Difference between revisions of "Artificial Neural Networks and Deep Learning"

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The following are last-minute news you should be aware of ;-)
 
The following are last-minute news you should be aware of ;-)
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* 28/10/2024: sent to all enrolled students email for the setup of the homeworks
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* 18/09/2024: A new edition of the AN2DL course starts today!!!
  
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* 12/03/2023: Grades of the [[Media:AN2DL_20230217.pdf|AN2DL 17/02/2023 call]] will appear here very soon!!!
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* 15/02/2023: Updates of grades from the [[Media:AN2DL_20230126_bis.pdf|AN2DL 26/01/2023 call]].
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* 14/02/2023: Grades of the [[Media:AN2DL_20230126.pdf|AN2DL 26/01/2023 call]].
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* 12/02/2023: Grades of the [[Media:AN2DL_2022_2023_Challenges.pdf|AN2DL Challenges]].
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* 23/01/2023: added link to the detailed course syllabus
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* 08/01/2023: update of the teaching material in the page ... a new detailed syllabus will follow too
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* 21/12/2022: Grades of the [[Media:AN2DL_2022_2023_FirstChallenge.pdf|first challenge (v2)]].
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<!--
 
<!--
 
  07/08/2022: Grades for the [[Media:AN2DL_Grades_20220726.pdf|06/07/2022 call are available here!]]
 
  07/08/2022: Grades for the [[Media:AN2DL_Grades_20220726.pdf|06/07/2022 call are available here!]]
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* [https://www.deib.polimi.it/ita/personale/dettagli/267262 Matteo Matteucci] and [https://www.deib.polimi.it/ita/personale/dettagli/549640 Giacomo Boracchi]: the course teachers  
 
* [https://www.deib.polimi.it/ita/personale/dettagli/267262 Matteo Matteucci] and [https://www.deib.polimi.it/ita/personale/dettagli/549640 Giacomo Boracchi]: the course teachers  
* [https://www.deib.polimi.it/ita/personale/dettagli/846174 Francesco Lattari] and [https://www.deib.polimi.it/ita/personale/dettagli/920490 Eugenio Lomurno]: the course teaching assistants
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* [https://www.deib.polimi.it/ita/personale/dettagli/920490 Eugenio Lomurno], [https://www.deib.polimi.it/ita/personale/dettagli/1128758 Alberto Archetti], and [https://www.deib.polimi.it/ita/personale/dettagli/1171162 Roberto Basla]: the course teaching assistants
  
 
===Course Program and Syllabus===
 
===Course Program and Syllabus===
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* Providing an overview of the most successful applications with particular emphasis on models for solving visual recognition tasks.
 
* Providing an overview of the most successful applications with particular emphasis on models for solving visual recognition tasks.
  
We have compiled a detailed syllabus of the course that students can use to double-check their preparation before the exam.  
+
We have compiled a detailed syllabus of the course that students can use to double-check their preparation before the exam.
* [[Media:AN2DL_Syllabus_2021.pdf|[2020/2021] Course Syllabus]]: a detailed list of topics covered by the course and which students are expected to know when approaching the exam
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* [https://docs.google.com/document/d/1BbcCJ7Om5LRvPCGeYkUkCk1RMjoi_ULDakkg0epsVFA/edit?usp=sharing Detailed Course Syllabus]
 +
<!--* [[Media:AN2DL_Syllabus_2022_2023.pdf|[2022/2023] Course Syllabus]]: a detailed list of topics covered by the course and which students are expected to know when approaching the exam-->
 +
<!--* [[Media:AN2DL_Syllabus_2021.pdf|[2020/2021] Course Syllabus]]: a detailed list of topics covered by the course and which students are expected to know when approaching the exam-->
 
<!--* [[Media:AN2DL_Syllabus.pdf|[2019/2020] Course Syllabus]]: a detailed list of topics covered by the course and which students are expected to know when approaching the exam-->
 
<!--* [[Media:AN2DL_Syllabus.pdf|[2019/2020] Course Syllabus]]: a detailed list of topics covered by the course and which students are expected to know when approaching the exam-->
  
===Detailed course schedule===
+
===Detailed course schedule and recordings===
  
A detailed schedule of the course can be found here; topics are just indicative while days and teachers are correct up to some last-minute change (I will notify you by email). Please note that not all days we have lectures!!
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A detailed schedule of the course is given in the form of google calendar; topics are just indicative while days and teachers are correct up to some last-minute change (I will notify you by email). Please note that not all days we have lectures!!
  
