# Social Force Model for Pedestrian Dynamics by Euler Method

The social force model is a model using newtonian forces to describe the movement of individuals. As seens here : page 1

Each individual feel the following forces :

->a driving force towards the goal where vi° is the desired velocity of the individual, ei° the direction of the goal, and vi the actual velocity of the individual. Ti is the relaxation time, meaning the time needed for an individual to reach the desired velocity.

->a repulsive force coming from other individuals and obstacles where Ai is the repulsion coefficient, Bi the distance before the individual feels the repulsion, rij-dij the distance between two individuals, k an elastic constant and g a function depending of the distances bewteen two individuals. What kg(rij-dij) does, is push more individual coming too close of the selected individual. nij is the direction of the repulsive force.

Finally, I get the following equation (1) using Newton second law :

This equation is applied at each individual of a room, and my aim is to solve it. To do so, I use the explicit Euler method, projecting the forces on an X and Y axis separately.

My reasonning is the following :

Definition of a derivative

ẍ[n]=(Ẋ[n+1]-Ẋ[n])/h where Ẋ is the speed projected on the X axis, and ẍ is its derivative.

(2) ẍ=(vi°cos(θ)-Ẋcos(α))/Ti+Σfij_x/m, by dividing (1) by m

[Σfij_x is the projection on the X axis of the sum of repulsive forces, individual i feels, θ the angle of directions of the driving force, α the angle of direction of the individual, set to random at first]

Therefore, I get :

Ẋ[n+1]=Ẋ[n]+ẍ[n]*h (By injecting (2))

Ẋ[n+1]=Ẋ[n]*(1-h/Ti)*cos(α)+(h/Ti)vi°cos(θ)+Σfij_x(h/m)

And I do the same for the Y axis but switching cos to sin.

I get the positions coordinates by applying : X[n+1]=X[n]+Ẋ[n]*h

All that is left is to repeat those instructions for N steps for X number of people.

