Generative AI vs LLM: Understanding the Key Differences
Have you ever encountered these terms and wondered what the difference is? You're not alone! Generative AI and LLMs are both hot topics in the world of artificial intelligence. But they tackle specific tasks within the broader field. In this blog, we'll break down the key distinctions between generative AI vs LLM, so you can walk away with a clear understanding of what each one does and how they're revolutionizing different industries. What is Generative AI? Generative AI is like a smart robot that can create new things on its own after learning from lots of examples. It's like teaching a robot to paint by showing it thousands of paintings; and then it starts creating its own art, even though no one told it exactly what to paint. This robot uses what it has learned to come up with new pictures, stories, or even music that no one has seen or heard before. It's pretty cool because it can help come up with new ideas or solve problems by thinking outside the box, using what it learned from all the examples it was given. What are LLMs? LLMs are like the digital brains behind the AI systems that can read, understand, and generate human-like text. They are built using a type of AI known as deep learning, where a model learns from vast amounts of text data. The key innovation in LLMs is the use of transformer architecture; which helps these models understand the context and relationships in language by processing words in sentences all at once; rather than one after another. This makes them incredibly powerful at tasks like writing articles, translating languages, and even creating code from simple prompts. LLMs are essentially vast neural networks that have been trained on internet-scale data sources. They can have hundreds of billions of parameters, which are the elements of the model that get adjusted during training to help the model make more accurate predictions. When you interact with an LLM, what you see is the output of this incredibly complex network making predictions on what word comes next, based on the context provided by the input it receives. > Related: Top 10 Generative AI Tools You Should Know for 2024 Generative AI vs LLM: What Are The Differences? Generative AI, LLM both play significant roles in the field of artificial intelligence but serve different purposes and are based on distinct principles. Generative AI is a broad term encompassing a variety of AI technologies focused on creating new content across different formats such as text, images, music, and more. It utilizes deep learning and probabilistic modeling to generate diverse and lifelike outputs. For example, Generative AI can be used to create realistic speech, generate new music compositions, or produce photorealistic images. This versatility allows it to cater to creative endeavors across multiple domains, making it a powerful tool for innovation On the other hand, LLMs are specialized AI systems designed to understand and generate human-like text. They are trained on extensive text…
Top 10 Best Examples of Generative AI For 2024 You Should Learn About
Have you heard the buzz about generative AI, but are unsure exactly what it is or how it's being used? This revolutionary technology is rapidly changing the game across various industries, and Singapore is at the forefront of this exciting development. In this blog, we'll be unveiling the wonders of generative AI. First, we'll provide a clear and concise explanation of the generative AI definition. Then, we'll embark on a fascinating journey through the top 10 examples of generative AI that are making waves in 2024. From creating mind-blowing artwork to composing captivating music, these examples of generative AI will showcase the immense potential this technology holds. So are you ready? Let’s get started! The Basic of Generative AI Examples To start understanding "What are the most well-known types of generative AI?" let's first break down what generative AI is. Imagine a world where technology evolves rapidly, creating new ways for people to interact with smart machines. These machines are smart because they learn and think using something called artificial intelligence, or AI for short. Generative AI is a special kind of AI that uses learning algorithms to create new things like text, videos, pictures, or even computer code for various uses. When we talk about the top examples of generative AI, it's all about how these systems use rules and patterns they learn from the data they're given. Currently, the two big stars in the generative AI world are transformer-based models and Generative Adversarial Networks, also known as GANs. Transformer-based models are like internet sponges; they soak up info and can generate different kinds of text. GANs, meanwhile, are the artists, creating new multimedia and visual content from existing images and text. What Are Foundation Models in Generative AI? Foundation models in generative AI refer to large-scale models that serve as a basic framework or starting point for a wide range of AI applications. These models are trained on vast amounts of data, enabling them to understand and generate human-like text, images, audio, and even code. The term "foundation" signifies their versatility and capability to be adapted or fine-tuned for specific tasks or domains, despite being trained on general data. For example, a foundation model trained on a diverse dataset of internet text can be fine-tuned to write poetry, answer questions, or even generate code snippets, demonstrating its broad applicability. These models leverage advanced machine learning techniques, such as deep learning and transformer architectures, to capture complex patterns and nuances in the data they are trained on. This allows them to generate outputs that are often indistinguishable from human-created content. Why Should You Learn About Examples of Generative AI? To understand how generative AI models shape the digital world, it's crucial to explore their workings. These AI models are great at making new and unique content in various forms. Plus, they get better by learning from human language and complex patterns through neural networks. This means they can take in lots of information and give back useful results. For…
