import numpy as np
from probnum.problems import InitialValueProblem
__all__ = [
"threebody",
"vanderpol",
"rigidbody",
"fitzhughnagumo",
"logistic",
"lotkavolterra",
"seir",
"lorenz",
]
[docs]def threebody(t0=0.0, tmax=17.0652165601579625588917206249, y0=None):
r"""Initial value problem (IVP) based on a three-body problem.
Let the initial conditions be :math:`y = (y_1, y_2, \dot{y}_1, \dot{y}_2)^T`.
This function implements the second-order three-body problem as a system of
first-order ODEs, which is defined as follows: [1]_
.. math::
f(t, y) =
\begin{pmatrix}
\dot{y_1} \\
\dot{y_2} \\
y_1 + 2 \dot{y}_2 - \frac{(1 - \mu) (y_1 + \mu)}{d_1}
- \frac{\mu (y_1 - (1 - \mu))}{d_2} \\
y_2 - 2 \dot{y}_1 - \frac{(1 - \mu) y_2}{d_1} - \frac{\mu y_2}{d_2}
\end{pmatrix}
with
.. math::
d_1 &= ((y_1 + \mu)^2 + y_2^2)^{\frac{3}{2}} \\
d_2 &= ((y_1 - (1 - \mu))^2 + y_2^2)^{\frac{3}{2}}
and a constant parameter :math:`\mu = 0.012277471` denoting the standardized moon mass.
Parameters
----------
t0
Initial time. Default is ``0.0``.
tmax
Final time. Default is ``17.0652165601579625588917206249`` which is the period of the solution.
y0
*(shape=(4, ))* -- Initial value. Default is ``[0.994, 0, 0, -2.00158510637908252240537862224]``.
Returns
-------
InitialValueProblem
InitialValueProblem object describing a three-body problem IVP with the prescribed
configuration.
References
----------
.. [1] Hairer, E., Norsett, S. and Wanner, G..
Solving Ordinary Differential Equations I.
Springer Series in Computational Mathematics, 1993.
"""
def rhs(t, y):
mu = 0.012277471 # a constant (standardised moon mass)
mp = 1 - mu
D1 = ((y[0] + mu) ** 2 + y[1] ** 2) ** (3 / 2)
D2 = ((y[0] - mp) ** 2 + y[1] ** 2) ** (3 / 2)
y1p = y[0] + 2 * y[3] - mp * (y[0] + mu) / D1 - mu * (y[0] - mp) / D2
y2p = y[1] - 2 * y[2] - mp * y[1] / D1 - mu * y[1] / D2
return np.array([y[2], y[3], y1p, y2p])
if y0 is None:
y0 = np.array([0.994, 0, 0, -2.00158510637908252240537862224])
return InitialValueProblem(f=rhs, t0=t0, tmax=tmax, y0=y0)
[docs]def vanderpol(t0=0.0, tmax=30, y0=None, params=1e1):
r"""Initial value problem (IVP) based on the Van der Pol Oscillator, implemented in `jax`.
This function implements the second-order Van-der-Pol Oscillator as a system
of first-order ODEs.
The Van der Pol Oscillator is defined as
.. math::
f(t, y) =
\begin{pmatrix}
y_2 \\
\mu \cdot (1 - y_1^2)y_2 - y_1
\end{pmatrix}
for a constant parameter :math:`\mu`.
:math:`\mu` determines the stiffness of the problem, where
the larger :math:`\mu` is chosen, the more stiff the problem becomes.
Default is :math:`\mu = 0.1`.
This implementation includes the Jacobian :math:`J_f` of :math:`f`.
Parameters
----------
t0 : float
Initial time point. Leftmost point of the integration domain.
tmax : float
Final time point. Rightmost point of the integration domain.
y0 : np.ndarray,
*(shape=(2, ))* -- Initial value of the problem.
params : (float), optional
Parameter :math:`\mu` for the Van der Pol Equations
Default is :math:`\mu=0.1`.
