jumeaux-numeriques/volet_roulant/volrou.py

496 lines
30 KiB
Python

import bge # Bibliothèque Blender Game Engine (UPBGE)
import twin # Bibliothèque de l'environnement 3D des jumeaux numériques
import math
import time
import runpy # Exécution de script Python légère (sans import)
###############################################################################
# volrou.py
# @title: Commandes pour le volet roulant
# @project: Blender-EduTech
# @lang: fr
# @authors: Philippe Roy <philippe.roy@ac-grenoble.fr>
# @copyright: Copyright (C) 2022-2023 Philippe Roy
# @license: GNU GPL
###############################################################################
# Récupérer la scène UPBGE
scene = bge.logic.getCurrentScene()
# Configuration des variables publiques
# 'nom_variable' :
# - Objet 3D : [nom de l'objet 3D, propriété associée à la valeur (activate ou activated_real), type de la valeur ('d' (digital, binary), 'a', (analog) ou 'n' (numeric)), échelle (1 si ommis)]
# - Configuration de la broche : [nom de la propriété stockant l'object broche (pyfirmata),
# type de broche par défaut : 'd' (digital), 'a' (analog) ou 'p' (pwm)), mode de la broche par défaut : 'i' (input) ou 'o' (output)]
# - Configuration du graphique : ['marque', 'type de ligne', 'couleur', linewidth]] (Codification de Matplotlib)
#
# 'nom_variable_r' est la valeur réelle de la variable (valeur numérique) 'nom_variable' issue du jumelage numérique.
# Dans ce cas, il n'y a pas configuration de broche car elle est présente sur la variable 'nom_variable'.
# Ce distinguo ne concerne que les entrées, car les sorties sont pilotées par le numérique.
public_vars = {
't' : [['System','time','a'], [], []],
'fdc_h' : [['Microrupteur haut','activated','d'], ['pin', 'd','i'], []],
'fdc_h_r' : [['Microrupteur haut','activated_real','d'], [], []],
'fdc_b' : [['Microrupteur bas','activated','d'], ['pin', 'd','i'], []],
'fdc_b_r' : [['Microrupteur bas','activated_real','d'], [], []],
'bp_m' : [['Bp monter','activated','d'], ['pin', 'd','i'], []],
'bp_m_r' : [['Bp monter','activated_real','d'], [], []],
'bp_d' : [['Bp descendre','activated','d'], ['pin', 'd','i'], []],
'bp_d_r' : [['Bp descendre','activated_real','d'], [], []],
'bp_a' : [['Bp arret','activated','d'], ['pin', 'd','i'], []],
'bp_a_r' : [['Bp arret','activated_real','d'], [], []],
'mot_m' : [['Moteur','up','d'], ['pin_up', 'd','o'], []],
'mot_d' : [['Moteur','down','d'], ['pin_down', 'd','o'], []],
'mot_angle' : [['Moteur','alpha','a'], [], []],
'mot_vitesse' : [['Moteur','speed','a'], [], []],
'mot_pas' : [['Moteur','step','a'], [], []],
'bp_auto' : [['Bp auto','activated','d'], ['pin', 'd','i'], []],
'bp_auto_r' : [['Bp auto','activated_real','d'], [], []],
'bg_auto' : [['Bg auto','activated','d'], ['pin', 'd','i'], []],
'bg_auto_r' : [['Bg auto','activated_real','d'], [], []],
'voy_auto' : [['Led auto','activated','d'], ['pin', 'd','o'], []],
'lum' : [['Recepteur LDR','activated','a'], ['pin', 'd','i'], []], # FIXME : Basculer en analogique
'lum_r' : [['Recepteur LDR','activated_real','a'], [], []]}
# Couleurs
color_passive = (0.800, 0.005, 0.315,1) # bouton non activable : magenta
color_active = (0.799, 0.130, 0.063,1) # bouton activable : orange
color_hl = (0.8, 0.8, 0.8, 1) # bouton focus : blanc
color_activated = (0.8, 0.619, 0.021, 1) # bouton activé numériquement uniquement : jaune
color_activated_real = (0.799, 0.031, 0.038, 1) # élément activé physiquement uniquement : rouge (hors clic)
color_activated_dbl = (0.246, 0.687, 0.078, 1) # élément activé physiquement et numériquement : vert clair
# Constantes UPBGE
JUST_ACTIVATED = bge.logic.KX_INPUT_JUST_ACTIVATED
JUST_RELEASED = bge.logic.KX_INPUT_JUST_RELEASED
ACTIVATE = bge.logic.KX_INPUT_ACTIVE
# JUST_DEACTIVATED = bge.logic.KX_SENSOR_JUST_DEACTIVATED
###############################################################################
# Initialisation de la scène
###############################################################################
def init(cont):
if cont.sensors['Init'].positive == False: # 1 seule fois
return False
twin.manip_init() # Manipulation du modèle 3D
twin.cmd_init() # Commandes
# Brochage
for pin in public_vars:
if public_vars[pin][1] != []:
scene.objects[public_vars[pin][0][0]][public_vars[pin][1][0]] = None
# Groupe de focus pour les actionneurs
twin.cycle_def_focusgroup([["Moteur","blue"],
["Capuchon moteur","blue"],
["Arriere moteur","blue"],
["Moteur axe-1","blue"],
["Moteur coupleur","blue-dark"],
["Moteur vis1","grey"],
["Moteur vis2","grey"]], "Moteur : mot_m(True | False), mot_d(True | False)")
twin.cycle_def_focusgroup([["Led auto", "led_yellow"]], "Voyant témoin mode automatique : voy_auto(True | False)")
