6 research outputs found
Patch-based Denoising Algorithms for Single and Multi-view Images
In general, all single and multi-view digital images are captured using sensors, where they are often contaminated with noise, which is an undesired random signal. Such noise can also be produced during transmission or by lossy image compression. Reducing the noise and enhancing those images is among the fundamental digital image processing tasks. Improving the performance of image denoising methods, would greatly contribute to single or multi-view image processing techniques, e.g. segmentation, computing disparity maps, etc. Patch-based denoising methods have recently emerged as the state-of-the-art denoising approaches for various additive noise levels. This thesis proposes two patch-based denoising methods for single and multi-view images, respectively.
A modification to the block matching 3D algorithm is proposed for single image denoising. An adaptive collaborative thresholding filter is proposed which consists of a classification map and a set of various thresholding levels and operators. These are exploited when the collaborative hard-thresholding step is applied. Moreover, the collaborative Wiener filtering is improved by assigning greater weight when dealing with similar patches.
For the denoising of multi-view images, this thesis proposes algorithms that takes a pair of noisy images captured from two different directions at the same time (stereoscopic images). The structural, maximum difference or the singular value decomposition-based similarity metrics is utilized for identifying locations of similar search windows in the input images. The non-local means algorithm is adapted for filtering these noisy multi-view images.
The performance of both methods have been evaluated both quantitatively and qualitatively through a number of experiments using the peak signal-to-noise ratio and the mean structural similarity measure. Experimental results show that the proposed algorithm for single image denoising outperforms the original block matching 3D algorithm at various noise levels. Moreover, the proposed algorithm for multi-view image denoising can effectively reduce noise and assist to estimate more accurate disparity maps at various noise levels
Deep Learning in Medical Image Analysis
The accelerating power of deep learning in diagnosing diseases will empower physicians and speed up decision making in clinical environments. Applications of modern medical instruments and digitalization of medical care have generated enormous amounts of medical images in recent years. In this big data arena, new deep learning methods and computational models for efficient data processing, analysis, and modeling of the generated data are crucially important for clinical applications and understanding the underlying biological process. This book presents and highlights novel algorithms, architectures, techniques, and applications of deep learning for medical image analysis
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Wind farm power output prediction based on machine learning recurrent neural networks
Scientists, investors and policy makers have become aware of the importance of providing near accurate prediction of renewable energy. This is why current studies show improvements in methodologies to provide more precise energy predictions. Wind energy is tied to variabilities of weather patterns, especially wind speeds, which are irregular in climates with erratic weather conditions. To predict wind power output, model technologies like autoregressive integrated moving average (ARIMA), variants of ARIMA, hybrid models involving ARIMA and artificial neural networks (ANN), Kalman filters and support vector regressions (SVR) have been applied for wind speed involving short, ultra-short, medium and long terms kind of predictions. ARIMA ensemble with ANN has shown better performance for short and ultra-short terms of two to three hours ahead. On the other hand, SVR, Kalman filters and ensemble of both has recorded good performance for medium-term kinds of wind speed predictions. Recently, neural networks in particular recurrent neural networks (RNN) have reported immense achievement in time series predictions particularly for medium and long-term. This is largely due to its retentive memory-mapping capabilities in fitting sequence in series. These capabilities are short-lived; when the sequence grows over time, the RNN tend to lose correlated information on back-propagation operations. This can lead to errors in the predicted potentials. Therefore, RNNs are exploited for enhanced wind-farm power output prediction. The main contribution of this research is the study of a model involving a combination of RNN regularisation methods using dropout and long short-term memory (LSTM) for wind-power output predictions. In this research, the regularisation method modifies and adapts to the stochastic nature of the wind and is optimised for the wind-farm power output (WFPO) prediction for up to 12-hours ahead – 72-timesteps. This algorithm implements a dropout method to suit the non-deterministic wind speed by applying LSTM to prevent RNN from overfitting. A demonstration for accuracy using the proposed method is performed on a 14-turbine wind farm with up to ten thousand wind samples for model training and five hundred for model validation and testing. The model out performs the ARIMA model with up to 90% accuracy and is expected to be applied to erratic weather condition, especially those observed in an off-shore wind farms
A virtual object point model for the calibration of underwater stereo cameras to recover accurate 3D information
The focus of this thesis is on recovering accurate 3D information from underwater images. Underwater 3D reconstruction differs significantly from 3D reconstruction in air due to the refraction of light. In this thesis, the concepts of stereo 3D reconstruction in air get extended for underwater environments by an explicit consideration of refractive effects with the aid of a virtual object point model. Within underwater stereo 3D reconstruction, the focus of this thesis is on the refractive calibration of underwater stereo cameras