Ch. 5b Linear Models & Matrix Algebra

Slides:

Advertisements

Similar presentations

Chapter 6 Matrix Algebra.

Advertisements

Introduction to Information Systems, 1st Edition

Slide 1Fig 26-CO, p.795. Slide 2Fig 26-1, p.796 Slide 3Fig 26-2, p.797.

Electronic Presentations in Microsoft® PowerPoint®

SJS SDI_81 Design of Statistical Investigations Stephen Senn 8 Factorial Designs.

Rae §2.1, B&J §3.1, B&M § An equation for the matter waves: the time-dependent Schrődinger equation*** Classical wave equation (in one dimension):

Macroeconomic Analysis 2003

Organizational Behavior, 8e Schermerhorn, Hunt, and Osborn

1 Overview of the MBA Corporate Finance Major and Investment Management Major Andrew Karolyi & John Persons Department of Finance Fisher College of Business.

PH0101 UNIT 1 LECTURE 81 Five Major Building Acoustic Design Aspects Worked and Exercise Problems Sources of Noise.

Christopher G. Hamaker, Illinois State University, Normal IL

9/19/2013PHY 113 C Fall Lecture 81 PHY 113 C General Physics I 11 AM-12:15 PM MWF Olin 101 Plan for Lecture 8: Chapter 8 -- Conservation of energy.

AVL Trees CSE 373 Data Structures Lecture 8. 12/26/03AVL Trees - Lecture 82 Readings Reading ›Section 4.4,

Chapter 2 Section 2 Solving a System of Linear Equations II.

Economics 214 Lecture 2 Mathematical Framework of Economic Analysis Continued.

Bogazici University Dept. Of ME. Laplace Transforms Very useful in the analysis and design of LTI systems. Operations of differentiation and integration.

Economics 214 Lecture 13 Systems of Equations. Examples of System of Equations Demand and Supply IS-LM Aggregate Demand and Supply.

ENGG2013 Unit 3 RREF and Applications of Linear Equations

§ 3.5 Determinants and Cramer’s Rule.

EGR 1101 Unit 7 Systems of Linear Equations in Engineering (Chapter 7 of Rattan/Klingbeil text)

Building an IO Model l Form Input-Output Transactions Table which represents the flow of purchases between sectors. l Constructed from ‘Make’ and ‘Use’

Spring 2013 Solving a System of Linear Equations Matrix inverse Simultaneous equations Cramer’s rule Second-order Conditions Lecture 7.

Academy Algebra II/Trig

3x – 5y = 11 x = 3y + 1 Do Now. Homework Solutions 2)2x – 2y = – 6 y = – 2x 2x – 2(– 2x) = – 6 2x + 4x = – 6 6x = – 6 x = – 1y = – 2x y = – 2(– 1) y =

1 Ch. 4 Linear Models & Matrix Algebra Matrix algebra can be used: a. To express the system of equations in a compact manner. b. To find out whether solution.

© 2005 Baylor University Slide 1 Fundamentals of Engineering Analysis EGR Adjoint Matrix and Inverse Solutions, Cramer’s Rule.

The Use of Linear Systems in Economics: The Use of Linear Systems in Economics: Math 214 Presentation Jenn Pope and Reni Paunova Professor Buckmire Leontief.

Economic Systems Ohio Wesleyan University Goran Skosples 14. Input-Output Example.

Systems of Linear Equations The Substitution Method.

Ch. 5 Linear Models & Matrix Algebra

Elimination Method: Solve the linear system. -8x + 3y=12 8x - 9y=12.

Chiang & Wainwright Mathematical Economics

Systems of Linear Equations in Two Variables. 1. Determine whether the given ordered pair is a solution of the system.

Objective 1 You will be able to find the determinant of a 2x2 and a 3x3 matrix.

Solving Linear Systems by Substitution

5.4 Third Order Determinants and Cramer’s Rule. Third Order Determinants To solve a linear system in three variables, we can use third order determinants.

Chapter 7 Solving systems of equations substitution (7-1) elimination (7-1) graphically (7-1) augmented matrix (7-3) inverse matrix (7-3) Cramer’s Rule.

Module 7 Test Review. Formulas Shifting Functions  Given g(x) on a graph, f(x) = g(x) + 7 would mean that…..  Answer: g(x) would be shifted 7 units.

Chapter 8 Systems of Linear Equations in Two Variables Section 8.3.

Solving Systems of Linear equations with 3 Variables To solve for three variables, we need a system of three independent equations.

Section 2.1 Determinants by Cofactor Expansion. THE DETERMINANT Recall from algebra, that the function f (x) = x 2 is a function from the real numbers.

SYSTEMS OF LINEAR EQUATIONS College Algebra. Graphing and Substitution Solving a system by graphing Types of systems Solving by substitution Applications.

Essential Question: How do you solve a system of 3 equations? Students will write a summary of the steps for solving a system of 3 equations. Multivariable.

Function Notation and Making Predictions Section 2.3.

