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Tuesday, November 23, 2021

Artificial Intelligence for Trading (Training)

Colleagues, the Artificial Intelligence for Trading program involves real-world projects designed by industry experts, covering topics from asset management to trading signal generation. Master AI algorithms for trading, and build your career-ready portfolio. Learn the basics of quantitative analysis, including data processing, trading signal generation, and portfolio management. Use Python to work with historical stock data, develop trading strategies, and construct a multi-factor model with optimization. Training modules - each with a hands-on project - include: 1) Basic Quantitative Trading - market mechanics and how to generate signals with stock data. Work on developing a momentum-trading strategy in your first project. (Project: Trading with Momentum); 2) Advanced Quantitative Trading - quant workflow for signal generation, and apply advanced quantitative methods commonly used in trading (Project: Breakout Strategy); 3) Stocks, Indices,and ETFs - portfolio optimization, and financial securities formed by stocks, including market indices, vanilla ETFs, and Smart Beta ETFs (Project: Smart Beta and Portfolio Optimization); 4) Factor Investing and Alpha Research - alpha and risk factors, and construct a portfolio with advanced optimization techniques (Project: Alpha Research and Factor Modeling); 5) Sentiment Analysis with Natural Language Processing - fundamentals of text processing, and analyze corporate filings to generate sentiment-based trading signals (Project: Sentiment Analysis Using NLP); 6) Advanced Natural Language Processing with Deep Learning - apply deep learning in quantitative analysis and use recurrent neural networks and long short-term memory to generate trading signals (Project: Deep Neural Network with News Data); 7) Combining Multiple Signals - advanced techniques to select and combine the factors you’ve generated from both traditional and alternative data (Project: Combine Signals for Enhanced Alpha); and 8) Simulating Trades with Historical Data - refine trading signals by running rigorous back tests. Track your P&L while your algorithm buys and sells (Project: Backtesting).

Enroll today (eams & execs welcome): https://tinyurl.com/hw9tnjjf 


Much career success, Lawrence E. Wilson - Artificial Intelligence Academy


Tuesday, November 16, 2021

Deep Neural Networks with PyTorch (IBM)

AI colleagues, the Deep Neural Networks with PyTorch from IBM equips you  to develop deep learning models using  Pytorch. The course will start with Pytorch's  tensors and Automatic differentiation package. Then each section will cover different models starting off with fundamentals such as Linear Regression, and logistic/softmax regression. Followed by  Feedforward deep neural networks, the role of different activation functions, normalization and dropout layers. Then Convolutional Neural Networks and Transfer learning will be covered. Finally, several other Deep learning methods will be covered. After completing this program you will be able to explain and apply their knowledge of Deep Neural Networks and related machine learning methods, know how to use Python libraries such as PyTorch  for Deep Learning applications and build Deep Neural Networks using PyTorch. Skill-based training modules cover: 1) Tensor and Datasets, 2) Differentiation in PyTorch, 3) Simple Datasets, 4) Linear Regression, 2) Gradient Descent, 3) Prediction in One Dimension, 4) PyTorch Linear Regression Training Slope and Bia, 5) Training Parameters in PyTorch, 6) Multiple Input Output Linear Regression, 7) Multiple Output Linear Regression, 8) Linear Classifier, 9) Logistic Regression: Prediction, 10) Bernoulli Distribution and Maximum Likelihood Estimation, 11) Softmax Regression, 12) Deep Neural Networks, 13) Convolutional Neural Network, and 14) TorchVision Models.

