F21-STAT 940-Proposal: Difference between revisions
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<p><b>Synopsis </b>: Electric power generation at a solar photovoltaic (PV) farm is predicted for near future based on historical data and weather features. A long-short-term-memory (LSTM) algorithm is used to perform time-series prediction.</p> | <p><b>Synopsis </b>: Electric power generation at a solar photovoltaic (PV) farm is predicted for near future based on historical data and weather features. A long-short-term-memory (LSTM) algorithm is used to perform time-series prediction.</p> | ||
<p>Solar energy is becoming increasingly popular as a viable renewable energy source. It offers many environmental advantages; however, fluctuations with changing weather patterns have always been a problem. While solar may not entirely replace fossil fuels, it has its place in the power generation portfolio. Many electricity companies are looking to add solar energy into their mix of power generation and in order to do so they require accurate solar production forecasts. Errors in forecasting could lead to large expenses like excess fuel consumption, emergency purchases of electricity from competitors, and/or might force utility operators to perform load shedding which directly affects electricity end-users. The major challenge in solar energy generation is the intermittency of photovoltaic system power generation mainly due to weather conditions which are extremely nonlinear and thus, analytical model-based approaches lack the required flexibility and complexity to capture the underlying patterns and behavior.</p> | <p>Solar energy is becoming increasingly popular as a viable renewable energy source. It offers many environmental advantages; however, fluctuations with changing weather patterns have always been a problem. While solar may not entirely replace fossil fuels, it has its place in the power generation portfolio. Many electricity companies are looking to add solar energy into their mix of power generation and in order to do so they require accurate solar production forecasts. Errors in forecasting could lead to large expenses like excess fuel consumption, emergency purchases of electricity from competitors, and/or might force utility operators to perform load shedding which directly affects electricity end-users. The major challenge in solar energy generation is the intermittency of photovoltaic system power generation mainly due to weather conditions which are extremely nonlinear and thus, analytical model-based approaches lack the required flexibility and complexity to capture the underlying patterns and behavior.</p> | ||
<p>Applied machine learning (ML) techniques can help improve the prediction accuracy and effectively increase social benefits by using multi-dimensional feature-based networks that digest tens of relevant input data streams including historical data and local weather conditions. In other words, ML-based tools are inevitably becoming indispensable for reducing the effect of uncertainty and energy costs in modern power systems and smart grids. The goal of this project is to implement machine learning algorithm to predict the electric energy output at a solar PV farm based on local weather and temporal parameters. </p> | <p>Applied machine learning (ML) techniques can help improve the prediction accuracy and effectively increase social benefits by using multi-dimensional feature-based networks that digest tens of relevant input data streams including historical data and local weather conditions. In other words, ML-based tools are inevitably becoming indispensable for reducing the effect of uncertainty and energy costs in modern power systems and smart grids. The goal of this project is to implement machine learning algorithm to predict the electric energy output at a solar PV farm based on local weather and temporal parameters. </p> | ||
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This project consists of four main parts: | This project consists of four main parts: | ||
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<p>3.Application/reporting: Apply the model and report back the findings including the accuracy of the results using the available dataset.</p> | <p>3.Application/reporting: Apply the model and report back the findings including the accuracy of the results using the available dataset.</p> | ||
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Revision as of 15:13, 8 October 2021
Use this format (Don’t remove Project 0)
Project # 0 Group members:
Abdelkareem, Youssef
Nasr, Islam
Huang, Xuanzhi
Title: Automatic Covid-19 Self-Test Supervision using Deep Learning
Description:
The current health regulations in Canada mandate that all travelers arriving who have to quarantine take a Covid-19 Self-test at home. But the process involves a human agent having a video call with you to walk you through the steps. The idea is to create a deep learning pipeline that takes a real-time video stream of the user and guides him through the process from start to end with no human interference. We would be the first to try to automate such a process using deep learning.
