4 research outputs found
A Novel Region based Image Fusion Method using Highboost Filtering and Fuzzy Logic
This paper proposes a novel region based image
fusion scheme based on high boost filtering concept using discrete
wavelet transform. In the recent literature, region based image
fusion methods show better performance than pixel based image
fusion method. Proposed method is a novel idea which uses
high boost filtering concept to get an accurate segmentation
using discrete wavelet transform. This concept is used to extract
regions form input registered source images which is than
compared with different fusion rules. The fusion rule based on
spatial frequency and standard deviation is also proposed to fuse
multimodality images. The different fusion rules are applied on
various categories of input source images and resultant fused
image is generated. Proposed method is applied on registered
images of multifocus and multimodality images and results are
compared using standard reference based and non-reference
based image fusion parameters. It has been observed from
simulation results that our proposed algorithm is consistent and
preserves more information compared to earlier reported pixel
based and region based methods
Vision-based Monitoring System for High Quality TIG Welding
The current study evaluates an automatic system for real-time arc welding quality assessment and defect detection. The system research focuses on the identification of defects that may arise during the welding process by analysing the occurrence of any changes in the visible spectrum of the weld pool and the surrounding area. Currently, the state-of-the-art is very simplistic, involving an operator observing the process continuously. The operator assessment is subjective, and the criteria of acceptance based solely on operator observations can change over time due to the fatigue leading to incorrect classification.
Variations in the weld pool are the initial result of the chosen welding parameters and torch position and at the same time the very first indication of the resulting weld quality.
The system investigated in this research study consists of a camera used to record the welding process and a processing unit which analyse the frames giving an indication of the quality expected.
The categorisation is achieved by employing artificial neural networks and correlating the weld pool appearance with the resulting quality. Six categories denote the resulting quality of a weld for stainless steel and aluminium. The models use images to learn the correlation between the aspect of the weld pool and the surrounding area and the state of the weld as denoted by the six categories, similar to a welder categorisation. Therefore the models learn the probability distribution of images’ aspect over the categories considered