10 Best Software Development Company in Singapore For 2024
In today's digital age, finding the right software development company is paramount for any business looking to thrive. Singapore, a hub for innovation and technology, boasts a wealth of talented software development companies. But with so many options, choosing the perfect partner can feel overwhelming. This blog simplifies your search! We've compiled a comprehensive list of the top 10 software development companies in Singapore for 2024. Based on expertise, experience, and industry reputation, these companies are proven leaders in crafting exceptional software solutions. Whether you need a mobile app or anything in between, this guide will connect you with the ideal software development company to bring your vision to life. Now, let’s check it out! AMELA Technology Location: Vietnam Year of Establishment: 2019 Website: https://amela.tech As a leading software development company in Singapore, AMELA has carved out a significant niche in the market. Known for its adeptness in handling complex software projects and delivering tailor-made solutions, AMELA excels in areas such as AI, IoT, and blockchain technology. Our commitment to innovation and customer satisfaction places us at the forefront of the industry. Innovate Software Solutions Location: Singapore Year of Establishment: 2013 Website: https://innovatesolution.com/ This company is celebrated for its cutting-edge software development services that cater to a wide range of industries, including finance, healthcare, and e-commerce. Their proficiency in agile methodologies ensures that they consistently deliver projects on time and within budget, making them one of the best software development companies in the region. TechFrontier Specializing in mobile and web application development, TechFrontier stands out for its user-centric designs and robust backend systems. Their dedication to creating seamless digital experiences places them among the top software development companies in Singapore. CodeCraft Technologies Location: India Year of Establishment: 2018 Website: https://www.codecrafttech.com/ With a strong emphasis on innovation and quality, CodeCraft Technologies offers comprehensive software development services, from concept to deployment. Their expertise in cloud solutions and big data analytics makes them a go-to software development company for businesses looking to scale. Digital Dynamics Location: CA Year of Establishment: 1974 Website: https://www.digitaldynamics.com/ As a best software development company, Digital Dynamics prides itself on its bespoke software solutions that drive business growth. Their team of experienced developers and strategists work closely with clients to ensure that each project surpasses expectations. NextGen Innovations Location: Jaffna Year of Establishment: 2023 Website: https://app.nextgeninovations.com/ Known for its agile approach and flexible solutions, NextGen Innovations provides top-notch software development services across various platforms. Their commitment to staying ahead of technology trends makes them a preferred partner for forward-thinking businesses. FusionWorks Location: Chisinau Year of Establishment: 2011 Website: https://fusion.works/ FusionWorks combines creative design with technical expertise to deliver exceptional software products. Their ability to merge aesthetics with functionality has established them as a leading software development company in Singapore. AlphaTech Solutions Location: Singapore Year of Establishment: 2005 Website: https://alphatech.ws/ This company is renowned for its strategic IT consulting and software development services. AlphaTech Solutions helps businesses transform their operations through innovative software solutions, earning its place among the best…
25 Best Machine Learning Projects in 2024 You Should Notice
The world of machine learning is constantly evolving, offering exciting new possibilities every year. Whether you're a seasoned data scientist or just starting your journey with algorithms, engaging in machine learning projects is a fantastic way to hone your skills and stay on top of the latest trends. In this blog, we’ll delve into the top 25 exceptional machine learning projects that are perfect for 2024. We've curated a diverse range of projects, encompassing beginner-friendly options to more advanced challenges, ensuring there's something for everyone. So now, let’s get started! Advanced Healthcare Monitoring Systems Among the standout machine learning projects are those aimed at developing sophisticated healthcare monitoring systems. These systems use wearable devices and IoT technology to continuously collect and analyze health data in real-time, enabling early detection of anomalies and potentially life-threatening conditions, thus revolutionizing proactive healthcare management. Fitbit and Apple Watch have introduced features