The steps of the test are as follows: - Pickup the swab - Place the swab in our nose up to a particular depth - Rotate in place for a certain period of time - Return back the swab to the required area - https://www.youtube.com/watch?v=jDIUFDMmBDo
Our pipeline will do the following steps: - Use a real-time face detector to detect bounding box around User's face (Such as SSD-MobileNetV2) - Use a real-time landmark detector to accurately detect the location of the nose. - Use a novel model to classify whether the swab is (Inside Left Nose, Inside right Node, Outside Nose) - Once the swab is detected to be inside the nose, the swab will have a marker (such as aruco marker) that can be automatically tracked in real-time using opencv, we will detect the location of the marker relative to the nose location and make sure it's correctly placed and rotated for the determined period. - This whole pipeline will be developed as a state machine, whenever the user violates the rule of a certain step he goes back to the corresponding step and repeats again.
Challenges: - There is no available dataset for training our novel model (to classify whether the swab is inside the nose or not), we will need to build our own dataset using both synthetic and real data. We will build a small dataset (5000-6000 images) and will rely on transfer learning to finetune an existing face attribute (such as moustache and glasses) classification model on our small dataset. - The whole pipeline will need to operate at a minimum of 30 FPS on CPU in order to match the FPS of a real-time video stream.
Project # 1 Group Members:
Feng, Jared
Salm, Veronica
Jones-McCormick, Taj
Sarangian, Varnan
Title: An Arsenal of Augmentation Strategies for Natural Language Processing
Description: Data augmentation is an effective technique for improving the generalization power of modern neural architectures, especially when trained over smaller datasets. Strategies for modifying training examples in domains such as computer vision and speech processing are typically straightforward, however it becomes more challenging in text processing where such generalized approaches are non-trivial. Unlike with images, where most geometric operations typically preserve the images' significant features, incorporating augmentation in text at the syntactic level can reduce the data quality as it may produce noisy examples that are no longer human-readable.
The purpose of this project is to investigate data augmentation techniques in NLP to accommodate for training robust neural networks over smaller datasets. Ideally, this may act as an alternative to relying on finetuning computationally demanding pretrained models. We will start with a survey of existing text augmentation techniques and evaluate them on several downstream tasks (using existing benchmark datasets and possibly novel ones). We will further attempt to adapt popular augmentation approaches from external domains (i.e. computer vision) into an NLP setting. This will include an empirical investigation into determining whether its appropriate to augment at the syntactic (i.e. raw text) or semantic (i.e. encoded vectors) level.
Project # 2 Group members:
Shi, Yuliang
Liang, Wei
Title: Ensemble Learning Of Neural Network On Chest X-ray Image for COVID-19 Patients
Description:
COVID-19 is a contagious disease that emerged in Wuhan, China in December 2019 and has been spreading worldwide rapidly, presenting unprecedented challenges to the world. Infected people may have a wide range of symptoms such as fever, cough, fatigue, etc. Researchers are tirelessly working together to better understand the methodology of death caused by COVID-19 . However, whether the x-ray chest image can be detected automatically by machine is still required further investigation. This gives us the motivation to consider deep learning methodology for classifying x-ray images of COVID-19 patients. In this study, we are going to use the two datasets. The first dataset is from confirmed positive cases of COVID-19 with x-ray images and the second dataset is posted on the Kaggle website. In total, there are 1493 images with 224x224 pixels in our dataset.
Purpose:
The objective of this project is to identify different chest x-ray images from four different categories - COVID-19, Pneumonia bacterial, Pneumonia viral and normal chest. This is an image classification problem and we set up our model based on convolutional neural networks (CNN), with inputs being the chest x-ray images and outputs being the disease categories. CNN is powerful in computer visions and has achieved extensive success. A typical CNN architecture consists of input layers, convolutional layers, pooling layers and fully connected output layers. We will tailor our networks based on this classical CNN architecture and adopt some techniques for more accurate detection of COVID-19 from the x-ray images.
