comb_profile_load = electrical.CombinationPowerProfile([load_bat], name='load_profil')
comb_profile_end = electrical.CombinationPowerProfile([end_bat], name='end_soc_profil')
# =============================================================================
# Electrical Optimizer
# =============================================================================
input_values = {}
blocks = []
block_ebo = wf.InstanciateModel(eo.ElecBatteryOptimizer, name='ElecBatteryOptimizer')
optimize_ebo = wf.ModelMethod(eo.ElecBatteryOptimizer, 'Optimize', name='Optimize-ElecBatteryOptimizer')
attribute_selection_ebo = wf.ModelAttribute('powerpack_electric_simulators')
blocks.extend([block_ebo, optimize_ebo, attribute_selection_ebo])
pipes = [wf.Pipe(block_ebo.outputs[0], optimize_ebo.inputs[0]),
wf.Pipe(optimize_ebo.outputs[1], attribute_selection_ebo.inputs[0])
]
# =============================================================================
# Thermal specs
# =============================================================================
altitude = 0.1
evol_power1 = electrical.Evolution(evolution = list(npy.linspace(0, 5., 10)))
evol_power2 = electrical.Evolution(evolution = list(npy.linspace(0, 6., 10)))
evol_h_min1 = electrical.Evolution(evolution = [0 + 0.3*1e1*p/(p + 0.1)/2. for p in npy.linspace(0, 1, 10)])
evol_h_max2 = electrical.Evolution(evolution = [altitude + 0.3*1e1*p/(p + 0.1)/2. for p in npy.linspace(0, 1, 10)])
ce_cooling1_min = electrical.CombinationEvolution(evolution1 = [evol_power1],
evolution2 = [evol_h_min1], name='Min', title1='power', title2='h')
ce_cooling1_max = electrical.CombinationEvolution(evolution1 = [evol_power2],
'bound': 750
}, {
'attribute': 'bms.number_cells',
'operator': 'lte',
'bound': 800
}, {
'attribute': 'bms.battery.number_cells',
'operator': 'gt',
'bound': 700
}]
filter_sort = wf.Filter(filters, 'Filters EBO')
blocks.extend([block_ebo, optimize_ebo, attribute_selection_ebo, filter_sort])
pipes = [
wf.Pipe(block_ebo.outputs[0], optimize_ebo.inputs[0]),
wf.Pipe(optimize_ebo.outputs[1], attribute_selection_ebo.inputs[0]),
wf.Pipe(attribute_selection_ebo.outputs[0], filter_sort.inputs[0])
]
workflow = wf.Workflow(blocks, pipes, filter_sort.outputs[0])
input_values = {
0: cells.CELL1_2RC,
1: limits_voltage_module,
2: limits_current_module,
3: limits_voltage_battery,
4: limits_current_battery,
5: [33, 34],
6: [24, 25],
7: [comb_profile_load, comb_profile_wltp, comb_profile_end],
12: 5
name='generate'),
name='Generate')
block_efficiencymap = wf.InstanciateModel(objects.EfficiencyMap,
name='Efficiency Map')
block_engine = wf.InstanciateModel(objects.Engine, name='Engine')
block_gearbox = wf.InstanciateModel(objects.GearBox, name='Gearbox')
block_cluster = wf.InstanciateModel(objects.Clustering, name='Clustering')
display = wf.Display(name='Display')
block_workflow = [
block_generator, block_generate, block_gearbox, block_engine,
block_efficiencymap, block_cluster, display
]
pipe_workflow = [
wf.Pipe(block_generator.outputs[0], block_generate.inputs[0]),
wf.Pipe(block_gearbox.outputs[0], block_generator.inputs[0]),
wf.Pipe(block_engine.outputs[0], block_gearbox.inputs[0]),
wf.Pipe(block_efficiencymap.outputs[0], block_engine.inputs[0]),
wf.Pipe(block_generate.outputs[0], block_cluster.inputs[0]),
wf.Pipe(block_cluster.outputs[0], display.inputs[0])
