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Question
the piecewise function h(x) is shown on the graph. what is the value of h(3)? options: (choices include -1, 1, 2; graph shows a piecewise function with segments: left from (-5, -4) to (-1, 2) (open circle at (-1,2)), middle from (-1, 3) (closed circle) to (1, 3), right from (1, 3) to (4, 0) (closed circle at (4,0)))
Step1: Locate x = 3 on the graph
Find the point on the graph where the x - coordinate is 3. The graph of the piece - wise function at x = 3 is on the line segment that goes from (2, 3) to (4, 0).
Step2: Determine the y - value at x = 3
We can use the two - point form of a line to find the equation of the line segment from (2, 3) to (4, 0). The slope $m=\frac{y_2 - y_1}{x_2 - x_1}=\frac{0 - 3}{4 - 2}=\frac{- 3}{2}$. Using the point - slope form $y - y_1=m(x - x_1)$ with the point (4, 0), we have $y-0=\frac{-3}{2}(x - 4)$, or $y=\frac{-3}{2}x + 6$. When $x = 3$, $y=\frac{-3}{2}\times3+6=\frac{-9 + 12}{2}=\frac{3}{2}=1.5$? Wait, no, maybe a better way is to look at the graph. The line from (2, 3) to (4, 0) has a slope of - 3/2. From x = 2 to x = 4 (a change of 2 in x), the y - value changes from 3 to 0 (a change of - 3). So for each 1 unit increase in x, y decreases by 3/2. At x = 2, y = 3. At x = 3 (1 unit from x = 2), y=3-\frac{3}{2}=\frac{3}{2}=1.5? Wait, but looking at the options, maybe I made a mistake. Wait, the graph: when x = 2, the point is (2, 3) (a closed dot), then it goes to (4, 0) (closed dot). Let's check the value at x = 3. The line passes through (2, 3) and (4, 0). The equation is $y=- \frac{3}{2}x + 6$. When x = 3, $y=- \frac{9}{2}+6=\frac{3}{2}=1.5$? But the options are 3, - 1, 1, 2. Wait, maybe I misread the graph. Wait, maybe the first part: from x=-5 to x=-1, then from x=-1 to x = 2, then from x = 2 to x = 4. Wait, the graph at x = 3: let's count the grid. If at x = 2, y = 3, and at x = 4, y = 0. So the line goes down 3 units over 2 units. So from x = 2 to x = 3 (1 unit), it goes down 1.5 units, so y = 3 - 1.5 = 1.5. But the options don't have 1.5. Wait, maybe the graph is different. Wait, maybe the line from (2, 3) to (4, 0) is actually a line where at x = 3, y = 1? Wait, no, let's re - examine. Wait, the options are 3, - 1, 1, 2. Wait, maybe I made a mistake in the graph interpretation. Wait, the first part: from x=-5 (the dot) to x=-1 (open circle at y = 2, closed circle at y = 3? Wait, no, the graph: the left part is a line from (-5, - 4) to (-1, 2) (open circle at (-1, 2)), then a horizontal line from (-1, 3) (closed circle) to (2, 3) (closed circle), then a line from (2, 3) to (4, 0) (closed circle). So the function for x in [2, 4] is the line from (2, 3) to (4, 0). Let's calculate the value at x = 3. The slope is (0 - 3)/(4 - 2)=-3/2. So the equation is y - 3=(-3/2)(x - 2). When x = 3, y-3=(-3/2)(1), so y=3 - 3/2=3/2 = 1.5. But the options are 3, - 1, 1, 2. Wait, maybe the graph is drawn with integer coordinates. Wait, maybe at x = 3, the y - value is 1? Wait, no, maybe I misread the graph. Wait, the options include 1. Let's think again. Maybe the line from (2, 3) to (4, 0) has a slope of - 1? If slope is - 1, then equation is y-3=-(x - 2), y=-x + 5. When x = 3, y = 2. No. If slope is - 2/3? No. Wait, maybe the graph is such that at x = 3, the y - value is 1. Wait, maybe the original graph has different coordinates. Alternatively, maybe I made a mistake. Wait, the options are 3, - 1, 1, 2. Let's check the horizontal line: from x=-1 to x = 2, y = 3. Then from x = 2 to x = 4, it's a line going down. At x = 3, which is between 2 and 4, let's see the distance from x = 2 to x = 4 is 2 units, and from y = 3 to y = 0 is 3 units. So per unit x, y decreases by 3/2. But 3/2 is 1.5. But since 1.5 is not an option, maybe the graph is intended to have at x = 3, y = 1? Wait, no, maybe the correct answer is 1? Wait, no, let's check again. Wait, maybe the line is from (2, 3) to (4, 0), so when x = 3, y = 1.5, but sin…
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