The left panel of Figure 3 shows an elliptic hyperboloid of two sheets given by 4x²-y²-2²=1. The middle panel shows the plane 2xy + z = k intersecting the two sheets, resulting in two space curves. With the plane removed for clarity, the right panel just shows the space curves and the hyperboloid.The magenta and navy space curves will be referred to as C₁ and C2 respectively. 10 -10 -10 -10 10 Figure 3 The parametrisation used to plot these space curves is x(t) = y(t) = t 212-4t+5 4(t-2) 3-4t 10 -10 10 -10 (1) (2) (3) z(t) == 2(t-2) a) Find the domain of t for C1 and C2 b) Using equations (1), (2) and (3) as a guide, determine the general space curve parametrisation in terms of k for the case presented above. This doesn't need to involve the 3 equations subbed directly in to the hyperboloid/plane equations, just ie sub the plane equation into the hyperboloid equation, leaving a relationship involving x,y and k; or y,z and k. c) Parametrically define the hyperboloid.

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The left panel of Figure 3 shows an elliptic hyperboloid of two sheets given by 4x² - y² - 2² = 1. The middle panel shows the plane 2x space curves. With the plane removed for clarity, the right panel just shows the space curves and the y + z = k intersecting the two sheets, resulting in two hyperboloid. The magenta and navy space curves will be referred to as C₁ and C2 respectively. -10 -10 10 10 10 zo -10 -10 ㅎ -10 0 10 Figure 3 The parametrisation used to plot these space curves is 2t² - 4t+5 x(t) = 4(t-2) y(t) t 3-4t z(t) = 2(t-2) 10 -10 Zo -10 -10 0 10 (1) (2) (3) a) Find the domain of t for C1 and C2 b) Using equations (1), (2) and (3) as a guide, determine the general space curve parametrisation in terms of k for the case presented above. This doesn't need to involve the 3 equations subbed directly in to the hyperboloid/plane equations, just ie sub the plane equation into the hyperboloid equation, leaving a relationship involving x,y and k; or y,z and k. c) Parametrically define the hyperboloid.