Note: Lecture timetable interpretation
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* For the [https://boracchi.faculty.polimi.it/teaching/AN2DLCalendar_CS.htm AN2DL Course Google Calendar] look here!
* On Wednesday, in 9.0.1, starts at 16:30, ends at 18:00
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* On Thursday, in 20.S.1, starts at 14:30, ends at 16:00
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Note: the course is given in parallel to two sessions, one by prof. Matteo Matteucci, the other by prof. Giacomo Boracchi. Two calendars exist; lectures are the same, but the scheduling is not necessarily aligned. The previous link points to prof. Matteo Matteucci session, on the same page you find the link to prof. Giacomo Boracchi session too.
  
 
Lectures will be recorded and shared afterward, no streaming of lectures is foreseen.
 
Lectures will be recorded and shared afterward, no streaming of lectures is foreseen.
  
For a [https://boracchi.faculty.polimi.it/teaching/AN2DLCalendar_CS.htm course google calendar] you might look here!
+
Recordings of lectures and lab sessions are linked from the google calendar events associated to the corresponding lecture.
 
<!--
 
<!--
 
  For a google calendar you might [https://boracchi.faculty.polimi.it/teaching/AN2DLCalendar.htm look here!]
 
  For a google calendar you might [https://boracchi.faculty.polimi.it/teaching/AN2DLCalendar.htm look here!]
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Slides from the lectures by Matteo Matteucci
 
Slides from the lectures by Matteo Matteucci
*[[Media:AN2DL_00_2223_Course_Introduction.pdf|[2022/2023] Course Introduction]]: introductory slides of the course with useful information about the course syllabus, grading, and the course logistics.  
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*[[Media:AN2DL_00_2324_Course_Introduction.pdf|[2023/2024] Course Introduction]]: introductory slides of the course with useful information about the course syllabus, grading, and the course logistics.  
*[[Media:AN2DL_01_2223_Deep_Learning_Intro.pdf|[2022/2023] Machine Learning vs Deep Learning]]: introduction to machine learning paradigms and definition of deep learning with examples
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*[[Media:AN2DL_01_2324_Deep_Learning_Intro.pdf|[2023/2024] Machine Learning vs Deep Learning]]: introduction to machine learning paradigms and definition of deep learning with examples.
*[[Media:AN2DL_02_2223_Perceptron_2_FeedForward.pdf|[2022/2023] From Perceptrons to Feed Forward Neural Networks]]: the original Perceptron model, Hebbian learning, feed-forward architecture, backpropagation and gradient descent, error functions and maximum likelihood estimation   
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*[[Media:AN2DL_02_2324_Perceptron_2_FeedForward.pdf|[2023/2024] From Perceptrons to Feed Forward Neural Networks]]: the original Perceptron model, Hebbian learning, feed-forward architecture, backpropagation and gradient descent, error functions and maximum likelihood estimation.  
*[[Media:AN2DL_03_2223_NeuralNetwroksTraining.pdf|[2022/2023] Neural Networks Training]]: dealing with overfitting (weight decay, early stopping, dropout), vanishing gradient (ReLU and friends), batch normalization  
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*[[Media:AN2DL_03_2324_NeuralNetwroksTraining.pdf|[2023/2024] Neural Networks Training]]: dealing with overfitting (weight decay, early stopping, dropout), vanishing gradient (ReLU and friends), batch normalization.
 
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*[[Media:AN2DL_04_2324_RecurrentNeuralNetworks.pdf|[2023/2024] Recurrent Neural Networks]]: learning with sequences, Recurrent Neural Networks, vanishing gradient, Long Short-Term Memories (LSTM), seq2seq model introduction.   
*[[Media:AN2DL_04_2122_RecurrentNeuralNetworks.pdf|[2021/2022] Recurrent Neural Networks]]: learning with sequences, Recurrent Neural Networks, vanishing gradient, Long Short-Term Memories (LSTM), seq2seq model.   
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*[[Media:AN2DL_05_2324_Seq2SeqAndWordEmbedding.pdf|[2023/2024] Seq2Seq and Word Embedding]]: sequence 2 sequence learning, neural autoencoders, language models, word embedding, word2vec.
*[[Media:AN2DL_05_2021_WordEmbedding.pdf|[2021/2022] Word Embedding]]: neural autoencoders, language models, word embedding, word2vec, glove.
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*[[Media:AN2DL_06_2324_AttentionAndTrasformers.pdf|[2023/2024] Beyond Sequence 2 Sequence Learning]]: Attention mechanisms in seq2seq models and Transformers.
*[[Media:AN2DL_06_2021_BeyondSeq2Seq.pdf|[2021/2022] Beyond Sequence 2 Sequence Learning]]: Neural Turing Machines, attention mechanisms, the Transformer.
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Slides from the lectures by Giacomo Boracchi are available in [https://boracchi.faculty.polimi.it/teaching/AN2DL.htm his webpage]; for your convenience, I am giving pointers to the slide here for you (in case you note discrepancies please notify me)
 
