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smt-optimizer/base_optimizer/optimizer_feederpriority.py

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from base_optimizer.optimizer_common import *
@timer_wrapper
def feeder_allocate(component_data, pcb_data, feeder_data, figure=False):
feeder_points, feeder_division_points = defaultdict(int), defaultdict(int) # 供料器贴装点数
mount_center_pos = defaultdict(int)
feeder_limit, feeder_arrange = defaultdict(int), defaultdict(int)
part_nozzle = defaultdict(str)
feeder_base = [-2] * max_slot_index # 已安装在供料器基座上的元件(-2: 未分配,-1: 占用状态)
feeder_base_points = [0] * max_slot_index # 供料器基座结余贴装点数量
for data in pcb_data.iterrows():
pos, part = data[1]['x'] + stopper_pos[0], data[1]['part']
part_index = component_data[component_data['part'] == part].index.tolist()[0]
if part not in component_data:
feeder_limit[part_index] = component_data.loc[part_index]['feeder-limit']
feeder_arrange[part_index] = 0
feeder_points[part_index] += 1
mount_center_pos[part_index] += ((pos - mount_center_pos[part_index]) / feeder_points[part_index])
part_nozzle[part_index] = component_data.loc[part_index]['nz']
for part_index, points in feeder_points.items():
feeder_division_points[part_index] = max(points // feeder_limit[part_index], 1)
nozzle_component, nozzle_component_points = defaultdict(list), defaultdict(list)
for part, nozzle in part_nozzle.items():
for _ in range(feeder_limit[part]):
nozzle_component[nozzle].append(part)
nozzle_component_points[nozzle].append(feeder_points[part])
if feeder_data is not None:
for _, feeder in feeder_data.iterrows():
slot, part = feeder['slot'], feeder['part']
part_index = component_data[component_data['part'] == part].index.tolist()[0]
# 供料器基座分配位置和对应贴装点数
feeder_base[slot], feeder_base_points[slot] = part_index, feeder_division_points[part_index]
feeder_type = component_data.loc[part_index]['fdr']
extra_width = feeder_width[feeder_type][0] + feeder_width[feeder_type][1] - slot_interval
while extra_width > 0:
slot += 1
feeder_base[slot] = -1
extra_width -= slot_interval
feeder_limit[part_index] -= 1
feeder_arrange[part_index] += 1
if feeder_limit[part_index] < 0:
info = 'the number of arranged feeder for [' + part + '] exceeds the quantity limit'
raise ValueError(info)
for nozzle, components in nozzle_component.items():
if part_index in components:
index_ = components.index(part_index)
nozzle_component[nozzle].pop(index_)
nozzle_component_points[nozzle].pop(index_)
break
nozzle_assigned_counter = optimal_nozzle_assignment(component_data, pcb_data)
head_assign_indexes = list(range(max_head_index))
nozzle_pattern, optimal_nozzle_pattern, optimal_nozzle_points = [], None, 0
# nozzle_pattern = ['CN220', 'CN065','CN065','CN065','CN065','CN220']
# 先排序
nozzle_pattern_list = []
for nozzle, counter in nozzle_assigned_counter.items():
nozzle_pattern_list.append([nozzle, sum(nozzle_component_points[nozzle]) // counter])
nozzle_pattern_list.sort(key=lambda x: x[1], reverse=True)
# 后确定吸嘴分配模式
head_index = [3, 2, 4, 1, 5, 0]
nozzle_pattern = [0] * max_head_index
for nozzle, _ in nozzle_pattern_list:
counter = nozzle_assigned_counter[nozzle]
while counter:
nozzle_pattern[head_index[0]] = nozzle
counter -= 1
head_index.pop(0)
while True:
best_assign, best_assign_points = [], []
best_assign_slot, best_assign_value = -1, -np.Inf
best_nozzle_component, best_nozzle_component_points = None, None
for slot in range(1, max_slot_index // 2 - (max_head_index - 1) * interval_ratio + 1):
nozzle_assigned_counter_cpy = copy.deepcopy(nozzle_assigned_counter)
feeder_assign, feeder_assign_points = [], []
tmp_feeder_limit, tmp_feeder_points = feeder_limit.copy(), feeder_points.copy()
tmp_nozzle_component, tmp_nozzle_component_points = copy.deepcopy(nozzle_component), copy.deepcopy(
nozzle_component_points)
# 记录扫描到的已安装的供料器元件类型
for head in range(max_head_index):
feeder_assign.append(feeder_base[slot + head * interval_ratio])
if scan_part := feeder_assign[-1] >= 0:
nozzle = part_nozzle[scan_part]
feeder_assign_points.append(feeder_base_points[slot + head * interval_ratio])
if feeder_assign_points[-1] <= 0:
feeder_assign[-1], feeder_assign_points[-1] = -1, 0
elif nozzle in nozzle_assigned_counter_cpy.keys():
nozzle_assigned_counter_cpy[nozzle] -= 1
