Genotyping Market Worth US$ 137,602.6 million by 2030 According to the Market Statsville Group, the global genotyping market size was valued at USD 19,952.6 million in 2021 and is projected to grow at a CAGR of 27.3% to reach USD 137,602.6 million by 2030 The genotyping market refers to the industry involved in the identification and analysis of an individual's genetic makeup, primarily focused on identifying specific variations or mutations in their DNA. Genotyping plays a crucial role in various fields, including healthcare, pharmaceuticals, agriculture, and research, as it helps understand genetic predispositions, diagnose diseases, develop personalized treatments, and study genetic diversity. Key components and factors in the genotyping market include: 1. Technologies: Various genotyping technologies are available, including polymerase chain reaction (PCR), microarray, sequencing (Sanger sequencing and next-generation sequencing), and others. Each technology has its advantages and is suited to specific applications. 2. Applications: o Clinical Diagnostics: Genotyping is used to diagnose genetic disorders, predict disease risk, and guide personalized medicine. o Pharmaceuticals: Genotyping helps identify suitable patients for clinical trials, understand drug response variability, and develop targeted therapies. o Agriculture: Genotyping assists in crop improvement, breeding programs, and the development of genetically modified organisms. o Research: Genotyping is a fundamental tool in genetics research, enabling the study of genetic diversity, evolutionary biology, and population genetics. Request Sample Copy of this Report: https://www.marketstatsville.com/request-sample/genotyping-market Genotyping Market Dynamics The dynamics of the genotyping market are influenced by various factors and trends that shape its growth and evolution. These dynamics can be categorized into several key aspects: 1. Technological Advancements: o Next-Generation Sequencing (NGS): Advances in NGS technologies have revolutionized genotyping, allowing for high-throughput, cost-effective, and accurate genetic analysis. The adoption of NGS-based genotyping continues to grow. o CRISPR-Cas9 and Gene Editing: Gene editing technologies like CRISPR-Cas9 have expanded genotyping applications by enabling precise modification of genes, leading to advancements in gene therapy and functional genomics research. o Single-Cell Genomics: Single-cell genotyping techniques provide insights into genetic heterogeneity within tissues, organs, and populations, opening new research avenues in fields like cancer biology and developmental biology. 2. Market Growth Drivers: o Personalized Medicine: The increasing emphasis on personalized medicine and targeted therapies drives demand for genotyping to identify genetic markers associated with disease susceptibility and drug responses. o Pharmacogenomics: Genotyping is essential for pharmacogenomics studies, helping to optimize drug prescriptions based on individual genetic profiles. o Agricultural Genomics: As global food demand rises, genotyping plays a pivotal role in developing disease-resistant crops, improving crop yields, and enhancing agricultural sustainability. 3. Data Management and Analysis: o Big Data Challenges: Genotyping generates vast amounts of genetic data, requiring robust data management and analysis solutions. Cloud computing and machine learning are increasingly used for data analysis. o Bioinformatics Tools: Advances in bioinformatics tools and software facilitate the interpretation of genotyping data, making it more accessible to researchers and clinicians. Direct Purchase Report: https://www.marketstatsville.com/buy-now/genotyping-market?opt=3338 Market Segmentation Analysis The study categorizes the global Genotyping market based on equipment type, technology, type, installation method, distribution channel, application, and regions. By Products Outlook (Revenue, USD Million, 2017-2030) • Reagents & Kits • Instruments • Services By Technology Outlook (Revenue, USD Million, 2017-2030) • Polymerase Chain Reaction (PCR) • Capillary Electrophoresis • Mass Spectrometry • Sequencing • Microarray • Others By Application Outlook (Sales, USD Million, 2017-2030) • Diagnostics • Drug Discovery & Development • Personalized Medicine • Academic Institutes • Agriculture • Others By Region Outlook (Sales, Production, USD Million, 2019-2033) • North America (Mexico, Canada, US) • South America (Peru, Brazil, Colombia, Argentina, Rest of Latin America) • Europe (Germany, Italy, France, UK, Spain, Poland, Russia, Slovenia, Slovakia, Hungary, Czech Republic, Belgium, the Netherlands, Norway, Sweden, Denmark, Rest of Europe) • Asia Pacific (China, Japan, India, South Korea, Indonesia, Malaysia, Thailand, Vietnam, Myanmar, Cambodia, the Philippines, Singapore, Australia & New Zealand, Rest of Asia Pacific) • The Middle East & Africa (Saudi Arabia, UAE, South Africa, Northern Africa, Rest of MEA) Access full Report Description, TOC, Table of Figure, Chart, etc: https://www.marketstatsville.com/table-of-content/genotyping-market REGIONAL ANALYSIS, 2023 Based on the region, the global Genotyping market has been analyzed and segmented into five regions, namely, North America, Europe, Asia-Pacific, South America, and the Middle East & Africa. North America has been a prominent market for Genotypings due to high consumer spending on electronics and a strong demand for home entertainment systems. The United States, in particular, has a large market for Genotypings, driven by the popularity of streaming services and the desire for immersive audio experiences. The Asia Pacific region, including countries like China, Japan, and South Korea, has witnessed substantial growth in the Genotyping market. Factors contributing to this growth include the rising disposable income, increasing urbanization, and the growing popularity of home theater systems among consumers in the region. Request For Report Description: https://www.marketstatsville.com/genotyping-market Major Key Players in the Genotyping Market The global Genotyping market is fragmented into a few major players and other local, small, and mid-sized manufacturers/providers, they are – The genotyping market is mildly concentrated in nature with few numbers of global players operating in the market such as Illumina, Thermo Fisher Scientific, QIAGEN, Agilent Technologies, Danaher Corporation, Roche Diagnostics, GE Healthcare, Fluidigm Corporation, PerkinElmer, Eurofins Scientific, Bio-Rad Laboratories, Pacific Biosciences of California, GENEWIZ, and Integrated DNA Technologies. Every company follows its own business strategy to attain the maximum market share.

