In the diagram, A(-2 ; 10), B(k ; k) and C(4 ; -2) are the vertices of \( \Delta ABC \) - NSC Mathematics - Question 3 - 2021 - Paper 2

For line AB, we need the coordinates of points A(-2, 10) and B(k, k).

Using the slope formula: [ m_{AB} = \frac{k - 10}{k + 2} ] For the specific angle provided (81.87°), we can use the tangent function: [ m_{AB} = \tan(81.87°) \approx 7 ] Thus, we can derive ( k ) based on the required slope.

To determine the equation of line BE, we already found the gradient as ( \frac{1}{4} ). Using point B(k, k), we can apply the point-slope form: [ y - y_1 = m(x - x_1) ] Substituting our values gives: [ y - k = \frac{1}{4}(x - k) ] Rearranging and solving will yield the equation in the desired form.

To find the specific coordinates of B(k, k) according to the previous calculations, substituting k will give: [ \text{If } k = -4, B(-4, -4) ]

Using the coordinates of points A, B, and C, the formula for angle A can be derived using the cosine rule. We utilize the lengths of sides and the known angles: [ a^2 = b^2 + c^2 - 2bc \cdot \cos A ] Substituting all lengths will yield ( \size{\hat{A}} ).

By calculating the midpoints of the lines AC and BE, we find the intersection at: [ M = \left( \frac{12 + (-2)}{2}, \frac{10 + (-2)}{2} \right) = (5, 4) ]

Given ( ET = \frac{4}{\sqrt{17}} ), and coordinates of point E: Substituting values into the distance formula will give the coordinates of T. Solve for ( p ) using the condition ( p > 0 ) yielding coordinates (p, p).

The equation of the circle can be established as: [ (x - 12)^2 + (y - 0)^2 = r^2 ] where ( r ) is the distance from E to either B or T, obtained from their coordinates.

To find the tangent at point B, we will use the formula for a tangent line, ensuring it meets the circle's equation responses accordingly from point B(k, k). This requires referencing the derivative of the circle at point B.