Some useful AI tools in 2024
Solves anything -> Gemini
Text to image -> Adobe Firefly
Create AI Avatar -> HeyGen
Create Art -> Midjourney
Video editing -> Topview AI
Text to video -> Pika 1.0
Create logo -> logodiffusion
Create interface -> Uiverse
Creates copycats -> Tome
Essay assistant -> Jenni AI
Repetitive tasks -> Zapier
Copies your voice -> Eleven Labs
Rewrite anything -> Quillbot
Drawing assistant -> Autodraw
Create slide deck -> Autodraw
Write any emails -> Addy AI
Summarize notes -> Wordtune
Create music -> Soundraw
Solves anything -> Gemini
Text to image -> Adobe Firefly
Create AI Avatar -> HeyGen
Create Art -> Midjourney
Video editing -> Topview AI
Text to video -> Pika 1.0
Create logo -> logodiffusion
Create interface -> Uiverse
Creates copycats -> Tome
Essay assistant -> Jenni AI
Repetitive tasks -> Zapier
Copies your voice -> Eleven Labs
Rewrite anything -> Quillbot
Drawing assistant -> Autodraw
Create slide deck -> Autodraw
Write any emails -> Addy AI
Summarize notes -> Wordtune
Create music -> Soundraw
π24π₯5β€4
Artificial intelligence (AI) and machine learning (ML) are changing the future of work. While both terms seem similar, machine learning is actually a specific technique used by AI designers to achieve artificially intelligent computer programs. Knowing the basics of how AI and ML relate to each other can help you navigate these technologies as they transform the work landscape, enabling you to effectively contribute to AI-driven projects or lead your own AI initiatives.
In this reading, you'll explore some of the ML techniques AI designers use to build AI programs, deepening your understanding of how ML leverages data to make decisions and perform tasks. You'll also explore how ML techniques have paved the way for generative AI.
AI development techniques
Artificial intelligence refers to computer programs that can complete cognitive tasks typically associated with human intelligence. There are two main techniques used to design AI programs:
Rule-based techniques involve creating AI programs that strictly follow predefined rules to make decisions. For example, a spam filter using rule-based techniques might block emails that contain specific keywords using its predefined logic.
Machine learning techniques involve creating AI programs that can analyze and learn from patterns in data to make independent decisions. For example, a spam filter using these techniques might flag potential spam for the recipient to review, preventing automatic blocking. If the recipient marks emails from trusted sources as safe, the spam filter learns and adapts its logic to include similar emails from that sender in the future.
AI tools can use either rule-based or ML techniques, or even a combination of both. In general, rule-based techniques are commonly used for tasks that require rigidity, such as blocking messages from untrusted senders that are obviously spam, like requests for bank transfers or private information. Conversely, ML techniques are better suited for tasks demanding flexibility and adaptability, like learning to recognize that messages from trusted senders containing typos are not spam.
Approaches to training ML programs
Recall that machine learning is a subset of AI focused on developing computer programs that can analyze data to make decisions or predictions. AI designers often use ML in their AI programs because it doesnβt have the limitations of rule-based techniques.
A large circle representing AI with a smaller circle representing ML inside.
There are three common approaches to training ML programs:
Supervised learning
Unsupervised learning
Reinforcement learning
Supervised learning
In this approach, the ML program learns from a labeled training set. A labeled training set includes data that is labeled or tagged, which provides context and meaning to the data. For instance, an email spam filter that's trained with supervised learning would use a training set of emails that are labeled as βspamβ or βnot spam.β Supervised learning is often used when there's a specific output in mind.
Unsupervised learning
In this approach, the ML program learns from an unlabeled training set. An unlabeled training set includes data that does not have labels or tags. For instance, ML might be used to analyze a dataset of unsorted email messages and find patterns in topics, keywords, or contacts. In other words, unsupervised learning is used to identify patterns in data without a specific output in mind.
Reinforcement learning
In this approach, the ML program uses trial-and-error to learn which actions lead to the best outcome. The program learns to do this by getting rewarded for making good choices that lead to the desired results. Reinforcement learning is commonly used by conversational AI tools. As these tools receive feedback from users and AI designers, they learn to generate effective responses.
