Browse Items (2832 total)

• Book Chapter

  Visual-audio fusion in multimedia content analysis

  The analysis of multimedia material has grown in importance due to the rapid expansion of digital media. Exploiting the combination of auditory and visual modalities for improved comprehension and interpretation of multimedia material has gained popularity in recent years. An extensive review of the methods, strategies, and uses of visual-audio fusion in multimedia content analysis is provided in this chapter. Combining auditory and visual modalities provides a number of benefits over single-modal analysis, such as increased robustness, deeper semantic comprehension, and better user experience. This chapter investigates a variety of fusion approaches, from late combination at the decision near to early synthesis at the feature nearby. Besides, it studies sophisticated fusion methods that allow for efficient integraton of data across modalities, such cross-modal attention processes and multimodal deep learning. Also looks at several other areas, such as multimedia retrieval, event detection, sentiment analysis, and emotional computing, where visual-audio fusion has been used successfully. It dialogs about the difficulties and potential paths ahead for the area, including how to deal with modality inconsistencies, manage massive multimedia information, and create fusion models that are understandable. To sum up, visual-audio fusion presents new possibilities for comprehending and analyzing complicated multimedia data and has the potential to significantly advance multimedia content analysis. 2026 Elsevier Inc. All rights reserved.
• Book Chapter

  Case studies: multimodal applications in natural language processing

  This chapter explores the incorporation of natural language processing (NLP) with multimodal information sources, including text, speech, and visual information, towards the improvement of practical applications. NLP may very significantly enhance tasks such as sentiment analysis, image captioning, and cross-modal retrieval by combining these modalities. Two examples of deep learning approaches are neural networks and transformers, which are examples of critical approaches for developing robots that analyze and understand complex multimodal inputs. The chapter is full of case examples that illustrate how multimodal NLP can revolutionize many industries, including healthcare data analysis and voice-activated assistant development. These illustrations demonstrate how NLP can enhance user interactions and decision-making processes by offering deeper, more contextual insights. In fact, the chapter also covers issues and ways ahead of multimodal NLPas integrating data, handling faulty or missing data, and how to resolve ethical dilemmas. These ongoing changes will define future artificial intelligence systems with increased adaptability, intuitiveness, and applicability. 2026 Elsevier Inc. All rights reserved.
• Book Chapter

  Cognitive computing: merging modalities for human like artificial intelligence

  Artificial intelligence (AI) has transformed with cognitive computing, which integrates different modalities such as vision, language, and reasoning to mimic human thought processes. Cognitive computing systems can recognize patterns, understand natural language, and make complex decisions by integrating these modalities. As a result of the interaction between machines, neural networks, and natural language processing, large amounts of data are analyzed, learning continuously from their interactions. As a result of this multimodal integration, the system is able to comprehend and interpret human communication with greater accuracy and context knowledge. Cognitive computing has made significant advances by processing and synthesizing information from a variety of sources, enabling a more holistic understanding of complicated situations. For instance, these systems can better understand context when visual data is combined with textual information. Using cognitive computing to analyze medical images, patients' histories, and clinical notes, healthcare professionals can find it especially helpful in diagnosing patients and planning treatment. As a result of cognitive computing, we can create systems that not only perform specific tasks but also mimic human cognitive functions, so that we can make better decisions. Human-like AI has the potential to revolutionize various industries with intelligent, context-aware solutions that increase productivity and decision-making. The advancement of cognitive computing has made it possible for humans and machines to communicate more intuitively and efficiently, bridging the gap between them. 2026 Elsevier Inc. All rights reserved.
• Book Chapter

