Sea states database: H,T, , probability of occurrence

1. Order of magnitude: 102 to 103 Sea states database: H,T,, probability of occurrence Discretization of the database, selection of the representative sea states, computation of responses for that subset Summation of damages with the probabilities of occurrence

2. Systems database: H,T,, probability of occurrence Sea states database: H1,T1,1, H2,T2,2, H3,T3,3, joint probability of occurrence Discretization of the sea states database results from that of the systems, selection of the representative sea states, computation of responses for that subset Order of magnitude: 106 to 109 Summation of damages with the joint probabilities of occurrence

3. Order of magnitude: 102 to 103 Order of magnitude: 106 to 109 Joint probabilities of occurrence Systems database: H,T,, probability of occurrence Discretization of the systems, selection of the representative systems, computation of responses to single systems ICA Combination of damages and summation with the joint probabilities of occurrence

4. Measured sea states SPOP Wave systems database RAO RAO Response to each sea state Response to each system Simulation Simulation Damage in each sea state Damage in each system ICA Summation Scaling to the foreseen life of the structure Application of joint probabilities COMPARISON

5. Measured sea states RAO Response to each sea state SPOP Response systems Unimodal formulas Simulation Damage in each sea state Damage in each « system » ICA Summation Scaling to the foreseen life of the structure Application of joint probabilities COMPARISON

6. Measured sea states SPOP + RAO + ???? RAO Response to each sea state Response systems climate Simulation Unimodal formulas Damage in each sea state Damage in each « system » ICA Summation Scaling to the foreseen life of the structure Application of joint probabilities COMPARISON