatabaie ◽

Thomas Ballard

Keyword(s):

Frequency Domain ◽

Linear Systems ◽

Time Domain ◽

Soil Structure ◽

Wave Radiation ◽

Far Field ◽

Frequency Dependent ◽

Nonlinear Springs ◽

Mat Foundation ◽

The Time Domain

Dynamic soil-structure interaction (SSI) analysis of nuclear power plants is often performed in frequency domain using programs such as SASSI [1]. This enables the analyst to properly a) address the effects of wave radiation in an unbounded soil media, b) incorporate strain-compatible soil shear modulus and damping properties and c) specify input motion in the free field using the de-convolution method and/or spatially variable ground motions. For structures that exhibit nonlinearities such as potential base sliding and/or uplift, the frequency-domain procedure is not applicable as it is limited to linear systems. For such problems, it is necessary to solve the problem in the time domain using the direct integration method in programs such as ADINA [2]. The authors recently introduced a sub-structuring technique called distributed parameter foundation impedance (DPFI) model that allows the structure to be partitioned from the total SSI system and analyzed in the time domain while the foundation soil is modeled using the frequency-domain procedure [3]. This procedure has been validated for linear systems. In this paper we have expanded the DPFI model to incorporate nonlinearities at the soil/structure interface by introducing nonlinear shear and normal springs arranged in series between the DPFI and structure model. This combination of the linear far-field impedance (DPFI) plus nonlinear near-field soil springs allows the foundation sliding and/or uplift behavior be analyzed in time domain while maintaining the frequency-dependent stiffness and radiation damping nature of the far-field foundation impedance. To check the accuracy of this procedure, a typical NPP foundation mat supported at the surface of a layered soil system and subjected to harmonic forced vibration was first analyzed in the frequency domain using SASSI to calculate the target linear response and derive a linear, far-field DPFI model. The target linear solution was then used to validate two linear time-domain ADINA models: Model 1 consisting of the mat foundation+DPFI derived from the linear SASSI model and Model 2 consisting of the total SSI system (mat foundation plus a soil block). After linear alignment, the nonlinear springs were added to both ADINA models and re-analyzed in time domain. Model 2 provided the target nonlinear solution while Model 1 provided the results using the DPFI+nonlinear springs. By increasing the amplitude of the vibration load, different levels of foundation sliding were simulated. Good agreement between the results of two models in terms of the displacement response of the mat and cyclic force-displacement behavior of the springs validates the accuracy of the procedure presented herein.

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