# twin.cycle_def_focusgroup([["Bg auto", "color_active"],
# ["Bg auto-on", "color_active"]], "Voyant témoin mode automatique : voy_auto(True | False)")
# Description des composants sensibles
scene.objects['Bp monter']['description']="Bouton poussoir monter volet : bp_m()"
scene.objects['Bp descendre']['description']="Bouton poussoir descendre volet : bp_d()"
scene.objects['Bp arret']['description']="Bouton poussoir arrêt volet : bp_a()"
scene.objects['Bp auto']['description']="Bouton poussoir mode automatique : bp_auto()"
scene.objects['Bg auto']['description']="Bouton à glissière mode automatique : bg_auto()"
scene.objects['Bg auto-on']['description']="Bouton à glissière mode automatique : bg_auto()"
scene.objects['Microrupteur haut']['description']="Capteur fin de course volet en haut : fdc_h()"
scene.objects['Microrupteur bas']['description']="Capteur fin de course volet en bas : fdc_b()"
scene.objects['Recepteur LDR']['description']="Capteur de luminosité (LDR) : lum()"
# Initialisation du système
system_init()
def get_public_vars():
return public_vars
###############################################################################
# Actionneurs
###############################################################################
##
# Moteur et volet
##
def mot (cont):
if scene.objects['System']['run']:
obj = cont.owner
layer = 0
# Monter
if obj['up']:
# Physique du modèle 3D
if obj['prior']:
# Physique (sens horaire -> négatif)
obj['step'] = abs(scene.objects['Axe enrouleur'].worldOrientation.to_euler().x - scene.objects['Axe enrouleur']['last_alpha'])
obj['alpha']=obj['last_alpha'] - obj['step']
if scene.objects['System']['time'] != obj['last_time']:
obj['speed']= -obj['step']/(scene.objects['System']['time']-obj['last_time'])
# print (obj['speed'], obj['step'],scene.objects['System']['time']-obj['last_time'], scene.objects['System']['time'], obj['last_time'])
# Animation
if obj['frame_down']<105: # Volet pas cassé
if obj['frame_up'] <0: # Réinit entre 0 et -4
obj['frame_up']=0
if obj['frame_up']<110 : # Cycle normal de 0 à 100 (butée en 110)
start = obj['frame_up']
end = 111
priority = 1
blendin = 1.0
mode = bge.logic.KX_ACTION_MODE_PLAY
layerWeight = 0.0
ipoFlags = 0
speed = 0.4 # FIXME
scene.objects['Axe enrouleur'].playAction('Axe enrouleur-Up', start, 135, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Axe fdc'].playAction('Axe fdc-Up', start, 135, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 1'].playAction('Lame volet 1-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 2'].playAction('Lame volet 2-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 3'].playAction('Lame volet 3-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 4'].playAction('Lame volet 4-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 5'].playAction('Lame volet 5-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 6'].playAction('Lame volet 6-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 7'].playAction('Lame volet 7-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 8'].playAction('Lame volet 8-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 9'].playAction('Lame volet 9-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 10'].playAction('Lame volet 10-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 11'].playAction('Lame volet 11-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 12'].playAction('Lame volet 12-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 13'].playAction('Lame volet 13-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
obj['frame_up'] = scene.objects['Axe enrouleur'].getActionFrame(layer)
else: # Tourner sans fin
# vitesse = 0.015
vitesse = 0.03
pas_axe_enrouleur = 0.5
pas_axe_fdc = 0.5/3
# scene.objects['Axe enrouleur'].applyRotation((pas_axe_enrouleur*vitesse, 0, 0), True)
scene.objects['Axe fdc'].stopAction(layer)
scene.objects['Axe fdc'].applyRotation((-pas_axe_fdc*vitesse, 0, 0), True)
if obj['frame_up'] ==170: # Réinit
obj['frame_up']=110
start = obj['frame_up']
end = 171
priority = 1
blendin = 1.0
mode = bge.logic.KX_ACTION_MODE_PLAY
layerWeight = 0.0
ipoFlags = 0
speed = 0.4 # FIXME
scene.objects['Axe enrouleur'].playAction('Axe enrouleur-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
