\subsection{Projectile Motion via Hamilton-Jacobi} This subsection solves the Hamilton--Jacobi equation for projectile motion in a uniform gravitational field, showing that Jacobi's theorem reproduces the standard parabolic kinematics of the AP Physics C curriculum. \dfn{Projectile Hamiltonian}{ A particle of mass $m$ moving in the $xy$-plane under uniform gravity $g$ has the Hamiltonian \[ \mcH = \frac{p_x^2 + p_y^2}{2m} + mgy, \] where $y$ is measured upward from ground level and $p_x$, $p_y$ are the canonical momenta conjugate to $x$ and $y$, respectively. The corresponding Hamilton--Jacobi equation $\mcH + \pdv{\mcS}{t} = 0$ reads \[ \frac{1}{2m}\left[\left(\pdv{\mcS}{x}\right)^2 + \left(\pdv{\mcS}{y}\right)^2\right] + mgy + \pdv{\mcS}{t} = 0. \]} \nt{The coordinate $x$ is cyclic (ignorable) because it does not appear in the Hamiltonian. Its conjugate momentum $p_x = \pdv{\mcS}{x}$ is therefore a constant of motion, which mirrors the familiar AP result that horizontal velocity remains unchanged during projectile motion.} \thm{Separated Hamilton--Jacobi equations for the projectile}{ Using the time-independent ansatz $\mcS(x,y,t) = W_x(x) + W_y(y) - Et$, the full Hamilton--Jacobi PDE reduces to two ordinary equations. Because $x$ is cyclic, $\der{W_x}{x} = \alpha_x$ (constant). The remaining vertical equation is \[ \frac{1}{2m}\left(\der{W_y}{y}\right)^2 + mgy = E - \frac{\alpha_x^2}{2m} \equiv E_y, \] where $\alpha_x$ is the constant horizontal momentum and $E_y$ is the transverse energy carrying the vertical kinetic and potential energy.} \pf{Separation and trajectory from Jacobi's theorem}{ Begin with the time-independent reduction $\mcS = W_x(x) + W_y(y) - Et$. Substituting into the Hamilton--Jacobi PDE, the time derivative contributes $-E$ and the spatial partial derivatives become ordinary derivatives: \[ \frac{1}{2m}\left[\left(\der{W_x}{x}\right)^2 + \left(\der{W_y}{y}\right)^2\right] + mgy = E. \] The coordinate $x$ is cyclic, so its derivative is a constant: \[ \der{W_x}{x} = \alpha_x, \] which integrates immediately to $W_x(x) = \alpha_x\,x$. Substitute back into the energy equation: \[ \frac{1}{2m}\left(\der{W_y}{y}\right)^2 + mgy = E - \frac{\alpha_x^2}{2m}. \] Define the transverse energy $E_y = E - \alpha_x^2/(2m)$ and solve for the vertical derivative: \[ \der{W_y}{y} = \pm\sqrt{2m\left(E_y - mgy\right)}. \] Integrate with respect to $y$. Set $u = E_y - mgy$, so $\dd u = -mg\,\dd y$: \[ W_y(y) = \pm\sqrt{2m}\int\sqrt{E_y - mgy}\,\dd y = \mp\frac{2\sqrt{2m}}{3mg}\left(E_y - mgy\right)^{3/2}. \] Assemble the complete principal function: \[ \mcS(x,y,t) = \alpha_x x \mp\frac{2\sqrt{2m}}{3mg}\left(E_y - mgy\right)^{3/2} - Et. \] Jacobi's theorem with respect to the separation constant $\alpha_x$ gives \[ \pdv{\mcS}{\alpha_x} = x - \frac{\alpha_x}{m}\,t = \beta_x. \] Solving for $x(t)$ with $\beta_x = 0$ (launch from the origin): \[ x(t) = \frac{\alpha_x}{m}\,t = v_{0x}\,t. \] From Jacobi's theorem with respect to $E$, using $\pdv{E_y}{E} = 1$: \[ \pdv{\mcS}{E} = \mp\frac{2\sqrt{2m}}{3mg}\cdot\frac{3}{2}\left(E_y - mgy\right)^{1/2} - t = \beta_E, \] which simplifies to \[ \mp\frac{\sqrt{2m}}{mg}\sqrt{E_y - mgy} - t = \beta_E. \] Solve the squared relation for $y(t)$. At $t = 0$ the particle is at $y = 0$ with vertical speed $v_{0y} = \sqrt{2E_y/m}$. The initial conditions fix $\beta_E$ and yield \[ y(t) = v_{0y}\,t - \frac{1}{2}\,g\,t^2. \] The two equations combine into the parabolic trajectory $y = (v_{0y}/v_{0x})\,x - \tfrac{g}{2v_{0x}^2}\,x^2$.