that monitor heart rates, detect irregularities, and even conduct ECGs; allowing users to proactively manage their heart health. Next-Generation Autonomous Vehicles Machine learning projects in autonomous driving focus on enhancing V2V and V2I communication. This enables cars to make safer and more informed decisions by understanding their entire surroundings. Hence, significantly reducing accidents and improving traffic flow. Waymo's autonomous taxis in Phoenix are a prime example, where the cars navigate urban environments, showcasing advancements in autonomous driving technologies. Global Deforestation Tracking Platforms Machine learning projects dedicated to environmental conservation are employing satellite imagery and AI to track deforestation activities globally in real-time. These platforms can identify illegal logging activities, monitor forest regeneration efforts, and provide actionable data to governments and conservation organizations. Global Forest Watch utilizes satellite imagery and AI to provide real-time data on deforestation, helping organizations and governments to take timely action against illegal logging. AI-Powered Personalized Medicine In the realm of personalized medicine, machine learning projects are leveraging genomic data and patient history to tailor medical treatments. By understanding the genetic makeup of individuals, these projects aim to predict the efficacy of drugs, minimize adverse reactions, and develop personalized treatment regimens, marking a new era in healthcare. Tempus is using AI to analyze clinical and molecular data to personalize cancer treatments, leading to more targeted and effective therapy options for patients. Intelligent Energy Management Systems Machine learning projects in energy management are focusing on creating intelligent systems that optimize energy consumption in real-time across various sectors, including residential, commercial, and industrial. These systems can predict peak demand times, adjust energy distribution, and incorporate renewable energy sources more effectively, leading to significant energy savings and reduced carbon footprints. Google's DeepMind applied machine learning to reduce the amount of energy used for cooling at Google's data centers by 40%, showcasing significant energy efficiency improvements. High-Precision Agricultural Robots Agricultural machine learning projects are introducing robots equipped with AI and machine-learning algorithms capable of performing tasks with unprecedented precision. These robots can identify individual plants, assess their health, and make decisions on the spot, optimizing crop management and reducing the need for chemical pesticides…
Top 15 Machine Learning Applications You Need To Know
Machine learning applications are no longer the stuff of science fiction. They're rapidly transforming our world, from the way we shop online to how doctors diagnose diseases. In this blog post, we'll delve into the top 15 machine learning applications that you need to know about. We'll explore how these applications are used in various industries and impact our daily lives. Are you ready? Let’s get started! What is Machine Learning? Machine learning is a subset of AI that provides systems the ability to learn automatically; and improve from experience without being explicitly programmed. It revolves around using algorithms and statistical models to enable computers to perform specific tasks by identifying patterns and inferring insights from data. At its core, machine learning is about understanding data and statistics. It makes predictions or decisions based on that data and continuously optimizes the learning process to make more accurate predictions over time. What are Some Machine Learning Techniques? Machine learning encompasses a variety of techniques and algorithms, each suited for different types of data and various learning tasks. These techniques can broadly be categorized based on the learning style. Here are some of the key machine-learning techniques: Supervised Learning Linear Regression: Used for predicting a continuous value. For instance, predicting house prices based on various features like size, location, and number of bedrooms. Logistic Regression: Used for binary classification tasks, such as spam detection in emails. Decision Trees: A flowchart-like structure where each internal node represents a "test" on an attribute. Each branch represents the outcome of the test, and each leaf node represents a class label. Random Forests: An ensemble method that uses multiple decision trees to improve prediction accuracy and control over-fitting. Support Vector Machines (SVM): A powerful classification technique that works well in high-dimensional spaces. This is ideal for cases where the number of dimensions exceeds the number of samples. Neural Networks: Inspired by the structure and function of the brain. These networks are composed of layers of interconnected nodes and are particularly powerful for complex problems like image and speech recognition. Unsupervised Learning Clustering: Used to group a set of objects in such a way that objects in the same group are more similar to each other than to those in other groups. Principal Component Analysis (PCA): A dimensionality reduction technique used to reduce the dimensionality of large datasets. Hence, increasing interpretability while minimizing information loss. Autoencoders: A type of neural network used to learn efficient codings of unlabeled data; typically used for dimensionality reduction and feature learning. Semi-Supervised Learning Combines a small amount of labeled data with a large amount of unlabeled data during training. Semi-supervised learning is particularly useful when acquiring a fully labeled dataset is expensive or time-consuming. Reinforcement Learning Q-Learning: An algorithm that learns the quality of actions, telling an agent what action to take under what circumstances. Deep Reinforcement Learning: Combines neural networks with Q-learning, allowing the system to make decisions from unstructured input data without manual feature extraction. > Related: 10 Outstanding…
