Solving Systems of Equations Using Substitution.  Graphing systems and comparing table values are good ways to see solutions.  It is not always easy.

Slides:

Advertisements

Similar presentations

Lines in the Coordinate Plane

Advertisements

Warm Up 0?1? 2? Graph the linear functions.0?1? 2?

Chapter 8: Linear Equations as Models

Objectives Find the two intercepts Graph a line using intercepts

Chapter Using Intercepts.

Solving Systems of Equations

Objectives Graph functions given a limited domain.

3.1 Solving Systems by Graphing or Substitution

Thinking Mathematically Algebra: Graphs, Functions and Linear Systems 7.3 Systems of Linear Equations In Two Variables.

A solution of a system of two equations in two variables is an ordered pair of numbers that makes both equations true. A solution to two equations (1,

Solving Systems by Graphing

Solving Systems of Linear Equations by Graphing

Graphing Systems of Equations Graph of a System Intersecting lines- intersect at one point One solution Same Line- always are on top of each other,

Chapter 7.1 Notes: Solve Linear Systems by Graphing Goal: You will solve a system of linear equations graphically.

3.1 Solve Linear Systems by Graphing. Vocabulary System of two linear equations: consists of two equations that can be written in standard or slope intercept.

Topic: Solving Systems of Linear Equations by Graphing.

Warm Up Graph the lines on the same grid and identify the point where they meet. 1. y=2x-2 2. y=x+1.

Starter Write an equation for a line that goes through point (-3,3) and (0,3) y = 1/2 x + 3/2.

Advanced Algebra Notes

Section 3.5 Systems of Equations. What is a system of equations? Two or more equations in the same variables.

Lesson 1 Contents Example 1Number of Solutions Example 2Solve a System of Equations Example 3Write and Solve a System of Equations.

ALGEBRA 1 Lesson 6-1 Warm-Up. ALGEBRA 1 “Solving Systems by Graphing” (6-1) What is a “system of linear equations”? What is the “solution of the system.

Systems of Linear Equations

Determine whether (2, 4) is a solution for y= 5x-6.

Warm up: Solve the given system by elimination

Objective Find slope by using the slope formula..

Points and Ordered Pairs Plot points on the rectangular coordinate system. Plot the x coordinate first then the y coordinate. This is an ordered pair.

Objective : Solving systems of linear equations by graphing System of linear equation two or more linear equations How do I solve linear systems of equations?

Section 7.1 Solving Linear Systems by Graphing. A System is two linear equations: Ax + By = C Dx + Ey = F A Solution of a system of linear equations in.

LESSON 2 – SOLVING LINEAR SYSTEMS GRAPHICALLY SYSTEMS OF LINEAR EQUATIONS.

Systems of Linear Equations Using a Graph to Solve.

 What is the slope of the line that passes through the following points. 1.(-2, 5) (1, 4)  Identify the slope and y -intercept of each equation. 2.y.

Solving Systems by Graphing

Linear Systems of Equations Section 3.1. What is a “system” of equations?

What is a system of equations? A system of equations is when you have two or more equations using the same variables. The solution to the system is the.

6-4 Solving Special Systems Warm Up Warm Up Lesson Presentation Lesson Presentation California Standards California StandardsPreview.

Lesson 7.1 Solving Systems of Equations by Graphing.

Holt Geometry 3-6 Lines in the Coordinate Plane 3-6 Lines in the Coordinate Plane Holt Geometry Warm Up Warm Up Lesson Presentation Lesson Presentation.

Section 4.2 Solving Systems of Equations by Substitution.

What happens if we graph a system of equations and the lines intersect? y = x-1 y = 2x-2.

 We have studied several linear relations in the previous chapters ◦ Height of elevators ◦ Wind chill ◦ Rope length ◦ Walks in front of a CRB  In this.

Objective The student will be able to: solve systems of equations by graphing.

EXAMPLE 1 Solve a system graphically Graph the linear system and estimate the solution. Then check the solution algebraically. 4x + y = 8 2x – 3y = 18.

7.2 – SOLVING LINEAR SYSTEMS GRAPHICALLY SYSTEMS OF LINEAR EQUATIONS.

Warm Up 116 Solve. 6n + 4 = n – 11 Determine whether each linear relationship is proportional. If so, state the constant of proportionality. Write an equation.

Using Systems of Equations to Solve Problems A Write and/or solve a system of linear equations (including problem situations) using graphing,

 Students will be able to solve linear systems using substitution. In Chapter 3-1, you were able to solve a linear system of equations by rewriting each.