} \nt{Comparison to AP kinematics}{The Hamilton--Jacobi equations $x(t) = v_{0x}t$ and $y(t) = v_{0y}t - \tfrac{1}{2}gt^2$ are identical to the standard AP C constant-acceleration kinematics. The separation constant $\alpha_x = mv_{0x}$ is the conserved horizontal momentum, and the transverse energy $E_y = \tfrac{1}{2}mv_{0y}^2$ encodes the initial vertical kinetic energy. The HJ approach thus reproduces, from first principles, every projectile-motion result derived elementarily in the AP C syllabus.} \qs{Projectile launched from the ground}{ A projectile of mass $m = 0.50\,\mathrm{kg}$ is launched from the origin with speed $v_0 = 20\,\mathrm{m/s}$ at angle $\theta_0 = 30.0^\circ$ above the horizontal. Use $g = 9.81\,\mathrm{m/s^2}$. \begin{enumerate}[label=(\alph*)] \item Separate the Hamilton--Jacobi equation. Show that $x$ is cyclic and find $\der{W_y}{y}$ in terms of $E_y$ and $y$. \item Compute the separation constant $\alpha_x = m v_0\cos\theta_0$ and the transverse energy $E_y = \tfrac{1}{2}m v_0^2\sin^2\theta_0$. \item From the trajectory equations, find the range $R$, the horizontal distance at which the projectile returns to $y = 0$. Verify with $R = v_0^2\sin(2\theta_0)/g$. \end{enumerate}} \sol \textbf{Part (a).} The time-independent Hamilton--Jacobi equation is \[ \frac{1}{2m}\left[\left(\der{W_x}{x}\right)^2 + \left(\der{W_y}{y}\right)^2\right] + mgy = E. \] The coordinate $x$ does not appear in the Hamiltonian, so $x$ is cyclic and \[ \der{W_x}{x} = \alpha_x. \] Substitute $(\der{W_x}{x})^2 = \alpha_x^2$ back: \[ \frac{1}{2m}\left(\der{W_y}{y}\right)^2 + mgy = E - \frac{\alpha_x^2}{2m} \equiv E_y. \] Solve for the vertical derivative: \[ \der{W_y}{y} = \pm\sqrt{2m\left(E_y - mgy\right)}. \] \textbf{Part (b).} The separation constant is the horizontal momentum: \[ \alpha_x = m v_0\cos\theta_0. \] Substitute the numerical values: \[ \alpha_x = (0.50)(20)\cos(30.0^\circ)\,\mathrm{kg\!\cdot\!m/s}. \] Using $\cos(30.0^\circ) = \sqrt{3}/2 \approx 0.8660$, \[ \alpha_x = (0.50)(20)(0.8660)\,\mathrm{kg\!\cdot\!m/s} = 8.66\,\mathrm{kg\!\cdot\!m/s}. \] The transverse energy is \[ E_y = \tfrac{1}{2}\,m\,v_0^2\sin^2\theta_0. \] The vertical speed component is \[ v_{0y} = v_0\sin(30.0^\circ) = (20)(0.500)\,\mathrm{m/s} = 10.0\,\mathrm{m/s}. \] Therefore, \[ E_y = \tfrac{1}{2}(0.50)(10.0)^2\,\mathrm{J} = 25\,\mathrm{J}. \] \textbf{Part (c).} The time of flight is found from requiring $y(T) = 0$: \[ v_{0y}\,T - \frac{1}{2}\,g\,T^2 = 0. \] The nonzero root is \[ T = \frac{2v_{0y}}{g} = \frac{2(10.0)}{9.81}\,\mathrm{s} = 2.04\,\mathrm{s}. \] The range is the horizontal distance traveled during this time: \[ R = v_{0x}\,T = \left(v_0\cos\theta_0\right)T. \] The horizontal speed is $v_{0x} = (20)\cos(30.0^\circ)\,\mathrm{m/s} = 17.3\,\mathrm{m/s}$. Hence, \[ R = (17.3)(2.04)\,\mathrm{m} = 35\,\mathrm{m}. \] Verify with the elementary range formula: \[ R = \frac{v_0^2\sin(2\theta_0)}{g} = \frac{(20)^2\sin(60.0^\circ)}{9.81}\,\mathrm{m} = \frac{(400)(0.8660)}{9.81}\,\mathrm{m} = 35\,\mathrm{m}. \] The two results agree to the stated number of significant figures. Therefore, \[ \alpha_x = 8.66\,\mathrm{kg\!\cdot\!m/s}, \qquad E_y = 25\,\mathrm{J}, \qquad R = 35\,\mathrm{m}. \]