A Wavelet-Based Rail Surface Defect Prediction and Detection Algorithm

Hopkins, Brad Michael

16 April 2012

Early detection of rail defects is necessary for preventing derailments and costly damage to the train and railway infrastructure. A rail surface flaw can quickly propagate from a small fracture to a broken rail after only a few train cars have passed over it. Rail defect detection is typically performed by using an instrumented car or a separate railway monitoring vehicle. Rail surface irregularities can be measured using accelerometers mounted to the bogie side frames or wheel axles. Typical signal processing algorithms for detecting defects within a vertical acceleration signal use a simple thresholding routine that considers only the amplitude of the signal. As a result, rail surface defects that produce low amplitude acceleration signatures may not be detected, and special track components that produce high amplitude acceleration signatures may be flagged as defects. The focus of this research is to develop an intelligent signal processing algorithm capable of detecting and classifying various rail surface irregularities, including defects and special track components. Three algorithms are proposed and validated using data collected from an instrumented freight car. For the first two algorithms, one uses a windowed Fourier Transform while the other uses the Wavelet Transform for feature extraction. Both of these algorithms use an artificial neural network for feature classification. The third algorithm uses the Wavelet Transform to perform a regularity analysis on the signal. The algorithms are validated with the collected data and shown to out-perform the threshold-based algorithm for the same data set. Proper training of the defect detection algorithm requires a large data set consisting of operating conditions and physical parameters. To generate this training data, a dynamic wheel-rail interaction model was developed that relates defect geometry to the side frame vertical acceleration signature. The model was generated by using combined systems dynamic modeling, and the system was solved with a developed combined lumped and distributed parameter system numerical approximation. The broken rail model was validated with real data collected from an instrumented freight car. The model was then used to train and validate the defect detection methodologies for various train and rail physical parameters and operating conditions. / Ph. D.

wheel/rail dynamic modeling

regularity analysis

rail defect detection

Wavelet Transform

artificial neural network

Detecting Defective Rail Joints on the Swiss Railways with Inception ResNet V2 : Simplifying Predictive Maintenance of Railway Infrastructure / Detektering av Defekta Järnvägsskarvar med Inception ResNet V2 : Förenkla Proaktivt Underhåll av Järnvägsinfrastruktur

Lu, Anton

January 2022

Manual investigation of railway infrastructure is a labor-intensive and time-consuming task, and automating it has become a high priority for railway operators to reduce unexpected infrastructure expenditure. In this thesis, we propose a new image classification approach for classifying defect and non-defective rail joints in image data, based on previous fault detection algorithms using object detection. The rail joints model is to our knowledge a world first, with the vast majority of research into applying computer vision for rail defect detection focusing mainly on the rail tracks and sleepers. Our new image classification models are based on the widely popular Inception ResNet V2, which we fine-tune and compare against a counterpart trained using self-supervision. Additional comparisons are performed against the Faster R-CNN object detector that has had successes with rail tracks and sleepers at the Swiss Federal Railways, as well as against the novel transformer-based DETR architecture. The research has used an in-house object detection annotated dataset from the Swiss railways, recorded in the context of predictive rail maintanance, with rail joints labeled as either defective, or non-defective. Our proposed image classification approach, using either a pre-trained and then fine-tuned, or self-supervised CNN, uses the bounding boxes in a dataset originally intended for object detection, to perform an expanded crop of the images around the rail joint before feeding it to the neural network. Our new image classification approach significantly outperforms object detection neural networks for the task of classifying defective and non-defective rail joints, albeit with the requirement that the rail joint has to be identified prior to classification. Furthermore, our results suggest that the trained models classify defective joints in the test set more consistently than human rail inspectors. The results show that our proposed method can achieve practical performance on unseen data, and can practically be applied to real-life defect detection with high precision and recall, notably on the railways operated by Swiss Federal Railways, SBB CFF FFS. / Manuell inspektion av järnvägsinfrastruktur är en tids- och arbetskrävande uppgift, och automatisering av inspektionerna har på senare tid blivit mer prioriterat av järnvägsoperatörer i syfte att minska oväntade utgifter som uppkommer till följd av undermålig infrastruktur. I det här examensarbetet presenterar vi en ny bildklassificeringsmetod för att klassificera defekta och icke-defekta järnvägsskarvar i bilder tagna från diagnostiska tåg. Modelleringen av järnvägsskarvar som vi har utfört är till vår kännedom något som aldrig gjorts förut för järnvägsinfrastruktur, då majoriteten av forskning inom datorseende för inspektion av järnvägsinfrastruktur historiskt mest har fokuserat på räls och sliprar. Den nya bildklassificeringsmodellen som vi har utvecklat använder den populära arkitekturen Inception ResNet V2, som vi finjusterar och jämför med ett dito som har tränats med självövervakad inlärning. Vidare jämförelser görs mot objektigenkänningsmetoden Faster R-CNN som fungerat väl för sliprar på den schweiziska järnvägen, samt mot den nya transformer-baserade arkitekturen DETR. Forskningen har använt ett dataset annoterat för objektigenkänning från den schweiziska järnvägen, med järnvägsskarvar märkta som defekta, eller icke-defekta. Vår föreslagna bildklassificeringsmetod, med antingen en förtränad och sedan finjusterad CNN, eller en CNN tränad med sjävövervakad inlärning, använder de annoterade boxarna från datasetet för att beskära bilderna runt skarvarna, och sedan klassificera dem. Vår nya metod baserad på bildklassificering presterar väsentligt bättre än neurala nätverk för objektigenkänning, dock med kravet att järnvägsskarven måste ha identifierats i bilden före klassificering. Vidare visar våra resultat att de tränade bildklassificeringsmodellerna klassificerar defekta skarvar i test-setet mer konsekvent än mänskliga järnvägsinspektörer. Resultaten visar att vår nya metod kan användas praktiskt för att upptäcka defekter i verkligheten, med hög precision och recall i data som inte setts under träningen. Specifikt visar vi att de nya modellerna är praktiskt användbara för järnvägen som drivs av Schweiziska Federala Järnvägarna, SBB CFF FFS.

Rail Defect Detection

Rail Image Classification

Rail Joints

Object Detection

Image Classification

Deep Learning

Järnvägsfeldetektering

Järnvägsbildigenkänning

Järnvägsskarvar

Objectigenkänning

Bildklassificering

Djupinlärning

Computer Sciences

Datavetenskap (datalogi)

Computer Engineering

Datorteknik

Computer and Information Sciences

Data- och informationsvetenskap