Consider the following quadratic equations in 2 variables. Write the equations in standard form.Find the centers...

1. Write the equation for the following conic sections in standard form: (a) An ellipse centered...

1. Write the equation for the following conic sections in standard form: (a) An ellipse centered at (2,-5) that passes through (2,-3) with foci at (4,-5) and (0,-5). (b) A hyperbola with vertices at (1,0) and (1, 4) and foci at (1,-1) and (1, 5).

1. Identify the vertex of the quadratic equation y=2x2+8x-10. using the formula 2. Write the equation...

1. Identify the vertex of the quadratic equation y=2x2+8x-10. using the formula 2. Write the equation y=2x2+8x-10. in vertex form using the vertex found in #1. 3. Show how you can use completing the square to go from the standard form of the equation in #1 to the vertex form found in #2. 4. Explain the relationship between the solutions to the quadratic equation 0=2x2+8x-10 and the graph of the quadratic equation y=2x2+8x-10. 5. How many solutions are possible when...

Consider the quadratic function f, given by f(x) = −x2 + 6x−8. (i) Determine if the...

Consider the quadratic function f, given by f(x) = −x2 + 6x−8. (i) Determine if the graph of y = −x2 + 6x − 8 is concave up or concave down, providing a justification with your answer. (ii) Re-write the equation of the quadratic function f, given by f(x) = −x2 +6x−8, in the standard form f(x) = a(x−h)2+k by completing the square. Hence determine the vertex of the graph of y = f(x). (iii) Identify the x-intercepts and y-intercept...

Solve the following differential equations using inspection: 1) y”+4y=12 2) y””+4y”+4y=-20 3) (D^4 -4D^2)y=24 4) y”-y=x-1...

Solve the following differential equations using inspection: 1) y”+4y=12 2) y””+4y”+4y=-20 3) (D^4 -4D^2)y=24 4) y”-y=x-1 5) D(D-3)y=4 6) (D^2+2D-8)(D+3)y=0 7) y”-y’-2y=18xe^(2x)

Use Gauss-Jordan method (augmented matrix method) to solve the following systems of linear equations. Indicate whether...

Use Gauss-Jordan method (augmented matrix method) to solve the following systems of linear equations. Indicate whether the system has a unique solution, infinitely many solutions, or no solution. Clearly write the row operations you use. (a) (5 points) x + y + z = 6 2x − y − z = 3 x + 2y + 2z = 0 (b) (5 points) x − 2y + z = 4 3x − 5y + 3z = 13 3y − 3z =...

Consider the following linear program: Max profit 8X + 4Y Subject to: 4X + 3Y ≤...

Consider the following linear program: Max profit 8X + 4Y Subject to: 4X + 3Y ≤ 480 2X + 3Y ≤ 360 X,Y ≥ 0 Use the corner point solution method to solve this linear program. The followings must be included in your answer: a) defined decision variables. b)a graph with constraints lines. c)highlighted feasible region. d)specified coordinates and profit for each corner point. e)specified optimal values of X and Y and optimal profit.

Decide whether or not the following equations are linear: (a) d^2/dx^2y(x) = -8(y(x))^2 is a -...

Decide whether or not the following equations are linear: (a) d^2/dx^2y(x) = -8(y(x))^2 is a - linear equation - non-linear equation (b) d/dx(yx) + sin(4y) = 0 is a - linear equation - non-linear equation (c) sin(8x)*d/dxy(x) + y(x) = 7x is a - linear equation - non-linear equation (d) d/dtx(t) +3x = -8t^3 is a - linear equation - non-linear equation (e) sin(5y(x))d/dxy(x) + y(x) = 9x is a - linear equation - non-linear equation

Consider the following linear programming model with 4 regular constraints: Maximize 3X + 5Y subject to:...

Consider the following linear programming model with 4 regular constraints: Maximize 3X + 5Y subject to: 4X + 4Y ≤ 48 (constraint #1) 2X + 3Y ≤ 50 (constraint #2) 1X + 2Y ≤ 20 (constraint #3) Y ≥ 2 (constraint #4) X, Y ≥ 0 (non-negativity constraints) (a) Which of the constraints is redundant? Constraint #____. Justify using the data from the above LP model: ________________________________________________________________________ ________________________________________________________________________ ________________________________________________________________________ (b) Is solution point (10,5) a feasible solution? _____. Explain using...

Consider the following joint distribution between random variables X and Y: Y=0 Y=1 Y=2 X=0 P(X=0,...

Consider the following joint distribution between random variables X and Y: Y=0 Y=1 Y=2 X=0 P(X=0, Y=0) = 5/20 P(X=0, Y=1) =3/20 P(X=0, Y=2) = 1/20 X=1 P(X=1, Y=0) = 3/20 P(X=1, Y=1) = 4/20 P(X=1, Y=2) = 4/20 Further, E[X] = 0.55, E[Y] = 0.85, Var[X] = 0.2475 and Var[Y] = 0.6275. a. (6 points) Find the covariance between X and Y. b. (6 points) Find E[X | Y = 0]. c. (6 points) Are X and Y independent?...

A statistical program is recommended. Consider the following data for two variables, x and y. xi...

A statistical program is recommended. Consider the following data for two variables, x and y. xi 135 110 130 145 175 160 120 yi 145 105 120 115 130 130 110 (a) Compute the standardized residuals for these data. (Round your answers to two decimal places.) xi yi Standardized Residuals 135 145 110 105 130 120 145 115 175 130 160 130 120 110 Do the data include any outliers? Explain. (Round your answers to two decimal places.) The standardized...