course Mth 163 ÝIåÑóä¢ ’šøá}ûššþïõÌõòJ¡µØ¨¨assignment #020
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22:24:08 What are the zeros of f(x) = 2x - 6 and g(x) = x + 2?
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RESPONSE --> f(x) = 2x - 6, zero when x=3 g(x) = x + 2, zero when x=-2
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22:24:14 ** f(x) = 2x - 6 is zero when 2x - 6 = 0. This equation is easily solved to yield x = 3. g(x) = x + 2 is zero when x + 2 = 0. This equation is easily solved to yield x = -2. **
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22:28:52 What does the quadratic formula give you for the zeros of the quadratic polynomial q(x)?
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RESPONSE --> q(x) =f(x)*g(x)=(2x-6)(x+2) =2x(x+2)-6(x+2)=2x^2+4x-6x-12 = 2x^2-2x-12 a=2, b=-2, c=-12 x=[2+-sqrt(4-4(2)(-12))]/4 =[2+-sqrt(4+96)]/4 =(2+-sqrt100)/4 =(2+-10)/4 =12/4 = 3 or -8/4=-2
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22:29:08 ** We get q(x) = f(x) * g(x) = (2x - 6) ( x + 2) = 2x ( x + 6) - 6 ( x + 2) = 2 x^2 + 4 x - 6 x - 12 = 2 x^2 - 2 x - 12. This polynomial is zero, by the quadratic formula, when and only when x = [ -(-2) +- sqrt( (-2)^2 - 4(2)(-12) ] / (2 * 2) = [ 2 +- sqrt( 100) ] / 4 = [ 2 +- 10 ] / 4. Simplifying we get x = (2+10) / 4 = 3 or x = (2 - 10) / 4 = -2. This agrees with the fact that f(x) = 0 when and only when x = -3, and g(x) = 0 when and only when x = 2. The only was f(x) * g(x) can be zero is for either f(x) or g(x) to be zero. **
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22:32:49 2. If z1 and z1 are the zeros of x^2 - x + 6, then what is the evidence that x^2-x + 6=(x - z1) * (x - z2)?
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RESPONSE --> (x - z1) * (x - z2) is a common, ambiguous form of x^2-x + 6 factored out.
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22:33:10 ** z1 and z2 both give zero when plugged into x^2 - x + 6 and also into (x-z1)(x-z2). (x-z1)(x-z2) gives an x^2 term, matching the x^2 term of x^2 - x + 6. Since the zeros and the highest-power term match both functions are obtained from the basic y = x^2 function by the same vertical stretch, both have parabolic graphs and both have the same zeros. They must therefore be identical. **
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22:35:33 3. Explain why, if the quadratic polynomial f(x) = a x^2 + bx + c has no zeros, that polynomial cannot be the product of two linear polynomials.
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RESPONSE --> if f(x) has linear factors then zeros are going to be included, any linear factor can be set to equal zero to make it easier to solve for x. so if f(x) doesn't have zeros, then it can't have linear factors.
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22:35:42 ** If f(x) has linear factors, then if any of these linear factors is zero, multiplying it by the other factors will yield zero. Any linear factor can be set equal to zero and solved for x. Thus if f(x) has linear factors, it has zeros. So if f(x) has no zeros, it cannot have linear factors. **
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22:37:37 4. Explain why no polynomial of degree 2 can be the product of three or more polynomials of degree 1.
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RESPONSE --> a 2 degree polynomial cannot be the product of three or more polynomials of degree 1 because if there is a multiple of x^3 it has to be atleast to the third degree so degree 2 is out of the question.