Heres, my code :

``````from math import*
from numpy import*
from copy import*
import matplotlib.pyplot as plt
##Condition initiale
purpose=[50,50] #Coordonné du sommet du rectangle [600,300]
purpose_exit=[purpose[0]+1E3,purpose[1]+20] #La seconde sortie X pixel plus loin
rayon=5
number_of_particles = 1 #Nb d'individus généré aléatoirement
v_désiré=1
m=70 #masse individu
A=200 #coefficient de répulsion
B=0.08 #coefficient d'interraction
τ=0.5

##Taille de l'objectif
lenght_goal=rayon*2 #Longueur du rectangle (Horizontale)
width_goal=rayon*4 #Largeur du rectangle (Verticale)

##Particle object
class Particle: #Ensemble tel que tout les objets qui appartiennt à cette ensemble ont les mêmes caractéristiques
def __init__(self, x, y, v, angle, rayon, n, type): #Initialisation du blueprint de l'objet désigné "self"
self.x = x #position
self.y = y
self.rayon = rayon
self.couleur = (0, 100, 255)
self.thickness = 1
self.v = v #vitesse
self.v_d = v_désiré #Vitesse désiré
self.angle = angle #angle d'orientation de la vitesse
self.n = n #numéro individu
self.goal = True #Indicateur de comportement, True vise la sortie, False non
self.goal1 = False #Pour l'autre sortie
self.type = type
class Barrier:
def __init__(self,x1,y1,x2,y2,couleur):
self.x1 = x1
self.y1 = y1
self.x2 = x2
self.y2 = y2
self.couleur = (0,200,200)
self.thickness = 6
self.particules = []
l = sqrt((x2-x1)**2+(y2-y1)**2) #longueur du mur
dx=x2-x1
rayon_obs = rayon*2
#Ajout auto des obstacles aux barrières
if (x2-x1)!=0 and (y2-y1)!=0:
c=round((y2-y1)/(x2-x1)) #coefficient directeur arrondie due aux pixels => Entiers
d=round(y1-c*x1)
for i in range(x1,x2+1,rayon_obs):
self.particules+=[Particle(i,(c*i+d),0,0,rayon_obs,i,"obstacle")] #Pour l'affichage
elif (x2-x1)==0: #Droite verticale
for i in range(1,int(l/rayon_obs)):
self.particules+=[Particle(x1,y1+rayon_obs*i,0,0,rayon_obs,i,"obstacle")] #Pour l'affichage
elif (y2-y1)==0: #Droite horizontale
for i in range(1,int(l/rayon_obs)):
self.particules+=[Particle(x1+rayon_obs*i,y1,0,0,rayon_obs,i,"obstacle")] #Pour l'affichage
def but(self,purpose1): #Vecteur de direction
but_y=purpose1[1]-self.y #Différence de vecteurs résultant en la direction de sortie
but_x=purpose1[0]-self.x
return math.atan2(but_y,but_x)

def f_α_β(p1,p2): #force de répulsion individuelle
return A*exp((-d_α_β(p1,p2))/B),angle_α_β(p1,p2)

def d_α_β(p1,p2): #Calcul la distance entre l'individu α et β
dx = p1.x - p2.x
dy = p1.y - p2.y
return sqrt(dx**2+dy**2) #Correspond à la distance séparant 2 particules (la norme de cette dernière)

def angle_α_β(p1,p2): #Direction de la force de répulsion
dx = p1.x - p2.x
dy = p1.y - p2.y
tangent = math.atan2(dy, dx) #Angle de rotation de collision des particules
angle = tangent #Prise en compte du décalage +pi/2
return pi+angle

def Euler_s():
global Position,Vitesse,Angle_v,Ẋ,Ẏ
h=T/N #le pas
for n in range(len(t)): #Boucle de temps
Vitesse+=deepcopy([Vitesse[0]])
Angle_v+=deepcopy([Angle_v[0]])
Position+=deepcopy([Position[0]])
Ẋ+=deepcopy([Ẋ[0]])
Ẏ+=deepcopy([Ẏ[0]]) #Les valeurs seront écrasés ensuite, il s'agit d'un place-holder
for j in range(len(my_particles)): #Boucle d'individu α
if my_particles[j].type=="individu": #On n'applique pas Euler aux obstacles
for z in range(len(my_particles)): #Calcul de la composante de répulsion
Σ_X=0
Σ_Y=0
if z!=j: #L'individu j ne se repousse pas lui-même
A=f_α_β(my_particles[j],my_particles[z]) #1 appel par rapport à une particule
norme, β = A[0], A[1]
# Σ_X+=norme*cos(β)
# Σ_Y+=norme*sin(β)
# print(Σ_X,Σ_Y)
θ = but(my_particles[j],purpose)
α = Angle_v[n][j]
##Calcul nouvelle Vitesse
Ẋ[n+1][j]=Ẋ[n][j]*(1-(h/τ)*cos(α))+(h/τ)*v_désiré*cos(θ)+(h/m)*Σ_X #Composante X de la Vitesse à l'instant t+1, de la particule j
Ẏ[n+1][j]=Ẏ[n][j]*(1-(h/τ)*sin(α))+(h/τ)*v_désiré*sin(θ)+(h/m)*Σ_Y
Vitesse[n+1][j]=sqrt(Ẋ[n+1][j]**2+Ẏ[n+1][j]**2) #Norme de la vitesse
arc_tangent = math.atan2(Ẏ[n+1][j], Ẋ[n+1][j]) #Angle de vitesse
Angle_v[n+1][j]= arc_tangent #Prise en compte du décalage +pi/2#Angle de la vitesse
my_particles[j].angle=Angle_v[n+1][j]
##Calcul nouvelle Position
X_1=Ẋ[n][j]*h+Position[n][j][0]
Y_1=Ẏ[n][j]*h+Position[n][j][1]
Position[n+1][j]=[X_1,Y_1]
my_particles[j].x=X_1
my_particles[j].y=Y_1
return

##Historique des grandeurs physiques
N=10000 #Nb de points, où N>>>T
T=120 #Temps final
t=linspace(1,T,N) #Nb de pas de temps
# Position=[[(100,100),(100,120),(120,100),(120,120)]] #Chaque lignes de la matrices correspond à un instant
# Position_backup=[[[rayon+80,rayon],[rayon+20,rayon+20],[rayon+20,rayon],[rayon,rayon+20]]] #Chaque lignes de la matrices correspond à un instant
Position_backup=[[[100,0]]]
Position=[[]]
Vitesse=[[]]
Ẋ=[[]] #Composante de la vitesse
Ẏ=[[]]
Ẋ[0]=number_of_particles*[0]
Ẏ[0]=number_of_particles*[0]
Angle_v=[[]] #A déterminé en fn de la pos° des individus

##Génération des individus
my_particles = []
for n in range(number_of_particles): #Attribution des caractères aléatoires des particules
Position[0]+=[Position_backup[0][n]]
Vitesse[0]+=[0] #Vitesse initiale nulle
x = Position[0][n][0] #Lit le 1er élèments de la liste, indexé par le n° de l'indi, puis par x/y
y = Position[0][n][1]
v=Vitesse[0][n]
angle_v = math.atan2(y,x) #Direction du vecteur vitesse, tous repéré par rapport à l'origine (Voire comment fonction atan2)
Angle_v[0]+=[angle_v]
type="individu"
my_particles.append(Particle(x, y, v, angle_v, rayon, n, type))

Euler_s()
##Drawing
fig = plt.figure()
n=0
X=[]
Y=[]
for i in range(len(Position)):
X+=[Position[i][n][0]]
Y+=[Position[i][n][1]]
plt.plot(X,Y,'ro')
plt.plot(purpose[0],purpose[1],'gs')
plt.axis([0, 100, 0, 100])
fig.show()
``````

You can directly copy it and run it for yourself. And that's where's my problem.

If I put an individual in some position, such as Position_backup=[[(80,20)]], but his goal is at purpose=[50,50], he just won't go there. I want that person to go towards that green goal. He should do it in a straight line.

I don't understand why it doesn't work. And I apologies in advance for grammar mistakes I may have done previously. I know I am very close to solve it, and I thank anyone who would take the time to help me.

• This is not so much a coding problem (apart from a small change to make it runnable), it is a modeling and method problem. A better place would be the scicomp, physics or math forum on stackexchange.com. – LutzL Feb 7 at 17:37
• Thank you, I'll try my luck on the physics one. However, what do you mean a small change to make it runnable ? When I copy the exact code, it runs fine on pyzo. – Jerome15 Feb 7 at 17:58
• When I run the code as posted, I get an error that `angle` is not defined. It would probably help much if you would make your code compatible with general ODE solvers. This means that you need a function that gets a flat state vector as input that you have to distribute to the system components, compute the derivatives resp. accelerations and collect them back to return a flat derivatives vector. – LutzL Feb 7 at 18:42
• Here, I think i fxed it. I changed `angle` to `angle_v`. – Jerome15 Feb 7 at 18:49
• @LutzL This has been crossposted on Physics.SE, but it doesn't belong there. This is not physics, it's social science that happens to use some terms from physics. And there is a 95% chance that the issue here has nothing to do with the equations, but rather arises from a bug in the code. – knzhou Feb 7 at 19:10