Fixed Asset Management Software Market Size, Historical Growth, Analysis, Opportunities and Forecast To 2030 Fixed Asset Management Software Market: Streamlining Asset Tracking and Optimization Introduction: The fixed asset management software market has experienced significant growth in recent years, driven by the increasing need for efficient tracking, maintenance, and optimization of physical assets. Fixed assets, such as buildings, machinery, equipment, and vehicles, play a crucial role in organizations across various industries. Fixed asset management software offers comprehensive solutions for effectively managing and monitoring these assets throughout their lifecycle. This article provides an overview of the fixed asset management software market, highlighting its key drivers, challenges, and future prospects. Understanding Fixed Asset Management Software: Fixed asset management software provides organizations with tools and functionalities to track, record, and manage their physical assets. These software solutions enable businesses to streamline asset acquisition, depreciation tracking, maintenance scheduling, compliance management, and reporting. By leveraging automation, data analytics, and integration capabilities, fixed asset management software enhances asset visibility, improves operational efficiency, and maximizes the return on investment (ROI) from fixed assets. Key Drivers of the Fixed Asset Management Software Market: Increasing Asset Complexity: Organizations today possess a wide range of assets that are often complex and require meticulous management. Fixed asset management software offers advanced features, such as barcode scanning, RFID tagging, and asset classification, to simplify asset tracking, reduce manual errors, and ensure accurate data management. Regulatory Compliance and Reporting: Compliance with accounting standards, tax regulations, and industry-specific requirements is crucial for organizations. Fixed asset management software automates compliance-related tasks, ensuring accurate financial reporting, facilitating audits, and minimizing the risk of penalties or non-compliance. Cost Reduction and Optimization: Effective fixed asset management software enables organizations to optimize asset utilization, reduce unnecessary asset purchases, and improve maintenance practices. By identifying underutilized assets, tracking maintenance schedules, and enabling data-driven decision-making, businesses can lower costs, extend asset lifecycles, and improve overall operational efficiency. Digital Transformation and Integration: The ongoing digital transformation across industries has accelerated the adoption of fixed asset management software. Integration with enterprise resource planning (ERP) systems, Internet of Things (IoT) devices, and other business applications enables real-time asset data updates, seamless workflows, and holistic asset visibility, facilitating efficient decision-making and resource allocation. Challenges in the Fixed Asset Management Software Market: Data Accuracy and Integrity: Maintaining accurate and up-to-date asset data is crucial for effective asset management. Organizations face challenges in ensuring data accuracy, especially during asset acquisition, transfers, or disposals. Manual data entry, data silos, and lack of standardized processes can lead to inaccuracies and impact the reliability of asset management software. Scalability and Adaptability: Organizations with a large number of assets or those experiencing rapid growth need scalable and adaptable fixed asset management software. Ensuring that the software can handle increasing asset volumes, accommodate new asset types, and integrate with evolving technologies can be a challenge. Change Management and User Adoption: Implementing fixed asset management software requires effective change management practices and user adoption. Training employees, overcoming resistance to change, and aligning processes with the software's functionalities are critical to maximizing the benefits of the software implementation. Browse In-depth Market Research Report (100 Pages, Charts, Tables, Figures) on Fixed Asset Management Software Market - https://www.marketresearchfuture.com/reports/fixed-asset-management-software-market-4398 Future Prospects: The fixed asset management software market is poised for continued growth and innovation. Several trends contribute to its promising future: Integration with Emerging Technologies: Fixed asset management software will increasingly integrate with emerging technologies such as artificial intelligence (AI), machine learning (ML), and IoT. This integration will enable predictive maintenance, asset performance analytics, and real-time monitoring, enhancing asset visibility, reducing downtime, and optimizing maintenance strategies. Related Reports Key management as a service Market Cloud ERP Market AI Robots Market

