Robustness of System Equivalent Reduction Expansion Process on Spacecraft Structure Model Validation

Sairajan, K.K.; Aglietti, Guglielmo S.

doi:10.2514/1.j051476

Cited by 22 publications

(12 citation statements)

References 18 publications

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“…In this study, only the target modes were used in the SEREP reduction [35]. The viscoelastic system considered in this study has more damping than conventional structures such as spacecraft.…”

Section: Standard Correlation Methods and The Modal Loss Factormentioning

confidence: 99%

Correlation of finite element models of multi-physics systems

Sairajan¹,

Aglietti²,

Walker³

2014

Journal of Sound and Vibration

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Section: Standard Correlation Methods and The Modal Loss Factormentioning

confidence: 99%

Correlation of finite element models of multi-physics systems

Sairajan¹,

Aglietti²,

Walker³

2014

Journal of Sound and Vibration

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“…It is considered that, if the mathematical model meets the threshold values specified by the different agencies for these correlation checks, the model is fit for the purpose [8,9]; otherwise, the model needs to be updated. However, it is demonstrated using synthetic experimental results that the MAC and NCO check are not adequate for ensuring the quality of the FEMs to predict the forced response characteristics [10,11]. The frequency response correlation methods, such as the frequency response assurance criterion (FRAC) [12] and the frequency domain assurance criterion (FDAC) [13], have limited application in complex structures where hundreds of frequency responses need to be monitored; hence, their correlation will be a tedious task.…”

mentioning

confidence: 97%

Use of Base Force Assurance Criterion for Spacecraft Structure Model Correlation

Sairajan

Patnaik

Deshpande

et al. 2015

Journal of Spacecraft and Rockets

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Base excitation analysis is widely used to predict the dynamic behavior of the structure, such as a spacecraft, and these results are generally verified by the dynamic testing. The standard correlation criteria, such as the modal assurance criterion and normalized cross-orthogonality check, are found to be insufficient for assuring the quality of the finite element model of the structure under base excitation. Here, to overcome these difficulties, the recently introduced base force assurance criterion is used to assess the correlation between the analytical and the experimental dynamic characteristics. The procedure is demonstrated using the experiment performed on a cantilever and two real spacecraft structures. The force transmitted to the base during the base excitation test and those calculated using the Craig-Bampton method are used to determine the base force assurance criterion for all three structures in different directions of excitation. It is demonstrated that the criterion can reasonably well predict the error in the absolute acceleration and the error in the natural frequencies of the fundamental modes, and it avoids the expensive modal testing for correlation. Nomenclature a Exp = measured peak acceleration, g a FEM = analytical peak acceleration, g F = force transmitted to the base, N g = acceleration due to gravity, ms −2 i = imaginary unit, −1 p M BB = mass matrix reduced to the boundary M mB = reduced couple mass matrix M SEREP = reduced mass matrix using system equivalent reduction expansion process P = experimentally measured base force, N p iB = modal participation factor, kg q m = modal acceleration x R = acceleration at the base, g ζ = modal damping ϕ = analytical mode shape ψ = experimentally measured mode shape Ω = forcing frequency, rad∕s ω = circular natural frequency, rad∕s Subscripts B = boundary degrees of freedom j, k = direction of force m = number of modes used in the Craig-Bampton reduction r, s = number of target modes Superscript T = matrix transpose

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“…It is, however, important to also consider that these benefits may be lessened if the TAM is not robust for dealing with noise and errors in the test and/or FEM results, which can make it more difficult to achieve the required levels of correlation as defined by the COC checks [9]. Further investigations into the use of SEREP for spacecraft FEM reduction, such as those of Aglietti et al [20,21], have found that the robustness of the TAM to errors is dependent on the number of modes included in the reduction. It is proposed that the robustness may be improved by inclusion of only the target modes in the reduction.…”

Section: System Equivalent Reduction Expansion Process (Serep)mentioning

confidence: 99%

“…The use of real spacecraft in this study has enabled final comparisons to be made between the FEM and the test mode shapes. While previous work has investigated the robustness of reduction methods in theory using analytical models [21], the differences between test and FEM mode shapes can be caused by a wide variety of factors and as such can be difficult to replicate using purely mathematical analyses. In real testing it is possible that: not all vibration modes will be properly excited; the dynamic influence of coupling with the shaker structure can influence the responses; there can be additional uncertainty in the test mode shapes introduced through curve-fitting estimations.…”

mentioning

confidence: 99%

“…There have already been several studies [6][7][8][9][10][11][12] comparing the various methods including; Static (or Guyan) reduction [13], Improved Reduction System (IRS) [14], Dynamic reduction [15], Modal reduction [5], System Equivalent Reduction Expansion Process (SEREP) [16], Hybrid [17] and Craig-Bampton [18]. Here the focus is on: the Guyan reduction method, which has some historical basis and availability within FE tools such as MSC-NASTRAN [19]; and SEREP which has been identified as potentially more suitable for generating spacecraft TAMs [20,21]. Where most previous work has focused on small, generic example cases, the main contribution of this work is to show and identify how these methodologies perform with real spacecraft and typical FEMs generated in industry.…”

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confidence: 99%

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