The motion of a point on the circumference of a rolling wheel of radius 4 feet is described by the vector function r(t) = 4(12t - sin(12t))i + 4(1 − cos(12t))] Find the velocity vector of the point. v(t) Find the acceleration vector of the point. ä(t) Find the speed of the point. s(t) =

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### Vector Calculus Problem: Motion on the Circumference of a Rolling Wheel The motion of a point on the circumference of a rolling wheel of radius 4 feet is described by the vector function: \[ \vec{r}(t) = 4(12t - \sin(12t))\hat{i} + 4(1 - \cos(12t))\hat{j} \] #### Find the Velocity Vector of the Point \[ \vec{v}(t) = \] #### Find the Acceleration Vector of the Point \[ \vec{a}(t) = \] #### Find the Speed of the Point \[ s(t) = \] ### Explanation: - \(\vec{r}(t)\) represents the position vector as a function of time \(t\). - The term \(4(12t - \sin(12t))\) is the x-component of the vector, denoted with \(\hat{i}\). - The term \(4(1 - \cos(12t))\) is the y-component of the vector, denoted with \(\hat{j}\). ### Steps to Solve: 1. **Calculate the Velocity Vector \(\vec{v}(t)\):** \[ \vec{v}(t) = \frac{d\vec{r}(t)}{dt} \] - Differentiate the x-component \(4(12t - \sin(12t))\) with respect to \(t\). - Differentiate the y-component \(4(1 - \cos(12t))\) with respect to \(t\). 2. **Calculate the Acceleration Vector \(\vec{a}(t)\):** \[ \vec{a}(t) = \frac{d\vec{v}(t)}{dt} \] - Differentiate the x-component of \(\vec{v}(t)\) with respect to \(t\). - Differentiate the y-component of \(\vec{v}(t)\) with respect to \(t\). 3. **Calculate the Speed \(s(t)\):** \[ s(t) = \|\vec{v}(t)\| \] - Find the magnitude of the velocity vector \(\vec{v}(t)\). Please input your answers in the designated fields to complete the vector functions