PROCESS IMAGE ANALYSIS USING BIG DATA, MACHINE LEARNING, AND COMPUTER VISION

The 6th biennial conference on object-based image analysis—GEOBIA 2016—took place in September 2016 at the University of Twente in Enschede, The Netherlands (see www [...]

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Big Universe, Big Data: Machine Learning and Image Analysis for Astronomy

IEEE Intelligent Systems ◽

10.1109/mis.2017.40 ◽

2017 ◽

Vol 32 (2) ◽

pp. 16-22 ◽

Cited By ~ 24

Author(s):

Jan Kremer ◽

Kristoffer Stensbo-Smidt ◽

Fabian Gieseke ◽

Kim Steenstrup Pedersen ◽

Christian Igel

Keyword(s):

Machine Learning ◽

Image Analysis ◽

Big Data

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Computational Healthcare System With Image Analysis

Computational Models for Biomedical Reasoning and Problem Solving - Advances in Bioinformatics and Biomedical Engineering ◽

10.4018/978-1-5225-7467-5.ch004 ◽

2019 ◽

pp. 89-127 ◽

Cited By ~ 2

Author(s):

Ramgopal Kashyap

Keyword(s):

Machine Learning ◽

Data Mining ◽

Computer Vision ◽

Image Analysis ◽

Social Insurance ◽

Valuable Data ◽

Clinical Notes ◽

Information Reporting ◽

Segmentation Methods ◽

Crucial Part

The quickly extending field of huge information examination has begun to assume a crucial part in the advancement of human services practices and research. In this chapter, challenges like gathering information from complex heterogeneous patient sources, utilizing the patient/information relationships in longitudinal records, understanding unstructured clinical notes in the correct setting and efficiently dealing with expansive volumes of medicinal imaging information, and removing conceivably valuable data is shown. Healthcare and IoT and machine learning along with data mining are also discussed. Image analysis and segmentation methods comparative study is given for the examination of computer vision, imaging handling, and example acknowledgment has gained considerable ground amid the previous quite a few years. Examiners have distributed an abundance of essential science and information reporting the advance and social insurance application on medicinal imaging.

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Computer vision, machine learning, and the promise of phenomics in ecology and evolutionary biology

10.32942/osf.io/98cuw ◽

2020 ◽

Author(s):

Moritz Lürig ◽

Seth Donoughe ◽

Erik Svensson ◽

Arthur Porto ◽

Masahito Tsuboi

Keyword(s):

Machine Learning ◽

Computer Vision ◽

Image Analysis ◽

Evolutionary Biology ◽

Image Data ◽

Phenotypic Trait ◽

Biological Phenomena ◽

Level Data ◽

Wide Range ◽

Insight Into

For centuries, ecologists and evolutionary biologists have used images such as drawings, paintings, and photographs to record and quantify the shapes and patterns of life. With the advent of digital imaging, biologists continue to collect image data at an ever-increasing rate. This immense body of data provides insight into a wide range of biological phenomena, including phenotypic trait diversity, population dynamics, mechanisms of divergence and adaptation and evolutionary change. However, the rate of image acquisition frequently outpaces our capacity to manually extract meaningful information from the images. Moreover, manual image analysis is low-throughput, difficult to reproduce, and typically measures only a few traits at a time. This has proven to be an impediment to the growing field of phenomics - the study of many phenotypic dimensions together. Computer vision (CV), the automated extraction and processing of information from digital images, is a way to alleviate this longstanding analytical bottleneck. In this review, we illustrate the capabilities of CV for fast, comprehensive, and reproducible image analysis in ecology and evolution. First, we briefly review phenomics, arguing that ecologists and evolutionary biologists can most effectively capture phenomic-level data by using CV. Next, we describe the primary types of image-based data, and review CV approaches for extracting them (including techniques that entail machine learning and others that do not). We identify common hurdles and pitfalls, and then highlight recent successful implementations of CV in the study of ecology and evolution. Finally, we outline promising future applications for CV in biology. We anticipate that CV will become a basic component of the biologist’s toolkit, further enhancing data quality and quantity, and sparking changes in how empirical ecological and evolutionary research will be conducted.

