5 repositorios
Operations for concatenating, stacking, or dividing tensors along specified dimensions.
Distinct from Tensor Concatenation: Covers both joining (concatenation/stacking) and splitting, whereas the sibling focuses only on joining.
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This project is a structured learning curriculum and technical reference for mastering deep learning with TensorFlow. It provides a comprehensive guide for building, training, and deploying neural networks, combining theoretical fundamentals with practical implementation examples. The repository distinguishes itself by covering the end-to-end machine learning workflow, from low-level tensor mathematics and linear algebra to the creation of complex model architectures. It includes specific guidance on developing data pipelines for diverse data types, such as images, text, and time-series seque
Implements operations for concatenating, stacking, or dividing tensors along specified dimensions.
This project is a comprehensive collection of educational examples and reference implementations for building vision and language models using PyTorch. It serves as a deep learning tutorial covering the end-to-end process of developing neural networks, from initial architecture definition to final production deployment. The repository provides detailed guides on implementing a wide range of domain-specific models, including convolutional neural networks for object detection and segmentation, as well as transformer and recurrent architectures for natural language processing. It emphasizes gene
Provides utilities to merge or divide tensor data along specific dimensions using concatenation and splitting.
This is an interactive notebook-based course that teaches machine learning from Python fundamentals through deep learning and natural language processing. It uses real datasets and multiple frameworks within a structured, hands-on curriculum that combines concise explanations with executable code cells, built-in datasets, and embedded exercise checkpoints. Learning progresses through data preparation and exploration, classical machine learning workflows, computer vision with convolutional neural networks, and natural language processing with deep learning, all delivered as a cohesive progressi
Provides operations for concatenating, stacking, or dividing tensors and arrays along specified dimensions.
Este proyecto es un recurso educativo integral y un curso para construir redes neuronales usando PyTorch. Cubre los bloques de construcción fundamentales del deep learning, incluyendo la manipulación de tensores, la diferenciación automática y la construcción de componentes modulares de redes neuronales. El repositorio sirve como guía técnica para varios dominios especializados. Proporciona detalles de implementación para tareas de visión artificial como clasificación de imágenes, detección de objetos y segmentación semántica, así como flujos de trabajo de procesamiento de lenguaje natural que involucran transformers, redes recurrentes y modelos generativos. Además, incluye una referencia para IA generativa, centrándose específicamente en la síntesis de imágenes mediante modelos de difusión y redes adversarias. El material se extiende a pipelines de optimización y despliegue de modelos. Cubre técnicas para reducir el tamaño del modelo y aumentar la velocidad de inferencia mediante cuantización y la exportación de modelos a formatos como ONNX y TensorRT. Otras áreas de capacidad incluyen ingeniería de datos para carga paralela, evaluación de modelos mediante métricas personalizadas y el despliegue de modelos de lenguaje grandes (LLM) de código abierto. El proyecto se entrega principalmente como una serie de Jupyter Notebooks.
Combines tensors via stacking and divides them into smaller chunks along specified dimensions.
TransformerLens is a library for mechanistic interpretability research designed to reverse engineer the learned algorithms within large language models. It provides a standardized framework for wrapping diverse transformer architectures, allowing researchers to extract, manipulate, and analyze internal activations and weights through a consistent interface. The project distinguishes itself through a comprehensive system of activation hooks that can capture, patch, and ablate internal tensors during the forward pass. It includes specialized utilities for decomposing fused projections, material
Divides weight tensors along specified dimensions to select chunks for model conversion.