Freight Management System Market Size, Historical Growth, Analysis, Opportunities and Forecast To 2032 Freight Management System Market: Driving Efficiency and Connectivity in the Global Logistics Industry Introduction: The global logistics industry has undergone significant transformations in recent years, driven by advancements in technology and the need for more efficient and streamlined operations. Freight management plays a crucial role in this landscape, and the adoption of freight management systems has become essential for businesses looking to optimize their supply chain operations. In this article, we will explore the key highlights and insights from the "Freight Management System Market" report by Market Research Future (MRFR), providing a comprehensive overview of the industry. Overview of the Freight Management System Market: The freight management system market has been experiencing substantial growth, propelled by the rising demand for real-time visibility, enhanced operational efficiency, and cost-effective transportation solutions. According to the MRFR report, The freight management system market industry is projected to grow from USD 28.08 Billion in 2023 to USD 60.77 billion by 2032 Factors Driving Market Growth: Technological Advancements: The integration of advanced technologies, such as artificial intelligence (AI), machine learning (ML), Internet of Things (IoT), and big data analytics, has revolutionized the freight management landscape. These technologies enable efficient route planning, real-time tracking, predictive analytics, and intelligent decision-making, leading to optimized operations and reduced costs. Increasing Global Trade: The expansion of international trade and e-commerce activities has significantly boosted the demand for freight management systems. As businesses strive to cater to a global customer base, they require robust logistics solutions to manage complex supply chains, handle customs regulations, and ensure timely delivery of goods across borders. Growing Complexity of Supply Chain: With the increase in global trade volumes, supply chains have become more complex, involving multiple stakeholders, modes of transport, and regulatory requirements. Freight management systems offer end-to-end visibility and control, enabling businesses to monitor and manage their supply chain activities seamlessly. Cost Optimization and Operational Efficiency: Freight management systems provide comprehensive tools for optimizing transportation routes, reducing fuel consumption, minimizing empty miles, and improving resource utilization. By automating manual processes, businesses can streamline their operations, reduce human errors, and achieve cost savings. Browse In-depth Market Research Report (141 Pages, Charts, Tables, Figures) on Freight Management System Market https://www.marketresearchfuture.com/reports/freight-management-system-market-8715 Market Segmentation: The freight management system market is segmented on the basis of component, transportation mode, end-use industry, and region. Component: a. Solutions b. Services Transportation Mode: a. Roadways b. Railways c. Airways d. Waterways End-use Industry: a. Retail & E-commerce b. Manufacturing & Automotive c. Healthcare & Pharmaceuticals d. Aerospace & Defense e. Others Regional Analysis: The market research report provides a comprehensive analysis of various regions, including North America, Europe, Asia-Pacific, and the rest of the world. North America is anticipated to dominate the freight management system market, owing to the presence of prominent logistics and transportation companies, technological advancements, and early adoption of innovative solutions. However, the Asia-Pacific region is expected to witness significant growth during the forecast period, driven by rapid industrialization, the booming e-commerce sector, and increasing investments in logistics infrastructure. Conclusion: The global freight management system market is witnessing substantial growth, driven by the need for streamlined supply chain operations, cost optimization, and enhanced customer satisfaction. With advancements in technology and the integration of AI, IoT, and analytics, freight management systems are playing a pivotal role in transforming the logistics industry. As businesses strive to navigate complex supply chains and cater to global markets, the adoption of these systems becomes imperative to drive efficiency, connectivity, and competitiveness in the ever-evolving global trade landscape. Related Reports Key management as a service Market Cloud ERP Market AI Robots Market