# scene.objects['Axe fdc'].playAction('Axe fdc-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 1'].playAction('Lame volet 1-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 2'].playAction('Lame volet 2-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 3'].playAction('Lame volet 3-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 4'].playAction('Lame volet 4-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 5'].playAction('Lame volet 5-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 6'].playAction('Lame volet 6-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 7'].playAction('Lame volet 7-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 8'].playAction('Lame volet 8-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 9'].playAction('Lame volet 9-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 10'].playAction('Lame volet 10-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 11'].playAction('Lame volet 11-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 12'].playAction('Lame volet 12-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 13'].playAction('Lame volet 13-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
obj['frame_up'] = scene.objects['Axe enrouleur'].getActionFrame(layer)
obj['frame_down']= 100-obj['frame_up']
# Physique après mouvement (last_*)
scene.objects['Axe enrouleur']['last_alpha'] = scene.objects['Axe enrouleur'].worldOrientation.to_euler().x
obj['last_time'] = scene.objects['System']['time']
obj['last_alpha'] = obj['alpha']
# Modele 3D -> Arduino
if scene.objects['System']['twins'] and obj['prior_real']:
if scene.objects['Moteur']['pin_m'] is not None:
if scene.objects['Moteur']['pin_d'] is not None:
scene.objects['Moteur']['pin_d'].write(0)
scene.objects['Moteur']['pin_m'].write(1)
# Descendre
if obj['down']:
# Physique du modèle 3D
if obj['prior']:
# Physique (sens trigo -> positif)
obj['step'] = abs(scene.objects['Axe enrouleur'].worldOrientation.to_euler().x - scene.objects['Axe enrouleur']['last_alpha'])
obj['alpha']=obj['last_alpha'] + obj['step']
if scene.objects['System']['time'] != obj['last_time']:
obj['speed']= obj['step']/(scene.objects['System']['time']-obj['last_time'])
# print (round(obj['last_alpha'], 3), round(obj['step'], 3), round(obj['alpha'], 3), round(obj['speed'], 3),
# round(scene.objects['Axe enrouleur']['last_alpha'],3), round(scene.objects['Axe enrouleur'].worldOrientation.to_euler().x,3))
# Animation
if obj['frame_up']<105: # Volet pas cassé
if obj['frame_down'] <0: # Réinit entre 0 et -4
obj['frame_down']=0
if obj['frame_down']<135 : # Cycle normal de 0 à 100 (butée en 135)
start = obj['frame_down']
end = 136
layer = 0
priority = 1
blendin = 1.0
mode = bge.logic.KX_ACTION_MODE_PLAY
layerWeight = 0.0
ipoFlags = 0
speed = 0.4 # FIXME
scene.objects['Axe enrouleur'].playAction('Axe enrouleur-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Axe fdc'].playAction('Axe fdc-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 1'].playAction('Lame volet 1-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 2'].playAction('Lame volet 2-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 3'].playAction('Lame volet 3-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 4'].playAction('Lame volet 4-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 5'].playAction('Lame volet 5-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 6'].playAction('Lame volet 6-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 7'].playAction('Lame volet 7-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 8'].playAction('Lame volet 8-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 9'].playAction('Lame volet 9-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 10'].playAction('Lame volet 10-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 11'].playAction('Lame volet 11-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 12'].playAction('Lame volet 12-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 13'].playAction('Lame volet 13-Down', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
obj['frame_down'] = scene.objects['Axe enrouleur'].getActionFrame(layer)
else: # Tourner sans fin et volet cassé
scene.objects['Axe enrouleur'].stopAction(layer)
scene.objects['Axe fdc'].stopAction(layer)
scene.objects['Lame volet 1'].stopAction(layer)
scene.objects['Lame volet 2'].stopAction(layer)
scene.objects['Lame volet 3'].stopAction(layer)
scene.objects['Lame volet 4'].stopAction(layer)
scene.objects['Lame volet 5'].stopAction(layer)
scene.objects['Lame volet 6'].stopAction(layer)
scene.objects['Lame volet 7'].stopAction(layer)
scene.objects['Lame volet 8'].stopAction(layer)
scene.objects['Lame volet 9'].stopAction(layer)
scene.objects['Lame volet 10'].stopAction(layer)
scene.objects['Lame volet 11'].stopAction(layer)
scene.objects['Lame volet 12'].stopAction(layer)
scene.objects['Lame volet 13'].stopAction(layer)
vitesse = 0.03 # FIXME
# vitesse = 0.015
pas_axe_enrouleur = 0.5
pas_axe_fdc = 0.5/3
pas_volet = 10
scene.objects['Axe enrouleur'].applyRotation((-pas_axe_enrouleur*vitesse, 0, 0), True)
scene.objects['Axe fdc'].applyRotation((pas_axe_fdc*vitesse, 0, 0), True)
