Machine Learning

Summarized using AI

How ChatGPT Works

Paolo "Nusco" Perrotta • June 16, 2023 • Verona, Italy

The video titled How ChatGPT Works, presented by Paolo Perrotta at the RubyDay 2023 event, offers a comprehensive overview of GPT (Generative Pre-trained Transformer) and the underlying principles of AI language models. The discussion focuses on demystifying the complexity of GPT by breaking it down into approachable segments.

Key points include:

- Introduction to GPT: The speaker expresses the delightful nature of experimenting with GPT, exemplifying its creativity by generating a Ruby program that composes a rap about Yukihiro Matsumoto.

- Neural Networks and Function Approximation: Paolo introduces how neural networks operate by approximating functions through a model involving inputs, outputs, and error adjustments. He uses a relatable analogy regarding a music label attempting to predict song popularity based on specific variables (e.g., BPM).

- Training Neural Networks: The training process involves initiating with random parameters and refining them iteratively through error calculation and backpropagation, enabling the model to learn from its predictions.

- Understanding Images and Word Representation: The explanation transitions to image recognition, where pixels serve as input variables, then into language models utilizing word embeddings—conceptualizing words in high-dimensional space based on attributes and relationships.

- Text Generation Process: The speaker elaborates on predicting sequences of words by utilizing attention mechanisms to discern hierarchies and relationships, ultimately enabling the model to generate coherent text sequences.

- Model Alignment: Discusses the importance of human feedback in aligning the model’s outputs with user expectations, ensuring effective and safe interactions.

- Emergent Abilities: As AI models scale, they exhibit abilities beyond their training, prompting inquiries about future capabilities and implications of such advancements.

- Philosophical Considerations: The conclusion emphasizes the ongoing discussions regarding consciousness, human cognition, and the profound relationship we have with AI technologies.

Overall, this presentation seeks to provide a high-level yet intuitive comprehension of how AI language models like GPT operate, recognizing both their capabilities and the mysteries that still surround their functions.

How ChatGPT Works
Paolo "Nusco" Perrotta • June 16, 2023 • Verona, Italy

ChatGPT astonishes everyone, including maybe his own designers.
As software developers, we're always looking for the gears behind the magic.
How can this thing possibly work?
Give me some time, and I'll give you an intuitive, high-level understanding of AI language models

