Uncertainty Quantification of Load Effects under Stochastic Traffic Flows

2018 ◽  
Vol 19 (01) ◽  
pp. 1940009 ◽  
Author(s):  
He-Qing Mu ◽  
Qin Hu ◽  
Hou-Zuo Guo ◽  
Tian-Yu Zhang ◽  
Cheng Su
Keyword(s):  
Probability Distribution ◽  
Uncertainty Quantification ◽  
Optimal Parameter ◽  
Probability Model ◽  
Probabilistic Approach ◽  
Bridge Engineering ◽  
Traffic Load ◽  
Distribution Model ◽  
Load Effect ◽  
Load Effects

Load effect characterization under traffic flow has received tremendous attention in bridge engineering, and uncertainty quantification (UQ) of load effect is critical in the inference process. Bayesian probabilistic approach is developed to overcome the unreliable issue caused by negligence of uncertainty of parametric and modeling aspects. Stochastic traffic load simulation is conducted by embedding the random inflow component into the Nagel–Schreckenberg (NS) model, and load effects are calculated by stochastic traffic load samples and influence lines. Two levels of UQ are performed for traffic load effect characterization: at parametric level of UQ, not only the optimal parameter values but also the associated uncertainties are identified; at model level of UQ, rather than using a single prescribed probability model for load effects, a set of probability distribution model candidates is proposed, and model probability of each candidate is evaluated for selecting the most suitable/plausible probability distribution model. Analytic work was done to give closed-form solutions for the expression involved in both parametric and model UQ. In the simulated examples, the efficiency and robustness of the proposed approach are firstly validated, and UQ are performed to different load effect data achieved by varying the structural span length under the changing total traffic volume. It turns out that the uncertainties of load effects are traffic-specific and response-specific, so it is important to conduct UQ of load effects under different traffic scenarios by using the developed approach.

scholarly journals Bayesian Updates for an Extreme Value Distribution Model of Bridge Traffic Load Effect Based on SHM Data

2021 ◽  
Vol 13 (15) ◽  
pp. 8631
Author(s):  
Xin Gao ◽  
Gengxin Duan ◽  
Chunguang Lan
Keyword(s):  
Probability Model ◽  
Extreme Value Distribution ◽  
Value Theory ◽  
Extreme Value ◽  
Value Distribution ◽  
Traffic Load ◽  
Monitoring Data ◽  
Distribution Model ◽  
Load Effect ◽  
Tail Distribution

As the distribution function of traffic load effect on bridge structures has always been unknown or very complicated, a probability model of extreme traffic load effect during service periods has not yet been perfectly predicted by the traditional extreme value theory. Here, we focus on this problem and introduce a novel method based on the bridge structural health monitoring data. The method was based on the fact that the tails of the probability distribution governed the behavior of extreme values. The generalized Pareto distribution was applied to model the tail distribution of traffic load effect using the peak-over-threshold method, while the filtered Poisson process was used to model the traffic load effect stochastic process. The parameters of the extreme value distribution of traffic load effect during a service period could be determined by theoretical derivation if the parameters of tail distribution were estimated. Moreover, Bayes’ theorem was applied to update the distribution model to reduce the statistical uncertainty. Finally, the rationality of the proposed method was applied to analyze the monitoring data of concrete-filled steel tube arch bridge suspenders. The results proved that the approach was convenient and found that the extreme value distribution type III might be more suitable as the traffic load effect probability model.

Monte Carlo Prediction of the Extreme Values of the Combined Load Effect and Semi-Probabilistic Design of Ocean-Going Ships

2013 ◽  
Author(s):  
Wenbo Huang ◽  
Ying Xiao
Keyword(s):  
Monte Carlo ◽  
Extreme Values ◽  
Empirical Distribution ◽  
Extreme Value Distribution ◽  
Distribution Model ◽  
Wave Load ◽  
Load Effect ◽  
Combined Load ◽  
Load Combination ◽  
Load Effects

Based on Poisson models, the Monte Carlo simulation of the combined still-water and wave load effects is carried out to estimate extreme values of the combined load effects of oceangoing ships. The extreme values predicted are compared with those based on the theoretical methods. The numerical analyses show that the results based on the two methods agree with very well. Moreover, the empirical distribution of the combine extreme values simulated and numerical theoretical distribution based on a load combination analysis can both be well fitted to an analytical extreme value distribution model of Type II. Besides, a strength model of a ship hull beam is developed based on the fatigue analyses. Finally, with the models developed for load effect and strength, the simplified reliability analyses are carried out for an ocean going ship.

Probability models of asperity constructed in terms of co-seismic displacements along surface rupture zones

2020 ◽  
Author(s):  
Zhengfang Li ◽  
Bengang Zhou
Keyword(s):  
Probability Distribution ◽  
Probability Model ◽  
Fault Slip ◽  
Rupture Zone ◽  
Western China ◽  
Distribution Model ◽  
Surface Rupture ◽  
Limit Values ◽  
Rupture Plane ◽  
Seismic Displacements