Artificial Neural Network Market Growing Geriatric Population to Boost Growth 2027 Artificial Neural Network Market The artificial neural network market is expected to grow at a CAGR of 20.5% from 2020 to 2027. The growth of the market is driven by the increasing use of artificial neural networks in a variety of industries, such as healthcare, finance, and manufacturing. Artificial neural networks are a type of machine learning algorithm that is inspired by the human brain. They are able to learn and adapt to new data, making them well-suited for tasks such as classification, regression, and forecasting. The artificial neural network market is segmented by type, application, and end-user. By type, the market is segmented into deep learning, machine learning, and traditional neural networks. Deep learning is the fastest-growing segment of the market, due to its ability to learn complex patterns from large amounts of data. By application, the market is segmented into healthcare, finance, manufacturing, retail, and others. Healthcare is the largest segment of the market, due to the increasing use of artificial neural networks for tasks such as image analysis, drug discovery, and patient diagnosis. By end-user, the market is segmented into small and medium-sized businesses (SMBs) and large enterprises. Large enterprises are the major users of artificial neural networks, due to their larger data sets and more complex computing needs. The artificial neural network market is a rapidly growing market, with a wide range of potential applications. The growth of the market is being driven by the increasing availability of data, the development of new algorithms, and the decreasing cost of computing power. Browse In-depth Market Research Report (100 Pages) on Artificial Neural Network Market https://www.marketresearchfuture.com/reports/artificial-neural-network-market-6287 Here are some of the key players in the artificial neural network market: IBM Microsoft Google Amazon Web Services Intel Nvidia MathWorks SAS Tibco Oracle These companies are developing and providing artificial neural network software and services to a wide range of industries. The artificial neural network market is a promising market with a lot of potential. The growth of the market is being driven by a number of factors, including the increasing availability of data, the development of new algorithms, and the decreasing cost of computing power. The market is expected to continue to grow in the coming years, as artificial neural networks are used in a wider range of applications. Related Reports AI in Social Media Market - AI in Social Media Market size exceeded USD 5.32 Billion in 2030 and is projected to expand at over 28.70% CAGR from 2020 to 2027. GPU Database Market - Globally, the market was estimated to cover a market value of USD 195.3 million which is expected to extend to USD 462.11 Billion during the GPU database market forecast period ranging from 2030. Cloud Radio Access Network Market - Cloud radio access network market is estimated to reach 16.4 billion USD by the end of 2030

Advanced Analytics Market Estimated To Experience A Hike In Growth By 2030 MRFR What is Advanced Analytics? Advanced analytics is a type of data analysis that uses sophisticated techniques and tools to extract hidden insights from data. It goes beyond traditional business intelligence (BI) by using machine learning, predictive modeling, and other statistical methods to identify patterns, trends, and relationships in data. Advanced analytics can be used to make predictions, optimize decision-making, and improve business performance. Benefits of Advanced Analytics There are many benefits to using advanced analytics, including: Improved decision-making: Advanced analytics can help businesses make better decisions by providing them with a deeper understanding of their customers, markets, and operations. This can lead to increased sales, improved customer satisfaction, and reduced costs. Increased efficiency: Advanced analytics can help businesses identify areas where they can improve efficiency and productivity. This can be done by identifying bottlenecks in processes, optimizing resource allocation, and improving forecasting accuracy. New product and service development: Advanced analytics can be used to identify new product and service opportunities. This can be done by analyzing customer data to identify unmet needs, understanding trends in the market, and developing new products and services that meet these needs. Risk mitigation: Advanced analytics can be used to identify and mitigate risks. This can be done by analyzing data to identify potential risks, developing plans to mitigate these risks, and monitoring the effectiveness of these plans. Types of Advanced Analytics There are many different types of advanced analytics, including: Machine learning: Machine learning is a type of artificial intelligence that allows computers to learn without being explicitly programmed. This can be used to develop predictive models, identify patterns in data, and make decisions without human intervention. Predictive analytics: Predictive analytics is a type of analytics that uses historical data to predict future events. This can be used to forecast sales, identify customers who are likely to churn, and predict the likelihood of fraud. Prescriptive analytics: Prescriptive analytics is a type of analytics that uses data to recommend actions that can improve business outcomes. This can be used to optimize marketing campaigns, develop new products and services, and improve customer service. Browse In-depth Market Research Report (100 Pages) on