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22:37:49 ** If you have 3 polynomials of degree one then each contains a nonzero multiple of x. Multiplying three such factors together will therefore yield a term which is a nonzero multiple of x^3. For example (x-2)(x+3)(x-1) = (x^2 + x - 6)(x+1) = x^3 + 2 x^2 - 5 x - 6. Any polynomial containing a nonzero multiple of x^3 has degree at least 3, and so cannot be of degree 2. Therefore a polynomial of degree 2 cannot be a product of three or more polynomials of degree 1. **
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22:43:47 5. What then would be the zeros and the large-x behavior of y = (x-7)(x+12)
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RESPONSE --> zeros are x = 7 or -12 if x is a large pos num, then y will also be a large pos num. also, if x is a large neg. number, then y will again be a large pos number the graph appears to be a parabola, it decreases on the left side, passes through the x axis at -12 then at some point shifts to be increasing and goes on to pass through the x axis again at 7
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22:44:01 ** y = 0 when x-7 = 0 or x+12 = 0, i.e., when x = 7 or x = -12. If x is a large positive number then both x-7 and x+12 are large positive numbers so that (x-7)(x+12) is a very large positive number. If x is a large negative number then both x-7 and x+12 are large negative numbers so that (x-7)(x+12) is again a very large positive number. So for large positive and negative x the function more and more rapidly approaches infinity. The graph will be decreasing, beginning with very large positive values at large negative x, as it passes through its leftmost zero at x = -12. The rate of decrease will initially be very rapid but will decrease less and less rapidly until the graph reaches a low point between x = 7 and x = -12, at which point it begins increasing at an increasing rate, passing through its rightmost zero at x = 7 and continuing with increasing slope as x becomes large. **
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22:46:04 Describe your graph of this function, describing all intercepts, intervals of increasing or decreasing behavior, concavity, and large-|x| behavior.
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RESPONSE --> for large x values, y is a pos. number. y-int= -84 zeros at 7 and -12 decreasing on left side and increasing on right side of vertex of the parabola
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22:46:34 STUDENT RESPONSE: for large | x | , y gets positive y intercept=-84 parabola opens upward very steeply rising with x intercepts at 7 and -12 INSTRUCTOR COMMENT: Good. Also, you should say that the polynomial is increasing for x > 2.5 and decreasing for x < 2.5
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22:50:17 6. Describe your graph of y = f(x) = (x-3)(x+2)(x+1), describing all intercepts, intervals of increasing or decreasing behavior, concavity, and large-|x| behavior.
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RESPONSE --> for large neg. x values, the graph is negative for large pos x values, the graph is postitive. zeros at 3, -2, and -1 graph is increasing starting with the large neg x value comes up to pass through (-2, 0) goes up, then begins to decrease and passes through (-1,0), continues to decrease passes through y intercept of -6, decreases goes through (1,-12) and inbetween this coordinate and (2,-12) the graph begins to increase and goes up through (3,0) and to the large pos x value.
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22:50:52 ** The function has zeros at x = 3, x = -2 and x = -1. For large positive x all three factors will be large positive numbers, so that the product will be a very large positive number. For large negative x all three factors will be large positive numbers, so that the product will be a very large negative number. The graph will be increasing, beginning with very large negative values at large negative x, as it passes through its leftmost zero at x = -2. The rate of increase will initially be very rapid but the graph will increase less and less rapidly until the graph reaches a relative maximum point between x = -2 and x = -1, at which point it begins decreasing. THe function will be decreasing as it passes through its zer0 at x = -1. Somewhere between x = -1 and its next zero at x = 3 the function will reach a relative minimum value after which it will begin to increase more and more rapidly. It will be increasing as it passes through its zero at x = 3 and will continue to increase faster and faster as x becomes larger. **
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22:52:55 1. Give the y = (x-x1)(x-x2)(x-x3) form of a degree 3 polynomial with zeros at x = -3, 1 and 2, as well as the y = ax^3 + bx^2 + cx + d form.
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RESPONSE --> y = (x-x1)(x-x2)(x-x3) y=(x+3)(x-1)(x-2) y = ax^3 + bx^2 + cx + d (x+3)(x-1)(x-2) (x+3)(x^2-2x-x+2) x^3-7x+6
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22:53:11 ** The factored form is y=(x+3)(x-1)(x-2) The standard polynomial form is obtained by multiplying these factors to obtain (x+3) ( x^2 - 2x - x + 2) = (x+3)( x^2 - 3x + 2) = (x^3 - 3 x^2 + 2 x) + (3 x^2 - 9 x + 6) = x^3 - 7 x + 6. **
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22:54:34 2. Describe how the two graphs of y = (x-1)(x+3)(x-4) and y = (1/12) * (x-1)(x+3)(x-4) compare.