In this reading, you'll explore some of the ML techniques AI designers use to build AI programs, deepening your understanding of how ML leverages data to make decisions and perform tasks. You'll also explore how ML techniques have paved the way for generative AI.
AI development techniques
Artificial intelligence refers to computer programs that can complete cognitive tasks typically associated with human intelligence. There are two main techniques used to design AI programs:
Rule-based techniques involve creating AI programs that strictly follow predefined rules to make decisions. For example, a spam filter using rule-based techniques might block emails that contain specific keywords using its predefined logic.
Machine learning techniques involve creating AI programs that can analyze and learn from patterns in data to make independent decisions. For example, a spam filter using these techniques might flag potential spam for the recipient to review, preventing automatic blocking. If the recipient marks emails from trusted sources as safe, the spam filter learns and adapts its logic to include similar emails from that sender in the future.
AI tools can use either rule-based or ML techniques, or even a combination of both. In general, rule-based techniques are commonly used for tasks that require rigidity, such as blocking messages from untrusted senders that are obviously spam, like requests for bank transfers or private information. Conversely, ML techniques are better suited for tasks demanding flexibility and adaptability, like learning to recognize that messages from trusted senders containing typos are not spam.
Approaches to training ML programs
Recall that machine learning is a subset of AI focused on developing computer programs that can analyze data to make decisions or predictions. AI designers often use ML in their AI programs because it doesnβt have the limitations of rule-based techniques.
A large circle representing AI with a smaller circle representing ML inside.
There are three common approaches to training ML programs:
Supervised learning
Unsupervised learning
Reinforcement learning
Supervised learning
In this approach, the ML program learns from a labeled training set. A labeled training set includes data that is labeled or tagged, which provides context and meaning to the data. For instance, an email spam filter that's trained with supervised learning would use a training set of emails that are labeled as βspamβ or βnot spam.β Supervised learning is often used when there's a specific output in mind.
Unsupervised learning
In this approach, the ML program learns from an unlabeled training set. An unlabeled training set includes data that does not have labels or tags. For instance, ML might be used to analyze a dataset of unsorted email messages and find patterns in topics, keywords, or contacts. In other words, unsupervised learning is used to identify patterns in data without a specific output in mind.
Reinforcement learning
In this approach, the ML program uses trial-and-error to learn which actions lead to the best outcome. The program learns to do this by getting rewarded for making good choices that lead to the desired results. Reinforcement learning is commonly used by conversational AI tools. As these tools receive feedback from users and AI designers, they learn to generate effective responses.
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Each ML technique has its own strengths and weaknesses. Depending on the type of data that's available and what's needed to solve the particular problem, AI designers may use one, two, or all three of these techniques to produce an AI-powered solution.
Generative AI
Advancements in machine learning have helped pave the way for generative AIβAI that can generate new content, like text, images, or other media. This type of AI often uses a combination of supervised, unsupervised, and reinforcement learning to create original content.
For instance, all three approaches play distinct roles in conversational AI tools. Supervised learning equips conversational AI tools with foundational dialogue data, enabling them to respond to common conversational cues appropriately. Unsupervised learning enables them to interpret nuances in language, like colloquialisms, that occur naturally in conversation. Reinforcement learning further strengthens these tools by allowing them to improve their responses in real-time based on user feedback. This enables them to adapt to the conversational context and engage in natural conversations.
Generative AI's ability to create and innovate offers a range of benefits to all sorts of workplaces and professions, such as marketing, product development, engineering, education, manufacturing, and research and development. These benefits include:
Greater efficiency: Generative AI can automate or augment routine tasks, allowing workers to focus on other work priorities.
Personalized experiences: Generative AI can tailor its interactions to individual preferences and needs.
Better decisions: Generative AI can quickly analyze vast amounts of data to uncover useful insights.
These are just some of the ways that generative AI can enhance your work.
Join for more: https://t.me/machinelearning_deeplearning
Generative AI
Advancements in machine learning have helped pave the way for generative AIβAI that can generate new content, like text, images, or other media. This type of AI often uses a combination of supervised, unsupervised, and reinforcement learning to create original content.
For instance, all three approaches play distinct roles in conversational AI tools. Supervised learning equips conversational AI tools with foundational dialogue data, enabling them to respond to common conversational cues appropriately. Unsupervised learning enables them to interpret nuances in language, like colloquialisms, that occur naturally in conversation. Reinforcement learning further strengthens these tools by allowing them to improve their responses in real-time based on user feedback. This enables them to adapt to the conversational context and engage in natural conversations.
