Foreword to Series xiii Introduction xvii List of Symbols xxi Chapter 1 Extreme Response Spectrum of a Sinusoidal Vibration 1 1.1 The effects of vibration 1 1.2 Extreme response spectrum of a sinusoidal vibration 2 1.3 Extreme response spectrum of a swept sine vibration 13 Chapter 2 Extreme Response Spectrum of a Random Vibration 21 2.1 Unspecified vibratory signal 22 2.2 Gaussian stationary random signal 23 2.3 Limit of the ERS at the high frequencies 49 2.4 Response spectrum with up-crossing risk 50 2.
5 Comparison of the various formulae 62 2.6 Effects of peak truncation on the acceleration time history 66 2.7 Sinusoidalvibration superimposed on a broadband random vibration 68 2.8 Swept sine superimposed on a broadband random vibration 83 2.9 Swept narrowbands on a wideband random vibration 85 Chapter 3 Fatigue Damage Spectrum of a Sinusoidal Vibration 89 3.1 Fatigue damage spectrum definition 89 3.2 Fatigue damage spectrum of a single sinusoid 92 3.3 Fatigue damage spectum of a periodic signal 96 3.
4 General expression for the damage 98 3.5 Fatigue damage with other assumptions on the S-N curve 98 3.6 Fatigue damage generated by a swept sine vibration on a single-degree-of-freedom linear system 102 3.7 Reduction of test time 121 3.8 Notes on the design assumptions of the ERS and FDS 124 Chapter 4 Fatigue Damage Spectrum of a Random Vibration 125 4.1 Fatigue damage spectrum from the signal as function of time 125 4.2 Fatigue damage spectrum derived from a power spectral density 127 4.3 Simplified hypothesis of Rayleigh''s law 132 4.
4 Calculation of the fatigue damage spectrum with Dirlik''s probability density 138 4.5 Up-crossing risk fatigue damage spectrum 140 4.6 Reduction of test time 144 4.7 Truncation of the peaks of the "input" acceleration signal 149 4.8 Sinusoidal vibration superimposed on a broadband random vibration 152 4.9 Swept sine superimposed on a broadband random vibration 161 4.10 Swept narrowbands on a broadband random vibration 162 Chapter 5 Fatigue Damage Spectrum of a Shock 165 5.1 General relationship of fatigue damage 165 5.
2 Use of shock response spectrum in the impulse zone 167 5.3 Damage created by simple shocks in static zone of the response spectrum 169 Chapter 6 Influence of Calculation Conditions of ERSs and FDSs 171 6.1 Variation of the ERS with amplitude and vibraiton duration 171 6.2 Variation of the FDS with amplitude and duration of vibration 175 6.3 Should ERSs and FDSs be drawn with a linear or logarithmic frequency step? 175 6.4 With how many points must ERSs and FDSs be calculated? 177 6.5 Difference between ERSs and FDSs calculated from a vibratory signal according to time and from its PSD 180 6.6 Influence of the number of PSD calculation points on ERS and FDS 187 6.
7 Influence of the PSD statistical error on ERS and FDS 192 6.8 Influence of the sampling frequency during ERS and FDS calculation from a signal on time 193 6.9 Influence of the peak counting method 202 6.10 Influence of a non-zero mean stress on FDS 206 Chapter 7 Tests and Standards 217 7.1 Definitions 217 7.2 Types of tests 218 7.3 What can be expected from a test specification? 223 7.4 Specification types 224 7.
5 Standards specifying test tailoring 235 Chapter 8 Uncertainty Factor 243 8.1 Need - definitions 243 8.2 Sources of uncertainty 247 8.3 Statistical aspect of the real environment and of material strength 249 8.4 Statistical uncertainty factor 272 Chapter 9 Aging Factor 293 9.1 Purpose of the aging factor 293 9.2 Aging functions used in reliability 293 9.3 Method for calculating the aging factor 296 9.
4 Influence of the aging law''s standard deviation 299 9.5 Influence of the aging law mean 300 Chapter 10 Test Factor 301 10.1 Philosophy 301 10.2 Normal distributions 303 10.3 Log-normal distributions 315 10.4 Weibull distributions 318 10.5 Choice of confidence level 320 Chapter 11 Specification Development 321 11.1 Test tailoring 321 11.
2 Step 1: analysis of the life-cycle profile. Review of the situations 322 11.3 Step 2: determination of the real environmental data associated with each situation 324 11.4 Step 3: determination of the environment to be simulated 325 11.5 Step 4: establishment of the test program 356 11.6 Applying this method ot the example of the "round robin" comparative study 363 11.7 Taking environment into account in project mamagement 366 Chapter 12 Influence of Calculation Conditions of Specification 375 12.1 Choice of the number of points in the specification (PSD) 375 12.
2 Influence of the Q factor on specification (outside of time reduction) 378 12.3 Influence of the Q factor on specification when duration id reduced 382 12.4 Validity of a specification established for a Q factor equal to 10 when the real structure has another value 387 12.5 Advantage in the consideration of a variable Q factor for the calculation of ERSs and FDSs 388 12.6 Influence of the value of parameter b on the specification 390 12.7 Choice of the value of parameter b in the case of material made up of several components 394 12.8 Influence of temperature on parameter b and constant C 395 12.9 Importance of a factor of 10 between the specification FDS and the reference FDS (real environment) in a small frequency band 396 12.
10 Validity of a specification established by reference to a one-degree-of-freedom system when real structures are multi-degree-of-freedom systems 398 Chapter 13 OPther Uses of Extreme Response, Up-Crossing Risk and Fitigue Damage Spectra 399 13.1 Comparisons of the severity of different vibrations 399 13.2 Swept sine excitation - random vibration transformation 403 13.3 Definition of a random vibration with the same severity as a series of shocks 408 13.4 Writing a specification only from an ERS (or an URS) 413 13.5 Establishment of a swept sine vibration specification 418 Appendix 421 Formulae 457 Bibliography 481 Index 497.