Analysis of Nifty 50 index stock market trends using hybrid machine learning model in quantum finance

Predicting equities market trends is one of the most challenging tasks for market participants. This study aims to apply machine learning algorithms to aid in accurate Nifty 50 index trend predictions. The paper compares and contrasts four forecasting methods: artificial neural networks (ANN), support vector machines (SVM), naive bayes (NB), and random forest (RF). In this study, the eight technical indicators are used, and then the deterministic trend layer is used to translate the indications into trend signals. The principal component analysis (PCA) method is then applied to this deterministic trend signal. This study's main influence is using the PCA technique to find the essential components from multiple technical indicators affecting stock prices to reduce data dimensionality and improve model performance. As a result, a PCA-machine learning (ML) hybrid forecasting model was proposed. The experimental findings suggest that the technical factors are signified as trend signals and that the PCA approach combined with ML models outperforms the comparative models in prediction performance. Utilizing the first three principal components (percentage of explained variance=80%), experiments on the Nifty 50 index show that support vector classifer (SVC) with radial basis function (RBF) kernel achieves good accuracy of (0.9968) and F1-score (0.9969), and the RF model achieves an accuracy of (0.9969) and F1-Score (0.9968). In area under the curve (AUC) performance, SVC (RBF and Linear kernels) and RF have AUC scores of 1

Novel Modelling Strategies for High-frequency Stock Trading Data

Full electronic automation in stock exchanges has recently become popular, generating high-frequency intraday data and motivating the development of near real-time price forecasting methods. Machine learning algorithms are widely applied to mid-price stock predictions. Processing raw data as inputs for prediction models (e.g., data thinning and feature engineering) can primarily affect the performance of the prediction methods. However, researchers rarely discuss this topic. This motivated us to propose three novel modelling strategies for processing raw data. We illustrate how our novel modelling strategies improve forecasting performance by analyzing high-frequency data of the Dow Jones 30 component stocks. In these experiments, our strategies often lead to statistically significant improvement in predictions. The three strategies improve the F1 scores of the SVM models by 0.056, 0.087, and 0.016, respectively.Comment: 28 pages, 5 tables, 5 figure

Principal Component Analysis

This book is aimed at raising awareness of researchers, scientists and engineers on the benefits of Principal Component Analysis (PCA) in data analysis. In this book, the reader will find the applications of PCA in fields such as taxonomy, biology, pharmacy,finance, agriculture, ecology, health and architecture

Forecasting financial asset price movements using convolutional neutral networks – application to the U.S. financial services sector and comparisson across industries

This thesis explores the applicability of CNNs as a price movement forecasting tool for ETFs, using a technical analysis approach and three different image encoding techniques. After developing a general methodology, the thesis focuses on the application to the U.S. financial services sector. Subsequently, the research draws comparisons to results obtained for other U.S. sector ETFs using the same model approach. Overall results show that the CNN models, while proving some potential and exceeding a random model in accuracy, show significant weaknesses for all industries in predicting Buy and Sell signals. Addressing these weaknesses, limitations of the approach are explored to suggest methods for model performance improvements

Stock market prediction using machine learning classifiers and social media, news

Accurate stock market prediction is of great interest to investors; however, stock markets are driven by volatile factors such as microblogs and news that make it hard to predict stock market index based on merely the historical data. The enormous stock market volatility emphasizes the need to effectively assess the role of external factors in stock prediction. Stock markets can be predicted using machine learning algorithms on information contained in social media and financial news, as this data can change investors’ behavior. In this paper, we use algorithms on social media and financial news data to discover the impact of this data on stock market prediction accuracy for ten subsequent days. For improving performance and quality of predictions, feature selection and spam tweets reduction are performed on the data sets. Moreover, we perform experiments to find such stock markets that are difficult to predict and those that are more influenced by social media and financial news. We compare results of different algorithms to find a consistent classifier. Finally, for achieving maximum prediction accuracy, deep learning is used and some classifiers are ensembled. Our experimental results show that highest prediction accuracies of 80.53% and 75.16% are achieved using social media and financial news, respectively. We also show that New York and Red Hat stock markets are hard to predict, New York and IBM stocks are more influenced by social media, while London and Microsoft stocks by financial news. Random forest classifier is found to be consistent and highest accuracy of 83.22% is achieved by its ensemble

Return Predictability and Market Sentiment: Evidence from Deep Learning

Recent studies in asset pricing find that Artificial Neural Networks (also known as Deep Learning models) provide the most accurate firm-level return predictions using a vast set of predictive signals. These models offer high predictive accuracy over long out-of-sample periods, translating into highly profitable trading strategies. In this thesis, I argue that sentiment-driven mispricing is a vital source of the high predictability and the resulting profitability implied by deep learning models. Using a novel Artificial Neural Network (ANN) regression model, I obtain firm-level predictions conditional on 54 firm-level characteristics and on an encoded representation of the macro-economic state. These predictions provide important insights into the sources of overall cross-sectional return predictability. First, the future negative returns are predictable out-of-sample which implies negative expected returns. Such predictability is hard to reconcile with a risk-based explanation. Secondly, the predictability in negative returns is higher following periods of high sentiment and vice versa. This evidence is consistent with the existence of a market-level investor sentiment that drives misvaluations. Third, a long-short strategy based on ANN prediction deciles is more profitable following periods of high sentiment. This disparity in profitability points to arbitrage asymmetry implied by short-sale constraints. Fourth, the predictability in losses and high profitability of the ANN top decile vanishes in estimation horizons longer than a month. This suggests that mispricing is short-lived and that predictability is realized due to corrections to such misvaluations. These corrections are preceded by high put-to-call(PCR) trading volumes and high implied volatility(VIX). Finally, the short-term and long-term predictions load on different conditioning variables indicating varying sources of predictability across return horizons. Overall, these findings are consistent with the existence of sentiment-driven short-lived mispricing that corrects in longer horizons

EPAK: A Computational Intelligence Model for 2-level Prediction of Stock Indices

This paper proposes a new computational intelligence model for predicting univariate time series, called EPAK, and a complex prediction model for stock market index synthesizing all the sector index predictions using EPAK as a kernel. The EPAK model uses a complex nonlinear feature extraction procedure integrating a forward rolling Empirical Mode Decomposition (EMD) for financial time series signal analysis and Principal Component Analysis (PCA) for dimension reduction to generate information-rich features as input to a new two-layer K-Nearest Neighbor (KNN) with Affinity Propagation (AP) clustering for prediction via regression. The EPAK model is then used as a kernel for predicting each of all the sector indices of the stock market. The sector indices predictions are then synthesized via weighted average to generate the prediction of the stock market index, yielding a complex prediction model for the stock market index. The EPAK model and the complex prediction model for stock index are tested on real historical financial time series in Chinese stock index including CSI 300 and ten sector indices, with results confirming the effectiveness of the proposed models