Returns
-------
InitialValueProblem
InitialValueProblem object describing the Van der Pol Oscillator IVP with the prescribed
configuration.
"""
if y0 is None:
y0 = np.array([2.0, 0.0])
def rhs(t, y, params=params):
y1, y2 = y
if isinstance(params, float):
mu = params
else:
(mu,) = params
return np.array([y2, mu * (1.0 - y1 ** 2) * y2 - y1])
def jac(t, y, params=params):
y1, y2 = y
if isinstance(params, float):
mu = params
else:
(mu,) = params
return np.array([[0.0, 1.0], [-2.0 * mu * y2 * y1 - 1.0, mu * (1.0 - y1 ** 2)]])
return InitialValueProblem(f=rhs, t0=t0, tmax=tmax, y0=y0, df=jac)
[docs]def rigidbody(t0=0.0, tmax=20.0, y0=None, params=(-2.0, 1.25, -0.5)):
r"""Initial value problem (IVP) for rigid body dynamics without external forces
The rigid body dynamics without external forces is defined through
.. math::
f(t, y) =
\begin{pmatrix}
y_2 y_3 \\
-y_1 y_3 \\
-0.51 \cdot y_1 y_2
\end{pmatrix}
The ODE system has no parameters.
This implementation includes the Jacobian :math:`J_f` of :math:`f`.
Parameters
----------
t0
Initial time. Default is 0.0
tmax
Final time. Default is 20.0
y0
*(shape=(3, ))* -- Initial value. Default is ``[1., 0., 0.9]``.
params
Parameter of the rigid body problem. Default is ``(-2.0, 1.25, -0.5)``.
Returns
-------
InitialValueProblem
InitialValueProblem object describing the rigid body dynamics IVP with the prescribed
configuration.
"""
if y0 is None:
y0 = np.array([1.0, 0.0, 0.9])
def rhs(t, y, params=params):
p1, p2, p3 = params
y1, y2, y3 = y
return np.array([p1 * y2 * y3, p2 * y1 * y3, p3 * y1 * y2])
def jac(t, y, params=params):
p1, p2, p3 = params
y1, y2, y3 = y
return np.array(
[[0.0, p1 * y3, p1 * y2], [p2 * y3, 0.0, p2 * y1], [p3 * y2, p3 * y1, 0.0]]
)
return InitialValueProblem(f=rhs, t0=t0, tmax=tmax, y0=y0, df=jac)
[docs]def logistic(t0=0.0, tmax=2.0, y0=None, params=(3.0, 1.0)):
r"""Initial value problem (IVP) based on the logistic ODE.
The logistic ODE is defined through
.. math::
f(t, y) = a y \left( 1 - \frac{y}{b} \right)
for some parameters :math:`(a, b)`.
Default is :math:`(a, b)=(3.0, 1.0)`. This implementation includes
the Jacobian :math:`J_f` of :math:`f` as well as a closed form
solution given by
.. math::
f(t) = \frac{b y_0 \exp(a t)}{b + y_0 \left[ \exp(at) - 1 \right]}
where :math:`y_0= y(t_0)` is the initial value.
Parameters
----------
t0
Initial time. Default is 0.0
tmax
Final time. Default is 2.0
y0
*(shape=(1, ))* -- Initial value. Default is ``[0.1]``.
params
Parameters :math:`(a, b)` for the logistic IVP.
Default is :math:`(a, b) = (3.0, 1.0)`.
Returns
-------
InitialValueProblem
InitialValueProblem object describing the logistic ODE with the prescribed
configuration.
