Figure 6 shows a sketch of the curve C with parametric equations $x = 2 an t + 1$ y = 2 ext{sec}^2 t + 3$ $-rac{rac{eta}{4}} ext{ } ext{ } rac{eta}{3} ext{ } | ext{}| | ext{}| ext{ }$ (a) The line l is the normal to C at the point P where $t = rac{eta}{4}$ (b) Show that all points on C satisfy the equation y = rac{1}{2} (x - 1)^2 + 5 (5) The straight line with equation y = rac{1}{2} (x - 1) + k ext{ where k is a constant} intersects C at two distinct points - Edexcel - A-Level Maths Pure - Question 1 - 2022 - Paper 2

To find the Cartesian equation relating x and y, we can express t in terms of x:

1. From the equation $x = 2 an(t) + 1$, we get: an(t) = rac{x - 1}{2}.

2. Substituting into the y equation: y = 2 ext{sec}^2(t) + 3 = 2igg(1 + an^2(t)igg) + 3 = 2igg(1 + ig(rac{x - 1}{2}ig)^2igg) + 3.

3. Simplifying: y = 2igg(1 + rac{(x - 1)^2}{4}igg) + 3 = rac{1}{2}(x - 1)^2 + 5.

4. This proves that all points (x, y) on C satisfy the equation: y = rac{1}{2} (x-1)^2 + 5.

To find the range of k for which the line intersects C at two distinct points:

1. Set the expressions for y equal: rac{1}{2}(x - 1)^2 + 5 = rac{1}{2}(x - 1) + k.

2. Rearranging gives: rac{1}{2}(x - 1)^2 - rac{1}{2}(x - 1) + (5 - k) = 0.

3. This is a quadratic equation in $x$, and for it to have two distinct roots, the discriminant must be positive: $b^2 - 4ac > 0$ Here, a = rac{1}{2}, b = -rac{1}{2}, c = 5 - k.

4. The discriminant is:

   $$$$

ightarrow rac{1}{4} - 2(5 - k) > 0 ightarrow rac{1}{4} < 10 - 2k$$

5. Simplifying: $$$$

ightarrow 2k < rac{40 - 1}{4} ightarrow 8k < 39 ightarrow k < rac{39}{8} = 4.875.$$

6. For the other bound, we also have: $$$$

ightarrow k > 0.125.$$

7. Thus, the range of k is: $0.125 < k < 4.875.$