MLG 033 Transformers
Machine Learning Guide
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This chapter explores the concept of transformers, a key technology in large language models, focusing on their simplicity and transformative potential. The host also discusses the benefits of incorporating exercise, such as treadmill desks, to boost concentration while studying machine learning.
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Links:
- Notes and resources at ocdevel.com/mlg/33
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- Try a walking desk stay healthy & sharp while you learn & code
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- RNN Limitations: Sequential processing prevents full parallelization—even with attention tweaks—making them inefficient on modern hardware.
- Breakthrough: “Attention Is All You Need” replaced recurrence with self-attention, unlocking massive parallelism and scalability.
- Layer Stack: Consists of alternating self-attention and feed-forward (MLP) layers, each wrapped in residual connections and layer normalization.
- Positional Encodings: Since self-attention is permutation invariant, add sinusoidal or learned positional embeddings to inject sequence order.
- Q, K, V Explained:
- Query (Q): The representation of the token seeking contextual info.
- Key (K): The representation of tokens being compared against.
- Value (V): The information to be aggregated based on the attention scores.
- Multi-Head Attention: Splits Q, K, V into multiple “heads” to capture diverse relationships and nuances across different subspaces.
- Dot-Product & Scaling: Computes similarity between Q and K (scaled to avoid large gradients), then applies softmax to weigh V accordingly.
- Causal Masking: In autoregressive models, prevents a token from “seeing” future tokens, ensuring proper generation.
- Padding Masks: Ignore padded (non-informative) parts of sequences to maintain meaningful attention distributions.
- Transformation & Storage: Post-attention MLPs apply non-linear transformations; many argue they’re where the “facts” or learned knowledge really get stored.
- Depth & Expressivity: Their layered nature deepens the model’s capacity to represent complex patterns.
- Residual Links: Crucial for gradient flow in deep architectures, preventing vanishing/exploding gradients.
- Layer Normalization: Stabilizes training by normalizing across features, enhancing convergence.
- Parallelization Advantage: Entire architecture is designed to exploit modern parallel hardware, a huge win over RNNs.
- Complexity Trade-offs: Self-attention’s quadratic complexity with sequence length remains a challenge; spurred innovations like sparse or linearized attention.
- Pretraining & Fine-Tuning: Massive self-supervised pretraining on diverse data, followed by task-specific fine-tuning, is the norm.
- Emergent Behavior: With scale comes abilities like in-context learning and few-shot adaptation, aspects that are still being unpacked.
- Distributed Representation: “Facts” aren’t stored in a single layer but are embedded throughout both attention heads and MLP layers.
- Debate on Attention: While some see attention weights as interpretable, a growing view is that real “knowledge” is diffused across the network’s parameters.
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