Application of matrices to real life problems | Blazingprojects Postgraduate Thesis
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Application of matrices to real life problems

 

Table Of Contents


Chapter ONE

INTRODUCTION

  • 1.1Introduction
  • 1.2Background of Study
  • 1.3Problem Statement
  • 1.4Objective of Study
  • 1.5Limitation of Study
  • 1.6Scope of Study
  • 1.7Significance of Study
  • 1.8Structure of the Research
  • 1.9Definition of Terms

Chapter TWO

LITERATURE REVIEW

  • 2.1Overview of Matrices
  • 2.2Historical Development of Matrices
  • 2.3Types of Matrices
  • 2.4Applications of Matrices in Engineering
  • 2.5Applications of Matrices in Computer Science
  • 2.6Applications of Matrices in Economics
  • 2.7Applications of Matrices in Biology
  • 2.8Applications of Matrices in Social Sciences
  • 2.9Challenges in Matrix Applications
  • 2.10Future Trends in Matrix Applications

Chapter THREE

RESEARCH METHODOLOGY

  • 3.1Research Design
  • 3.2Data Collection Methods
  • 3.3Sampling Techniques
  • 3.4Data Analysis Procedures
  • 3.5Research Ethics
  • 3.6Reliability and Validity
  • 3.7Research Limitations
  • 3.8Research Assumptions

Chapter FOUR

DATA PRESENTATION AND ANALYSIS

  • 4.1Overview of Findings
  • 4.2Analysis of Data
  • 4.3Comparison with Existing Literature
  • 4.4Interpretation of Results
  • 4.5Discussion of Key Findings
  • 4.6Implications of Findings
  • 4.7Recommendations for Future Research
  • 4.8Conclusion of Findings

Chapter FIVE

SUMMARY, CONCLUSION AND RECOMMENDATIONS

  • 5.1Summary of Research
  • 5.2Conclusions Drawn
  • 5.3Contributions to Knowledge
  • 5.4Practical Implications
  • 5.5Recommendations
  • 5.6Areas for Future Research
  • 5.7Reflection on the Research Process
  • 5.8Final Thoughts

Thesis Abstract

Abstract
Matrices are powerful mathematical tools that have wide applications in various real-life problems across different disciplines. This research project explores the practical uses of matrices in solving real-world problems. The application of matrices to real-life situations involves understanding how to represent data and relationships between variables in a structured and organized manner. One common application of matrices is in the field of computer graphics, where they are used to represent transformations of objects on the screen. Matrices can be used to perform operations such as translation, rotation, and scaling of images, allowing for the creation of complex visual effects in video games, animation, and computer-aided design. In the field of engineering, matrices are used to solve systems of linear equations that arise in structural analysis, electrical circuit analysis, and control systems. Engineers use matrix methods to model and analyze complex systems, making it possible to design efficient structures, circuits, and control systems that meet specific requirements. Matrices also play a crucial role in the field of economics and finance. They are used to model input-output relationships in production systems, analyze market trends, and optimize investment portfolios. By representing economic data in matrix form, economists and financial analysts can make informed decisions that maximize efficiency and profitability. Furthermore, matrices find applications in the field of statistics, where they are used for data analysis, regression analysis, and multivariate analysis. By organizing data into matrices, statisticians can identify patterns, correlations, and trends that provide valuable insights for making predictions and informed decisions. In the field of biology, matrices are used to model population dynamics, gene interactions, and ecological relationships. Biologists use matrix models to study the growth and interactions of populations, analyze genetic data, and understand the complex dynamics of ecosystems. Overall, the application of matrices to real-life problems demonstrates their versatility and importance in various fields. By utilizing matrix methods, researchers and practitioners can solve complex problems, make accurate predictions, and optimize systems for improved performance. Understanding how to apply matrices in practical situations is essential for advancing knowledge and innovation across disciplines.