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RESPONSE --> both graphs have zeros at -3, 1, and 4 with the difference between the two being that the graph of y = (1/12) * (x-1)(x+3)(x-4) is 12 times closer to the x axis then y = (x-1)(x+3)(x-4) is.
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22:55:14 ** The graphs both have zeros when x - 1 = 0, when x + 3 = 0 and when x - 4 = 0. These zeros therefore occur at x = 1, x = -3 and x = 4. The only difference is that the graph of y = 1/12 ( x-1)(x+3)(x-4) is everywhere 12 times closer to the x axis than that of y = (x-1)(x+3)(x-4), with 1/12 the slope at every point. **
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22:58:43 4. What function describes the approximate behavior of the graph of y = p(x) = (x-3)(x-3)(x+4) near the point (3,0)?
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RESPONSE --> y=7(x-3)^2 because x is close to 3 so 4+3 is clost to 7. But x-3 depends on how near to 3 the point is because if it is 3, it becomes a zero.
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22:58:58 ** If x is close to 3 then x + 4 is close to 7 and is not significantly different for various values near x = 3. However the nature of x - 3 depends greatly on just how close x is to 3, and whether x is greater or less than 3. x - 3 = 0 when x = 3, x - 3 < 0 when x > 3 and x - 3 > - when x < 3. (x-3)^2 will be zero when x = 3, and will increase at an increasing rate as x moves away from 3. So the function y = (x-3)(x-3)(x+4) is close to y = 7(x-3)^2. Note that this function describes a parabola with vertex at (3, 0), the 2d-degree zero of the given polynomial, and basic points (3, 0), (4, 7) and (2, 7). So near x = 3 the graph of p(x) = (x-3)(x-3)(x+4) will be very nearly matched by the parabolic graph of the function y = 7 ( x - 3) ^2. As x moves out of the vicinity of x = 3 the graphs will at first gradually, then more and more rapidly move apart. In general near z second-degree 0, like 3 in the present example, the graph of a parabola will look like a parabola whose vertex is at that zero. **
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23:00:56 Why do we say that near (3,0) the graph of (x-3)(x-3)(x+4) is approximately the same as the graph of 7(x-3)^2?
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RESPONSE --> the grah of (x-3)(x-3)(x+4) is approximately the same graph as 7(x-3)^2 near (3,0) because x+4=7 with a zero of 3 so that point is the same then the varying x values are ""approximately"" equal to one another wil little variation.
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23:01:07 with the zero of 3, x+4 will equal 7, so that portion of the graph will appear as a quadratic equation or a parabola
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23:02:12 Describe the graph of 7(x-3)^2.
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RESPONSE --> parabola with a horizontal shift of 3 and a vertical stretch of 7 units. vertex is (3,0) and basic points are (2,7) and (4,7)
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23:02:28 This is a parabola, obtained from the basic y = x^2 parabola by a vertical stretch of 7 and horizontal shift of 3 units. It will be a steep parabola with vertex (3, 0) and basic points at (2, 7) and (4, 7).
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23:03:23 How do the graphs made on your calculator or computer compare?
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RESPONSE --> the two graphs match closely at (3,0). at the right, parabola is gradually lower then the other graph and to the right it is gradually higher.
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23:03:42 The two graphs should match very closely near (3, 0). To the right the graph of the polynomial will gradually move higher than that of the parabola, and to the left will gradually move lower.
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23:05:32 What does the graph of a polynomial look like near a second-degree zero and why?
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RESPONSE --> i am not sure why,
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23:06:52 STUDENT ANSWER: parabola, when that portion is factored out it is a quadratic, since that zero is repeated the graph cannot cross the x axis at that point but must touch it sou appearing as a parabola INSTRUCTOR'S ADDITION: Also because the other factors of the polynomial remain nearly constant close to the zero.
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RESPONSE --> I still am not sure why, the polynomial only crosses the x axis once so this is the vertex of the parabola?