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Artificial Intelligence and Machine Learning Algorithms

Advances in Computer and Electrical Engineering - Challenges and Applications for Implementing Machine Learning in Computer Vision ◽

10.4018/978-1-7998-0182-5.ch008 ◽

2020 ◽

pp. 188-219

Author(s):

Amit Kumar Tyagi ◽

Poonam Chahal

Keyword(s):

Artificial Intelligence ◽

Machine Learning ◽

Computer Vision ◽

Big Data ◽

Deep Learning ◽

Internet Of Things ◽

Learning Algorithms ◽

Machine Learning Algorithms ◽

Learning Techniques

With the recent development in technologies and integration of millions of internet of things devices, a lot of data is being generated every day (known as Big Data). This is required to improve the growth of several organizations or in applications like e-healthcare, etc. Also, we are entering into an era of smart world, where robotics is going to take place in most of the applications (to solve the world's problems). Implementing robotics in applications like medical, automobile, etc. is an aim/goal of computer vision. Computer vision (CV) is fulfilled by several components like artificial intelligence (AI), machine learning (ML), and deep learning (DL). Here, machine learning and deep learning techniques/algorithms are used to analyze Big Data. Today's various organizations like Google, Facebook, etc. are using ML techniques to search particular data or recommend any post. Hence, the requirement of a computer vision is fulfilled through these three terms: AI, ML, and DL.

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Survey of Machine Learning Applications of Convolutional Neural Networks to Medical Image Analysis

International Journal for Research in Applied Science and Engineering Technology ◽

10.22214/ijraset.2021.38947 ◽

2021 ◽

Vol 9 (11) ◽

pp. 1186-1196

Author(s):

Dr. K. Naveen Kumar

Keyword(s):

Neural Network ◽

Machine Learning ◽

Computer Vision ◽

Image Analysis ◽

Deep Learning ◽

Convolutional Neural Network ◽

Medical Image ◽

Medical Image Analysis ◽

Learning Techniques ◽

Before And After

Abstract: Recently, a machine learning (ML) area called deep learning emerged in the computer-vision field and became very popular in many fields. It started from an event in late 2012, when a deep-learning approach based on a convolutional neural network (CNN) won an overwhelming victory in the best-known worldwide computer vision competition, ImageNet Classification. Since then, researchers in many fields, including medical image analysis, have started actively participating in the explosively growing field of deep learning. In this paper, deep learning techniques and their applications to medical image analysis are surveyed. This survey overviewed 1) standard ML techniques in the computer-vision field, 2) what has changed in ML before and after the introduction of deep learning, 3) ML models in deep learning, and 4) applications of deep learning to medical image analysis. The comparisons between MLs before and after deep learning revealed that ML with feature input (or feature-based ML) was dominant before the introduction of deep learning, and that the major and essential difference between ML before and after deep learning is learning image data directly without object segmentation or feature extraction; thus, it is the source of the power of deep learning, although the depth of the model is an important attribute. The survey of deep learningalso revealed that there is a long history of deep-learning techniques in the class of ML with image input, except a new term, “deep learning”. “Deep learning” even before the term existed, namely, the class of ML with image input was applied to various problems in medical image analysis including classification between lesions and nonlesions, classification between lesion types, segmentation of lesions or organs, and detection of lesions. ML with image input including deep learning is a verypowerful, versatile technology with higher performance, which can bring the current state-ofthe-art performance level of medical image analysis to the next level, and it is expected that deep learning will be the mainstream technology in medical image analysis in the next few decades. “Deep learning”, or ML with image input, in medical image analysis is an explosively growing, promising field. It is expected that ML with image input will be the mainstream area in the field of medical image analysis in the next few decades. Keywords: Deep learning, Convolutional neural network, Massive-training artificial neural network, Computer-aided diagnosis, Medical image analysis, Classification (key words)

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Image Analysis Techniques on Phenotype for Plant System

International Journal of Engineering and Advanced Technology - Regular Issue ◽

10.35940/ijeat.a1125.1291s419 ◽

2019 ◽

Vol 9 (1S4) ◽

pp. 565-568

Keyword(s):

Machine Learning ◽

Computer Vision ◽

Image Analysis ◽

Deep Learning ◽

Plant Species ◽

High Efficiency ◽

Phenotypic Traits ◽

Phenotype Analysis ◽

Plant Phenomics ◽

Plant Image

In recent years, there is a rapid advancement in computer vision technology which is much effective in extracting useful information from plant images in the field of plant phenomics. Phenomic approaches are widely used in the identification of relationship between phenotypic traits and genetic diversities among the plant species. The need for automation and precision in phenotyping have been accelerated by the significant advancement in genotyping. Regardless of its significance, the shortage of freely available research databases having plant imageries has significantly obstructed the plant image analysis advancement. There were several existing computer vision techniques employed in the analysis of plant phenotypes. Conversely, recent trends in image analysis with the use of machine learning and deep learning based approaches including convolutional neural networks have increased their expansion for providing high-efficiency phenotyping of plant species. Thus, to enhance the efficiency of phenotype analysis, various existing machine learning and deep learning algorithms have been reviewed in this paper along with their methods, advantages, and limitations.

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