Holt Algebra Solving Special Systems 6-4 Solving Special Systems Holt Algebra 1 Warm Up Warm Up Lesson Presentation Lesson Presentation Lesson Quiz.

Lessons 8-5 to 8-10 and Graphing Inequalities

Solve. 6n + 4 = n – 11 Determine whether each linear relationship is proportional. If so, state the constant of proportionality. Warm Up 116 Write an.

Writing Linear Equations in Slope-Intercept Form

Warm Up Problem of the Day Lesson Presentation Lesson Quizzes.

3-1 Graphing Systems of Equations

Solve Systems of Equations by Graphing

Special Cases Involving Systems

Notes Over 4.7 Solving an Equation Graphically

Unit 7: Systems of Equations

Solving Systems by Graphing

9.3 – Graphing Linear Equations

6-1 Solving Systems by Graphing

2. A System of Equations is a pair of equations with two variables

Day 5 – Forms of Equation.

has one solution, it is the point where the lines intersect

2. A System of Equations is a pair of equations with two variables

Solve Systems of Equations by Graphing

Writing Linear Equations

Equations With Two Variables pages

Unit 7: Systems of Equations

Graphing Systems of Equations.

Solving Linear Systems by Graphing

Presentation transcript:

Solving Systems of Equations Using Substitution

 Graphing systems and comparing table values are good ways to see solutions.  It is not always easy to find a good graphing window or the right settings for the table to view the solution.  Often these solutions are only approximations.  To find the exact solutions, you’ll need to work algebraically with the equations.  Let’s look at the substitution method.

 On a rural highway a police officer sees a motorist run a red light at 50 mph and begins pursuit. At the instant the police officer passes through the intersection at 60 mph, the motorist is 0.2 mi down the road. When and where will the office catch up to the motorist? ◦ Write an equation in two variables to model this situation. Motorist: Police: d= the distance from the intersection t= time traveled

 On a rural highway a police officer sees a motorist run a red light at 50 mph and begins pursuit. At the instant the police officer passes through the intersection at 60 mph, the motorist is 0.2 mi down the road. When and where will the office catch up to the motorist? ◦ Solve this system by the substitution method and check the solution.

When the officer catches up to the motorist they will the same distance from the intersection (so both equations will have the same d value. Replace the d value in one equation with the d value from the other equation. Solve this new equation for t.

So at t=0.02 hours the police and motorist will be the same distance from the intersection. At t=0.02 hours both the police and motorist will be 1.2 miles from the intersection. This is the only ordered pair that works in both equations.

 Materials needed ◦ Two ropes of different thickness about 1 m long ◦ Measuring tape ◦ One 9 meter long thin rope (optional) ◦ One 10 meter long thick rope (optional)

 Step 1 Measure the length of the thinner rope without any knots. ◦ Then tie a knot and measure the length of the rope again. Continue tying knots until no more can be tied. Knots should be of the same kind, size, and tightness. Record the data for number of knots and length of rope in a table.

 Step 2 Define variables and write an equation in intercept form to model the data you collected in Step 1. ◦ What are the slope and y-intercept, and how do they relate to the rope?  Step 3 Repeat Steps 1 and 2 for the thicker rope.

 Step 4 Suppose you have a 9-meter-long thin rope and a 10-meter-long thick rope. ◦ Write a system of equations that gives the length of each rope depending on the number of knots tied.

 Step 5 Solve this system of equations using the substitution method.  Step 6 Select an appropriate window setting and graph this system of equations. Estimate coordinates for the point of intersection to check your solution. Compare this solution with the one from Step 5.  Step 7 Explain the real-world meaning of the solution to the system of equations.  Step 8 What happens to the graph of the system if the two ropes have the same thickness? The same length?

Number of KnotsLength (cm) Number of KnotsLength (cm) Sample Data I

Number of KnotsLength (cm) Number of KnotsLength (cm) Sample Data II

 So far you have seen equations written in intercept form.  These equations make it easy to use the substitution method since they are already both solved for y. ◦ y=900 -6x ◦ y= x  Sometimes it is necessary to place equations in intercept form before using substitution.

 A pharmacist has 5% saline (salt) solution and 20% saline solution. How much of each solution should be combined to create a bottle of 90 ml of 10% solution. ◦ Write a system of equations that models this situation. If x represents the amount of 5% solution and y represents the amount of 20% solution then Thinking about the salt in each solution gives another equation

 A pharmacist has 5% saline (salt) solution and 20% saline solution. How much of each solution should be combined to create a bottle of 90 ml of 10% solution. ◦ Solve the one equation for x or y and substitute it into the other equation. Find a solution.

 Saw limitations to solving a problem graphically  Learned how to solve a system of equations using substitution.