]
workflow = wf.Workflow(block_workflow, pipe_workflow,
block_generate.outputs[0])
workflow.plot()
engine_speeds = list(np.linspace(500, 6000, num=12)) #Engine speed in rpm
engine_speeds = [float(i) * (np.pi / 30) for i in engine_speeds] # in rad/s
engine_torques = [
15.6, 31.2, 46.8, 62.4, 78, 93.6, 109.2, 124.8, 140.4, 156, 171.6
concatenate = wf.ClassMethod(class_=Catalog,
method_name='concatenate',
name='Concatenate')
display = wf.Display(order=0)
array_attribute = wf.ModelAttribute(attribute_name='array', name='Array')
blocks = [
import_csv, instantiate_pareto, catalog1, filter1, filtered_catalog1,
catalog2, filter2, filtered_catalog2, catalogs, concatenate, display,
array_attribute
]
# Pipes
pipes = [
wf.Pipe(import_csv.outputs[0], catalog1.inputs[0]),
wf.Pipe(import_csv.outputs[1], catalog1.inputs[1]),
wf.Pipe(instantiate_pareto.outputs[0], catalog1.inputs[2]),
wf.Pipe(import_csv.outputs[0], catalog2.inputs[0]),
wf.Pipe(import_csv.outputs[1], catalog2.inputs[1]),
wf.Pipe(instantiate_pareto.outputs[0], catalog2.inputs[2]),
wf.Pipe(catalog1.outputs[0], filter1.inputs[0]),
wf.Pipe(catalog2.outputs[0], filter2.inputs[0]),
wf.Pipe(filter1.outputs[0], filtered_catalog1.inputs[0]),
wf.Pipe(import_csv.outputs[1], filtered_catalog1.inputs[1]),
wf.Pipe(instantiate_pareto.outputs[0], filtered_catalog1.inputs[2]),
wf.Pipe(filtered_catalog1.outputs[0], catalogs.inputs[0]),
wf.Pipe(filter2.outputs[0], filtered_catalog2.inputs[0]),
wf.Pipe(import_csv.outputs[1], filtered_catalog2.inputs[1]),
wf.Pipe(instantiate_pareto.outputs[0], filtered_catalog2.inputs[2]),
wf.Pipe(filtered_catalog2.outputs[0], catalogs.inputs[1]),
# filtered = wf.MultiPlot(choice_args, 1, name='Filtered')
# objectives_method = wf.ModelMethod(model_class=Catalog,
# method_name='find_best_objective',
# name="Find best objectives")
# objectives_attributes = wf.ModelAttribute(attribute_name='objectives',
# name='Objectives')
blocks = [
import_csv, instantiate_pareto, instantiate_catalog, filter_method,
filtered_catalog, display, filtered
]
# , objectives_method, objectives_attributes]
# Pipes
pipes = [
wf.Pipe(import_csv.outputs[0], instantiate_catalog.inputs[0]),
wf.Pipe(import_csv.outputs[1], instantiate_catalog.inputs[1]),
wf.Pipe(instantiate_pareto.outputs[0], instantiate_catalog.inputs[2]),
wf.Pipe(instantiate_catalog.outputs[0], display.inputs[0]),
# wf.Pipe(instantiate_catalog.outputs[0], objectives_method.inputs[0]),
wf.Pipe(instantiate_catalog.outputs[0], filter_method.inputs[0]),
wf.Pipe(filter_method.outputs[0], filtered_catalog.inputs[0]),
wf.Pipe(import_csv.outputs[1], filtered_catalog.inputs[1]),
wf.Pipe(filtered_catalog.outputs[0], filtered.inputs[0]),
wf.Pipe(instantiate_pareto.outputs[0], filtered_catalog.inputs[2])
# wf.Pipe(objectives_method.outputs[1], objectives_attributes.inputs[0])
]
# Workflow
workflow = wf.Workflow(blocks=blocks,
pipes=pipes,
generator_generate = wf.ModelMethod(model_class=Generator,
method_name='generate',
name='Generator Generate')
attribute_selection = wf.ModelAttribute(attribute_name='models',
name='Attribute Selection')
# Subworkflow of model optimization
instanciate_optimizer = wf.InstanciateModel(model_class=Optimizer,
name='Instantiate Optimizer')
optimization = wf.ModelMethod(model_class=Optimizer,
method_name='optimize',
name='Optimization')