Enroll today (eams & execs welcome): https://tinyurl.com/4uj75b2z 


Much career success, Lawrence E. Wilson - Artificial Intelligence Academy


Thursday, October 21, 2021

Machine Learning Engineer for Microsoft Azure

Colleagues, the Machine Learning Engineer for Microsoft Azure program will strengthen your machine learning skills and build practical experience by training, validating, and evaluating models using Azure Machine Learning. Students will enhance their skills by building and deploying sophisticated machine learning solutions using popular open source tools and frameworks, and gain practical experience running complex machine learning tasks using the built-in Azure labs accessible inside the Udacity classroom. The three skill-based training modules with a hands-on project include: 1) Using Azure Machine Learning - Machine learning is a critical business operation for many organizations. Learn how to configure machine learning pipelines in Azure, identify use cases for Automated Machine Learning, and use the Azure ML SDK to design, create, and manage machine learning pipelines in Azure (Project - Optimizing an ML Pipeline in Azure)., 2) Machine Learning Operations - operationalizing machine learning, from selecting the appropriate targets for deploying models, to enabling Application Insights, identifying problems in logs, and harnessing the power of Azure’s Pipelines. All these concepts are part of core DevOps pillars that will allow you to demonstrate solid skills for shipping machine learning models into production (Project - Operationalizing Machine Learning), and 3) Capstone Project - use the knowledge you have obtained from this Nanodegree program to solve an interesting problem. You will have to use Azure’s Automated ML and HyperDrive to solve a task. Finally, you will have to deploy the model as a web service and test the model endpoint. Prior experience with Python, Machine Learning, and Statistics is recommended.

Sign-up today (teams & execs welcome): https://tinyurl.com/2pe8hrvj 


Much career success, Lawrence E. Wilson - Online Learning Central


Tuesday, October 19, 2021

Computer Vision (Training)

Colleagues, this Computer Vision training program equips you to write programs to analyze images, implement feature extraction, and recognize objects using deep learning models. Learn cutting-edge computer vision and deep learning techniques—from basic image processing, to building and customizing convolutional neural networks. Apply these concepts to vision tasks such as automatic image captioning and object tracking, and build a robust portfolio of computer vision projects. Master the computer vision skills behind advances in robotics and automation. Write programs to analyze images, implement feature extraction, and recognize objects using deep learning models. Training modules - each with a hands-on project cover: 1) Introduction to Computer Vision - Master computer vision and image processing essentials. Learn to extract important features from image data, and apply deep learning techniques to classification tasks (Project: Facial Keypoint Detection), 2) Facial Keypoint Detection - Advanced Computer Vision and Deep Learning, learn to apply deep learning architectures to computer vision tasks. Discover how to combine CNN and RNN networks to build an automatic image captioning application (Project: Automatic Image Captioning), and 3) Automatic Image Captioning - Object Tracking and Localization, learn how to locate an object and track it over time. These techniques are used in a variety of moving systems, such as self-driving car navigation and drone flight (Project: Landmark Detection and Tracking). Basic knowledge of Python, Statistics, Machine Learning and  Deep Learning is recommended.

Sign-up today (teams & execs welcome): https://tinyurl.com/3s9syf3r 


Much career success, Lawrence E. Wilson - Artificial Intelligence Academy 


Tuesday, October 12, 2021

How to Implement Search Algorithms with Python

Colleagues, the How to Implement Search Algorithms with Python program teaches you to optimize your approach for each search in your application and makes your overall system more efficient. Proficiency in this topic will help prepare you for your next coding interview and will help you understand how data retrieval methods work. Gain high-demand, marketable skills in Linear Search, 2) Finding Elements in Lists - Linear search can be used to search for a desired value in a list. It achieves this by examining each of the elements and comparing it with the search element starting with the first element, 3) Best Case Performance - Linear search is not considered the most efficient search algorithm, especially for lists of large magnitudes. However linear search is a great choice if you expect to find the target value, 4) Worst Case Performance - There are two worst cases for linear search. Case 1: when the target value at the end of the list, 5) Average Case Performance - If this search was used 1000 times on 1000 different lists, some of them would be the best case, some the worst. For most searches, it would be somewhere in between., 6) Time Complexity of Linear Search - Linear search runs in linear time. Its efficiency can be expressed as a linear function, with the number of comparisons to find a target increasing linearly as the size of the list, N, 7) Review - Congratulations! You have learned how linear search works and how to use it to search for values in lists. Let’s review what we learned: * Linear search is a search algorithm that is sequential, and 8) Linear & Binary Search Project - Learn to modify a version of binary search to look for data in a sparse dataset.