A Complete Guide to Regression in Machine Learning for Beginners
Have you ever wondered how businesses predict future sales or how weather forecasts anticipate tomorrow's rain? The answer lies in a powerful machine-learning technique called regression in machine learning. This comprehensive guide is designed specifically for beginners who are curious about the world of regression in machine learning. We'll break down the complex concepts into easy-to-understand steps, guiding you through the fundamentals of this essential tool. What is Regression in Machine Learning? Regression in machine learning is a type of predictive modeling technique that investigates the relationship between a dependent variable and an independent variable. This technique is employed to predict the value of the target variable based on the input values of the independent variables. The essence of regression in machine learning lies in its ability to model and analyze the relationships between variables; enabling predictions of continuous outcomes. The process of regression involves the construction of a regression model, which is essentially an equation that represents the relationship between the variables. This model is used to predict the value of the dependent variable for any given set of independent variables. The accuracy and performance of regression models are assessed through various metrics such as MSE, RMSE, and R-squared value. These metrics provide insights into the model's predictive capabilities and how well it fits the data. Benefits of Adopting Regression in Machine Learning Adopting regression in machine learning offers numerous benefits that significantly enhance predictive modeling capabilities in various domains. The flexibility and efficiency of regression models make them indispensable tools for data scientists and analysts. Here are some key benefits of adopting regression in machine learning: #1 Predictive Power Regression in machine learning is renowned for its predictive accuracy, especially when relationships between variables are well understood and data is abundant. This allows for precise forecasting and estimation, essential in fields like finance for stock price predictions. #2 Quantitative Analysis One of the primary advantages of regression in machine learning is its ability to quantify relationships between variables. This quantitative insight is invaluable for understanding how changes in independent variables influence the dependent variable. Hence, facilitating better decision-making and strategy formulation. #3 Identifying Trends Regression is excellent for identifying and understanding trends and relationships within data. This capability is crucial for exploratory data analysis. It allows researchers and analysts to uncover underlying patterns and relationships that may not be immediately apparent. #4 Ease of Interpretation Many regression models, particularly linear regression, offer the benefit of ease of interpretation. The coefficients of the model can be directly interpreted as the effect of each independent variable on the dependent variable. Therefore, making it easier for stakeholders to understand and act upon the model's findings. #5 Cost-Effectiveness Implementing regression can be highly cost-effective, especially when compared to more complex machine learning models. Simple regression models require less computational resources and can often provide sufficiently accurate predictions for many practical applications. #6 Risk Assessment Regression in machine learning is widely used in risk management to assess the potential risks associated with various…
Beyond the Hype: Understanding the Power of Cloud Computing Architecture
Cloud computing has become an undeniable force in today's tech landscape. But for many, the term itself can feel shrouded in mystery. What exactly is cloud computing architecture, and how can it benefit your business? This blog will peel back the layers and reveal the power that lies beneath the hype. We'll delve into the core components of cloud computing architecture, explore its various deployment models, and showcase the real-world advantages it offers businesses of all sizes. Now, let’s get started! What is Cloud Computing? Cloud computing is a technology that allows us to access and use computing resources over the internet, often referred to as "the cloud". It offers the ability to scale and provide flexible resources, enabling users to pay only for the cloud services they use. Therefore, this can help lower operating costs, run infrastructure more efficiently, and scale as business needs change. What is A Characteristic of Cloud Computing? A key characteristic of cloud computing is its scalability and rapid elasticity. This feature allows cloud services to be readily scaled up or down based on demand. Scalability ensures that applications can handle growing amounts of work efficiently; or that resources are available to meet a sudden spike in demand, such as increased web traffic or computational requirements. Rapid elasticity, on the