Advanced Analytics Market Challenges of Advanced Analytics There are a number of challenges associated with using advanced analytics, including: Data quality: The quality of the data used for advanced analytics is critical to the success of any project. If the data is not accurate or complete, the results of the analysis will be unreliable. Technical expertise: Advanced analytics requires a high level of technical expertise. This can be a challenge for businesses that do not have the resources to hire or train data scientists. Interpretation of results: The results of advanced analytics can be complex and difficult to interpret. This can make it difficult for businesses to make decisions based on the results. Conclusion Advanced analytics is a powerful tool that can help businesses improve decision-making, increase efficiency, and develop new products and services. However, there are a number of challenges associated with using advanced analytics, including data quality, technical expertise, and interpretation of results. Businesses that are considering using advanced analytics should carefully consider these challenges and make sure they have the resources in place to overcome them. Related Reports Application Management Services Market - The Application Management Services market industry is projected to grow from USD18.711 Billion in 2023 to USD 60.1942027 billion by 2030 Cash Management System Market - The Cash Management System market industry is projected to grow from USD 14.9424 Billion in 2022 to USD 35.5914225 billion by 2030 Pharma Knowledge Management Software Market - Pharma knowledge management software market valuation is expected to reach approximately 5.15 billion by 2030.

Chatbots Market Global Opportunity Analysis and Industry Forecast 2022-2030 Chatbots: The Future of Customer Service Chatbots are software programs that can simulate conversation with human users. They are often used in customer service applications, where they can answer questions, resolve problems, and provide support. Chatbots are becoming increasingly popular, as they offer a number of advantages over traditional customer service channels. The Chatbots industry is projected to grow from USD 4.92 Billion in 2022 to USD 24.64 Billion by 2030, exhibiting a compound annual growth rate (CAGR) of 23.91% during the forecast period (2022 - 2030). Advantages of Chatbots 24/7 availability: Chatbots are available 24 hours a day, 7 days a week, which can be a major advantage for businesses that operate on a global scale. Cost savings: Chatbots can help businesses save money on customer service costs. This is because chatbots can handle a large volume of inquiries without the need for human intervention. Improved customer satisfaction: Chatbots can improve customer satisfaction by providing a more personalized and convenient experience. Customers can simply type or speak their questions or requests, and the chatbot will respond in a timely and helpful manner. Types of Chatbots There are two main types of chatbots: rule-based chatbots and machine learning chatbots. Rule-based chatbots: Rule-based chatbots are programmed with a set of rules that define how they should respond to user input. This type of chatbot is relatively easy to develop, but it can be limited in its ability to handle complex requests. Machine learning chatbots: Machine learning chatbots are trained on a large corpus of data, which allows them to learn to respond to user input in a more natural and human-like way. This type of chatbot is more complex to develop, but it can offer a more personalized and engaging experience for users. The Future of Chatbots Chatbots are still a relatively new technology, but they are rapidly gaining popularity. As chatbot technology continues to develop, we can expect to see more and more businesses adopt chatbots for customer service and other applications. Chatbots have the potential to revolutionize the way we interact with businesses, and they are sure to play a major role in the future of customer service. Browse In-depth Market Research Report (100 Pages) on Chatbots Market https://www.marketresearchfuture.com/reports/chatbots-market-2981 Here are some of the ways chatbots are being used today: Customer service: Chatbots can be used to answer customer questions, resolve problems, and provide support. Sales: Chatbots can be used to generate leads, qualify prospects, and close deals. Marketing: Chatbots can be used to promote products and services, collect feedback, and build relationships with customers. Education: Chatbots can be used to provide personalized instruction, answer questions, and provide feedback. Healthcare: Chatbots can be used to provide patient education, answer questions, and schedule appointments. The future of chatbots is bright. As technology continues to advance, chatbots will become more sophisticated and capable. This will lead to even more widespread adoption of chatbots by businesses and organizations of all size. Related Reports Body-worn Camera Market - The global body-worn camera market Size was valued at 545.9 million in 2021 and is expected to surpass USD 2,074.0 million by 2030 with a significant CAGR rate of 16.4% during 2022-2030. Warehouse Management System (WMS) Market - The Warehouse management system market industry is projected to grow from USD 3.2 Billion in 2023 to USD 9.9 Billion by 2030 Blockchain Identity Management Market - The Blockchain Identity Management market is projected to grow from USD 190.4 Million in 2023 to USD 6,500 Million by 2030

