Quadratic Functions and Projectile Motion (Hard) - SAT Physics Practice Questions

The maximum height occurs at the vertex of the parabola \( h(t) = -4.9t^2 + 29.4t + 50 \). Using the vertex formula \( t = -\frac{b}{2a} = \frac{29.4}{2 \times 4.9} = 3 \) seconds. Substituting \( t = 3 \) into the equation gives \( h(3) = -4.9(3)^2 + 29.4(3) + 50 = -44.1 + 88.2 + 50 = 94.1 \) meters. The height of the cliff is the initial height when \( t = 0 \): \( h(0) = 50 \) meters.

The velocity is the derivative of the altitude function: \( v(t) = h'(t) = -10t + 20 \). Setting \( v(t) = 0 \) gives \( -10t + 20 = 0 Rightarrow t = 2 \) seconds. To find the maximum altitude, substitute \( t = 2 \) into \( h(t) = -5t^2 + 20t + 100 \): \( h(2) = -5(2)^2 + 20(2) + 100 = -20 + 40 + 100 = 120 \) meters.

First, find the times when the car changes direction by setting the velocity to zero. The velocity is the derivative of the position function: \( v(t) = s'(t) = -6t + 18 \). Setting \( v(t) = 0 \) gives \( -6t + 18 = 0 Rightarrow t = 3 \) seconds. Calculate the positions at \( t = 0, 3, 6 \): \( s(0) = 2, s(3) = 29, s(6) = 2 \). The total distance is the sum of distances traveled in each interval: \( |s(3) - s(0)| + |s(6) - s(3)| = |29 - 2| + |2 - 29| = 27 + 27 = 54 \) meters.

The projectile returns to the ground when \( h(t) = 0 \). Solving \( -4.9t^2 + 19.6t + 1.5 = 0 \) using the quadratic formula \( t = \frac{-b \pm \sqrt{b^2 - 4ac}}{2a} \), we get \( t = \frac{-19.6 \pm \sqrt{(19.6)^2 - 4(-4.9)(1.5)}}{2(-4.9)} \). Simplifying, \( t = \frac{-19.6 \pm \sqrt{384.16 + 29.4}}{-9.8} = \frac{-19.6 \pm \sqrt{413.56}}{-9.8} \). The positive root gives \( t \approx 4.07 \) seconds.

The maximum height occurs at the vertex of the parabola \( h(t) = -5t^2 + 20t + 50 \). Using the vertex formula \( t = -\frac{b}{2a} = \frac{20}{2 \times 5} = 2 \) seconds. Substituting \( t = 2 \) into the equation gives \( h(2) = -5(2)^2 + 20(2) + 50 = 70 \) meters.

The maximum height occurs at the vertex of the parabola \( h(t) = -5t^2 + 20t + 100 \). Using the vertex formula \( t = -\frac{b}{2a} = \frac{20}{2 \times 5} = 2 \) seconds.

The initial height is the value of \( h(t) \) at \( t = 0 \). Substituting \( t = 0 \) into \( h(t) = -4.9t^2 + 20 \) yields \( h(0) = 20 \) meters.

The car moves fastest when its velocity is at a maximum, which is the time when the acceleration changes sign. The acceleration is the second derivative of \( D(t) \), which is \( a(t) = -4 \). Since acceleration is constant, the car moves fastest at the vertex of the parabola \( D(t) = -2t^2 + 8t + 10 \), at \( t = -\frac{b}{2a} = \frac{8}{2 \times 2} = 2 \) seconds. Substituting \( t = 2 \) into \( D(t) \) gives \( D(2) = -2(2)^2 + 8(2) + 10 = 18 \) meters.

The maximum height occurs at the vertex of the parabola \( h(t) = -3t^2 + 12t + 50 \). Using the vertex formula \( t = -\frac{b}{2a} = \frac{12}{2 \times 3} = 2 \) seconds.

The maximum height occurs at the vertex of the parabola \( h(t) = -5t^2 + 10t + 20 \). Using the vertex formula \( t = -\frac{b}{2a} = \frac{10}{2 \times 5} = 1 \) seconds. Substituting \( t = 1 \) into the equation gives \( h(1) = -5(1)^2 + 10(1) + 20 = 25 \) meters.

The rocket starts descending after reaching its peak altitude, which occurs at the vertex of the parabola \( A(t) = -4t^2 + 24t + 15 \). The vertex is found at \( t = -\frac{b}{2a} = \frac{24}{2 \times 4} = 3 \) seconds.

The velocity is the derivative of the position function. Differentiating \( s(t) = -3t^2 + 18t + 2 \) gives \( v(t) = -6t + 18 \). Substituting \( t = 4 \) into \( v(t) \) results in \( v(4) = -6(4) + 18 = -6 \) meters per second.

The initial height is the value of \( H(t) \) at \( t = 0 \). Substituting \( t = 0 \) into \( H(t) = -5t^2 + 20t + 10 \) yields \( H(0) = 10 \) meters.

To find the time at which the car reaches its maximum distance, we use the vertex formula for the quadratic function \( d(t) = -2t^2 + 12t + 3 \). The vertex occurs at \( t = -\frac{b}{2a} = \frac{12}{2 \times 2} = 3 \) seconds.

The maximum height occurs at the vertex of the parabola described by \( h(t) = -4.9t^2 + 19.6t + 1.5 \). Using the vertex formula \( t = -\frac{b}{2a} \), we find \( t = \frac{19.6}{2 \times 4.9} = 2 \) seconds. Substituting \( t = 2 \) into the equation gives \( h(2) = -4.9(2)^2 + 19.6(2) + 1.5 = 21.5 \) meters.