Challenges and Improvements:
We develop and improve our CNN based model in the following three domains:
First, we can use the pre-trained model to do transfer learning for higher precision. The last several layers will be refined in order to better train the images. Several techniques will be applied to avoid overfitting issue, including regulazations, batchnormal, and data augmentation.
Second, as there are so many networks has been proposed for COVID-19 detection using x-ray images, we can ensemble them together for lower variance and better performance.
Finally, vision Transformer (ViT) is a new but milestone technology in deep learning. Transformer was firstly came up for natural language processing. It was later applied to computer vision and achieved huge success. We are going to figure out the application of this new technology in classification of chest x-ray images.
Link To Proposal: STAT 940 Proposal
Project # 3 Group Members:
Leung, Alice
Yalsavar, Maryam
Jamialahmadi, Benyamin
Title: MLP-Mixer: MLP Architecture for NLP
Description: Although transformers, and other attention-based architectures are the common parts of the most state-of-the-art models in both Vision and Natural Language Processing (NLP), recently, “MLP-Mixer: An all-MLP Architecture for Vision” (https://arxiv.org/pdf/2105.01601.pdf) paper disclosed a model that is entirely based on multi-layer perceptrons (MLPs) with competitive results on both accuracy and computational cost to these advanced methods in field of vision. This paper claims that neither of attention, and convolutions are necessary which the claim is proved by its well-stablished experiments and results. Beside its astounding results, the application of this model is not yet addressed in field of NLP. So, this project approaches towards implementation of this model for NLP tasks. The overall outline and steps can be:
1. Paper and code assessment
2. Applying the model to a named entity recognition problem
3. Data preparation
4. Training, fine-tuning, and testing
Challenges: Challenges will be finding a good data set to apply NER to, and figuring out how to adapt this architecture from a computer vision problem to a NLP problem.
Project # 4 Group Members:
Mina Kebriaee
Title: Short-term Forecast for Solar Photovoltaic Farm Output
Description:
<p><b>Synopsis </b>: Electric power generation at a solar photovoltaic (PV) farm is predicted for near future based on historical data and weather features. A long-short-term-memory (LSTM) algorithm is used to perform time-series prediction.</p> <p>Solar energy is becoming increasingly popular as a viable renewable energy source. It offers many environmental advantages; however, fluctuations with changing weather patterns have always been a problem. While solar may not entirely replace fossil fuels, it has its place in the power generation portfolio. Many electricity companies are looking to add solar energy into their mix of power generation and in order to do so they require accurate solar production forecasts. Errors in forecasting could lead to large expenses like excess fuel consumption, emergency purchases of electricity from competitors, and/or might force utility operators to perform load shedding which directly affects electricity end-users. The major challenge in solar energy generation is the intermittency of photovoltaic system power generation mainly due to weather conditions which are extremely nonlinear and thus, analytical model-based approaches lack the required flexibility and complexity to capture the underlying patterns and behavior.</p> <p>Applied machine learning (ML) techniques can help improve the prediction accuracy and effectively increase social benefits by using multi-dimensional feature-based networks that digest tens of relevant input data streams including historical data and local weather conditions. In other words, ML-based tools are inevitably becoming indispensable for reducing the effect of uncertainty and energy costs in modern power systems and smart grids. The goal of this project is to implement machine learning algorithm to predict the electric energy output at a solar PV farm based on local weather and temporal parameters. </p>
This project consists of four main parts: <p>1.Data: Pre-processing of the raw data files (input) and historical power generation data files (output) from the solar farm to get meaningful numeric values on an hourly basis.</p> <p>2.Machine Learning: Designing and implementing Deep Neural Network (Long Short-Term Memory (LSTM) model to accurately forecast short-term photovoltaic solar power). This approach exploits the desirable properties of LSTM, which is a powerful tool for modeling dependency in data.</p> <p>3.Application/reporting: Apply the model and report back the findings including the accuracy of the results using the available dataset.</p>