Struct MorsePotentialF32

pub struct MorsePotentialF32 {
    pub radius: f32,
    pub potential_stiffness: f32,
    pub cutoff: f32,
    pub strength: f32,
}

Famous Morse potential for diatomic molecules.

Parameters & Variables

Symbol	Struct Field	Description
$R$	radius	Radius of the particle
$\lambda$	potential_stiffness	Can be interpreted as the inverse width of the potential
	cutoff	Cutoff after which the interaction strength is identically 0
$V_0$	strength	Interaction strength
$r$		Distance between interacting particles

\begin{equation} V(r) = V_0\left(1 - e^{-\lambda(r-R)}\right)^2 \end{equation}

References

[1] P. M. Morse, “Diatomic Molecules According to the Wave Mechanics. II. Vibrational Levels,” Physical Review, vol. 34, no. 1. American Physical Society (APS), pp. 57–64, Jul. 01, 1929. doi: 10.1103/physrev.34.57.

Fields

radius: f32

Radius of the object

potential_stiffness: f32

Defines the length for the interaction range

cutoff: f32

Cutoff after which the interaction is exactly 0

strength: f32

Strength of the interaction

Implementations

impl MorsePotentialF32

pub fn new( radius: f32, potential_stiffness: f32, cutoff: f32, strength: f32, ) -> MorsePotentialF32

Available on crate feature cpu_os_threads only.

Constructs a new MorsePotentialF32

use cellular_raza_building_blocks::MorsePotentialF32;
let morse_potential = MorsePotentialF32::new(
    radius,
    potential_stiffness,
    cutoff,
    strength,
);

Trait Implementations

impl Clone for MorsePotentialF32

fn clone(&self) -> MorsePotentialF32

Returns a copy of the value.

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source.

impl Debug for MorsePotentialF32

fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter.

impl<'de> Deserialize<'de> for MorsePotentialF32

fn deserialize<__D>( __deserializer: __D, ) -> Result<MorsePotentialF32, <__D as Deserializer<'de>>::Error>

where __D: Deserializer<'de>,

Deserialize this value from the given Serde deserializer.

impl<const D: usize> Interaction<Matrix<f32, Const<D>, Const<1>, ArrayStorage<f32, D, 1>>, Matrix<f32, Const<D>, Const<1>, ArrayStorage<f32, D, 1>>, Matrix<f32, Const<D>, Const<1>, ArrayStorage<f32, D, 1>>, f32> for MorsePotentialF32

fn get_interaction_information(&self) -> f32

Get additional information of cellular properties (ie. for cell-specific interactions). For now, this can also be used to get the mass of the other cell-agent. In the future, we will probably provide a custom function for this.

fn calculate_force_between( &self, own_pos: &Matrix<f32, Const<D>, Const<1>, ArrayStorage<f32, D, 1>>, _own_vel: &Matrix<f32, Const<D>, Const<1>, ArrayStorage<f32, D, 1>>, ext_pos: &Matrix<f32, Const<D>, Const<1>, ArrayStorage<f32, D, 1>>, _ext_vel: &Matrix<f32, Const<D>, Const<1>, ArrayStorage<f32, D, 1>>, ext_info: &f32, ) -> Result<(Matrix<f32, Const<D>, Const<1>, ArrayStorage<f32, D, 1>>, Matrix<f32, Const<D>, Const<1>, ArrayStorage<f32, D, 1>>), CalcError>

Calculates the forces (velocity-derivative) on the corresponding external position given external velocity. By providing velocities, we can calculate terms that are related to friction. The function returns two forces, one acting on the current agent and the other on the external agent.

fn is_neighbor( &self, own_pos: &Pos, ext_pos: &Pos, ext_inf: &Inf, ) -> Result<bool, CalcError>

Checks if the other cell represented by position and information is a neighbor to the current one or not.

fn react_to_neighbors(&mut self, neighbors: usize) -> Result<(), CalcError>

Reacts to the results gathered by the Interaction::is_neighbor method and changes the state of the cell.

impl IntoPy<Py<PyAny>> for MorsePotentialF32

fn into_py(self, py: Python<'_>) -> Py<PyAny>

Performs the conversion.

impl PartialEq for MorsePotentialF32

fn eq(&self, other: &MorsePotentialF32) -> bool

Tests for self and other values to be equal, and is used by ==.

fn ne(&self, other: &Rhs) -> bool

Tests for !=. The default implementation is almost always sufficient, and should not be overridden without very good reason.

impl PyClass for MorsePotentialF32

type Frozen = False

Whether the pyclass is frozen.

impl PyTypeInfo for MorsePotentialF32

const NAME: &'static str = "MorsePotentialF32"

Class name.

const MODULE: Option<&'static str> = ::core::option::Option::None

Module name, if any.

fn type_object_raw(py: Python<'_>) -> *mut PyTypeObject

Returns the PyTypeObject instance for this type.

fn type_object_bound(py: Python<'_>) -> Bound<'_, PyType>

Returns the safe abstraction over the type object.

fn is_type_of_bound(object: &Bound<'_, PyAny>) -> bool

Checks if object is an instance of this type or a subclass of this type.

fn is_exact_type_of_bound(object: &Bound<'_, PyAny>) -> bool

Checks if object is an instance of this type.

impl Serialize for MorsePotentialF32

fn serialize<__S>( &self, __serializer: __S, ) -> Result<<__S as Serializer>::Ok, <__S as Serializer>::Error>

where __S: Serializer,

Serialize this value into the given Serde serializer.

impl DerefToPyAny for MorsePotentialF32

impl StructuralPartialEq for MorsePotentialF32