  Multimodal learning for autonomous systems and robotics

  The realm of autonomous systems and robotics is experiencing a paradigm shift driven by the integration of advanced artificial intelligence (AI) techniques and multimodal learning approaches. This abstract explores the latest advancements and research topics that are propelling the field toward more intelligent, efficient, and versatile autonomous systems. Multimodal learning leverages multiple sensory inputs to enhance the perception and decision-making capabilities of autonomous systems. This involves the integration of visual, auditory, tactile, and other sensory data to form a coherent understanding of the environment. Deep learning techniques, such as multimodal neural networks and crossmodal embeddings, play a pivotal role in this integration, enabling the system to learn joint representations and improve robustness in perception under varying conditions. Computer vision remains a cornerstone of autonomous systems, with advancements in techniques such as real-time object detection, tracking, and high-resolution image synthesis through generative adversarial networks. Vision-based reinforcement learning is also gaining traction, enabling systems to learn from visual inputs and improve their decision-making processes in dynamic environments. The integration of advanced sensors, including high-resolution light detection and ranging, radio detection and ranging, and event-based cameras, enhances the capability of autonomous systems to perceive their surroundings accurately. Multisensor data fusion, using methods like Kalman and particle filters, ensures robust perception even in adverse conditions, providing a comprehensive view of the environment. Innovations in actuation and control systems are fundamental for the development of responsive and adaptive robots. Soft robotics, inspired by biological systems, offers new possibilities in design, modeling, and control. Hybrid control systems facilitate the coordination of multimodal actuation, enhancing the robots versatility and performance. The deployment of high-performance embedded systems, incorporating heterogeneous computing architectures (CPU-GPU-FPGA integration), is vital for real-time data processing and decision-making. Neuromorphic computing and AI hardware accelerators provide low-power solutions that are crucial for the efficiency of autonomous systems. Techniques for uncertainty estimation, outlier detection, and anomaly detection are essential for maintaining system reliability. Advanced robotic perception and cognition, combined with cognitive architectures for autonomous reasoning, enable systems to operate safely in complex and dynamic environments. The interface between humans and robots is evolving, with a focus on multimodal human-robot interaction. Learning from human demonstrations and ensuring safety and trust in human-robot teams are critical areas of research, promoting effective collaboration between humans and robots. Advanced simulation techniques, including high-fidelity physics-based simulations and domain randomization, are employed to test and validate autonomous systems. Virtual reality and augmented reality provide immersive environments for training and testing. Real-time simulation and hardware-in-the-loop testing ensure the robustness and reliability of autonomous systems before deployment. Ethical AI and autonomous decision-making frameworks are being developed to address these issues. Privacy-preserving machine learning techniques and cybersecurity measures are essential for protecting sensitive data and ensuring the security of autonomous systems. This comprehensive overview underscores the rapid advancements and multifaceted nature of multimodal learning and autonomous systems, heralding a new era of intelligent and adaptive robotics capable of transforming numerous industries and improving the quality of human life. 2026 Elsevier Inc. All rights reserved.
• Book Chapter

  Deep learning architectures for multimodal fusion

  The advancement in technology during the recent years has provided deep learning technology as an emerging and powerful paradigm which can be used for processing and understanding complex data across various domains. Multimodal fusion is integrating the information that is collected from various sources or modalities, which requires a comprehensive understanding of data like autonomous driving, medical diagnosis, etc. In this chapter, we will explore the various advanced deep learning architectures that have been specially designed based on the multimodal fusion. The various challenges that are being faced in multimodal data, which include heterogeneity, noise, reliability of data, etc. Various deep learning architectures that are built to address the various challenges, like convolutional neural networks, recurrent neural networks, are reviewed, and the suitability of the fusion strategies is highlighted. The various techniques that are used for combining the information from disparate modalities, like early fusion, late fusion, and hybrid approaches, are also discussed with their pros and cons. Various real-time applications in the field of healthcare, multimedia, robotics, etc., are demonstrated based on the impact of the architectures. Finally, the potential of deep learning architecture based on the revolutionary multimodal fusion will be discussed. 2026 Elsevier Inc. All rights reserved.
• Book Chapter