Enroll today (eams & execs welcome): https://fxo.co/Ccqx 


Much career success, Lawrence E. Wilson - Artificial Intelligence Academ

Thursday, October 7, 2021

Custom Models, Layers, and Loss Functions with TensorFlow

Colleagues, the Custom Models, Layers, and Loss Functions with TensorFlow program provide learners with more control over their model architecture and tools that help them create and train advanced ML models. Gain high-demand skills in Functional APIs, Custom Layers, Custom and Exotic Models with Functional APIs and Custom Loss Functions. Compare Functional and Sequential APIs, discover new models you can build with the Functional API, and build a model that produces multiple outputs including a Siamese network, Build custom loss functions (including the contrastive loss function used in a Siamese network) in order to measure how well a model is doing and help your neural network learn from training data, Build off of existing standard layers to create custom layers for your models, customize a network layer with a lambda layer, understand the differences between them, learn what makes up a custom layer, and explore activation functions, and Build off of existing models to add custom functionality, learn how to define your own custom class instead of using the Functional or Sequential APIs, build models that can be inherited from the TensorFlow Model class, and build a residual network (ResNet) through defining a custom model class. Training modules include: 1) Functional APIs - Compare how the Functional API differs from the Sequential API, and see how the Functional API gives you additional flexibility in designing models. Practice using the functional API and build a Siamese network, 2) Custom Loss Functions - measure how well a model is doing, and are used to help a neural network learn from the training data. Learn how to build custom loss functions, including the contrastive loss function that is used in a Siamese network, 3) Custom Layers - flexibility to implement models that use non-standard layers. Practice building off of existing standard layers to create custom layers for your models, 4) Custom Models - build off of existing models to add custom functionality. This week, extend the TensorFlow Model Class to build a ResNet model, and 5) Bonus Content - customize what your model outputs or how it behaves during training and implement a custom callback to stop training once the callback detects overfitting.

Enroll today (individuals & teams welcome): https://tinyurl.com/98u4wn2c 


Much career success, Lawrence E. Wilson - Artificial Intelligence Academy


Monday, September 27, 2021

Advanced Computer Vision with TensorFlow

Colleagues, the Advanced Computer Vision with TensorFlow training program will enable you to explore image classification, image segmentation, object localization, and object detection. Apply transfer learning to object localization and detection, apply object detection models such as regional-CNN and ResNet-50, customize existing models, and build your own models to detect, localize, and label your own rubber duck images, implement image segmentation using variations of the fully convolutional network (FCN) including U-Net and d) Mask-RCNN to identify and detect numbers, pets, zombies, and more., and identify which parts of an image are being used by your model to make its predictions using class activation maps and saliency maps and apply these ML interpretation methods to inspect and improve the design of a famous network, AlexNet. Gain high-demand skills in Salience, Image Segmentation, Model Interpretability, Class Activation Maps and TensorFlow Object Detection API. Training modules that will help advance your career include: 1) Introduction to Computer Vision - overview of image classification, object localization, object detection, and image segmentation. Also be able to describe multi-label classification, and distinguish between semantic segmentation and instance segmentation. In the rest of this course, you will apply TensorFlow to build object detection and image segmentation models, 2) Object Detection - overview of some popular object detection models, such as regional-CNN and ResNet-50. You’ll use object detection models that you’ll retrieve from TensorFlow Hub, download your own models and configure them for training, and also build your own models for object detection. By using transfer learning, you will train a model to detect and localize rubber duckies using just five training examples, 3) Image Segmentation - using variations of the fully convolutional neural network, 4) Visualization and Interpretability - learn about the importance of model interpretability, which is the understanding of how your model arrives at its decisions and  implement class activation maps, saliency maps, and gradient-weighted class activation maps.