scene.objects['Lame volet 1'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 2'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 3'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 4'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 5'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 6'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 7'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 8'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 9'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 10'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 11'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 12'].applyMovement((0, 0, -pas_volet*vitesse), False)
scene.objects['Lame volet 13'].applyMovement((0, 0, -pas_volet*vitesse), False)
obj['frame_down'] +=1
obj['frame_up']= 100-obj['frame_down']
# Physique après mouvement (last_*)
scene.objects['Axe enrouleur']['last_alpha'] = scene.objects['Axe enrouleur'].worldOrientation.to_euler().x
obj['last_time'] = scene.objects['System']['time']
obj['last_alpha'] = obj['alpha']
# Modele 3D -> Arduino
if scene.objects['System']['twins'] and obj['prior_real']:
if scene.objects['Moteur']['pin_d'] is not None:
if scene.objects['Moteur']['pin_m'] is not None:
scene.objects['Moteur']['pin_m'].write(0)
scene.objects['Moteur']['pin_d'].write(1)
# Arrêt
if obj['up'] == False and obj['down'] == False:
# Physique du modèle 3D
if obj['prior']:
obj['speed']= 0
scene.objects['Axe enrouleur']['last_alpha'] = scene.objects['Axe enrouleur'].worldOrientation.to_euler().x
obj['last_time'] = scene.objects['System']['time']
obj['last_alpha'] = obj['alpha']
# Animation
if scene.objects['Axe enrouleur'].isPlayingAction(layer):
scene.objects['Axe enrouleur'].stopAction(layer)
scene.objects['Axe fdc'].stopAction(layer)
scene.objects['Lame volet 1'].stopAction(layer)
scene.objects['Lame volet 2'].stopAction(layer)
scene.objects['Lame volet 3'].stopAction(layer)
scene.objects['Lame volet 4'].stopAction(layer)
scene.objects['Lame volet 5'].stopAction(layer)
scene.objects['Lame volet 6'].stopAction(layer)
scene.objects['Lame volet 7'].stopAction(layer)
scene.objects['Lame volet 8'].stopAction(layer)
scene.objects['Lame volet 9'].stopAction(layer)
scene.objects['Lame volet 10'].stopAction(layer)
scene.objects['Lame volet 11'].stopAction(layer)
scene.objects['Lame volet 12'].stopAction(layer)
scene.objects['Lame volet 13'].stopAction(layer)
# Modele 3D -> Arduino
if scene.objects['System']['twins'] and obj['prior_real']:
if scene.objects['Moteur']['pin_d'] is not None:
if scene.objects['Moteur']['pin_m'] is not None:
scene.objects['Moteur']['pin_m'].write(0)
scene.objects['Moteur']['pin_d'].write(0)
###############################################################################
# Capteurs fin de course
###############################################################################
##
# Etat capteur fin de course volet en haut
##
def fdc_h (cont):
if scene.objects['System']['run'] :
obj = cont.owner
# Arduino -> Modele 3D
if scene.objects['System']['twins'] and obj['prior_real']:
if obj['pin'] is not None:
if obj['pin'].read()==True and obj['activated_real'] == False :
obj['activated_real'] = True
if obj['pin'].read()==False and obj['activated_real'] == True :
obj['activated_real'] = False
# Etat capteur en fonction du volet
scene.objects['Axe fdc']['rx']= scene.objects['Axe fdc'].localOrientation.to_euler().x *(180/math.pi)
if scene.objects['Axe fdc']['rx'] >= -175 and scene.objects['Axe fdc']['rx'] <= -155 and obj['activated'] == False and obj['prior']:
obj['activated'] = True
if scene.objects['Axe fdc']['rx'] < -175 or scene.objects['Axe fdc']['rx'] > -155 and obj['activated'] == True and obj['prior']:
obj['activated'] = False
# Forçage par clic
if obj['click'] == True and obj['prior']:
obj['activated'] = True
# Couleurs
twin.cycle_sensitive_color(obj)
##
# Etat capteur fin de course volet en bas
##
def fdc_b (cont):
if scene.objects['System']['run'] :
obj = cont.owner
# Arduino -> Modele 3D
if scene.objects['System']['twins'] and obj['prior_real']:
if obj['pin'] is not None:
if obj['pin'].read()==True and obj['activated_real'] == False :
obj['activated_real'] = True
if obj['pin'].read()==False and obj['activated_real'] == True :
obj['activated_real'] = False
# Etat capteur en fonction du volet
if scene.objects['Axe fdc']['rx'] >= -10 and scene.objects['Axe fdc']['rx'] <= 10 and obj['activated'] == False and obj['prior']:
obj['activated'] = True
if scene.objects['Axe fdc']['rx'] < -10 or scene.objects['Axe fdc']['rx'] > 10 and obj['activated'] == True and obj['prior']:
obj['activated'] = False
# Forçage par clic
if obj['click'] == True and obj['prior']:
obj['activated'] = True
# Couleurs
twin.cycle_sensitive_color(obj)