"""
if y0 is None:
y0 = np.array([0.1])
def rhs(t, y, params=params):
l0, l1 = params
return l0 * y * (1.0 - y / l1)
def jac(t, y, params=params):
l0, l1 = params
return np.array([l0 - l0 / l1 * 2 * y])
def hess(t, y, params=params):
l0, l1 = params
return np.array([[-2 * l0 / l1]])
def sol(t):
l0, l1 = params
nomin = l1 * y0 * np.exp(l0 * t)
denom = l1 + y0 * (np.exp(l0 * t) - 1)
return nomin / denom
return InitialValueProblem(
f=rhs, t0=t0, tmax=tmax, y0=y0, df=jac, ddf=hess, solution=sol
)
[docs]def fitzhughnagumo(t0=0.0, tmax=20.0, y0=None, params=(0.2, 0.2, 3.0, 1.0)):
r"""Initial value problem (IVP) based on the FitzHugh-Nagumo model.
The FitzHugh-Nagumo (FHN) model is defined through
.. math::
f(t, y) =
\begin{pmatrix}
y_1 - \frac{1}{3} y_1^3 - y_2 + a \\
\frac{1}{d} (y_1 + b - c y_2)
\end{pmatrix}
for some parameters :math:`(a, b, c, d)`.
Default is :math:`(a, b)=(0.2, 0.2, 3.0)`.
This implementation includes the Jacobian :math:`J_f` of :math:`f`.
Parameters
----------
t0
Initial time. Default is 0.0
tmax
Final time. Default is 20.0
y0
*(shape=(2, ))* -- Initial value. Default is ``[1., -1.]``.
params
Parameter of the FitzHugh-Nagumo model. Default is ``(0.2, 0.2, 3.0, 1.0)``.
Returns
-------
InitialValueProblem
InitialValueProblem object describing the FitzHugh-Nagumo model with the prescribed
configuration.
"""
if y0 is None:
y0 = np.array([1.0, -1.0])
def rhs(t, y, params=params):
y1, y2 = y
a, b, c, d = params
return np.array([y1 - y1 ** 3.0 / 3.0 - y2 + a, (y1 + b - c * y2) / d])
def jac(t, y, params=params):
y1, y2 = y
a, b, c, d = params
return np.array([[1.0 - y1 ** 2.0, -1.0], [1.0 / d, -c / d]])
return InitialValueProblem(f=rhs, t0=t0, tmax=tmax, y0=y0, df=jac)
[docs]def lotkavolterra(t0=0.0, tmax=20.0, y0=None, params=(0.5, 0.05, 0.5, 0.05)):
r"""Initial value problem (IVP) based on the Lotka-Volterra model.
The Lotka-Volterra (LV) model is defined through
.. math::
f(t, y) =
\begin{pmatrix}
a y_1 - by_1y_2 \\
-c y_2 + d y_1 y_2
\end{pmatrix}
for some parameters :math:`(a, b, c, d)`.
Default is :math:`(a, b)=(0.5, 0.05, 0.5, 0.05)`.
This implementation includes the Jacobian :math:`J_f` of :math:`f`.
Parameters
----------
t0
Initial time. Default is 0.0
tmax
Final time. Default is 20.0
y0
*(shape=(2, ))* -- Initial value. Default is ``[1., -1.]``.
params
Parameter of the Lotka-Volterra model. Default is ``(0.2, 0.2, 3.0)``.
Returns
-------
InitialValueProblem
InitialValueProblem object describing the Lotka-Volterra system with the prescribed
configuration.
"""
if y0 is None:
y0 = np.array([20.0, 20.0])
def rhs(t, y, params=params):
a, b, c, d = params
y1, y2 = y
return np.array([a * y1 - b * y1 * y2, -c * y2 + d * y1 * y2])
def jac(t, y, params=params):
a, b, c, d = params
y1, y2 = y
return np.array([[a - b * y2, -b * y1], [d * y2, -c + d * y1]])
return InitialValueProblem(f=rhs, t0=t0, tmax=tmax, y0=y0, df=jac)
[docs]def seir(t0=0.0, tmax=200.0, y0=None, params=(0.3, 0.3, 0.1)):
r"""Initial value problem (IVP) based on the SEIR model.