Solving Systems of Equations Chapter 3. System of Linear Equations 0 Consists of two or more equations. 0 The solution of the equations is an ordered.

Algebra 2 Chapter 3 Review Sections: 3-1, 3-2 part 1 & 2, 3-3, and 3-5.

CHAPTER III LAPLACE TRANSFORM

Chapter 12 Section 1.

The Inverse of a Square Matrix

Solving Systems of Linear Equations in 3 Variables.

Leontief Input-Output Model

Solving Linear Systems Algebraically

Solve a system of linear equation in two variables

Lesson 13-3: Determinants & Cramer’s Rule

Evaluate Determinants & Apply Cramer’s Rule

Systems of Linear Equations in Engineering

Systems of Linear Equations in Two Variables

Chapter 4 Systems of Linear Equations; Matrices

Simultaneous Equations

Use Inverse Matrices to Solve 2 Variable Linear Systems

Matrix Solutions to Linear Systems

4.6 Cramer’s Rule System of 2 Equations System of 3 Equations

Method 1: Substitution methods

An algebraic expression that defines a function is a function rule.

Algebra 2 Ch.3 Notes Page 15 P Solving Systems Algebraically.

Solving Systems of Linear Equations in 3 Variables.

Solve the linear system.

Chapter 4 Systems of Linear Equations; Matrices

Multivariable Linear Systems

Lesson 3.3 Writing functions.

Presentation transcript:

Ch. 5b Linear Models & Matrix Algebra 5.5 Cramer's Rule 5.6 Application to Market and National-Income Models 5.7 Leontief Input-Output Models 5.8 Limitations of Static Analysis

5.2 Evaluating a third-order determinant Evaluating a 3rd order determinant by Laplace expansion Ch. 5a Linear Models and Matrix Algebra 5.1 - 5.4

5.5 Deriving Cramer’s Rule (nxn) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.5 Deriving Cramer’s Rule (3x3) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.5 Deriving Cramer’s Rule (3x3) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.5 Deriving Cramer’s Rule (3x3) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.5 Deriving Cramer’s Rule (3x3) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.5 Deriving Cramer’s Rule (nxn) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.5 Deriving Cramer’s Rule (nxn) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.5 Deriving Cramer’s Rule (nxn) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.6 Applications to Market and National-income Models: Matrix Inversions Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.6 Macro model Section 3.5, Exercise 3.5-2 (a-d), p. 47 and Section 5.6, Exercise 5.6-2 (a-b), p. 111 Given the following model (a) Identify the endogenous variables (b) Give the economic meaning of the parameter g (c) Find the equilibrium national income (substitution) (d) What restriction on the parameters is needed for a solution to exist? Find Y, C, G by (a) matrix inversion (b) Cramer’s rule Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.6 The macro model (3.5-2, p. 47) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.6 The macro model (3.5-2, p. 47) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5. 6 Application to Market & National Income Models: Cramer’s rule (3 5.6 Application to Market & National Income Models: Cramer’s rule (3.5-2, p. 47) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.6 Application to Market & National Income Models: Matrix Inversion (3.5-2, p. 47) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.6 Application to Market & National Income Models: Matrix Inversion (3.5-2, p. 47) Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

Total gross output (xi) 5.7 Leontief Input-Output Models Miller and Blair 2-3, Table 2-3, p 15 Economic Flows ($ millions) Inputs (col’s) Outputs (rows) Sector 1 (zi1) Sector 2 (zi2) Final demand (di) Total gross output (xi) Intermediate inputs: Sector 1 150 500 350 1000 Intermediate inputs: Sector 2 200 100 1700 2000 Primary inputs (wi) 650 1400 1100 3150 Total outlays (xi) 6150 Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

Primary inputs (wi/xi) 5.7 Leontief Input-Output Models Miller and Blair 2-3, Table 2-3, p 15 Inter-industry flows as factor shares Inputs (col’s) Outputs (rows) Sector 1 (zi1/x1 =ai1) Sector 2 (zi2/x2 =ai2) Final demand (di) Total output (xi) Intermediate inputs: Sector 1 0.15 0.25 350 1000 Intermediate inputs: Sector 2 0.20 0.05 1700 2000 Primary inputs (wi/xi) 0.65 0.70 1100 3150 Total outlays (xi/xi) 1.00 6150 Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5. 7 Leontief Input-Output Models. Structure of an input-output model 5.7 Leontief Input-Output Models Structure of an input-output model Miller & Blair, p. 102 Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.7 Leontief Input-Output Models Structure of an input-output model Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

5.8 Limitations of Static Analysis Static analysis solves for the endogenous variables for one equilibrium Comparative statics show the shifts between equilibriums Dynamics analysis looks at the attainability and stability of the equilibrium Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8

Why use matrix method at all? Compact notation 5.6 Application to Market and National-Income Models Market model National-income model Matrix algebra vs. elimination of variables Why use matrix method at all? Compact notation Test existence of a unique solution Handy solution expressions subject to manipulation Ch. 5b Linear Models and Matrix Algebra 5.5 - 5.8