روشی نوین مبتنی بر شبکه عصبی بدون بازرس عمیق جهت شناسایی آسیب های کلی و موضعی سازه های عمرانی

نوع مقاله : پژوهشی اصیل (کامل)

نویسندگان
دکتر پدرام قادری
امین عبدالمالکی
دانشگاه علم و صنعت ایران
چکیده
سازه های مهندسی عمران به دلیل قرار گرفتن در معرض شرایط جوی و بارگذاری های مختلف در طول عمر خود ممکن است دچار آسیب های گوناگون شوند به همین دلیل پایش سلامت سازه همواره جز مسائل مورد توجه مهندسین عمران بوده است. در این مقاله یک روش نوین جهت شناسایی آسیب های موضعی و کلی سازه های عمرانی با استفاده از شبکه عصبی بدون بازرس عمیق ارائه می شود. در این روش ابتدا سازه بدون آسیب تحت اثر بارهای محیطی قرار می گیرد. پاسخ های سازه تحت اثر بارهای محیطی به قطعات کوچکتری تقسیم بندی می شوند و با استفاده از تبدیل فوریه گسسته به حوزه فرکانس منتقل می شوند. یک شبکه عصبی بدون بازرس عمیق که از چند لایه ماشین بولتزمن مجزا تشکیل شده است با استفاده از پاسخ های سازه بدون آسیب آموزش داده می شود. شبکه عصبی بدون بازرس عمیق پس از آموزش قادر به شناسایی ویژگی های معنادار موجود در پاسخ های سازه است. در مرحله بعد سازه در وضعیت نامشخص از نظر سلامت مورد بررسی قرار می گیرد. پاسخ های سازه در وضعیت مجهول در برابر بارهای محیطی جمع آوری شده و با استفاده از شبکه عصبی که قبلا آموزش دیده، ویژگی های موجود در داده های جدید استخراج می شوند. این عمل می تواند به صورت جداگانه برای هر یک از بخش های مورد نظر در سازه انجام شود. با استفاده از ویژگی های استخراج شده از سازه ی سالم و سازه در وضعیت مجهول از نظر سلامت سازه، شاخص سلامت برای هر یک از بخش های مورد بررسی سازه محاسبه می شود. با توجه به ویژگی های استخراج شده در حالت سالم و مجهول سازه، وجود و شدت آسیب های احتمالی شناسایی می شوند. یکی از مزیت های روش ارائه شده عدم نیاز به مدلسازی آسیب ها برای آموزش شبکه عصبی است و فقط پاسخ های سازه سالم برای آموزش شبکه عصبی استفاده می شود. جهت بررسی روش پیشنهادی یک ساختمان بلند مرتبه مدلسازی شده و شاخص های سلامت برای هر یک از قسمت های سازه محاسبه شده است. شاخص های سلامت محاسبه شده برای ساختمان مورد بررسی دارای دقت قابل قبولی هستند و دقت روش پیشنهادی تقریبا ۹۵ درصد می باشد همچنین آسیب های موجود و شدت آنها با دقت مناسبی شناسایی شده اند.

کلیدواژه‌ها

موضوعات

عنوان مقاله English

A novel unsupervised deep neural network based method for damage detection in civil structures

نویسندگان English

Pedram Ghaderi
amin abdolmaleki
Iran University of Science and Technology
چکیده English

Civil structures may experience unexpected loads and consequently damages during their life cycle. Damage identification has been a challenging inverse problem in structural health monitoring. The main difficulty is characterizing the unknown relation between the measurements and damage patterns. Such damage indicators would ideally be able to identify the existence, location, and severity of damages. In order to solve such problems, biologically inspired soft-computing techniques have gained traction. The most widely used soft-computing method, called neural networks is designed such that it can learn from data without a need of feature design process. Damage pattern can be detected using neural network. A deep unsupervised neural network can recognize patterns and extract features from data. In this paper a methodology is described for global and local health condition assessment of structural systems using vibration response of the structure. The model incorporates Fast Fourier Transform and unsupervised deep Boltzmann machine to extract features from the frequency domain of the recorded signals. Restricted boltzmann machine is a shallow neural network with two layer. First layer of restricted boltzmann machine called input layer and second layer of restricted boltzmann machine called hidden layer.Deep Boltzmann machine created by setting some restricted Boltzmann machine sequentional. Hidden layer of each restricted boltzmann machine is input layer of next restricted boltzmann machine. Each layer of restricted Boltzmann machine extract features form input data Recorded data divided to smaller vectors. Fast fourier transformation used to transform divided vectors into frequency domain. A benefit of the proposed model is that it does not require costly experimental results to be obtained from a scaled version of the structure to simulate different damage states of the structure and only vibration response of the healthy structure is needed to training deep neural network. The input consists of a set of records obtained from the healthy state of the structure and another set of records with unknown health states. The model extracts information from both healthy and unknown sets to determine the health states of the unknown set. The healthy records are low intensity vibrations of the structure at least in one planar direction in the healthy state in the form of time series signals and The unknown records are low intensity vibrations of the structure on unknown state of health. Ambient vibrations can be due to wind, traffic, or human/pedestrian activities. An appropiate health index is defined and calculated for each part of the structure. The value of this index is between 0 and 1. The closer the value is to 1 the healthier the structure. To evaluate the efficiency of the proposed method a building structures with 35 story has been simulated in OPENSEES. Data collection should be selected appropriately to prevent errors. Obtained result demonstrate that proposed method has about 95 percent efficiency to predict damages and their severity. Different damage state put on due to three earthquakes with different severity. Structural health index calculated after each earthquake. Calculated structural health index demonstrate efficieency of proposed method for detecting damages and severity of damages.

کلیدواژه‌ها English

Structural health monitoring
Deep Unsupervised Neural Network
deep learning
Feature Extraction
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مهندسی عمران مدرس
دوره 22، شماره 1
فروردین و اردیبهشت 1401
صفحه 143-159