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MATHEMATICS 2204

MATHEMATICS 2204. ST. MARY’S ALL GRADE SCHOOL. Unit 01. Investigating Equations in 3-Space. Solving Systems of Equations Involving Two Variables. Choosing a phone plan. Solving Systems of Equations Involving Two Variables.

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MATHEMATICS 2204

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  1. MATHEMATICS 2204 ST. MARY’S ALL GRADE SCHOOL

  2. Unit 01 Investigating Equations in 3-Space

  3. Solving Systems of Equations Involving Two Variables Choosing a phone plan

  4. Solving Systems of Equations Involving Two Variables developing equations relating 2 variables and the corresponding graphs - cdli - math 2204.swf

  5. Finding points of intersection • finding points of intersection algebraicly - cdli - math 2204.swf

  6. SEATWORK Complete Investigation 1 on pages 2 & 3 of your text. • Do Investigation Question 1 AND also answer the following questions: • For what number of minutes of phoning would it be best to have Plan A? • For what number of minutes of phoning would it be best to have Plan B? • For what number of minutes of phoning would it be best to have Plan C?

  7. HOMEWORK • Do CYU Questions 2 - 4 on page 3.

  8. Visualization in Three Dimensions Labelling Axes in Three Dimensions

  9. classroom as a model of 3-space • For a point (x , y , z), the z-axis (the dependent variable) is always vertical, with positive in the up direction • the y-axis is always to the left and right, with positive to the right • the x-axis is always depicted as coming out of the page toward you. with positive coming out and negative "back behind the page".

  10. classroom as a model of 3-space • Stripping away the "room" above gives the following set of axes, the dashed lines are the parts you can't see in the above diagram:

  11. 3 – space coordinate system conventions • For a point (x , y ,z), the z-axis (the dependent variable)is always vertical, with positive in the up direction; • the y-axis is always to the left and right, with positive to the right; • the x-axis is always depicted as coming out of the page toward you. with positive coming out and negative "back behind the page".

  12. Introducing 3 space • introducing three space - cdli - math 2204.swf

  13. Equations in 3 variables • writing equations in three variables - cdli - math 2204.swf

  14. Visualization in Three Dimensions Sketching Planes on Paper

  15. interactive • constructing planes in 3 space using cubes - cdli - math 2204.swf

  16. sketching planes on isometric paper sketching planes on isometric paper cdli - math 2204.swf

  17. a two dimensional drawing of a three dimensional object diagrams on page 14 & 15

  18. Using the intercept method to sketch a plane • One method of graphing an equation in two variables such as y = 2x - 6 was to use the two-intercept method. • To find the y-intercept, just substitute x = 0, in the above equation, this gives y = 2(0) - 6 or y = -6. • So the y-intercept is (0 , -6). • Similarly, if we substitute y = 0 into the equation we have 0 = 2x - 6, and rearranging this gives x = 3. • So the x-intercept is (3 , 0). • Plotting these points on a set of axes and drawing the line through them gives the following graph:

  19. Using the intercept method to sketch a plane

  20. graph a plane on a set of three dimensional axes using the intercept method • Consider the equation z = -2x -3y +6, • the z-intercept (substituting x = 0, y = 0) is 6 • the y-intercept (substituting x = 0, z = 0) is 2 • the x-intercept (substituting y = 0, z = 0) is 3

  21. Plotting points in 3 space • plotting points in three space - cdli - math 2204.swf

  22. graphing a plane on a set of three dimensional axes using the intercept method

  23. example • Use the intercept method to sketch the plane with equation 3x + 6y - 2z = 6

  24. homework • Do Focus A: Investigation 3: Visualizing the Phone Charges Page 9 • Do Focus Questions 1 & 2 on page 10. • Complete Investigation 3 on pages 10 - 12. • Do Investigation Questions 3 - 8 on pages 12 and 13. • Do CYU Questions 9 -11 on page 13.

  25. Solving systems of equations involving two and three variables Combining information from different equations

  26. substitution method • One method used to solve two equations with two variables (unknowns). 

  27. Substitution example • Page 1 • Solve: • Page 2

  28. Examples done in class • Solve the following systems using the substitution method:                                              • 2x + 5y = 1                     -x  + 2y = 4                      • 0.29k + 9d  = 119 0.10k + 29d = 300

  29. interactive • focus d - math 2204.swf

  30. homework • Do the CYU Questions 5 to 11 on pages 26 and 27.

  31. Solving systems of equations involving two and three variables Graphing equivalent systems of equations

  32. creating and analyzing equivalent systems of equations Rearrange each equation to get its slope and y-intercept and sketch the graph of the system.

  33. creating and analyzing equivalent systems of equations Rearrange each equation to get its slope and y-intercept and sketch the graph of the system.

  34. creating and analyzing equivalent systems of equations the graph of the system

  35. elimination • Another algebraic method for solving two equations with two variables (that is, finding their intersection point) is the Elimination Method.

  36. elimination We could either eliminate y by multiplying the first equation by 3 and add or we could multiply the second equation by -2, which gives -2x - 6y = -18, and add. Let's choose the second option:

  37. graphing the resulting equation on the same axes as the original system

  38. Example done in class • Graph the following system of equations:  • Draw a vertical line and a horizontal line through the point of intersection of the two lines.

  39. Example done in class • Solve by the method of Elimination:

  40. Example done in class Solve by the method of Elimination:

  41. Seatwork and homework • Complete Investigation 4 on pages 27 & 28 of your text. • Do Investigation Questions 12-14 on page 28. Pay particular attention to Question 13, it shows the main point of the lesson. • Do the CYU Questions 15 - 21 on pages 28 and 29.

  42. Seatwork and homework • Complete Investigation 5 on page 30 of your text. • Do Investigation Questions 22 - 27, on page 31. • Do the CYU Questions 28 - 31 on pages 31 - 32.

  43. Seatwork and homework • Complete Investigation 6 on pages 32 & 33 of your text. • Do Investigation Questions 33 -35 page 33. • Do the CYU Questions 36 - 45 pages 34 - 35.

  44. Solving Systems of Equations Using Matrices: Writing Equations in Another Form

  45. Matrix multiplication example • Notebooks cost $1.19 and a pen costs $1.69 • Susan bought 5 notebooks and 3 pens • Mary bought 4 notebooks and 2 pens • Art bought 3 notebooks and no pens How much each person spent can be represented by the following matrix multiplication:

  46. Matrix multiplication example • Recall that to multiply two matrices, the number of columns in the left matrix must equal the number of rows in the right matrix. • In our example, the left matrix has 2 columns (it is a 3 x 2 matrix) and the right matrix has 2 rows (it is a 2 x 1 matrix).

  47. Matrix multiplication example • The product matrix is shown below:

  48. writing systems in matrix form • write one matrix containing the coefficients of the variables, one containing the variables, and one containing the constant terms.

  49. Another matrix multiplication example • To write the matrix form of a system of equations, there must be the same number of rows as there are variables. • If any variables or equations are missing, they must be filled in with zero coefficients.

  50. Example done in class • Write the following systems in matrix form:

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