Generative AI's ability to create and innovate offers a range of benefits to all sorts of workplaces and professions, such as marketing, product development, engineering, education, manufacturing, and research and development. These benefits include:
Greater efficiency: Generative AI can automate or augment routine tasks, allowing workers to focus on other work priorities.
Personalized experiences: Generative AI can tailor its interactions to individual preferences and needs.
Better decisions: Generative AI can quickly analyze vast amounts of data to uncover useful insights.
These are just some of the ways that generative AI can enhance your work.
Join for more: https://t.me/machinelearning_deeplearning
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https://ai.google/education/
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β€6π4
The Process Of Training AI Models
AI designers and engineers develop AI models through a process called training. Hereβs an example of the typical steps a designer might take in this process, in this case for building a model that predicts rainfall:
Define the problem to be solved.
AI designers and engineers want to predict rain to help people stay dry when commuting to and from work. They start by considering AIβs capabilities and limitations before identifying an AI solution.
Collect relevant data to train the model.
AI designers and engineers gather historical data of days when it rained and days when it didn't rain over the past 50 years.
Prepare the data for training.
AI designers and engineers prepare the data by labeling important features, such as outdoor temperature, humidity, and air pressure, and then noting whether it rained. It's also common to separate the data into two distinct sets: a training set and a validation set to test with later.
Train the model.
AI designers and engineers apply machine learning (ML) programs to their rain prediction model, which helps it recognize patterns in its training data that indicate the likelihood of rainfall. Those patterns might include high temperatures, low air pressure, and high humidity.
Evaluate the model.
AI designers and engineers use the validation set they prepared earlier to assess their model's ability to predict rainfall accurately and reliably. Analyzing a model's performance can uncover potential issues impacting the model, such as insufficient or biased training data. If any issues exist, the AI designers and engineers may revisit an earlier step in this process to try a different approach. Once the model performs well with its validation set, the process continues to the next step.
Deploy the model.
When the AI designers and engineers are satisfied with their model's performance, they deploy it in an AI toolβhelping people in their city stay dry on their way to work!
Model training is an iterative process. AI designers and engineers can repeat each step as many times as necessary and make adjustments until they create the best model possible.
But the process doesn't stop at deployment. Once users interact with a model in practical situations, the model might be exposed to new challenges. AI designers and engineers should continuously monitor and collect feedback on their models, ensuring their models continue to perform reliably and to identify areas for improvement. It's this iterative process of continual refinement that makes AI models precise and versatile, which ultimately leads to effective, reliable AI tools. When you understand how AI models are developed, you can make informed decisions about when and how to use an AI tool to accomplish your goals.
Join for more: https://t.me/machinelearning_deeplearning
AI designers and engineers develop AI models through a process called training. Hereβs an example of the typical steps a designer might take in this process, in this case for building a model that predicts rainfall:
Define the problem to be solved.
AI designers and engineers want to predict rain to help people stay dry when commuting to and from work. They start by considering AIβs capabilities and limitations before identifying an AI solution.
Collect relevant data to train the model.
AI designers and engineers gather historical data of days when it rained and days when it didn't rain over the past 50 years.
Prepare the data for training.
AI designers and engineers prepare the data by labeling important features, such as outdoor temperature, humidity, and air pressure, and then noting whether it rained. It's also common to separate the data into two distinct sets: a training set and a validation set to test with later.
Train the model.
AI designers and engineers apply machine learning (ML) programs to their rain prediction model, which helps it recognize patterns in its training data that indicate the likelihood of rainfall. Those patterns might include high temperatures, low air pressure, and high humidity.
Evaluate the model.
AI designers and engineers use the validation set they prepared earlier to assess their model's ability to predict rainfall accurately and reliably. Analyzing a model's performance can uncover potential issues impacting the model, such as insufficient or biased training data. If any issues exist, the AI designers and engineers may revisit an earlier step in this process to try a different approach. Once the model performs well with its validation set, the process continues to the next step.
Deploy the model.
When the AI designers and engineers are satisfied with their model's performance, they deploy it in an AI toolβhelping people in their city stay dry on their way to work!