model_fetcher = wf.ModelAttribute(attribute_name='model_to_optimize',
name='Model Fetcher')
pipe1_opt = wf.Pipe(input_variable=instanciate_optimizer.outputs[0],
output_variable=optimization.inputs[0])
pipe2_opt = wf.Pipe(input_variable=optimization.outputs[1],
output_variable=model_fetcher.inputs[0])
optimization_blocks = [instanciate_optimizer, optimization, model_fetcher]
optimization_pipes = [pipe1_opt, pipe2_opt]
optimization_workflow = wf.Workflow(blocks=optimization_blocks,
pipes=optimization_pipes,
output=model_fetcher.outputs[0],
name='Optimization Workflow')
optimization_workflow_block = wf.WorkflowBlock(workflow=optimization_workflow,
name='Workflow Block')
parallel_optimization = wf.ForEach(
workflow_block=optimization_workflow_block,
workflow_iterable_input=optimization_workflow_block.inputs[0],
name='Pattern Generator')
block_generate = wf.ModelMethod(MethodType(class_=patterns.PatternGenerator,
name='generate'),
name='Generate')
list_attribute = [
'minor_axis_size_in_mm', 'excentricity', 'clearence', 'piece_diameter'
]
display = wf.MultiPlot(list_attribute, order=1, name='Display')
# display = wf.Display(name='Display')
block_workflow = [block_generator, block_generate]
pipe_workflow = [
wf.Pipe(block_generator.outputs[0], block_generate.inputs[0]),
wf.Pipe(block_generate.outputs[0], display.inputs[0])
]
workflow = wf.Workflow(block_workflow, pipe_workflow,
block_generate.outputs[0])
list_diameters = [0.1, 0.125, 0.15, 0.175, 0.2, 0.225, 0.25, 0.275, 0.3]
excentricity_min_max = (0.6, 0.9)
diameter_percetage_clearence_min_max = (0.1, 0.6)
MINOR_AXIS_SIZE_IN_MM = 1
input_values = {
workflow.input_index(block_generator.inputs[0]):
MINOR_AXIS_SIZE_IN_MM,
workflow.input_index(block_generator.inputs[1]):
block_generator = wf.InstanciateModel(bp.MainRevenueGenerator, name='MainRevenueGenerator')
method_generate = wf.ModelMethod(bp.MainRevenueGenerator, 'decision_tree', name='generate')
block_optimizer = wf.InstanciateModel(bp.MainRevenueOptimizer, name='MainRevenueOptimizer')
method_minimize = wf.ModelMethod(bp.MainRevenueOptimizer, 'minimize', name='minimize')
method_sort = wf.ModelMethod(bp.MainRevenueOptimizer, 'sort_solutions', name='sort')
parallel_plot_block = wf.ParallelPlot(['last_margin', 'cumulative_cost', 'cumulative_revenue',
'number_main_area', 'number_area',
'last_revenue', 'strategy_txt', 'revenue_txt'])
blocks = []
blocks.extend([block_generator, method_generate, block_optimizer, method_minimize,
method_sort, parallel_plot_block])
pipes = [wf.Pipe(block_generator.outputs[0], method_generate.inputs[0]),
wf.Pipe(method_generate.outputs[0], method_minimize.inputs[1]),
wf.Pipe(block_optimizer.outputs[0], method_minimize.inputs[0]),
wf.Pipe(method_minimize.outputs[0], method_sort.inputs[1]),
wf.Pipe(block_optimizer.outputs[0], method_sort.inputs[0]),
wf.Pipe(method_sort.outputs[0], parallel_plot_block.inputs[0])]
workflow = wf.Workflow(blocks, pipes, method_sort.outputs[0], name='Generation')
workflow.plot_jointjs()
input_values = {workflow.index(block_generator.inputs[0]): [France, Germany, Italy, USA, Canada, China, Japan],
workflow.index(method_generate.inputs[1]): 2020,
workflow.index(method_generate.inputs[2]): 2022,
workflow.index(method_minimize.inputs[2]): 1e6,
from dessia_common.typings import MethodType