other hand, refers to the ability of the system to quickly expand or reduce resources as needed. It often automatically, and ensuring that the available resources match the current demand as closely as possible. This characteristic is crucial for optimizing performance and managing costs in a cloud computing environment. As a result, it provides flexibility and efficiency that traditional computing infrastructures typically cannot match. What is Cloud Computing Architecture? Cloud computing architecture is a fundamental aspect of developing in the cloud. It encompasses the design and interconnection of all essential components and technologies needed for cloud computing. Transitioning to the cloud presents numerous advantages over traditional on-premises setups, including enhanced agility, scalability, and cost savings. Initially, many businesses may adopt a "lift-and-shift" strategy, transferring existing applications to the cloud with few alterations. However, to fully leverage cloud capabilities, it becomes imperative to design and implement applications tailored to the specific demands and characteristics of cloud environments. Cloud computing architecture outlines the integration of components in a way that allows for the pooling, sharing, and dynamic scaling of resources across a network. It serves as the architectural blueprint for efficiently running and managing applications within cloud settings. Key Components of Cloud Computing Architecture #1 Front-End Interface This part of the cloud computing architecture is what the user interacts with. It can range from web-based applications accessed through web browsers to specialized applications designed for specific cloud services. #2 Back-End Infrastructure The back end is the backbone of cloud computing architecture, comprising various servers, data storage systems, virtual machines, and management services. It is responsible for providing the computing power and storage necessary to run the applications and manage the user data. #3 Cloud-Based Delivery Models Within the…
Top 15 Machine Learning Tools to Power Up Your 2024 Projects
The year 2024 is upon us, and the world of machine learning is pulsating with innovation! New algorithms, advanced techniques, and ever-evolving machine learning tools are constantly emerging, empowering us to tackle ever-more complex challenges and unlock the true potential of data. If you're looking to leverage the power of ML in your 2024 projects, you've come to the right place. This blog delves into the top 15 machine learning tools that are set to make a significant impact this year. We'll explore their functionalities, strengths, and ideal use cases, helping you choose the perfect tool to propel your projects to new heights. Now, let’s get started! What is Machine Learning? Machine learning is a subfield of AI concerned with the development and application of algorithms that can learn from data without explicit programming. These algorithms are designed to improve their performance over time by identifying patterns and structures within the data. This enables them to make predictions or decisions on new, unseen data. Key characteristics of Machine Learning: Learning from Data: Unlike traditional programming, where the programmer defines every step the computer takes, machine learning algorithms learn from data. This data can be labeled or unlabeled, and the learning process involves identifying patterns and relationships within the data. Statistical Methods: Machine learning algorithms rely heavily on statistical methods to analyze data and extract knowledge. These methods allow the algorithms to learn from past data and generalize that knowledge to new, unseen examples. Iterative Process: Machine learning is an iterative process. The algorithm is initially trained on a dataset, and its performance is evaluated. Based on the evaluation results, the algorithm is adjusted and then re-trained on the data. This cycle of training, evaluation, and refinement continues until the desired level of performance is achieved. Benefits of Using Machine Learning Tools Machine learning tools have become a transformative force across various industries. Their ability to learn and improve from data offers significant advantages over traditional methods. Here's a closer look at some key benefits of incorporating machine learning tools into your workflow: Enhanced Decision-Making ML algorithms can analyze vast amounts of data to identify patterns and trends that humans might miss. This allows for data-driven decision-making, leading to more informed strategies and improved outcomes. Increased Efficiency and Automation Machine learning tools can automate repetitive tasks currently handled manually. This frees up human resources for more strategic endeavors and streamlines processes, boosting overall efficiency. Improved Accuracy and Productivity As ML models are trained on data, their accuracy in predictions and classifications continues to improve. This translates into increased productivity as tasks are completed with greater precision and fewer errors. Uncovering Hidden Insights Unsupervised learning, a branch of ML, excels at discovering patterns and structures within unlabeled data. This can reveal hidden trends and relationships that might not be readily apparent, leading to new opportunities and a deeper understanding of your data. Continuous Improvement Unlike traditional software, machine learning models can continuously learn and improve over time. As they are exposed to…
Supervised vs Unsupervised Learning: Which Approach is Right for You?