Slides from the lectures by Giacomo Boracchi are available in [https://boracchi.faculty.polimi.it/teaching/AN2DL.htm his webpage]; for your convenience, I am giving pointers to the slide here for you (in case you note discrepancies please notify me)
* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2021_AN2DL_Lez1_ImageClassification.pdf [2021/2022] The Image Classification Problem]
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* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2022_AN2DL_Lez1_ImageClassification.pdf [2022/2023]] The Image Classification Problem
* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2021_AN2DL_Lez2_CNN.pdf [2021/2022] Convolutional Neural Networks]
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* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2022_AN2DL_Lez2_CNN.pdf [2022/2023]] Convolutional Neural Networks
* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2021_AN2DL_Lez3_CNN_TL_Data_Scarcity.pdf [2021/2022] CNN Parameters and Training with Data Scarcity]
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* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2022_AN2DL_Lez3_CNN_TL_Data_Scarcity.pdf [2022/2023]] CNN Parameters and Training with Data Scarcity
* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2021_AN2DL_Lez4_CNN_for_segmentation.pdf [2021/2022] Fully Convolutional CNN and CNN for Semantic Segmentation]
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* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2022_AN2DL_Lez4_CNN_Famous_Architectures_CNN_Visualization.pdf [2022/2023] Famous CNN architectures and CNN Visualization
* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2021_AN2DL_Lez5_CNN_Localization_Explanations_Famous_Architectures.pdf [2021/2022] CNN for Localization, CNN Explanations and Famous Architectures]
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* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2022_AN2DL_Lez5_CNN_for_segmentation.pdf [2022/2023]] Fully Convolutional CNN and CNN for Semantic Segmentation
* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2021_AN2DL_Lez7_Generative_Models.pdf [2021/2022] Autoencoders and Generative Adversarial Networks]
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* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2022_AN2DL_Lez6_Localization_Explanations.pdf [2022/2023]] CNN for Localization and CNN Explanations
* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2021_AN2DL_Lez6_CNN_for_object_detection_Metric_Learning.pdf [2021/2022] Object Detction Networks and Metric Learning]
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* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2022_AN2DL_Lez7_CNN_for_object_detection_Metric_Learning.pdf [20223/2023]] Object Detection Networks and Metric Learning
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* [https://boracchi.faculty.polimi.it/teaching/AN2DL/2022_AN2DL_Lez8_Generative_Models.pdf [2022/2023]] Autoencoders and Generative Adversarial Networks
  
Slides from the practicals by Francesco Lattari and Eugenio Lomurno will be published here after each lab session: [https://drive.google.com/drive/folders/1iKWNyTBk1KMpnnkkjLwccgOFm6EYzsry?usp=sharing CHECK THIS FOLDER!]
+
Slides from the practicals by Francesco Lattari, Eugenio Lomurno, and Loris Giulivi will be published here after each lab session: [CHECK THIS FOLDER!]
 +
<!--https://drive.google.com/drive/folders/1iKWNyTBk1KMpnnkkjLwccgOFm6EYzsry?usp=sharing-->
 
<!--* [https://drive.google.com/drive/folders/1zO_E89H3mjc7nysBkGUt_MmCn1Mb2DzP?usp=sharing Python and convolutions]: a Colab notebook with a crash course on Python 3 to prepare for the practicals and extra material about convolutions!
 
<!--* [https://drive.google.com/drive/folders/1zO_E89H3mjc7nysBkGUt_MmCn1Mb2DzP?usp=sharing Python and convolutions]: a Colab notebook with a crash course on Python 3 to prepare for the practicals and extra material about convolutions!
 
* [https://drive.google.com/drive/folders/1-WFu2S-MBOrNsFRy1IWEptF_hTMLmic9?usp=sharing Feed Forward Neural Networks]: NumPy Arrays, TensorFlow2 Tensors, and Feed Forward Neural Network
 
* [https://drive.google.com/drive/folders/1-WFu2S-MBOrNsFRy1IWEptF_hTMLmic9?usp=sharing Feed Forward Neural Networks]: NumPy Arrays, TensorFlow2 Tensors, and Feed Forward Neural Network

Latest revision as of 22:10, 28 October 2024


The following are last-minute news you should be aware of ;-)

* 28/10/2024: sent to all enrolled students email for the setup of the homeworks
* 18/09/2024: A new edition of the AN2DL course starts today!!!


Course Aim & Organization

Neural networks are mature, flexible, and powerful non-linear data-driven models that have successfully been applied to solve complex tasks in science and engineering. The advent of the deep learning paradigm, i.e., the use of (neural) network to simultaneously learn an optimal data representation and the corresponding model, has further boosted neural networks and the data-driven paradigm.