Enroll today (individuals & teams welcome): https://tinyurl.com/drm2pss 


Much career success, Lawrence E. Wilson - Artificial Intelligence Academy


Tuesday, September 21, 2021

Model Tuning for Machine Learning (Training)

Colleagues, the Model Tuning for Machine Learning training program will equip you to slingshot the predictive capabilities of your models, far out-pacing the limits of out-of-box ML. From a ground-up perspective, we'll understand how a model functions, the part of the model that is able to fit the data on its own, and how important additional tuning and fitting by a trained ML engineer is. This module includes real-world examples, coding assignments, and lots of in-depth exploration of how and why model tuning should be done. If you understand the material in this course, your models will improve, and the results you will be able to deliver will as well. The 32 training modules address: Introduction and expectation-setting, Hyperparameters, Intro to Bayesianism, Intro to Bayesian Model Averaging, Bayesian Model Averaging- Specification, Occam's Window, Computing the Integral, Bayesian Model Averaging-Worked Example, Intro to Bootstrap Aggregation, Intro to Bootstrap Aggregation- CART, Problem with Bagged Decision Trees, Random Forests- Start to Finish, Random Forests: Time-Accuracy Tradeoff, Boosted Trees- Differences from Random Forest, Boosted trees- Adaboost Procedure, XGBoost- Gradient Boosting, Boosted Trees- Final Decision, Introduction to Hyper-Parameters- Basics, Hyperparameters in Decision Trees, Hyperparamters in Decision Trees- Levels, Hyperparameters in decision trees- AUC, Finding optimal hyperparameters- Brute Force, Finding Optimal Hyperparameters- Sanity Check, Intro to Stacking, Intro to Stacking- Motivation, Stacking- Pedigree, Know Your Data, Time/Value Tradeoff, and Example Scenario - Network Transactions. 

Enroll today (individuals & teams welcome): https://tinyurl.com/kkesjbb4 


Much career success, Lawrence E. Wilson - Artificial Intelligence Academy


Thursday, September 16, 2021

Data Science: K-Means Clustering in Python (Training)

Colleagues, the Data Science: K-Means Clustering in Python program will equip you in mathematics, statistics and programming skills that are necessary for typical data analysis tasks. You will consider these fundamental concepts on an example data clustering task, and you will use this example to learn basic programming skills that are necessary for mastering Data Science techniques. During the course, you will be asked to do a series of mathematical and programming exercises and a small data clustering project for a given dataset. Define and explain the key concepts of data clustering, Demonstrate understanding of the key constructs and features of the Python language, Implement in Python the principle steps of the K-means algorithm while Designing and executing a whole data clustering workflow and interpret the outputs. Gain high-demand data science skills in K-Means Clustering, Machine Learning and Programming in Python. Training modules include: 1)  Foundations of Data Science: K-Means Clustering in Python, 2) Means and Deviations in Mathematics and Python, 3) Moving from One to Two Dimensional Data, 4) Introducing Pandas and Using K-Means to Analyse Data, and 5) A Data Clustering In-Class Project. 

Enroll today (individuals & teams welcome): https://tinyurl.com/2uuhjjr9 


Much career success, Lawrence E. Wilson - Artificial Intelligence Academy


Monday, August 16, 2021

TensorFlow: Advanced Techniques Specialization

Colleagues, master your skill set with the TensorFlow: Advanced Techniques Specialization from DeepLearning.AI. Customize your machine learning models through four hands-on courses. Understand the underlying basis of the Functional API and build exotic non-sequential model types, custom loss functions, and layers, learn optimization and how to use GradientTape & Autograph, optimize training in different environments with multiple processors and chip types, practice object detection, image segmentation, and visual interpretation of convolutions, and explore generative deep learning, and how AIs can create new content, from Style Transfer through Auto Encoding and VAEs to GANs. Gain high demand skills in Model Interpretability, Custom Training Loops, Custom and Exotic Models, Generative Machine Learning, Object Detection, Functional API, Custom Layers, Custom and Exotic Models with Functional API, Custom Loss Functions, Distribution Strategies, Basic Tensor Functionality and GradientTape for Optimization. The four skill-based training modules include: 1) Custom Models, Layers, and Loss Functions with TensorFlow, 2) Custom and Distributed Training with TensorFlow, 3) Advanced Computer Vision with TensorFlow, and 4) Generative Deep Learning with TensorFlow. 

Sign-up today (individuals & teams welcome): https://tinyurl.com/k9pnhsra 


Much career success, Lawrence E. Wilson - Artificial Intelligence Academy


Deep Learning: Convolutional Neural Networks in Python (training)

Colleagues, in the “ Deep Learning: Convolutional Neural Networks in Python ” program you will learn Tensorflow, CNNs for Computer Vision, ...