https://azure.microsoft.com/en-us/blog/announcing-microsoft-s-coco-framework-for-enterprise-blockchain-networks/ https://opensourcelibs.com/lib/diffnet https://github.com/Messi-Q/GraphDeeSmartContract https://xscode.com/jdlc105/Must-read-papers-and-continuous-tracking-on-Graph-Neural-Network-GNN-progress Must-read papers and continuous track on Graph Neural Network(GNN) progress Many important real-world applications and questions come in the form of graphs, such as social network, protein-protein interaction network, brain network, chemical molecular graph and 3D point cloud. Therefore, driven by the above interdisciplinary research, the neural network model for graph data-oriented has become an emerging research hotspot. Among them, two of the three pioneers of deep learning, Professor Yann LeCun (2018 Turing Award Winner), Professor Yoshua Bengio (2018 Turing Award Winner) and famous Professor Jure Leskovec from Stanford University AI lab also participated in it. This project focuses on GNN, lists relevant must-read papers and keeps track of progress. We look forward to promoting this direction and providing some help to researchers in this direction. Contributed by Allen Bluce (Dr. Bentian Li) and Anne Bluce (Dr. Yunxia Lin), If there is something wrong or GNN-related issue, welcome to send email (Address: jdlc105@qq.com, lbtjackbluce@gmail.com). Technology Keyword: Graph Neural Network, Graph convolutional network, Graph network, Graph attention network, Graph auto-encoder, Graph convolutional reinforcement learning, Graph capsule neural network.... GNN and its variants are an emerging and powerful neural network approach. Its application is no longer limited to the original field. It has flourished in many other areas, such as Data Visualization, Image Processing, NLP, Recommendation System, Computer Vision, Bioinformatics, Chemical informatics, Drug Development and Discovery, Smart Transportation. Very hot research topic: the representative work--Graph convolutional networks (GCNs) proposed by T.N. Kipf and M. Welling (ICLR2017 [5] in conference paper list) has been cited 1,020 times in Google Scholar (on 09 May 2019). Update: 1, 065 times (on 20 May 2019); Update: 1, 106 times (on 27 May 2019); Update: 1, 227 times (on 19 June 2019); Update: 1, 377 times (on 8 July 2019); Update: 1, 678 times (on 17 Sept. 2019); Update: 1, 944 times (on 29 Oct. 2019); Update: 2, 232 times (on 9 Dec. 2019); Update: 2, 677 times (on 2 Feb. 2020).Update: 3, 018 times (on 17 March. 2020); Update: 3,560 times (on 27 May. 2020); Update: 4,060 times (on 3 July. 2020); Update: 5,371 times (on 25 Oct. 2020). Update: 6,258 times (on 01 Jan. 2021). Thanks for giving us so many stars and supports from the developers and scientists on Github around the world！！！ We will continue to make this project better. Project Start time: 11 Dec 2018, Latest updated time: 01 Jan. 2021 New papers about GNN models and their applications have come from NeurIPS2020, AAAI2021 .... We are waiting for more paper to be released. Survey papers: Bronstein M M, Bruna J, LeCun Y, et al. Geometric deep learning: going beyond euclidean data. IEEE Signal Processing Magazine, 2017, 34(4): 18-42. paper Jie Zhou, Ganqu Cui, Zhengyan Zhang, Cheng Yang, Zhiyuan Liu, Maosong Sun, Graph Neural Networks: A Review of Methods and Applications, ArXiv, 2018. paper. Battaglia P W, Hamrick J B, Bapst V, et al. Relational inductive biases, deep learning, and graph networks, arXiv 2018. paper Zonghan Wu, Shirui Pan, Fengwen Chen, Guodong Long, Chengqi Zhang, Philip S. Yu(Fellow,IEEE), A Comprehensive Survey on Graph Neural Networks, IEEE Transactions on Neural Networks and Learning Systems, 2020. paper. Ziwei Zhang, Peng Cui, Wenwu Zhu, Deep Learning on Graphs: A Survey, IEEE Transactions on Knowledge and Data Engineering, 2020. paper. Chen Z, Chen F, Zhang L, et al. Bridging the Gap between Spatial and Spectral Domains: A Survey on Graph Neural Networks. arXiv preprint. 2020. paper Abadal S, Jain A, Guirado R, et al. Computing Graph Neural Networks: A Survey from Algorithms to Accelerators. arXiv preprint. 2020. paper Lamb L, Garcez A, Gori M, et al. Graph Neural Networks Meet Neural-Symbolic Computing: A Survey and Perspective. arXiv preprint. 