The SEIR model with no vital dynamics is defined through
.. math::
f(t, y) =
\begin{pmatrix}
\frac{-\beta y_1 y_3}{N} \\
\frac{\beta y_1 y_3}{N} - \alpha y_2 \\
\alpha y_2 - \gamma y_3 \\
\gamma y_3
\end{pmatrix}
for some parameters :math:`(\alpha, \beta, \gamma)` and population
count :math:`N`. Without taking vital dynamics into consideration,
:math:`N` is constant such that for every time point :math:`t`
.. math::
S(t) + E(t) + I(t) + R(t) = N
holds.
Default parameters are :math:`(\alpha, \beta, \gamma)=(0.3, 0.3, 0.1)`.
The population count is computed from the (mean of the)
initial value random variable.
This implementation includes the Jacobian :math:`J_f` of :math:`f`.
Parameters
----------
t0
Initial time. Default is 0.0
tmax
Final time. Default is 200.0
y0
*(shape=(4, ))* -- Initial value. Default is ``[998, 1, 1, 0]``.
params
Parameter of the SEIR model. Default is ``(0.3, 0.3, 0.1)``.
Returns
-------
InitialValueProblem
InitialValueProblem object describing the SEIR model with the prescribed
configuration.
"""
if y0 is None:
y0 = np.array([998, 1, 1, 0])
params = params + (np.sum(y0),)
def rhs(t, y, params=params):
alpha, beta, gamma, population_count = params
y1, y2, y3, y4 = y
y1_next = -beta * y1 * y3 / population_count
y2_next = beta * y1 * y3 / population_count - alpha * y2
y3_next = alpha * y2 - gamma * y3
y4_next = gamma * y3
return np.array([y1_next, y2_next, y3_next, y4_next])
def jac(t, y, params=params):
alpha, beta, gamma, population_count = params
y1, y2, y3, y4 = y
d_dy1 = np.array(
[-beta * y3 / population_count, 0.0, -beta * y1 / population_count, 0.0]
)
d_dy2 = np.array(
[beta * y3 / population_count, -alpha, beta * y1 / population_count, 0.0]
)
d_dy3 = np.array([0.0, alpha, -gamma, 0.0])
d_dy4 = np.array([0.0, 0.0, gamma, 0.0])
jac_matrix = np.array([d_dy1, d_dy2, d_dy3, d_dy4])
return jac_matrix
return InitialValueProblem(f=rhs, t0=t0, tmax=tmax, y0=y0, df=jac)
[docs]def lorenz(t0=0.0, tmax=20.0, y0=None, params=(10.0, 28.0, 8.0 / 3.0)):
r"""Initial value problem (IVP) based on the Lorenz system.
The Lorenz system is defined through
.. math::
f(t, y) =
\begin{pmatrix}
a(y_2 - y_1) \\
y_1(b-y_3) - y_2 \\
y_1y_2 - cy_3
\end{pmatrix}
for some parameters :math:`(a, b, c)`.
Default is :math:`(a, b, c)=(10, 28, 2.667)`.
This implementation includes the Jacobian :math:`J_f` of :math:`f`.
Parameters
----------
t0
Initial time. Default is 0.0
tmax
Final time. Default is 20.0
y0
*(shape=(3, ))* -- Initial value. Default is ``[0., 1., 1.05]``.
params
Parameter of the Lotka-Volterra model. Default is ``(0.2, 0.2, 3.0)``.
Returns
-------
InitialValueProblem
InitialValueProblem object describing the Lorenz system with the prescribed
configuration.
"""
if y0 is None:
y0 = np.array([0.0, 1.0, 1.05])
def rhs(t, y, params=params):
a, b, c = params
y1, y2, y3 = y
return np.array([a * (y2 - y1), y1 * (b - y3) - y2, y1 * y2 - c * y3])
def jac(t, y, params=params):
a, b, c = params
y1, y2, y3 = y
return np.array([[-a, a, 0], [b - y3, -1, -y1], [y2, y1, -c]])
return InitialValueProblem(f=rhs, t0=t0, tmax=tmax, y0=y0, df=jac)