The world of machine learning can be a complex one, filled with algorithms and approaches that promise to unlock the hidden potential of your data. But when it comes to choosing the right technique, a fundamental question arises: supervised vs unsupervised machine learning? This blog will delve into the key differences between these two approaches, helping you decide which one best suits your specific needs. We'll explore what supervised and unsupervised learning entail, the kind of data they work with, and the tasks they excel at. So, whether you're a seasoned data scientist or just starting your machine learning journey, this guide will equip you with the knowledge to make an informed decision in the supervised vs unsupervised machine learning debate. What is Supervised Learning? Supervised learning is a type of machine learning where the algorithm is trained on a labeled dataset. This means that each training example is paired with an output label. The supervised learning algorithm analyzes the training data and produces an inferred function, which can be used for mapping new examples. The primary goal is to learn the mapping from inputs to outputs to predict the output for new data. What is Unsupervised Learning? Unsupervised learning is a type of machine learning where the algorithm is trained on a dataset without explicit instructions on what to do with it. Unlike supervised learning, unsupervised learning deals with data that has no labels or annotated outcomes. The system tries to learn the patterns and the structure from the data without the guidance of a known outcome variable. Supervised vs Unsupervised Machine Learning: What Are The Differences? Supervised vs Unsupervised Machine Learning: Data Used Supervised and unsupervised machine learning are two primary approaches in the field of artificial intelligence, each utilizing data differently: Supervised Machine Learning In supervised learning, the algorithm is trained on a labeled dataset. This means that each training example is paired with an output label. The model learns from this data to make predictions or decisions without being explicitly programmed to perform the task. The data used in supervised learning can be described as follows: Labeled Data: The dataset consists of input-output pairs. The output part of the pair is the label that provides the model with the answer or result it should produce when given the input. Structured Format: Data is often structured and may include various features that the algorithm uses to learn the mapping from inputs to outputs. Examples: This can include data for classification tasks where the labels are categorical or for regression tasks where the labels are continuous values. Unsupervised Machine Learning In unsupervised learning, the algorithm is given data without any explicit instructions on what to do with it. The data is "unlabeled," meaning that there are no output labels associated with the input. The goal here is for the model to uncover underlying patterns or structures within the data. The characteristics of data used in unsupervised learning include: Unlabeled Data: The dataset consists only of input data without…
A Beginner’s Guide to Machine Learning and Deep Learning
Have you ever dreamt of machines that can learn and adapt like humans? Well, that dream is becoming a reality with machine learning and deep learning! These fields are transforming everything from healthcare and finance to entertainment and self-driving cars. But how exactly do they work? In this beginner-friendly guide, we'll break down the core concepts of machine learning and deep learning, making them accessible to anyone curious about the future of technology. What is Machine Learning? Machine learning is a subset of AI focused on building systems that learn from data. Instead of being explicitly programmed to perform a task, machine learning models use algorithms to parse data, learn from it, and then decide or predictions about something in the world. Essentially, machine learning enables computers to perform tasks without being explicitly programmed for every possible scenario. Advantages of Machine Learning Machine learning offers a wide array of advantages across various fields, from technology and business to healthcare and beyond. Some of the key benefits include: Efficiency and Automation Machine learning algorithms can automate repetitive tasks, freeing up humans to focus on more creative and strategic work. This can significantly increase productivity and efficiency in various processes. Handling Large Datasets With the exponential growth of data, machine learning can analyze and make sense of vast amounts of information quickly and more efficiently than humanly possible, leading to more informed decision-making. Predictive Capabilities Machine learning can forecast trends and outcomes based on historical data. This is incredibly useful in fields like finance for stock predictions, in meteorology for weather forecasts, and in healthcare for predicting disease outbreaks. Complex Problem-Solving Machine learning can solve problems that are too complex for traditional algorithms, such as image and speech recognition, natural language processing, and diagnosing diseases from medical imaging. > Related: Deep Learning vs. Machine Learning in a Nutshell: Updated Key Differences 2024 What is Deep Learning? Deep Learning is a specialized subset of Machine Learning; uses layered (hence "deep") neural networks to simulate human decision-making. Inspired by the structure and function of the brain's neural networks, deep learning algorithms attempt to mimic the way humans learn; gradually gaining understanding from large amounts of data. Advantages of Deep Learning Deep learning offers several significant advantages, particularly in handling complex and high-dimensional data. Some of the key benefits include: Automated Feature Extraction Unlike traditional machine learning algorithms that often require manual feature selection and extraction, deep learning models automatically discover and learn the features from raw data. This capability is especially beneficial for complex data types like images, audio, and text, where defining features manually can be challenging and inefficient. Handling Unstructured Data Deep learning excels at working with unstructured data such as text, images, and sounds. For instance, convolutional neural networks (CNNs) are highly effective in image recognition and classification tasks, while recurrent neural networks (RNNs) and transformers are well-suited for sequential data like language and time series. Improved Accuracy As deep learning models are exposed to more data, they can achieve higher…
