Harmonic forms in displacement response spectra and a novel definition of duration in pulse-type strong motion

Abstract

Neat sine (cosine) shapes have been observed in peaks of high-resolution deformation response spectra corresponding to real earthquake records. Theoretically, these smooth and special spectral forms should appear only when the excitation is a mathematical shock or pulse. Some seismic records, especially near-fault, are considered pulses and more generally, earthquake excitation can be considered as a large action applied over a short time, which is shock excitation; therefore, there is an explanation to the observation or discovery of those harmonic forms. Now, an explanation on why these sinusoidal peaks had not been observed or studied before can lie in that most research has been done on acceleration response spectra, rather than on displacement ones; moreover, previous publications on the latter have been with a very-low resolution. A main objective here is, first, to demonstrate that the shapes in actual response spectra are indeed harmonic, this by means of fitting. Then and additionally, an application to Earthquake Engineering, and Seismology, of these revealed sine forms is presented, which is to the subfield of strong motion duration; in particular, a new procedure is proposed to estimate earthquake duration in the case of pulse-type excitation, which is associated to the near field.

Keywords

Earthquake motion duration harmonic shapes cosine forms pulse deformation response spectra

Get full access to this article

View all access options for this article.

References

Alavi

Krawinkler

(2004) Behavior of moment-resisting frame structures subjected to near-fault ground motions. Earthquake Engineering & Structural Dynamics 33: 687–706.

Banerjee

Gupta

(2022) A statistical study of inelastic displacement ratio spectrum for existing structures. Earthquake Engineering and Resilience 1: 454–479.

Bommer

Martínez

(1999) The effective duration of earthquake strong motion. Journal of Earthquake Engineering 3: 127–172.

Chopra

(2020) Dynamics of Structures. Upper Saddle River: Pearson.

Decanini

Liberatore

Mollaioli

(2003) Characterization of displacement demand for elastic and inelastic SDOF systems. Soil Dynamics and Earthquake Engineering 23: 455–496.

Garakaninezhad

Amiri

(2022) Inelastic acceleration ratio of structures under pulse-like earthquake ground motions. Structures 44: 1799–1810.

Harris

Piersol

(2002) Shock & Vibration Handbook. McGraw-Hill.

Havelaud

Morikawa

(2013) Reliable displacement response spectra at long periods in the near field of large earthquakes. Bulletin of the Seismological Society of America 103(2534): 2539.

Kawashima

Aizawa

(1989) Bracketed and normalized durations of earthquake ground accelerations. Earthquake Engineering & Structural Dynamics 18: 1041–1151.

10.

Konstandakopoulou

Hatzigeorgiou

(2020) Constant-ductility inelastic displacement, velocity and acceleration ratios for systems subjected to simple pulses. Soil Dynamics and Earthquake Engineering 131: 106027.

11.

Konstandakopoulou

Kemeli

Asteris

, et al. (2025) Inelastic displacement, velocity, and acceleration ratios for constant-ductility response spectra corresponding to European earthquakes. Soil Dynamics and Earthquake Engineering 190: 109110.

12.

Lumantarna

Wilson

Lam

NTK

(2012) Bi-linear displacement response spectrum model for engineering applications in low and moderate seismicity regions. Soil Dynamics and Earthquake Engineering 43: 85–96.

13.

McGuire

Barnhard

(1979) The usefulness of ground motion duration in prediction of severity of seismic shaking. In: Proc. of the Second US National Conference on Earthquake Engineering, 713–722.

14.

Mohraz

(1992) Recent studies of earthquake ground motion and amplification. In: Tenth World Conference on Earthquake Engineering, 6695–6704.

15.

Morales

(2010) Further seismic displacement PSDF results. Structural Engineering & Mechanics 34: 663–666.

16.

Morales

(2021a) Narrowbandness of seismic ground displacement on a broader area of the lithosphere and importance on base motion in isolated structures. Journal of Vibroengineering 23: 400–406.

17.

Morales

(2021b) On some errors in seismic data in highly-cited literature on base isolation. International Review of Civil Engineering 12: 425–427.

18.

Morales

(2022) Inerter-added transmissibility to control base displacement in isolated structures. Engineering Structures 251: 113564.

19.

Morales

(2024) Predominant frequency in near-field strong ground motion by analysis of displacement response spectra. Buildings 14: 78.

20.

Morales

(2025) Enhancement of three isolation optimizations by more reliable estimation of seismic action predominant period. Journal of Vibration and Control 31: 2490–2496. Online First.

21.

Salmon

Short

Kennedy

(1992) Strong motion duration and earthquake magnitude duration. Tech. Rep. UCRL-CR-117769, L. Livermore National Lab.

22.

Schiappapietra

Lanzano

Sgobba

(2022) Empirical predictive models for fling step and displacement response spectra based on the NESS database. Soil Dynamics and Earthquake Engineering 158: 107294.

23.

Soong

Grigoriu

(1993) Random Vibration of Mechanical and Structural Systems. Prentice-Hall.

24.

Trifunac

Brady

(1975) A study on the duration of strong earthquake ground motion. Bulletin of the Seismological Society of America 65: 581–626.

25.

Wang

(2023) Seismic behavior of structures under long-duration ground motions. Structures 54: 1224–1236.

26.

Yaghmaei

Daneshgari

(2023) Effect of ground motion duration on inelastic displacement ratio of SDOF systems. Earthquake Engineering and Engineering Vibration 22: 423–439.