  An introduction to multimodal data representation

  The contemporary digital epoch is characterized by a radical transformation of data representation methodologies that imply increased intricacy as well as an enlarged bulk of data. An unimodal approach focusing on judicious data types, considered in isolation, was the earlier norm. The emphasis was on structured data, which had the advantage of being arranged systematically within relational databases and entity-relationship frameworks. This facilitated efficient data management. With the introduction of the internet and digital communication, such unstructured data as textual content, images, and audio began to be placed up front. But unimodal techniques were not adequately equipped to manage the intricate and interconnected nature of real-world phenomena. The welcome result was the development of multimodal data representation methodologies, which constitute a sophisticated paradigm that integrates data from such varied sources as text, images, audio, video, and sensor data. This results in a more holistic comprehension of complex scenarios. Distinct attributes and inherent challenges characterize each modality. To exemplify, text data need advanced natural language processing strategies to comprehend context and semantics; Image data necessitate methodologies well versed in managing spatial features and elevated dimensionality; audio data requires concentration on temporal patterns and noise; video data, on the contrary, integrates these complexities, leading to efficient processing techniques to accommodate its substantial volume and dynamic characteristics. The unsynchronous and heterogeneous sensor data complicate the integration of diverse data streams. Sophisticated fusion techniques, that is, early fusion, late fusion, and hybrid fusion, capable of integrating features from various modalities, are employed to mitigate the challenges faced by multimodal data representation. It increases interpretative insights and precision. The deep learning technologies, such as convolutional neural networks for image analysis, recurrent neural networks for sequential data processing, and attention mechanisms, have led to advancements in this domain. These models have become competent in recognizing complex patterns across modalities. Naturally, they bring about significant progress in domains such as health care, autonomous systems, multimedia processing, and natural language comprehension. This chapter explores the historical background of data representation, right from the beginnings in unimodal to its advancement in multimodal. The unique characteristics and challenges associated with each modality are scrutinized; Fusion techniques alongside contemporary deep learning models are examined; and underscore real-world applications, which are effective examples of the transformative potential of multimodal data representation. The chapter also emphasizes the necessity of escalating these methodologies in an increasingly data-centric world. It lays the foundation for advancements in the future with the goal of overcoming existing limitations and enlarging the scope of multimodal applications. 2026 Elsevier Inc. All rights reserved.
• Book Chapter

  Introduction to multimodal learning and heterogenous data

  With the rising advancements in computation, technology, and many innovative evolutions coming into play, multimodal learning is one of the most rapidly growing fields within the domain of artificial intelligence and Machine Learning. It mainly focuses on integrating information from multiple sources called "modalities," allowing the systems to utilize the varieties of data to furtherenhance their understanding and performance. These so-called modalities make use of various types of data in the form of text, images, audio, and sensor readings. They are able to process complex information due to these modalities and thus provide more insightful results for the tasks that they are assigned. Another important aspect of multimodal learning is heterogeneous datadata that differs significantly in structure, format, and origin. This type of data falls mainly into three categories, comprising structured data, which is quite organized and therefore easy to locate or search, as in the case of the database records. Then comes unstructured data characterized by the free form, which comprises mainly social media posts, videos, and images. In addition, it has been possible to separate semistructured data. It incorporates some features of being ordered, like the metadata included in XML or JSON files; however, a fixed schema does not apply. The understanding of the kind is important because each type calls for a different problem, and each type poses new opportunities in analysis. Handling the heterogeneous data effectively is all the more important because the said system will be fed heterogeneous data, and if its combination and analysis go reasonably logically, it is expected to be a source for multimodal systems. The ability to merge structured, unstructured, and semistructured data improves performance across a wide range of tasks, including but not limited to common applications like image recognition, sentiment analysis, and decision-making processes in autonomous systems. For example, in the multimodal learning case, it would be beneficial for the system that learns customer feedback to merge textual reviews, audio recordings of customer interactions, and visual data from product images. It has been known to yield a much clearer picture of what customers really want and how they actually behave. This chapter introduces notions of multimodal learning as well as heterogeneous datatheir characteristics, types, sources, and practical usage. It will attempt to establish a basic understanding of these two concepts in relation to each other in order to support more advanced applications through machine learning. In a review of the possible compositions between multimodal learning as well as heterogeneous data, the chapter will introduce their importance regarding the creation of intelligent systems that can address complex, intricate tasks across differing fields. As we enter the data age, with multiple sources churning out data at unprecedented rates that appear to have no bounds, integration of multimodal learning with heterogeneous data cannot be ignored. This will be vital for coming up with flexible yet useful applications to real-world problems. This region is promising for systems that perceive, interpret, and respond to the variability of information in a fashion similar to human reasoning and decision-making. Future application of artificial intelligence in the life of man will result from continuous research in the areas of multimodal learning and heterogeneous data. 2026 Elsevier Inc. All rights reserved.
• Book Chapter