<p>          Usually, an earthquake of magnitude Mw6.0 or greater can produce a rupture zone on the surface of the Earth’s ground. And displacements can be observed along such a rupture zone, called co-seismic displacements. Although these surface displacements are somewhat different from slip on the rupture plane of the causative fault, which is often vertical or sub-vertical, there exists a certain proportional relationship between them. It means that major slip at depth can produce bigger co-seismic displacements on the ground. As assumed above, major fault slip is generated by asperities. Thus it is possible to establish an asperity model in terms of data of ground co-sesimic displacements.</p><p>          Asperity models can be used to describe heterogeneities of the rupture plane of the fault as an earthquake source. This work follows such an idea that an asperity is defined as a region in which the slip is larger by a prescribed amount than the average slip over the entire fault. Because co-seismic displacements along a surface rupture zone depend on slip on the subsurface fault, we attempt to construct probability distribution model for a seismic source in terms of such displacements observed on the ground. Using data of 10 historical earthquakes of Ms7.0 or greater in western China, we make a statistical analysis to distributions of co-seismic displacements on surface rupture zones, yielding the probability distribution model based on a series of ratios of maximum displacements to the average ones in intervals on the rupture. Then, upon the lower and upper limit values of these ratios, we infer the asperities along the rupture zones and analyze further the relationships between asperity parameters, rupture geometries, and earthquake magnitudes based on real data of more earthquakes. Finally, we use the data of the 2001 Kunlunshan Mw7.8 event to test this approach for construction of probability model of asperity and discuss its possible application to assessment of seismic hazard. </p><p><strong>Keywords: </strong> Probability model of asperity, fault slip, surface rupture, co-seismic displacement</p>

scholarly journals Influence of pre-existing vibrations on the dynamic response of medium span bridges

2009 ◽  
Vol 36 (1) ◽  
pp. 73-84 ◽  
Author(s):  
Paraic H. Rattigan ◽  
Arturo González ◽  
Eugene J. OBrien
Keyword(s):  
Initial Conditions ◽  
Traffic Load ◽  
Dynamic Effects ◽  
Load Effect ◽  
Maximum Lifetime ◽  
Loading Case ◽  
Load Effects ◽  
Inaccurate Estimation ◽  
Dynamic Amplification ◽  
Bridge Failure

Critical static bridge loading scenarios are often expressed in terms of the number of vehicles that are present on the bridge at the time of occurrence of maximum lifetime load effect. For example, 1-truck, 2-truck, 3-truck, or 4-truck events usually govern the critical static loading cases in short and medium span bridges. However, the dynamic increment of load effect associated with these maximum static events may be assessed inaccurately if it is calculated in isolation of the rest of the traffic flow. In other words, a heavy vehicle preceding a critical loading case causes the bridge initial conditions of displacement and acceleration to be nonzero when the critical combination of traffic arrives on the bridge. Failure to consider these pre-existing vibrations will result in inaccurate estimation of dynamic amplification. This paper explores these dynamic effects and, using statistical analyses, outlines the relative importance of pre-existing vibrations in the assessment of total traffic load effects.

A Probability Distribution Model to Simulate Wind Power Output Fluctuation

2014 ◽  
Vol 1070-1072 ◽  
pp. 171-176
Author(s):  
Chi Li ◽  
Chun Liu ◽  
Yue Hui Huang
Keyword(s):  
Probability Distribution ◽  
Wind Power ◽  
Power Output ◽  
Wind Farm ◽  
Probability Model ◽  
Distribution Model ◽  
Model Parameters ◽  
Stable Operation ◽  
Power Fluctuation ◽  
Short Time

It is of great significance for the safe and stable operation of power system to master the fluctuation characteristics of wind power output. On the basis of analyzing a large number of field measured data, a weighted mixed Gaussian probability model is proposed to simulate short-time wind power fluctuation characteristics of wind farm cluster, that evaluation indices to reflect the short-time maximum fluctuation of wind power output and maximum likelihood estimation algorithm based on Expectation Maximization (EM) to estimate model parameters are put forward. This model is compared with various other kinds of probability distribution model and the simulation results show that the weighted mixed Gaussian probability model possesses the highest precision, so as the effectiveness of the weighted mixed Gaussian probability model is verified.

A new probability distribution model of turbulent irradiance based on Born perturbation theory

2010 ◽  
Vol 53 (10) ◽  
pp. 1811-1818
Author(s):  
HongXing Wang ◽  
Min Liu ◽  
Hao Hu ◽  
Qian Wang ◽  
XiGuo Liu
Keyword(s):  
Perturbation Theory ◽  
Probability Distribution ◽  
Distribution Model

scholarly journals Characteristic dynamic traffic load effects in bridges

2009 ◽  
Vol 31 (7) ◽  
pp. 1607-1612 ◽  
Author(s):  
Eugene J. OBrien ◽  
Paraic Rattigan ◽  
Arturo González ◽  
Jason Dowling ◽  
Aleš Žnidarič
Keyword(s):  
Traffic Load ◽  
Dynamic Traffic ◽  
Load Effects ◽  
Characteristic Dynamic

A Reliability-Based Early Warning System for Real-Time Monitoring on RC Buildings

2012 ◽  
Vol 446-449 ◽  
pp. 3422-3427
Author(s):  
Wang Sheng Liu ◽  
Ming Zhao
Keyword(s):  
Probability Distribution ◽  
Real Time ◽  
Early Warning ◽  
Early Warning System ◽  
Limit State ◽  
Warning System ◽  
State Function ◽  
Real Time Monitoring ◽  
Rc Buildings ◽  
Load Effect

Today there is an urgent need for effective monitoring whether for old buildings or new ones. While conventional early warning system for real-time monitoring is based on safety factor, this paper proposes a new reliability-based framework to monitor the safety of RC buildings probabilistically. The framework includes modeling resistance, predicting probability distribution of load effect, calculating reliability and setting reliability index threshold. The in-situ test data enables to update the resistance model through a Bayesian process. Meanwhile, the observed monitoring data predicts the probability distribution of load effect. FORM is used to calculate the reliability because the limit state function for real-time monitoring is linear and simple. This study shows that the reliability-based early warning system is of more scientific sense in quantifying the safety and may be applied to many engineering fields.

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