block_optimizer = wf.InstanciateModel(objects.GearBoxOptimizer, name='Gearbox Optimizer')
method_optimize = wf.ModelMethod(MethodType(class_ =objects.GearBoxOptimizer,name= 'optimize'), name='Optimize')
block_gearbox = wf.InstanciateModel(objects.GearBox, name='Gearbox')
block_engine = wf.InstanciateModel(objects.Engine, name= 'Engine')
block_efficiencymap = wf.InstanciateModel(objects.EfficiencyMap, name= 'Efficiency Map')
block_wltpcycle = wf.InstanciateModel(objects.WLTPCycle, name = 'WLTP Cycle')
list_attribute = ['average_fuel_consumption', 'average_engine_speed', 'average_engine_torque', 'ratio_min', 'ratio_max', 'average_ratio']
display = wf.MultiPlot(list_attribute, order = 1, name= 'Display')
block_workflow = [block_optimizer, method_optimize, block_gearbox, block_engine, block_efficiencymap, block_wltpcycle, display]
pipe_workflow = [wf.Pipe(block_optimizer.outputs[0], method_optimize.inputs[0]),
wf.Pipe(block_gearbox.outputs[0], block_optimizer.inputs[0]),
wf.Pipe(block_wltpcycle.outputs[0], block_optimizer.inputs[1]),
wf.Pipe(block_engine.outputs[0], block_gearbox.inputs[0]),
wf.Pipe(block_efficiencymap.outputs[0], block_engine.inputs[0]),
wf.Pipe(method_optimize.outputs[0], display.inputs[0])]
workflow = wf.Workflow(block_workflow, pipe_workflow, method_optimize.outputs[0])
engine_speeds = list(np.linspace(500, 6000, num = 12)) #Engine speed in rpm
engine_speeds = [float(i)*(np.pi/30) for i in engine_speeds] # in rad/s
engine_torques = [15.6,31.2, 46.8, 62.4, 78, 93.6, 109.2, 124.8, 140.4, 156, 171.6] #engine torque in N*m
mass_flow_rate = [[0.1389, 0.2009, 0.2524, 0.3006, 0.3471, 0.4264, 0.4803, 0.5881, 0.5881, 0.6535, 0.7188],
block_optimize = wf.ModelMethod(method_type=method_type, name='Optimize')
block_instanciate_reductor = wf.InstantiateModel(objects.InstanciateReductor,
name='Instanciate Reductor')
method_type = MethodType(class_=objects.InstanciateReductor,
name='instanciate')
block_instanciate = wf.ModelMethod(method_type=method_type, name='Instanciate')
block_motor = wf.InstantiateModel(objects.Motor, name='Motor')
list_attribute1 = ['mass_reductor', 'number_solution']
display_reductor = wf.MultiPlot(list_attribute1, 1, name='Display Reductor')
block_workflow = [block_optimizer, block_optimize, block_instanciate_reductor,
block_instanciate, block_motor, display_reductor]
pipe_worflow = [wf.Pipe(block_optimizer.outputs[0], block_optimize.inputs[0]),
wf.Pipe(block_instanciate_reductor.outputs[0],
block_instanciate.inputs[0]),
wf.Pipe(block_motor.outputs[0],
block_instanciate_reductor.inputs[0]),
wf.Pipe(block_instanciate.outputs[0],
block_optimizer.inputs[0]),
wf.Pipe(block_optimize.outputs[0], display_reductor.inputs[0])]
workflow = wf.Workflow(block_workflow, pipe_worflow, block_optimize.outputs[0])
input_values = {workflow.index(block_optimizer.inputs[1]): 500,
workflow.index(block_optimizer.inputs[2]): [-1, 1],
workflow.index(block_optimizer.inputs[3]): [-1, 1],
workflow.index(block_instanciate_reductor.inputs[1]): 0.01,
# solutions = opti1.optimize(assemblies=[assembly1], number_solution_per_assembly=2)
block_optimizer = wf.InstanciateModel(tuto.Optimizer, name='Optimizer')
method_type_optimize = MethodType(tuto.Optimizer, 'optimize')
block_optimize = wf.ModelMethod(method_type_optimize, name='optimize')
list_attribute1 = [
'length', 'min_radius', 'max_radius', 'distance_input', 'straight_line'