  AI- and ML-driven intelligent design of digital twins

  Digital twins (DTs), or virtual copies of real-world systems, have changed and improved many industries in terms of monitoring, analysis, and optimization in real time. Artificial intelligence (AI) and machine learning (ML) together have significantly enhanced the functionalities of DTs so that they become more efficient and versatile decision-making and process improvement tools. The production and application of DTs most importantly rely on AI and ML. Such technologies allow integration and analysis of very large amounts of data from various sources and provide an overview of the physical system. The personnel involved in the company may gain deeper insights into overall business processes and identify changes that would remain unknown when applying the traditional methods, based on the employment of the capabilities of AI-based integration and data analysis. An essential example of ML use cases in the framework of DTs is predictive maintenance. Any ML algorithm can resort to historical data and immediate sensor data to predict potential failures of application equipment and propose a repair schedule, significantly reducing operational downtime and refining the distribution of resources. The AI-powered optimization and simulation methods can give organizations the possibility to consider numerous scenarios and identify the most effective ways to resolve complex issues. The DTs are AI-enabled and can detect and decide on the fly, which allows them to react to changing conditions instantly and prevent some of the issues before they happen. In addition, AI-powered predictive analysis and risk management allow the firms to go a step ahead and address the potential problems in advance by developing effective risk reduction strategies. DTs are mainly constructed with AI and ML in various industries. In the context of manufacturing and Industry 4.0, DTs play an important role in optimizing production and increasing the quality control standards. Urban planners use the DTs to strategize building smart cities, while healthcare professionals use them for medical diagnosis and planning. In the aerospace and auto industries, DTs are beneficial in improving the product development, testing, and other maintenance processes. This chapter focuses on the smart creation of DTs with the help of AI and ML technology. The discussion will also dive into the complex mechanism behind building advanced, digital replicas of physical systems, particularly the support of the AI and ML in the advancement of their usefulness and precision. The chapter begins with the discussion of the role of data integration and analysis in the creation of a DT. This section shows how AI and ML algorithms facilitate the seamless combination of different sources of data into one and reach a much more dynamic and detailed similitude of the physical member. The chapter illustrates how these technologies can convert raw information into valuable information, which makes the DT capable of replicating the real-world situations and behaviors quite dramatically. Moreover, the chapter addresses the profound role of AI and ML in the optimization and simulation of DTs. We observe how these advanced technologies are able to give more precise predictions and process the decision-making and testing of even complex scenarios. The chapter focuses on how AI-enabled optimization methodologies and AI-based simulations driven by ML are broadening the opportunities of DTs, thus driving innovation in a number of verticals. 2026 Elsevier Inc. All rights reserved.
• Book Chapter

  Pangenomics for developing viral disease-resistant plants: Harnessing synergenetic pangenomics for advanced viral disease resistance in crops

