Goddart's rocket problem: Difference between revisions

Goddart's rocket problem
State dimension:	1
Differential states:	3
Continuous control functions:	1
Path constraints:	1
Interior point equalities:	4

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Latest revision as of 12:45, 10 October 2025

In Goddart's rocket problem we model the ascent (vertical; restricted to 1 dimension) of a rocket. The aim is to reach a certain altitude with minimal fuel consumption. It is equivalent to maximize the mass at the final altitude.

Variables

The state variables $r, v, m$ describe the altitude(radius), speed and mass respectively.

The drag is given by

D (r, v) : = A v^{2} ρ (r), with ρ (r) : = \exp (- k \cdot (r - r_{0})) .

All units are renormalized.

Mathematical formulation

\begin{array}{llcll} \min_{m, r, v, u, T} & - m (T) \\ s.t. & \dot{r} & = & v, \\ \dot{v} & = & - \frac{1}{r^{2}} + \frac{1}{m} (T_{m a x} u - D (r, v)) \\ \dot{m} & = & - b u, \\ u (t) & \in & [0, 1] \\ r (0) & = & r_{0}, \\ v (0) & = & v_{0}, \\ m (0) & = & m_{0}, \\ r (T) & = & r_{T}, \\ D (r, v) & \leq & C \\ T free \end{array}

Parameters

\begin{array}{rcl} r_{0} & = & 1 \\ v_{0} & = & 0 \\ m_{0} & = & 1 \\ r_{T} & = & 1.01 \\ b & = & 7 \\ T_{m a x} & = & 3.5 \\ A & = & 310 \\ k & = & 500 \\ C & = & 0.6 \end{array}

Reference Solution

The following reference solution was generated using BOCOP. The optimal value of the objective function is -0.63389.

Reference solution plots
Control u over time.
Position r over time.
Speed v over time.
Mass m over time.

Source Code

Model descriptions are available in:

References

The Problem can be found in the BOCOP User Guide.

@@ Line 15: / Line 15: @@
 <dd>
 <math>
-D(r,v):= Av^2 \rho(r)\text{, with }\rho(r):= exp(-k\cdot (r-r_0)).
+D(r,v):= Av^2 \rho(r)\text{, with }\rho(r):= \exp(-k\cdot (r-r_0)).
 </math>
 </dd>
@@ Line 26: / Line 26: @@
 \begin{array}{llcll}
   \displaystyle \min_{m,r,v,u,T} &  -m(T)\\[1.5ex]
-  \mbox{s.t.} & \dot{r}(t) & = & v, \\
+  \mbox{s.t.} & \dot{r} & = & v, \\
-  & \dot{v}(t) & = & -\frac{1}{r(t)^2} + \frac{1}{m(t)} (T_{max}u(t)-D(r,v)) \\[1.5ex]
+  & \dot{v} & = & -\frac{1}{r^2} + \frac{1}{m} (T_{\mathrm{max}}u-D(r,v)) \\[1.5ex]
-& \dot{m}(t) & = & -b T_{max} u(t), \\
+& \dot{m} & = & -b u, \\
 & u(t) &\in& [0,1] \\
   & r(0) &=& r_0, \\
@@ Line 34: / Line 34: @@
   & m(0) &=& m_0, \\
   & r(T) &=& r_T, \\
-  & D(r(t),v(t))&\le& C \\
+  & D(r,v)&\le& C \\
-& T \, free
+& T \quad \text{free}
 \end{array}
 </math>
@@ Line 50: / Line 50: @@
 r_T &=& 1.01 \\
 b &=& 7 \\
-T_{max} &=& 3.5 \\
+T_{\mathrm{max}} &=& 3.5 \\
 A &=& 310 \\
 k &=& 500 \\
@@ Line 74: / Line 74: @@
 * [[:Category: Bocop | Bocop code]] at [[Goddart's rocket problem (Bocop)]]
+* [[:Category: AMPL/TACO | AMPL/TACO code]] at [[Goddart's rocket problem (TACO)]]
 == References ==