2020. paper Journal papers: F. Scarselli, M. Gori, A.C. Tsoi, M. Hagenbuchner, G. Monfardini, The graph neural network model, IEEE Transactions on Neural Networks(IEEE Transactions on Neural Networks and Learning Systems), 2009. paper. Scarselli F, Gori M, Tsoi A C, et al. Computational capabilities of graph neural networks, IEEE Transactions on Neural Networks, 2009. paper. Micheli A . Neural Network for Graphs: A Contextual Constructive Approach. IEEE Transactions on Neural Networks, 2009. paper. Goles, Eric, and Gonzalo A. Ruz. Dynamics of Neural Networks over Undirected Graphs. Neural Networks, 2015. paper. Z. Luo, L. Liu, J. Yin, Y. Li, Z. Wu, Deep Learning of Graphs with Ngram Convolutional Neural Networks, IEEE Transactions on Knowledge & Data Engineering, 2017. paper. code. Petroski Such F , Sah S , Dominguez M A , et al. Robust Spatial Filtering with Graph Convolutional Neural Networks. IEEE Journal of Selected Topics in Signal Processing, 2017. paper. Kawahara J, Brown C J, Miller S P, et al. BrainNetCNN: convolutional neural networks for brain networks; towards predicting neurodevelopment. NeuroImage, 2017. paper. Muscoloni A , Thomas J M , Ciucci S , et al. Machine learning meets complex networks via coalescent embedding in the hyperbolic space. Nature Communications, 2017. paper. D.M. Camacho, K.M. Collins, R.K. Powers, J.C. Costello, J.J. Collins, Next-Generation Machine Learning for Biological Networks, Cell, 2018. paper. Marinka Z , Monica A , Jure L . Modeling polypharmacy side effects with graph convolutional networks. Bioinformatics, 2018. paper. Sarah P , Ira K S , Enzo F , et al. Disease Prediction using Graph Convolutional Networks: Application to Autism Spectrum Disorder and Alzheimer’s Disease. Medical Image Analysis, 2018. paper. Sofia Ira Ktena, Sarah Parisot, Enzo Ferrante, Martin Rajchl, Matthew Lee, Ben Glocker, Daniel Rueckert, Metric learning with spectral graph convolutions on brain connectivity networks, NeuroImage, 2018. paper. Xie T , Grossman J C . Crystal Graph Convolutional Neural Networks for an Accurate and Interpretable Prediction of Material Properties. Physical Review Letters, 2018. paper. Phan, Anh Viet, Minh Le Nguyen, Yen Lam Hoang Nguyen, and Lam Thu Bui. DGCNN: A Convolutional Neural Network over Large-Scale Labeled Graphs. Neural Networks, 2018. paper Song T, Zheng W, Song P, et al. Eeg emotion recognition using dynamical graph convolutional neural networks. IEEE Transactions on Affective Computing, 2018. paper Levie R, Monti F, Bresson X, et al. Cayleynets: Graph convolutional neural networks with complex rational spectral filters. IEEE Transactions on Signal Processing 2019. paper Zhang, Zhihong, Dongdong Chen, Jianjia Wang, Lu Bai, and Edwin R. Hancock. Quantum-Based Subgraph Convolutional Neural Networks. Pattern Recognition, 2019. paper Qin A, Shang Z, Tian J, et al. Spectral–Spatial Graph Convolutional Networks for Semisupervised Hyperspectral Image Classification. IEEE Geoscience and Remote Sensing Letters, 2019. paper Coley C W, Jin W, Rogers L, et al. A graph-convolutional neural network model for the prediction of chemical reactivity. Chemical Science, 2019. paper Zhang Z, Chen D, Wang Z, et al. Depth-based Subgraph Convolutional Auto-Encoder for Network Representation Learning. Pattern Recognition, 2019. paper Hong Y, Kim J, Chen G, et al. Longitudinal Prediction of Infant Diffusion MRI Data via Graph Convolutional Adversarial Networks. IEEE transactions on medical imaging, 2019. paper Khodayar M, Mohammadi S, Khodayar M E, et al. Convolutional Graph Autoencoder: A Generative Deep Neural Network for Probabilistic Spatio-temporal Solar Irradiance Forecasting. IEEE Transactions on Sustainable Energy, 2019. paper Zhang Q, Chang J, Meng G, et al. Learning graph structure via graph convolutional networks. Pattern Recognition, 2019. paper Xuan P, Pan S, Zhang T, et al. Graph Convolutional Network and Convolutional Neural Network Based Method for Predicting lncRNA-Disease Associations. Cells, 2019. paper Sun M, Zhao S, Gilvary C, et al. Graph convolutional networks for computational drug development and discovery. Briefings in bioinformatics, 2019. paper Spier N, Nekolla S, Rupprecht C, et al. Classification of Polar Maps from Cardiac Perfusion Imaging with Graph-Convolutional Neural Networks. Scientific reports, 2019. paper Heyuan Shi, et al. Hypergraph-Induced Convolutional Networks for Visual Classification. IEEE Transactions on Neural Networks and Learning Systems, 2019. paper S.Pan, et al. Learning Graph Embedding With Adversarial Training Methods. IEEE Transactions on Cybernetics, 2019. paper D. Grattarola, et al. Change Detection in Graph Streams by Learning Graph Embeddings on Constant-Curvature Manifolds. IEEE Transactions on Neural Networks and Learning Systems. 2019. paper Kan Guo, et al. Optimized Graph Convolution Recurrent Neural Network for Traffic Prediction. IEEE Transactions on Intelligent Transportation Systems. 2020. paper Ruiz L, et al. Invariance-preserving localized activation functions for graph neural networks. IEEE Transactions on Signal Processing, 2020. paper Li J, et al. Neural Inductive Matrix Completion with Graph Convolutional Networks for miRNA-disease Association Prediction. Bioinformatics, 2020. paper Bingzhi Chen, et al. 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AI 科学家整理6 (凯西柯兹科夫(Cassie Kozyrkov) 谷歌首席决策科学家(Chief Decision Scientis)凯西柯兹科夫(Cassie Kozyrkov)在2018年非常高产，为大家写了非常多关于人工智能、大数据的文章。