  Agriculture plays a pivotal role in the global economy, but it also faces several significant challenges. One major challenge is the necessity to sustainably provide food for a rapidly expanding population. Additionally, agriculture must withstand the threat of different disease-causing pathogens, including various microorganisms like bacteria, viruses, and fungi. Viral diseases significantly impact crop growth, vitality, and yields, posing substantial threats to global agriculture. Despite their compact genomes, the viruses still lead to major losses in crop production. The study of plant viruses began over a century ago with the tobacco mosaic virus discovery, marking the inception of plant virology. Since then, hundreds of viruses have been identified, many of which induce severe damage to various crops. Viruses exhibit extensive genetic diversity, with RNA serving as the predominant genetic material. This genetic diversity profoundly influences their reproductive cycles and lifestyles, necessitating innovative strategies for disease management. This chapter discusses different pathogenic viruses along with various approaches to pest management, including the emergence of pangenomics as one of the advanced tools for understanding the diversity of genes among plant populations. Pangenomics encompasses both function-based and structure-based approaches, elucidating the core and dispensable genomes that contribute to discovering many agronomic traits related to disease resistance mechanisms, crop yield, flowering time, etc. Integrating the information from pangenomics into plant virology can revolutionize agriculture by enhancing crop production and crop yield, and also engineering viral disease-resistant plants to ensure global food security. 2025 Elsevier Inc. All rights reserved.
• Book Chapter

  Pangenomics for developing salinity stress-tolerant plants

  Soil salinity is a critical agricultural challenge that significantly reduces crop productivity and threatens global food security. With approximately 20% of irrigated land affected by salinity, innovative strategies are essential to develop salinity stress-tolerant crops. The field of pangenomics, a comprehensive approach to studying the genetic diversity within species, has immense potential to address this issue. Pangenomics includes core genomes, spanning the entire genus, and accessory genomes, which are species-specific, thus capturing the full spectrum of genetic variation. This approach enables the identification of novel genes and alleles associated with salinity tolerance, providing a robust foundation for genetic improvement programs. Salinity stress has a profound molecular and physiological impact on plants with multiple phenotypic manifestations, such as stunted growth, lesser crop yield, and reduced reproductive success. To solve these issues, advanced sequencing technologies and bioinformatics tools used in constructing and analyzing pangenomes play a crucial role. This chapter goes into detail about techniques such as comparative genomics and genome-wide association studies (GWAS), which are important for their effectiveness in identifying salinity tolerance genes. Functional validation methods, including CRISPR/Cas9 and RNA interference (RNAi), have also been discussed. This chapter highlights case studies on crops like rice and wheat to demonstrate the practical applications of pangenomics in developing salinity-tolerant varieties. Furthermore, by addressing the challenges and future directions in the field, one can emphasize the need for integrating multiomics data and refining analytical methods. Such an approach can help guide future research and breeding efforts toward sustainable agricultural practices and enhanced global food security. 2025 Elsevier Inc. All rights reserved.
• Book Chapter

  Upconversion nanoparticles for detection of small biomolecules and ions

  In recent years, upconversion nanoparticles (UCNPs) have resulted in substantial advances in the area of sensitive and selective detection of small biomolecules and ions. UCNPs possess a unique optical property known as lanthanide upconversion luminescence. This phenomenon enables them to absorb low-energy light from the near-infrared region and subsequently emit higher-energy light in the visible or ultraviolet part of the spectrum. This process, often referred to as the anti-Stokes shift, resists the conventional fluorescence behavior by absorbing lower-energy photons, followed by emission of higher-energy photons. This chapter provides a comprehensive overview of the mechanism of upconversion fluorescence and explores the properties of UCNPs. It then delves into the applications of UCNPs in detection of biomolecules like proteins and amino acids, nucleic acids, and tumor biomarkers, thus facilitating early diagnosis and patient care. Additionally, UCNPs are useful in the detection of ions by altering their surface chemistry to bind selectively to target ions, expanding their utility in environmental monitoring and chemical analysis. 2026 Elsevier Ltd. All rights reserved.
• Book Chapter

  CRISPR plants against heavy metal and metalloid stresses: Methods and applications