Model training is an iterative process. AI designers and engineers can repeat each step as many times as necessary and make adjustments until they create the best model possible.
But the process doesn't stop at deployment. Once users interact with a model in practical situations, the model might be exposed to new challenges. AI designers and engineers should continuously monitor and collect feedback on their models, ensuring their models continue to perform reliably and to identify areas for improvement. It's this iterative process of continual refinement that makes AI models precise and versatile, which ultimately leads to effective, reliable AI tools. When you understand how AI models are developed, you can make informed decisions about when and how to use an AI tool to accomplish your goals.
Join for more: https://t.me/machinelearning_deeplearning
π4π₯°1
AI Engineers can be quite successful in this role without ever training anything.
This is how:
1/ Leveraging pre-trained LLMs: Select and tune existing LLMs for specific tasks. Don't start from scratch
2/ Prompt engineering: Craft effective prompts to optimize LLM performance without model modifications
3/ Implement Modern AI Solution Architectures: Design systems like RAG to enhance LLMs with external knowledge
Developers: The barrier to entry is lower than ever.
Focus on the solution's VALUE and connect AI components like you were assembling Lego! (Credits: Unknown)
This is how:
1/ Leveraging pre-trained LLMs: Select and tune existing LLMs for specific tasks. Don't start from scratch
2/ Prompt engineering: Craft effective prompts to optimize LLM performance without model modifications
3/ Implement Modern AI Solution Architectures: Design systems like RAG to enhance LLMs with external knowledge
Developers: The barrier to entry is lower than ever.
Focus on the solution's VALUE and connect AI components like you were assembling Lego! (Credits: Unknown)
π₯4π2
There are several AI tools and libraries available to assist with coding in Python. Here are some of the most popular ones:
1. GitHub Copilot: An AI-powered code completion tool developed by GitHub and OpenAI. It can suggest entire lines or blocks of code based on the context of what you're writing.
2. Tabnine: An AI code completion tool that supports various IDEs and code editors. It uses deep learning models to predict and suggest code completions.
3. Kite: An AI-powered code completion and documentation tool that integrates with many popular IDEs. It offers in-line code completions and documentation for Python.
4. PyCharm's Code Completion: JetBrains' PyCharm IDE comes with advanced code completion features, which are enhanced by AI to provide context-aware suggestions.
5. Jupyter Notebooks with AI Integration: Jupyter notebooks can integrate with various AI tools and libraries for code completion and suggestions, like JupyterLab Code Formatter or extensions that integrate with AI models.
6. DeepCode: An AI-based code review tool that helps identify and fix bugs, security vulnerabilities, and code quality issues.
7. IntelliCode: An extension for Visual Studio Code that uses AI to provide code suggestions and improve productivity.
8. Codota: An AI-powered code suggestion tool that integrates with many IDEs and provides context-aware code completions.
9. Repl.it Ghostwriter: An AI-powered code completion tool available in the Repl.it online coding environment.
Join for more: https://t.me/machinelearning_deeplearning
1. GitHub Copilot: An AI-powered code completion tool developed by GitHub and OpenAI. It can suggest entire lines or blocks of code based on the context of what you're writing.
2. Tabnine: An AI code completion tool that supports various IDEs and code editors. It uses deep learning models to predict and suggest code completions.
3. Kite: An AI-powered code completion and documentation tool that integrates with many popular IDEs. It offers in-line code completions and documentation for Python.
4. PyCharm's Code Completion: JetBrains' PyCharm IDE comes with advanced code completion features, which are enhanced by AI to provide context-aware suggestions.
5. Jupyter Notebooks with AI Integration: Jupyter notebooks can integrate with various AI tools and libraries for code completion and suggestions, like JupyterLab Code Formatter or extensions that integrate with AI models.
6. DeepCode: An AI-based code review tool that helps identify and fix bugs, security vulnerabilities, and code quality issues.
7. IntelliCode: An extension for Visual Studio Code that uses AI to provide code suggestions and improve productivity.
8. Codota: An AI-powered code suggestion tool that integrates with many IDEs and provides context-aware code completions.
9. Repl.it Ghostwriter: An AI-powered code completion tool available in the Repl.it online coding environment.
Join for more: https://t.me/machinelearning_deeplearning
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