]
display_reductor = wf.ParallelPlot(list_attribute1, 1, name='Display')
block_workflow = [block_optimizer, block_optimize, display_reductor]
pipe_worflow = [
wf.Pipe(block_optimizer.outputs[0], block_optimize.inputs[0]),
wf.Pipe(block_optimize.outputs[0], display_reductor.inputs[0])
]
workflow = wf.Workflow(block_workflow,
pipe_worflow,
block_optimize.outputs[0],
name="workflowpipe")
input_values = {
workflow.index(block_optimize.inputs[1]): assemblies,
workflow.index(block_optimize.inputs[2]): 1,
}
workflow_run = workflow.run(input_values)
from dessia_common import workflow
import automotive.interior as interior
cockpit = workflow.TypedVariable(interior.Cockpit, name='Cockpit')
population_instanciator = workflow.ClassMethod(interior.Population,
'random_population')
mark_cockpit = workflow.ModelMethod(interior.Population, 'mark_cockpit')
extremas = workflow.ModelMethod(interior.SeatErgonomyAnalysis, 'extremas')
interior_instanciator = workflow.InstanciateModel(
interior.CarInterior) #cockpit: 0
cockpit_pipe1 = workflow.Pipe(cockpit, mark_cockpit.inputs[1])
cockpit_pipe2 = workflow.Pipe(cockpit, interior_instanciator.inputs[0])
population_pipe = workflow.Pipe(population_instanciator.outputs[0],
mark_cockpit.inputs[0])
marks_pipe = workflow.Pipe(mark_cockpit.outputs[0], extremas.inputs[0])
passenger_pipe = workflow.Pipe(extremas.outputs[0],
interior_instanciator.inputs[4])
simple_analysis = workflow.Workflow([population_instanciator, mark_cockpit],
[population_pipe],
mark_cockpit.outputs[0],
name='Simple analysis')
seat_analysis_workflow = workflow.Workflow(
[population_instanciator, mark_cockpit, interior_instanciator, extremas],
[
population_pipe, marks_pipe, passenger_pipe, cockpit_pipe1,
#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
A simple workflow composed of functions
"""
import math
import dessia_common.workflow as workflow
def sinus_f(x: float) -> float:
return math.sin(x)
def asin_f(x: float) -> float:
return math.asin(x)
sinus = workflow.Function(sinus_f)
arcsin = workflow.Function(asin_f)
pipe1 = workflow.Pipe(sinus.outputs[0], arcsin.inputs[0])
workflow = workflow.WorkFlow([sinus, arcsin], [pipe1])
workflow.plot_graph()
workflow_run = workflow.run([math.pi / 3])
import hello_dessia as hd
import dessia_common.workflow as wf
from dessia_api_client import Client
block_generator = wf.InstanciateModel(hd.Generator, name='Generator')
methode_generate = wf.ModelMethod(hd.Generator, 'generate', name='generate')
list_attribute = [
'rivet_diameter', 'rivet_length', 'head_diameter', 'head_length', 'price',
'mass'
]
display = wf.ParallelPlot(list_attribute, 1, name='Display')
block_workflow = [block_generator, methode_generate, display]
pipe_worflow = [
wf.Pipe(block_generator.outputs[0], methode_generate.inputs[0]),
wf.Pipe(methode_generate.outputs[0], display.inputs[0])
]
workflow = wf.Workflow(block_workflow, pipe_worflow,
methode_generate.outputs[0])
workflow_block = wf.WorkflowBlock(workflow=workflow, name='Workflow')
final_pipe_workflow = pipe_worflow + [
wf.Pipe(methode_generate.outputs[1], workflow_block.inputs[0])
]
final_block_workflow = block_workflow + [workflow_block]
final_workflow = wf.Workflow(final_block_workflow,
final_pipe_workflow,
methode_generate.outputs[0],
name="")
# final_workflow.plot_jointjs()