  Metal and metalloid stresses present substantial obstacles for plants, exerting an impact on agricultural productivity as well as environmental well-being. The assimilation and accumulation of heavy metals, for example, cadmium and lead, along with metalloids such as arsenic, has the potential to affect the growth and development of plants detrimentally. To address these stresses, innovative biotechnological approaches involving genetic engineering, clustered regularly interspaced short palindromic repeat (CRISPR) technology, phytoremediation, nanobiotechnology, and panomics are required to augment plant-metal tolerance. The dawn of CRISPR technology has revolutionized the field of plant biotechnology with its unparalleled precision in enhancing a plants capability to tolerate heavy metal and metalloid stresses. This present review aims to discuss the various applications and techniques of CRISPR technology in the enhancement of metal stress-tolerant capability in plants. It places special attention on the technologys critical role in abbreviating the detrimental effects of metal stress on plant growth and productivity. CRISPR technology enables researchers to engage in precise gene editing, thereby allowing for the deliberate targeting of specific genes associated with metal transport, detoxification, and stress responses in plants. By manipulating these key genes, CRISPR facilitates the creation of plant varieties that exhibit enhanced resilience to the challenges posed by heavy metal and metalloid stresses. In addition, this approach contributes to the advancement of agricultural sustainability and environmental stewardship by enhancing a plants ability to resist and overcome heavy metals contamination. Moreover, in the face of a changing climate landscape influenced by metal pollution challenges, the precise gene editing capabilities of CRISPR can be harnessed to engineer plants that possess heightened resilience to metal stress, thereby playing a vital role in ensuring food security and promoting sustainable agriculture. The review also underscores the pivotal role of CRISPR technology in shaping the future of research on plant stress tolerance and highlights its immense potential in addressing the evolving challenges associated with metal stress in plant systems. 2025 Elsevier Inc. All rights are reserved.
• Book Chapter

  CRISPR plants against heavy metal and metalloid stresses: Methods and applications

  Metal and metalloid stresses present substantial obstacles for plants, exerting an impact on agricultural productivity as well as environmental well-being. The assimilation and accumulation of heavy metals, for example, cadmium and lead, along with metalloids such as arsenic, has the potential to affect the growth and development of plants detrimentally. To address these stresses, innovative biotechnological approaches involving genetic engineering, clustered regularly interspaced short palindromic repeat (CRISPR) technology, phytoremediation, nanobiotechnology, and panomics are required to augment plant-metal tolerance. The dawn of CRISPR technology has revolutionized the field of plant biotechnology with its unparalleled precision in enhancing a plants capability to tolerate heavy metal and metalloid stresses. This present review aims to discuss the various applications and techniques of CRISPR technology in the enhancement of metal stress-tolerant capability in plants. It places special attention on the technologys critical role in abbreviating the detrimental effects of metal stress on plant growth and productivity. CRISPR technology enables researchers to engage in precise gene editing, thereby allowing for the deliberate targeting of specific genes associated with metal transport, detoxification, and stress responses in plants. By manipulating these key genes, CRISPR facilitates the creation of plant varieties that exhibit enhanced resilience to the challenges posed by heavy metal and metalloid stresses. In addition, this approach contributes to the advancement of agricultural sustainability and environmental stewardship by enhancing a plants ability to resist and overcome heavy metals contamination. Moreover, in the face of a changing climate landscape influenced by metal pollution challenges, the precise gene editing capabilities of CRISPR can be harnessed to engineer plants that possess heightened resilience to metal stress, thereby playing a vital role in ensuring food security and promoting sustainable agriculture. The review also underscores the pivotal role of CRISPR technology in shaping the future of research on plant stress tolerance and highlights its immense potential in addressing the evolving challenges associated with metal stress in plant systems. 2025 Elsevier Inc. All rights are reserved.
• Book Chapter

