Clearly, the parabolas must intersect the x-axis at the same two points. Their distance multiplied by <math>4 - (-2)</math> (the distance between the y-intercepts), all divided by 2 is equal to 12, the area of the kite (half the product of the diagonals). That distance is thus 4, and so the x-intercepts are <math>(2, 0), (-2, 0).</math> Then <math>0 = 4a - 2 \rightarrow a = 0.5</math>, and <math>0 = 4 - 4b \rightarrow b = 1.</math> Then <math>a + b = \boxed{\textbf{(B)}\ 1.5}</math>.

Clearly, the parabolas must intersect the x-axis at the same two points. Their distance multiplied by <math>4 - (-2)</math> (the distance between the y-intercepts), all divided by 2 is equal to 12, the area of the kite (half the product of the diagonals). That distance is thus 4, and so the x-intercepts are <math>(2, 0), (-2, 0).</math> Then <math>0 = 4a - 2 \rightarrow a = 0.5</math>, and <math>0 = 4 - 4b \rightarrow b = 1.</math> Then <math>a + b = \boxed{\textbf{(B)}\ 1.5}</math>.

The parabolas must intersect the x-axis at the same two points for the kite to form. We find the x values at which they intersect by equating them and solving for x as shown below. <math>y = ax^2-2</math> and <math>y = 4 - bx^2\rightarrow ax^2-2 = 4-bx^2\rightarrow (a+b)x^2 = 6 \rightarrow x = +\sqrt{\dfrac{6}{a+b}}</math> or <math>-\sqrt{\dfrac{6}{a+b}}</math>. The x-values of the y-intercepts is 0, so we plug in zero in each of them and get <math>-2</math> and <math>4</math>. The area of a kite is <math>\dfrac{d_1*d_2}{2}</math>. The <math>d_1</math> is <math>2+4 = 6</math>. The <math>d_2</math> is <math>2\sqrt{\dfrac{6}{a+b}}</math>. Solving for the area <math>\rightarrow \dfrac{1}{2}*(6)*(2*\sqrt{\dfrac{6}{a+b}}) = 12 \rightarrow (2*\sqrt{\dfrac{6}{a+b}}) = 4 \rightarrow (\sqrt{\dfrac{6}{a+b}}) = 2 \rightarrow \dfrac{6}{a+b} = 4 \rightarrow  

The parabolas must intersect the x-axis at the same two points for the kite to form. We find the x values at which they intersect by equating them and solving for x as shown below. <math>y = ax^2-2</math> and <math>y = 4 - bx^2\rightarrow ax^2-2 = 4-bx^2\rightarrow (a+b)x^2 = 6 \rightarrow x = +\sqrt{\dfrac{6}{a+b}}</math> or <math>-\sqrt{\dfrac{6}{a+b}}</math>. The x-values of the y-intercepts is 0, so we plug in zero in each of them and get <math>-2</math> and <math>4</math>. The area of a kite is <math>\dfrac{d_1*d_2}{2}</math>. The <math>d_1</math> is <math>2+4 = 6</math>. The <math>d_2</math> is <math>2\sqrt{\dfrac{6}{a+b}}</math>. Solving for the area <math>\rightarrow \dfrac{1}{2}*(6)*(2*\sqrt{\dfrac{6}{a+b}}) = 12 \rightarrow (2*\sqrt{\dfrac{6}{a+b}}) = 4 \rightarrow (\sqrt{\dfrac{6}{a+b}}) = 2 \rightarrow \dfrac{6}{a+b} = 4 \rightarrow  

\dfrac{6}{4} = (a+b)</math>, therefore <math>a + b = \boxed{\textbf{(B)}\ 1.5}</math>.

\dfrac{6}{4} = (a+b)</math>, therefore <math>a + b = \boxed{\textbf{(B)}\ 1.5}</math>.