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23:14:35 5. Sketch graphs of y = (x-2)^2 * (x+3)^2 * (x-1) and y = -.5 * (x-3) (x+2)^3, including intercepts, the large-| x | behavior for both positive and negative x, concavity, and intervals of increasing and decreasing behavior.
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RESPONSE --> the graph of y = (x-2)^2 * (x+3)^2 * (x-1) has zeros at -3, 1 and 2 large neg x values have large neg y values and large pos x values have large pos y values. it starts increasing, reaches (-3,0) and begins decreasing, between this point ant (1,0) the graph begins to increase reaches about (1.5,2.75) and begins to decrease to (2,0) then again increases to large y values. the graph of y = -.5 * (x-3) (x+2)^3 has zeros at -2 and 3, for large neg x values there are large neg y values, for large pos x values, there are large neg y values. The graph increases, reaches (-2,0), levels off then begins to increase again and turns around at some larger y value, and begins to decrease to go through point (3,0) then continues to decrease to large neg y values.
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23:14:58 ** The graph of y = (x-2)^2 * (x+3)^2 * (x-1) is nearly parabolic in the vicinity of the zeros at 2 and -3. It only passes through the x axis at x = 1. Near x = 2 we can approximate all factors except (x-2)^2 by substituting x = 2, which gives us y = (x-2)^2 * (x+3)^2 * (x-1) = (x-2)^2 * (2+3)^2 * (2-1) = 25 (x-2)^2, an upward-opening parabola with vertex at x = 2. Near x = -3 we can approximate all factors except (x+3)^2 by substituting x = -3, which gives us y = (x-2)^2 * (x+3)^2 * (x-1) = (-3-2)^2 * (x+3)^2 * (-3-1) = -100 (x+3)^2, a downward-opening parabola with vertex at x = -3. For large positive x the graph is positive and concave up, increasing very rapidly. For large negative x the graph is negative and concave down, decreasing very rapidly. The graph rises from extremely large negative x values to the zero at x = -3, where it touches the x axis and turns back toward negative values without ever passing through the x axis. It reaches a minimum somewhere between x = -3 and x = 1, in the process passing through the y axis at (0, -36). The graph passes through the x axis at x = 1, going from negative to positive. It turns back toward the x axis at some point between x = 1 and x = 2, touches the x axis moving along in which is nearly parabolic in the vicinity of that point, and the turns back upward, increasing with a rapidly increasing slope as x moves to the right. The graph increases at a decreasing rate up to (-3,0), then decreases at an increasing rate until concavity changes from negative to positive sometime before the function reaches its minimum somewhere between (-3,0) and (1,0). Then it decreases at an increasing rate and continues to do so until a point between the local minimum and (1,0), probably close to (1,0), at which concavity again becomes negative. From that point the function increases as a decreasing rate until it reaches a local maximum somewhere between x=1 and x=2, at which point it begins decreasing at an increasing rate, remaining concave down until at some point before (2,0) the concavity becomes upward and the function begins decreasing at a decreasing rate until reaching the local minimum at (2,0). From that point it begins increasing at an increasing rate, maintaining an upward concavity and rapidly increasing to very large y values. ALTERNATIVE DESCRIPTION: The graph of y = -.5 * (x-3) (x+2)^3 passed thru the x axis at x = 3 and at x = -2. Near x = -2 we can approximate all factors except (x-2)^2 by substituting x = 2, which gives us y = -.5 ( -2 - 3) ( x + 2)^3 = 2.5 (x+2)^3. This function gives us a cubic polynomial with zero at x = -2 and basic points (-2, 0), (-3, -2.5) and (3, 2.5). For large positive x the graph is negative and concave down, decreasing very rapidly. For large negative x the graph is negative and concave up, decreasing very rapidly as x moves in the negative direction. The graph rises from extremely large negative x values toward the zero at x = -2, leveling off at (-2, 0) before again beginning to increase at a increasing rate. Somewhere before the zero at x = 3 the graph turns around and begins decreasing, passing downward through (3, 0) as it declines faster and faster into negative values.**
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