  Electrospinning of polyetheretherketone-based homopolymers and block copolymers

  Electrospinning involves the fabrication of ultrafine fibers, typically ranging in diameter from nanometers to micrometers. This process entails applying a high voltage to a polymer solution or melt, resulting in the production of fibers that can be collected on a designated surface. Polyetheretherketone (PEEK) is a semicrystalline linear polycyclic aromatic polymer with high thermal stability. It is a high-performance thermoplastic known for its mechanical strength, thermal stability, and chemical resistance. The rigid radiolucency, stable physicochemical properties, and biocompatibility of electrospun PEEK homopolymer fibers make them suitable reinforcements in composite materials, medical sutures, removable prosthetics, vertebral surgery, orthopedics, and scaffolds for tissue engineering. PEEK homopolymers offer a wide range of advantages; however, they have a high melting temperature, high viscosity in the molten state, and a low glass transition temperature. Blending PEEK with other polymers and the formation of block copolymers introduces an additional set of functionalities by combining the properties of PEEK and other polymers. PEEK block copolymers can be electrospun with tailored properties and diverse morphologies, resulting in enhanced processability and compatibility for broad applications, including medical implants, filtration membranes, and reinforcing materials. This chapter discusses the principles and parameters of electrospinning, the factors responsible for the electrospinning of PEEK-based homopolymers and block copolymers, issues such as solubility, spinnability, and related costs, and possible solutions for overcoming these issues. Various applications of electrospun PEEK homopolymers and block copolymers are also discussed in this chapter. 2026 Elsevier Inc. All rights reserved.
• Book Chapter

  Unveiling the root causes of diabetes using explainable AI

  Diabetes is a non-communicable wide spread disease across the world. To investigate the risky factors that are associated with diabetes, and to start early and customized treatment, researchers are fascinated to explore existing machine learning or deep learning models and to develop more reliable algorithms. The advancement in technology and the increase in world population is an enriching source to prompt and explore the factors that decide a person to be diabetic. Several algorithms and approaches are in place to address these factors but are lacking in emphasizing with more interpretable features which convinces patent to trust the medicine, treatment, and have meaningful conversation with the physicians and artificially intelligent systems. To encourage the participation of people with diabetes for customized treatment and considering societal needs, this chapter explores the possibility of Explainable Artificial Intelligence (XAI) in diabetes detection and figuring out the significant features that dominate diabetes. 2025 Elsevier Inc. All rights reserved.
• Book Chapter

  Explainable artificial intelligence in epilepsy management: Unveiling the model interpretability

  The field of epileptic seizure classification has witnessed significant advancements in the use of electroencephalogram (EEG) data for accurate and timely diagnoses. This study introduces a comprehensive framework for EEG-based seizure classification, encompassing data preprocessing and the application of machine learning techniques, specifically the supervised learning classifier known as Extreme Gradient Boosting (Xgboost). Machine learning methods have shown promising accuracy in binary classification tasks, particularly in distinguishing between seizure and healthy EEG signals. However, the need for a robust explanation of these results and decision-making processes is imperative for technical verification and clinical validation, especially for potential clinical applications. Explainable Artificial Intelligence (XAI) emerges as a critical component in addressing this need. In this chapter, we propose and discuss a binary classification model that leverages Xgboost to classify EEG signals as either Seizure or normal, a crucial aspect in epilepsy diagnosis. XAI techniques such as LIME (Local Interpretable Model-agnostic Explanations) and SHAP (Shapley Additive Explanations) are incorporated to elucidate the model's predictions. LIME offers localized interpretability by creating surrogate models for individual predictions, revealing the essential EEG features influencing each classification decision. Conversely, SHAP provides a global perspective on feature importance, shedding light on the collective impact of EEG features on classification outcomes. The synergy between LIME and SHAP enhances our understanding of the model's predictions and the intricate nuances within EEG data. This research highlights the transformative potential of LIME and SHAP in EEG-based seizure classification. The integration of XAI techniques not only enhances the transparency and interpretability of the model but also empowers clinicians and researchers to make more informed decisions, ultimately improving patient care and outcomes in epilepsy management. By bridging the gap between complex EEG data and actionable insights, this study marks a significant paradigm shift in the application of XAI techniques in medical diagnostics. It paves the way for a new era in epilepsy diagnosis and management, where advanced machine learning models guided by LIME and SHAP play a crucial role in revolutionizing healthcare practices. 2025 Elsevier Inc. All rights reserved.
• Book Chapter