以下是他感觉她写过最优秀30篇文章，这些文章主要关注：数据科学和分析、人工智能、机器学习.... ... 当然，除了给出文章链接之外，她还对文章给出了总结性极强的“妙语”。 一起来欣赏吧！ 数据科学与分析 《数据科学究竟是什么?》：这篇文章快速介绍了数据科学、数据工程、统计学、分析学、机器学习和人工智能。 数据科学是使数据有用的学科。 https://towardsdatascience.com/data-science-conversation-starters-84affd2347f6 2014年，推特对“数据科学家”的定义 《伟大的数据分析师都在做什么？为什么每个组织机构都需要他们？》：这篇文章主要介绍：优秀的分析师是保证高效的数据工作的先决条件。不要低估他们，他们的离职对你来说是非常危险的。 https://hbr.org/2018/12/what-great-data-analysts-do-and-why-every-organization-needs-them 数据科学的三个支柱分别有各自的优点。统计学家保证严谨，机器学习工程师改善性能表现，分析师提供速度。 《哈佛商业评论中的秘密段落》是对《哈佛商业评论》补充的思考内容。里面的主题包括混合角色，研究的本质，蝙蝠信号，数据骗子和伟大分析师们! 企业家需要注意：现在有很多冒充数据科学家的数据骗子。遗憾的是，目前还没有十全十美的办法可以辨别数据骗子。 http://bit.ly/quaesita_bsides 《人工智能和数据科学的十大角色》：这篇文章介绍了不同的职位名称和它们对应的级别。 如果你的第一份工作的职称就是“研究员”，那么你公司的职称系统可能不是很完善。 https://hackernoon.com/top-10-roles-for-your-data-science-team-e7f05d90d961 机器学习/人工智能概念 《可能是你读过的最简单的机器学习知识介绍》的主旨是，机器学习是以实践用例为导向的，而不仅仅是文字说明。 机器学习是一种新的编程范式，一种将你的想法传达给电脑的方式。兴奋的是它可以使你将不可说的想法表达出来。 https://hackernoon.com/the-simplest-explanation-of-machine-learning-youll-ever-read-bebc0700047c 《你是不是用错了“人工智能”这个词？》：由于定义不明确，实际上我们都没有正确地使用“人工智能”这个词。这个词人人都在用，在本文中我提供了一份快速指南来介绍人工智能、机器学习、深度学习、强化学习和类人工智能。 如果你担心会不会每个橱柜里都潜伏着具拥有类似人类智慧的物种，放心吧，不会的，所有这些工业化的人工智能应用程序都在忙着解决真正的商业问题。 http://bit.ly/quaesita_ai 《向孩子（或老板）解释监督学习》：希望让所有人都熟悉一些基本术语，例如：实例、标签、特性、模型、算法和监督学习。 不要被术语吓倒。例如，“模型”其实只是“菜谱”的比较花哨的说法。 http://bit.ly/quaesita_slkid 《机器学习——是皇帝的新装吗?》：是一篇为初学者准备的可以查看核心概念的文章，包括通过图片和猫咪介绍算法和损失函数的概念。 不要因为机器学习太简单而嫌弃它。杠杆也很简单，但它们可以撬起世界。 https://towardsdatascience.com/data-science-conversation-starters-84affd2347f6 神经网络也可以称为“瑜伽网络”，因为它的神奇力量可以帮助你无限拓展边界。 《无监督学习的启发》：这篇文章讲了无监督学习可以帮助你在数据中找到灵感。他们会将相似的东西以分组的形式呈现给你，结果就像是罗夏墨迹卡那样。 你们可以把无监督学习看作是“物以类聚，人以群分”的数学版本。 http://bit.ly/quaesita_unsupervised 《可解释的人工智能却无法传播的原因》：许多人被带有人工智能字样的的宣传所吸引，他们认为这意味着可信度。但事实并非如此，陷入信任炒作可能意味着你将错过人工智能的一大优点：灵感。 如果你不相信任何你不理解的人事物，那么你就应该炒掉所有的人类员工，因为没人知道大脑（它拥有数千亿的神经元！）是如何做决定的。 https://towardsdatascience.com/data-science-conversation-starters-84affd2347f6 如何在机器学习/人工智能项目上保持不败 《为什么企业在机器学习项目中失败了》：讲述了许多企业没有意识到“应用机器学习”与“机器学习算法研究”是两个截然不同的学科。 想象一下，你想要开一家餐厅，却雇佣了那些一辈子都在制造微波炉但从来没下厨的人……那么，会有什么结果呢? https://hackernoon.com/why-businesses-fail-at-machine-learning-fbff41c4d5db 你在做什么生意？你的答案决定了你应该雇佣什么样的团队。 《寻找人工智能实践用例的建议》：先假设人工智能是个骗局，然后进行的头脑风暴，试图寻找应用人工智能的机会…… 企业经常犯的一个错误是，想当然地认为机器学习是魔法，所以就不用多加思考该怎样将任务做好。 https://hackernoon.com/imagine-a-drunk-island-advice-for-finding-ai-use-cases-8d47495d4c3f 《人工智能的第一步可能会让你大吃一惊》：这篇文章回答了启动人工智能项目的正确方法是什么，是获得人工智能学位吗？不是。是雇佣人工智能专家吗？也不是。是选择一个很棒的算法吗？也不是。是钻研数据吗？依然不是！ 永远不要要求一群博士“把机器学习应用到业务上，然后……好事就会发生。” http://bit.ly/quaesita_first “我想做什么” 《你的人工智能项目成功了吗？》：提供了一份（现实的）在你为一个应用机器学习项目雇佣工程师或获得数据之前，你应该仔细检查的清单。 不要为“人工智能”这个词所限制。多想想它可以为你做什么。 http://bit.ly/quaesita_realitycheck 《开始使用人工智能？从这里开始！》：是一份详细的指南，阐述了决策者在一个应用机器学习/人工智能项目中的作用和责任。 有能力完成和充分利用时间是两码事。我们习惯性地爱上我们已经为之付出的努力的人事物，即使它是一堆有毒的垃圾。 http://bit.ly/quaesita_dmguide 《当人工智能出错时，是谁的错？》：阐述了机器学习、人工智能的关键在于你是在用例子而不是文字说明来表达你的想法。要让机器学习/人工智能起作用，示例必须是相关的。 如果你使用的工具没有经过安全验证，那么你造成的任何混乱都是你的锅。人工智能和其他任何工具一样。 https://towardsdatascience.com/dont-trust-ai-10a7df520925 数据科学主导力 《数据驱动？再想想》：要做出数据驱动的决策，就必须以数据为主导。这个道理似乎很简单，但在现实中却鲜有人这样执行，因为决策者缺乏这样的观念。 分析数据的途径越多，越是容易产生确认偏差。而“解药”就是提前制定决策标准。 https://towardsdatascience.com/data-science-conversation-starters-84affd2347f6 《数据科学是否是泡沫？》：发现越来越多的人自称是“数据科学家”，但是整个行业似乎都在玩危险游戏。 “雇佣数据科学家等同于毒枭在自家后院养了一只老虎。事实上你也不知道老虎有什么用，就只知道毒枭都爱养老虎。” http://bit.ly/quaesita_bubble 《数据科学家领导》：教你如何训练决策者掌握技能，领导成功的数据科学团队。 崇尚数学亚文化的人容易表现出一副藐视一切的“软”技能。熬夜证明某些定理或者用第六种语言编程都是虚张声势之举。 https://towardsdatascience.com/data-science-leaders-there-are-too-many-of-you-37bff8088505 《重新思考数据科学中的快和慢》：讲述了产品开发团队如何协调快速迭代与进展缓慢的庞然深入研究过程的节奏，如何取舍？ 灵感廉价，精确不易。 https://towardsdatascience.com/data-science-conversation-starters-84affd2347f6 《采访：给予数据科学家的建议》：对于同行数据科学家问题的直白回答。主题包含：受欢迎的资源、职业、统计学教育和数据科学领导力。 有用的不见得复杂。数据质量比解决方案更重要。沟通能力胜过另一种编程语言。 http://bit.ly/mlconf_cassie 技术 《关于Tensorflow，你需要知道这9件事》：如果你拥有许多的数据，或者你紧随人工智能领域的最新进展，那么TensorFlow会是你的好伙伴。 有了TensorFlow Hub，不同于传统方法，以更高效的方式帮你整合自己和他人的代码，或者说你自己的代码（否则称之为专业软件工程）。 https://towardsdatascience.com/data-science-conversation-starters-84affd2347f6 《什么是不繁琐的人工智能？》：Kubeflow致力于为数据科学家摆脱一切不喜欢的琐事。如同一把滑雪橇助你越过琐事之丘。 祝贺你总算盼来为你打造的基础设施，听上去就像你不需要为自己制造一台电脑一样。 http://bit.ly/quaesita_kubeflow 《5小步概述数据科学》：来自谷歌2018 Cloud Next大会受欢迎的演讲。5个视频概述，均不超过5分钟。 炒作了半个世纪的人工智能并未实现。为什么会是现在呢？许多人未意识到如今的人工智能应用讲的是云计算的故事。 http://bit.ly/quaesita_ds5 统计学 《不要在统计学上浪费时间》：如何确定你是否需要掌握统计学，如果不知道，你该怎么办。 统计学是改变思维的科学。 http://bit.ly/quaesita_pointofstats 《不要从假设开始》：学习数学却没有理解其本质常犯的错误是只做假设而不行动。看一下如何使用数理统计做决定。 假设像是蟑螂。当你看见一只蟑螂时，代表不止一只。通常附近还隐藏着更多的蟑螂。 http://bit.ly/quaesita_damnedlies 《统计学入门》：让你迅速掌握统计学代表的含义和用通俗易懂的话语理解各类术语。 数学是在虚设世界中构建一个模型。如此你才得到了P值。 http://bit.ly/quaesita_statistics 《总体——你犯了什么错》：统计学方法只有在你需要的信息（总体）与你拥有的信息（样本）不匹配的时候才能发挥作用。 从样本到总体如同伊卡洛斯似的跳跃，在你不知道目标的情况下，结果将是一次大的碰撞。 http://bit.ly/quaesita_popwrong 《统计学理解自测》：能否通过小测验来检验自己的统计学专业能力？如果光凭STAT101告诉你的东西，你还差的远呢。 如果你掌握了真相，你就不需要统计学了。 http://bit.ly/quaesita_savvy 《Incompetence, delegation, and population》： 如果决策者技能不过关，那么整个统计项目注定会失败。 什么时候统计学家应该和决策者撕逼，什么时候应该顺从指示呢？ 如果你希望用数据说服他人，你就必须摒弃严谨，绘制漂亮的图表 相关报道： https://towardsdatascience.com/data-science-conversation-starters-84affd2347f6