rubyday 2023 happened in Verona on 16th June 2023

Info and details of this edition:
2023.rubyday.it/

rubyday 2023

00:00:07.759 So, I asked it yesterday to generate a Ruby program that, in turn, generates a rap song about Yukihiro Matsumoto.
00:00:38.840 I wouldn't know much about the mic of the rap—maybe that's not the best—but the rhymes? I mean, rhyming 'needle' with 'Matsumoto'? That's good stuff! You will also notice that I always say 'please' when I ask GPT for something because the idea is that when it eventually takes over, I hope it remembers and it will kill me last.
00:01:25.560 So, let's try to wrap our minds around GPT at a high level and how it works. I will do that in five chapters, and I will start from scratch, so anyone with experience with neural networks, please bear with me. I want everyone to be on board.
00:01:34.920 A short disclaimer: we don’t actually know how GPT-4 works because OpenAI won’t tell us. But we can assume it works kind of like GPT-3, which works like most large language models. We have no hints that OpenAI has any secret recipe; their models are just big, they're good at executing, but otherwise, they’re just neural networks.
00:01:56.159 Chapter one: instead of showing you the usual diagrams with bubbles on how neural networks work, let's start with a concrete example—a toy example. Let's assume we have a small music label, and we want to predict how popular our songs will be based on several factors, such as BPM (beats per minute) and the number of streams over the last couple of weeks.
00:02:25.160 We plot this history on a chart, with every dot representing a track we released. So far, it looks like our audience is into chill-out music around 100 BPM. Obviously, there's another area for very unsuccessful songs, but it picks up again around 185 BPM. This gives us a rough idea, but it's not great at predicting the future.
00:03:14.519 It gets better if we take these points and approximate them with a continuous function. Once we have this function, we can make better predictions. For example, if our latest track is 175 BPM, the function will tell us how successful it might be. But of course, we can't predict success based on BPM alone, so we need more data, such as the week of the year that the song was released.
00:04:10.280 We add important variables to our model, and now we have a three-dimensional function instead of a two-dimensional one. If we add more variables, the function becomes more complex, but that's fine because neural networks can handle it. In general, neural networks approximate functions. It's simply a function in a box. Once we have that function, we can input different variables and receive an output.
00:05:29.080 Now, how do neural networks approximate functions? For example, let's consider the classic problem of recognizing pictures of cats. What are our inputs? Well, we can take images, breaking them down to pixels, with each pixel representing an input variable. Or we might break down the pixels into their RGB values—three input variables per pixel. Ultimately, we want a Boolean result indicating whether it’s a cat or not.
00:06:04.720 What people usually ask for is a number from 0 to 1, representing how sure the network is about the truth of the answer. For instance, it might return 0.9 for 'probably a cat' and a low number for 'definitely not a cat.' The idea is that there's a function that exists, mapping the pixels to some surface in a high-dimensional space. While we can't visualize it, if we could, we'd see this 'cat surface.'
00:06:56.400 Inside the neural network, there are layers, and these layers are essentially matrices. These matrices can be two-dimensional or three-dimensional, depending on the situation. They contain numbers that undergo operations—typically matrix multiplication—which are essentially combinations of multiplications and sums, alongside other simple operations, like clipping to prevent negative values.
00:07:50.240 Having enough operations and numbers allows us to approximate any function. The specific function approximated depends on the parameters—numbers inside the matrices. The trick, then, is finding the parameters that approximate the desired function, a stage called training the neural network.
00:08:38.079 Training essentially starts with random numbers, giving a random function. Next, we express the error of this function numerically compared to what we aim to achieve. For example, using song data, we can calculate how off the predictions are; if the error is significant, an algorithm will adjust the numbers slightly to decrease the error.
00:09:10.120 This process continues iteratively—hundreds of thousands or millions of times—until acceptable error levels are reached. That results in a function in a box, which is crucial in artificial intelligence, known as backpropagation.
00:10:03.120 Backpropagation starts from the end of the network, working backward to tweak numbers in each layer until the desired output is achieved. To summarize, neural networks define their own architecture through operations that are suited to the data they handle. For instance, for image data, convolutions are utilized to maintain geometric structure, unlike methods that might distort this critical information.
00:10:51.639 Another interesting point about neural networks is that deeper networks—those with more layers—tend to perform better. Each layer tends to recognize progressively more complex shapes. Initially, they may pick out simple lines and edges, but as layers deepen, more complex structures (like objects) are identified. In essence, these networks serve as abstraction machines, creating layers of meaning, which was a significant breakthrough. Just a few years ago, we needed to guide networks by defining parameters, but deep networks can identify their own features without external labor.
00:12:13.480 Let's transition to the topic of language—the technique that specifically handles linguistic tasks. Consider word representation where we create a chart to categorize words based on their attributes, like cuteness and speed.
00:12:55.560 As we organize words in this multi-dimensional space—like a cute but slow sloth versus a fast but less cute airplane—we can establish coordinates that conceptualize words as numerical arrays known as word embeddings. This idea is powerful because it helps us perceive how meaning is defined in relation to multiple attributes.
00:14:18.160 When generating text—such as utilizing Charles Darwin's 'On the Origin of Species'—we can train the neural network with sequences of words, masked at certain junctures, to let the network predict missing words. This provides abundant training material without needing specific examples, as we can slide our window to garner numerous instances of word pairings.
00:15:35.560 However, predicting the next word can be intricate, as it’s hard for the model to ascertain the possibilities. Even with extensive vocabulary, it may struggle to suggest the right word accurately. An important part of this process involves an embedding matrix that represents the vocabulary, where each row symbolizes a word's embedding in a high-dimensional space.
00:16:54.439 As we train this model, we continually adjust the embeddings while refining the neural network’s predictions. Over time, we expect similar context words to share similar embeddings. Such a training structure allows us to leverage the language model's capacities without explicitly defining word meanings.
00:18:11.800 Eventually, we observe the emergence of patterns within the matrix as certain semantics thread through the word embeddings, anchoring relationships like those between 'man,' 'woman,' 'boy,' and 'girl' visually. This illustrates how geometry plays into representational learning, revealing correlations without direct instruction.
00:19:39.839 Now that we’ve discussed individual words, we must emphasize that the true challenge comes with sentences. Understanding sentences mandates discerning their hierarchical structure and implicit meanings, resulting in nuanced interpretations. To address this, neural networks develop a framework to ascertain the interrelations between words in context.
00:20:41.440 They utilize structures like queries, keys, and values in what's called ‘attention mechanisms’ to sift through sentence elements. These attention heads help identify the significance of words conditional on underlying queries, which may encompass numerous layers of syntactical and contextual analyses.
00:21:40.320 As immersed sentences are processed through multiple attention heads, it becomes possible to distill down ideas and relationships, allowing models to capture intricate connections present in natural language.
00:22:30.960 From there, we structure the architecture of GPT, utilizing these operations on word embeddings and passing them through attention mechanisms layered atop conventional neural network architectures. This culminates into a system capable of generating text by predicting the next word given a context of greater length, refining its processes as nuanced feedback reveals potential errors.
00:23:44.000 Ultimately, we achieve a machine that excels in generating text by understanding the context and predictively offering words, forming coherent sentences as they evolve through the interaction. The cycle continues, generating the new context invariably enhancing the model’s output.
00:24:45.760 Moreover, it’s essential to address how this approach aligns language models with user expectations. Alignment revolves around satisfying interactions, enabling the AI to maintain a cordial and appealing conversation rather than simply continuing a thought or providing fragmented responses.
00:25:32.120 Humans often leverage reinforcement learning from human feedback to funnel the model's tendencies towards desired outputs, calibrating its behavior so that it becomes beneficial and safer. This involves having people curate training data and reviewing responses to influence model training positively. Importantly, a few training exchanges can reorient behavior effectively.
00:26:40.760 After pretraining, the model is adjusted with minimal human effort to create versions, nailing the language model's robustness. These transformations enhance its flexibility, allowing it to engage in a multitude of contexts including logical operations, significantly broadening the horizon of practical applications of the model.
00:27:53.440 Consequently, as these systems advance, the capacity for emergent abilities becomes noteworthy. They begin performing tasks that haven’t been explicitly trained yet simply due to underlying scaling, prompting important inquiries regarding our relationship with these models and the types of capabilities we should anticipate in the future.
00:29:26.960 Ultimately, while we find ourselves in a fascinating age of AI, the philosophical debates about the nature of consciousness, comparisons of our cognition to AI behavior, and the exploration of our relationship with the technology become imminent even as we strive for understanding.
00:30:46.960 This brings us to a close as we’ve extensively examined the mechanics behind GPT and the wider context of artificial intelligence innovation. Thank you for your attention, and I hope you gained valuable insights into how AI, particularly GPT, operates.
00:31:46.079 Thank you, this was great! And as you said yesterday, we still don’t know what this thing is doing. Let's find out, for better or for worse.
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