Thesis Overview

<p> </p><h2>INTRODUCTION AND LITERATURE REVIEW</h2><p><strong>INTRODUCTION</strong></p><p>Matrices and determinants were discovered and developed in the 18th and 19th centuries. Initially, their development dealt with transformation of geometric objects and solution of systems of linear equations. Historically, the early emphasis was on the determinant, not the matrix. In modern treatment of Linear Algebra, matrices are considered first.</p><p>Matrices provide a theoretically and practically useful way of approaching many types of problems including; Solutions of system of linear equations, Equilibrium of rigid bodies, Graph theory, Theory of games, Leontief economics model, Forest management, Computer graphics and Computed tomography, Genetics, Cryptography, Electrical networks, etc.</p><p>Matrices are a very important tool in expressing and discussing problems which arise from real life issues. Matrices are applied in the study of electrical circuits, quantum mechanics and optics, in the calculation of battery power outputs and resistor conversion of electrical energy into another useful energy.</p><p>Matrices play a major role in the projection of three-dimensional images into a two-dimensional screen creating the realistic seeming motion. Matrices are used in calculating the gross domestic products in Economics which eventually helps in calculating the goods production efficiently.</p><p>Matrices are the base elements for robot movements. The movements of robots are programmed with the calculation of matrices row and columns. The inputs for controlling robots are given based on the calculations from matrices. Matrices are also used in many organizations by scientists for recording data of their experiment.</p><h2>HISTORY OF MATRICES</h2><p>The history of matrices goes back to ancient times, but the term “matrix” was not applied to the concept till 1850. Matrix is the Latin word for womb and it retains that sense in English. It can also mean more generally any place where something is formed or produced.</p><p>The origin of mathematical matrices lies with the study of simultaneous linear equations. An important text of the mathematical Art Chiu Chang SuanShu gives the first known example of the use of the matrix method to solve simultaneous equations. The concept of determinant first appeared nearly two millennia before its supposed invention by the Japanese Mathematician Seki Kowa in 1683 or his German contemporary Godfried Leibnitz.</p><p>The beginning of matrices and determinants goes back to the 2nd century BC although traces can be seen back to the 4th century BC. However, it was not until near the end of the 17th century that the ideas reappeared and development really got under way. The beginning of matrices arose through the study of systems of linear equations. The Babylonians first started studying problems which led to simultaneous linear equations and some of these are preserved in clay tablets which survived.</p><p>The Chinese between 200BC and 100BC came much closer to matrices than the Babylonians. Indeed, it is fair to say that the nine chapters’ text on Mathematical Art written during the Han Dynasty gives the first known example of matrix methods. One method would include what is now known as the Gaussian Elimination method (which is a method used to solve simultaneous linear equations). This method was not popular to mathematicians until the 19th century. The matrix theory was the result of a fifty-year study done by a man named Leibniz who studied Co-efficient systems of quadratic forms. Many common manipulations of the uncomplicated matrix theory appeared long before matrices were the object of mathematical investigation.</p><p>Gauss first started to describe matrix multiplication (which he thinks of as an organization of numbers, so he had not yet reached the concept of matrix algebra) and the inverse of a matrix in the particular context of the collection of coefficients of quadratic forms. During Gauss’ work on the study of Asteroid Pallas done between 1803 and 1809, Gauss obtained a system of six linear equations with six unknowns. Gauss gave a systematic method for solving such equations which is precisely Gaussian elimination method on the coefficient matrix. The multiplication theorem was proven and published for the first time in an 1812 paper.</p><p>Eisenstein, in 1844, denoted linear substitutions by a single letter and showed how to add and multiply them like ordinary numbers. It is rational to state that Eisenstein was the first to think of linear substitutions. Cramer presented his determinant based formula for solving systems of linear equations which is today known as the “Cramer’s rule” in 1750 after Leibniz’ use of determinant.</p><p>The first person to use the term “matrix” was Sylvester in 1850. Sylvester defined a matrix to be an oblong arrangement of terms and saw it as something that led to various determinants from square assortment contained within it. In 1853, a man named Cayley was the first to publish a note which spoke on the inverse of a matrix. Cayley defined the matrix algebraically using addition, multiplication, scalar multiplication and inverses. He gave a precise explanation of an inverse of a matrix. After using addition, multiplication and inverses with matrices, subtraction was soon to follow.</p> <br><p></p>

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