###############################################################################
# Système
###############################################################################
##
# Initialisation du système
# Le moteur est géré en continue.
##
def system_init ():
# Voyants statiques
scene.objects['Led capteur courant'].setVisible(True,False)
scene.objects['Led capteur courant-on'].setVisible(False,False)
scene.objects['Led moteur'].setVisible(True,False)
scene.objects['Led moteur-on'].setVisible(False,False)
scene.objects['Led alimentation'].setVisible(True,False)
scene.objects['Led alimentation-on'].setVisible(False,False)
system_reset()
##
# Réinitialisation du système
##
def system_reset ():
# Mise en place de la variante
runpy.run_path(scene.objects['System']['script'], run_name='init')
# Entrées à l'état initial
objs= ['Bp monter', 'Bp arret', 'Bp descendre', 'Bp auto', 'Bg auto', 'Microrupteur haut','Microrupteur bas', 'Recepteur LDR']
for obj in objs:
scene.objects[obj]['activated']=False
scene.objects[obj]['activated_real']=False
scene.objects['Bg auto-on'].setVisible(False,False)
# Voyants aux états initiaux
scene.objects['Led auto']['activated']=False
scene.objects['Led auto'].setVisible(True,False)
scene.objects['Led auto-on'].setVisible(False,False)
# Volet et moteur
scene.objects['Moteur']['up']=False
scene.objects['Moteur']['down']=False
scene.objects['Moteur']['alpha']=0
scene.objects['Moteur']['last_alpha']=0
scene.objects['Moteur']['speed']=0
scene.objects['Moteur']['speed_setting']=125.6 # Vitesse du moteur numérique : 125.6 rad /s ( 20 tr / s )
scene.objects['Moteur']['step']=0
scene.objects['Axe enrouleur']['last_alpha']=scene.objects['Axe enrouleur'].worldOrientation.to_euler().x
obj = scene.objects['Moteur']
start = 49
end = 50
priority = 1
layer = 0
blendin = 1.0
mode = bge.logic.KX_ACTION_MODE_PLAY
layerWeight = 0.0
ipoFlags = 0
speed = 0.4
scene.objects['Axe enrouleur'].playAction('Axe enrouleur-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Axe fdc'].playAction('Axe fdc-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 1'].playAction('Lame volet 1-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 2'].playAction('Lame volet 2-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 3'].playAction('Lame volet 3-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 4'].playAction('Lame volet 4-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 5'].playAction('Lame volet 5-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 6'].playAction('Lame volet 6-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 7'].playAction('Lame volet 7-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 8'].playAction('Lame volet 8-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 9'].playAction('Lame volet 9-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 10'].playAction('Lame volet 10-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 11'].playAction('Lame volet 11-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 12'].playAction('Lame volet 12-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
scene.objects['Lame volet 13'].playAction('Lame volet 13-Up', start, end, layer, priority, blendin, mode, layerWeight, ipoFlags, speed)
obj['frame_up'] = scene.objects['Axe enrouleur'].getActionFrame(layer)
obj['frame_down']= 100-obj['frame_up']
# Priorités activées
objs= ['Bp monter', 'Bp arret', 'Bp descendre', 'Bp auto', 'Bg auto', 'Microrupteur haut','Microrupteur bas', 'Recepteur LDR',
'Moteur', 'Led auto']
for obj in objs:
scene.objects[obj]['prior']=True
scene.objects[obj]['prior_real']=True