  Tribological aspects of Al and Mg composites

  It is well known that the technical function of a large number of engineering components/parts depends on motion. However, the term motion here is not as simple as it sounds, because it comes with consequences in the form of friction and wear. Along with lubrication, the science that deals with friction and wear is known as tribology. Therefore, it is necessary to pay more attention to tribology and acquire knowledge on the tribological behavior of materials, as the tribological characteristics such as friction and wear have been causing poor efficiency in engineering structures, huge economic losses, and environmental impacts. One way of addressing these issues lies in the development of lightweight materials based on metals such as aluminum and magnesium. Although one cannot employ these metals in their pure form, but modification in their microstructure and properties can certainly address the needs required for tribological applications. Keeping this in mind, this chapter covers the properties of aluminum and magnesium metals, basic aspects of tribology and most importantly, the work carried out on the friction and wear behavior of aluminum- and magnesium-based composites. The importance of this chapter lies in promoting better knowledge of the tribological behavior of aluminum and magnesium composites, especially from a various wear parameters point of view. The influence of material composition and wear parameters on tribological behavior is covered with a follow-up section on numerical and optimization methods employed for predicting tribological characteristics. 2026 Elsevier Inc. All rights reserved..
• Book Chapter

  Raman spectroscopy: an introduction, instrumentation, and its applications in polymer composites and nanocomposites

  Raman spectroscopy, a nondestructive technique based on molecular vibrations, offers insights into molecular structures and interactions through the inelastic scattering of monochromatic light. This method facilitates the identification of chemicals by using unique molecular fingerprints. The ability of this technique to analyze samples in situ, in any form, is very advantageous. Over the years, improvements have been made in the sensitivity and resolution of Raman spectroscopy in instrumentation and data analysis, which has broadened its range of applications in chemistry, biology, and materials research. Raman spectroscopy has become a vital tool for applied research and basic sciences. In the area of composites and nanocomposites, it offers tremendous possibilities, such as material identification, phase separation, and defect analysis, reinforcement agent characterization, stress and strain analysis, crystallinity and orientation, and micromechanical deformation. 2026 Elsevier Ltd. All rights reserved.
• Book Chapter

  Blockchain Technology: Proof of Work vs Proof of Stake Consensus Mechanism

  The purpose of blockchain technology is to record transactions after they have been confirmed. Blockchain?s ability to guarantee decentralized, transparent transactions with solid security has increased the appeal of new virtual currencies. The consensus mechanism, one of the key components of a blockchain network?s operation, plays a crucial role in a decentralized system. The debate surrounding an adequate consensus method has attracted significant attention, particularly in comparing Proof of Work (PoW) and Proof of Stake (PoS). This chapter comprehensively examines the Proof of Work (PoW) and Proof of Stake (PoS) algorithms and compares other consensus algorithms utilized in contemporary blockchain systems. 2026 Elsevier Inc. All rights are reserved, including those for text and data mining, AI training, and similar technologies.
• Book Chapter

  Business Resilience

  Business resilience has emerged as one of the key elements for ensuring the survival and success of the organization in the 21st century which has been marked by socio-economic crisis, notable disruptions, and tumultuous market shifts. The term Business resilience is defined as the capacity of an organization to navigate through adversity, adapt to changing conditions, and emerge stronger from setbacks. Financial, operational, organizational, digital, and supply chain resilience are among the measures that resilient organizations invest on. Companies that are financially strong put careful money management first and protect shareholders wealth. Organizational resilience promotes flexibility and ongoing learning, whereas operational resilience guarantees the continuation of vital business operations. While supply chain resilience concentrates on minimizing disruptions, digital resilience entails strong cybersecurity measures. Effective leadership is essential for managing uncertainty, and a flexible strategy for enhancing resilience guarantees continuous adjustment. In the end, corporate resilience is about overcoming hardship and integrating resilience as a strategic requirement for sustained success in a changing business climate. 2026 Elsevier Inc. All rights are reserved, including those for text and data mining, AI training, and similar technologies.