Curve sketching This Power Point presentation shows the

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Curve sketching This Power. Point presentation shows the different stages involved in sketching the

Curve sketching This Power. Point presentation shows the different stages involved in sketching the graph

Sketching the graph Step 1: Find where the graph cuts the axes When x

Sketching the graph Step 1: Find where the graph cuts the axes When x = 0, y = 3, so the graph goes through the point (0, 3). When y = 0, there are no real values of x, so the graph does not cut the x-axis.

Sketching the graph Step 2: Find the vertical asymptotes The denominator is zero when

Sketching the graph Step 2: Find the vertical asymptotes The denominator is zero when x = -1 The vertical asymptote is x = -1

Sketching the graph Step 2: Find the vertical asymptotes The denominator is zero when

Sketching the graph Step 2: Find the vertical asymptotes The denominator is zero when x = -1 The vertical asymptote is x = -1 For now, don’t worry about the behaviour of the graph near the asymptote. You may not need this information.

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing out gives For numerically large values of x, y → x + 2. This means that y = x + 2 is an oblique asymptote.

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing out gives For numerically large values of x, y → x + 2. This means that y = x + 2 is an oblique asymptote.

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing out gives For numerically large values of x, y → x + 2. This means that y = x + 2 is an oblique asymptote. For large positive values of x, y is slightly greater than x + 2. So as x → ∞, y → x + 2 from above.

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing out gives For numerically large values of x, y → x + 2. This means that y = x + 2 is an oblique asymptote. For large negative values of x, y is slightly less than x + 2. So as x → ∞, y → x + 2 from below.

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing

Sketching the graph Step 3: Examine the behaviour as x tends to infinity Dividing out gives For numerically large values of x, y → x + 2. This means that y = x + 2 is an oblique asymptote. For large negative values of x, y is slightly less than x + 2. So as x → ∞, y → x + 2 from below.

Sketching the graph Step 4: Complete the sketch It is easy to complete the

Sketching the graph Step 4: Complete the sketch It is easy to complete the part of the graph to the right of the asymptote, which must pass through the point on the y axis.

Sketching the graph Step 4: Complete the sketch It is easy to complete the

Sketching the graph Step 4: Complete the sketch It is easy to complete the part of the graph to the right of the asymptote, which must pass through the point on the y axis.

Sketching the graph Step 4: Complete the sketch We can also complete the part

Sketching the graph Step 4: Complete the sketch We can also complete the part of the graph to the left of the asymptote, remembering that the graph does not cut the x-axis.

Sketching the graph Step 4: Complete the sketch We can also complete the part

Sketching the graph Step 4: Complete the sketch We can also complete the part of the graph to the left of the asymptote, remembering that the graph does not cut the x-axis.