Nowadays, deep neural networks can outperform traditional hand-crafted algorithms, achieving human performance in solving many complex tasks, such as natural language processing, text modeling, gene expression modeling, and image recognition. The course provides a broad introduction to neural networks (NN), starting from the traditional feedforward (FFNN) and recurrent (RNN) neural networks, till the most successful deep-learning models such as convolutional neural networks (CNN) and long short-term memories (LSTM).

The course's major goal is to provide students with the theoretical background and the practical skills to understand and use NN, and at the same time become familiar and with Deep Learning for solving complex engineering problems.

Teachers

The course is composed of a blending of lectures and exercises by the course teachers and a teaching assistant.

Course Program and Syllabus

This goal is pursued in the course by:

  • Presenting major theoretical results underpinning NN (e.g., universal approx, vanishing/exploding gradient, etc.)
  • Describing the most important algorithms for NN training (e.g., backpropagation, adaptive gradient algorithms, etc.)
  • Illustrating the best practices on how to successfully train and use these models (e.g., dropout, data augmentation, etc.)
  • Providing an overview of the most successful Deep Learning architectures (e.g., CNNs, sparse and dense autoencoder, LSTMs for sequence to sequence learning, etc.)
  • Providing an overview of the most successful applications with particular emphasis on models for solving visual recognition tasks.

We have compiled a detailed syllabus of the course that students can use to double-check their preparation before the exam.

Detailed course schedule and recordings

A detailed schedule of the course is given in the form of google calendar; topics are just indicative while days and teachers are correct up to some last-minute change (I will notify you by email). Please note that not all days we have lectures!!

Note: the course is given in parallel to two sessions, one by prof. Matteo Matteucci, the other by prof. Giacomo Boracchi. Two calendars exist; lectures are the same, but the scheduling is not necessarily aligned. The previous link points to prof. Matteo Matteucci session, on the same page you find the link to prof. Giacomo Boracchi session too.

Lectures will be recorded and shared afterward, no streaming of lectures is foreseen.

Recordings of lectures and lab sessions are linked from the google calendar events associated to the corresponding lecture.

Course Evaluation

Course evaluation is composed of two parts:

  • A written examination covering the whole program graded up to 20/30
  • 2 home projects in the form of a "Kaggle style" challenge practicing the topics of the course graded up to 5/30 each

The final score will sum up the grade of the written exam and the grade of the home projects. Home projects are not compulsory and they are issued only once a year.

Teaching Material (the textbook)

Lectures will be based on material from different sources, teachers will provide their slides to students as soon they are available. As a general reference, you can check the following textbook, but keep in mind that teachers will not follow it strictly

  • Deep Learning. Ian Goodfellow, Yoshua Bengio, and Aaron Courville, MIT Press, 2016.

Regarding the Python programming language, we will provide you with the basics about NumPy and python scripting in case you want some introductory material you can check here

  • Python tutorials: these are the official python tutorials, we suggest 3.An Informal Introduction to Python (Numbers, Strings, Lists), 4.More Control Flow Tools (if, for, range, functions), 5.Data Structures (More on lists, Dictionaries), 9.Classes.

Course Slides

Slides from the lectures by Matteo Matteucci

Slides from the lectures by Giacomo Boracchi are available in his webpage; for your convenience, I am giving pointers to the slide here for you (in case you note discrepancies please notify me)

  • [2022/2023] The Image Classification Problem
  • [2022/2023] Convolutional Neural Networks
  • [2022/2023] CNN Parameters and Training with Data Scarcity
  • [2022/2023 Famous CNN architectures and CNN Visualization
  • [2022/2023] Fully Convolutional CNN and CNN for Semantic Segmentation
  • [2022/2023] CNN for Localization and CNN Explanations
  • [20223/2023] Object Detection Networks and Metric Learning
  • [2022/2023] Autoencoders and Generative Adversarial Networks

Slides from the practicals by Francesco Lattari, Eugenio Lomurno, and Loris Giulivi will be published here after each lab session: [CHECK THIS FOLDER!]

External Sources

Exams

Politecnico di Milano exams will be held digitally in presence via the Politecnico di Milano remote exam platform using the Safe Exams Browser, it works only on Windows and iOS so please be prepared and test it in advance. You can have a flavor of what to expect by looking at some past exam calls.

Note: written exams will be graded 20 points plus 10 points are given by 2 software challenges issues only during the semester. Laude will be given to students who, beside getting the highest grade, will show participation in class, will perform particularly well in the challenges (this includes the quality of the report), will submit ahead of time the written exams.