if nozzle_assigned_counter_cpy[nozzle] == 0:
nozzle_assigned_counter_cpy.pop(nozzle)
else:
feeder_assign_points.append(0)
if -2 not in feeder_assign: # 无可用槽位
if sum(feeder_assign_points) > optimal_nozzle_points:
optimal_nozzle_points = sum(feeder_assign_points)
optimal_nozzle_pattern = [''] * max_head_index
for head in range(max_head_index):
optimal_nozzle_pattern[head] = part_nozzle[feeder_assign[head]]
continue
assign_part_stack, assign_part_stack_points = [], []
for idx in head_assign_indexes:
if feeder_assign[idx] != -2:
continue
if len(nozzle_pattern) == 0: # 吸嘴匹配模式为空,优先分配元件,根据分配元件倒推吸嘴匹配模式
nozzle_assign = ''
max_points, max_nozzle_points = 0, 0
for nozzle in nozzle_assigned_counter_cpy.keys():
if len(tmp_nozzle_component[nozzle]) == 0:
continue
part = max(tmp_nozzle_component[nozzle],
key=lambda x: tmp_feeder_points[x] / tmp_feeder_limit[x] if
tmp_feeder_points[x] != 0 else 0)
index_ = tmp_nozzle_component[nozzle].index(part)
if max_points < tmp_nozzle_component_points[nozzle][index_]:
max_points, nozzle_assign = tmp_nozzle_component_points[nozzle][index_], nozzle
else:
# 吸嘴匹配模式非空,按对应吸嘴类型进行元件分配
nozzle_assign = nozzle_pattern[idx]
if len(tmp_nozzle_component[nozzle_assign]) == 0:
# 当前头对应吸嘴类型无可用元件,将计划分配的元件压入堆栈
part = max(tmp_feeder_points.keys(),
key=lambda x: tmp_feeder_points[x] / tmp_feeder_limit[x] if tmp_feeder_limit[
x] != 0 else 0)
for nozzle, component_list in tmp_nozzle_component.items():
if part in component_list:
nozzle_assign = nozzle
assign_part_stack.append(part)
assign_part_stack_points.append(feeder_division_points[part])
break
else:
# 当前头对应吸嘴类型有可用元件,直接分配对应类型的元件
index_ = tmp_nozzle_component[nozzle_assign].index(max(tmp_nozzle_component[nozzle_assign],
key=lambda x: tmp_feeder_points[x] /
tmp_feeder_limit[x] if
tmp_feeder_limit[x] != 0 else 0))
part = tmp_nozzle_component[nozzle_assign][index_]
feeder_type = component_data.loc[part]['fdr']
extra_width, extra_slot = feeder_width[feeder_type][0] + feeder_width[feeder_type][1] - slot_interval, 1
slot_overlap = False
while extra_width > 0:
slot_ = slot + idx * interval_ratio + extra_slot
if feeder_base[slot_] != -2 or slot_ > max_slot_index // 2:
slot_overlap = True
break
extra_width -= slot_interval
extra_slot += 1
# 可用供料器数目充足且不存在和已有供料器的占位冲突
if tmp_feeder_limit[part] > 0 and not slot_overlap:
feeder_assign[idx], feeder_assign_points[idx] = part, feeder_division_points[part]
extra_width, extra_head = feeder_width[feeder_type][0] + feeder_width[feeder_type][
1] - head_interval, 1
while extra_width > 0 and idx + extra_head < max_head_index:
feeder_assign[idx + extra_head] = -1
extra_head += 1
extra_width -= head_interval
else:
part = -1 # 存在位置冲突的元件,不占用可用供料器数
# 更新吸嘴匹配模式的吸嘴数
if nozzle_assign in nozzle_assigned_counter_cpy.keys():
nozzle_assigned_counter_cpy[nozzle_assign] -= 1
if nozzle_assigned_counter_cpy[nozzle_assign] == 0:
nozzle_assigned_counter_cpy.pop(nozzle_assign)
if part >= 0 and tmp_feeder_limit[part] == 0:
continue
if part in tmp_nozzle_component[nozzle_assign]:
part_index = tmp_nozzle_component[nozzle_assign].index(part)
tmp_nozzle_component[nozzle_assign].pop(part_index)
tmp_nozzle_component_points[nozzle_assign].pop(part_index)
tmp_feeder_limit[part] -= 1
tmp_feeder_points[part] -= feeder_division_points[part]
# 元件堆栈出栈,首先分配吸嘴类型一致的头
if nozzle_pattern:
for head, feeder in enumerate(feeder_assign):
if feeder != -2:
continue
for idx, part in enumerate(assign_part_stack):
feeder_type = component_data.loc[part]['fdr']
extra_width, extra_slot = feeder_width[feeder_type][0] + feeder_width[feeder_type][
1] - slot_interval, 1
slot_overlap = False
while extra_width > 0:
slot_ = slot + head * interval_ratio + extra_slot
if feeder_base[slot_] != -2 or slot_ > max_slot_index // 2:
slot_overlap = True
break
extra_width -= slot_interval
extra_slot += 1
if component_data.loc[part]['nz'] == nozzle_pattern[head] and not slot_overlap:
feeder_assign[head], feeder_assign_points[head] = assign_part_stack[idx], \
assign_part_stack_points[idx]
assign_part_stack.pop(idx)
assign_part_stack_points.pop(idx)
break
# 元件堆栈,然后分配元件堆栈中未分配的其它元件
for head in head_assign_indexes:
if feeder_assign[head] != -2 or len(assign_part_stack) == 0:
continue
part, points = assign_part_stack[0], assign_part_stack_points[0]
feeder_type = component_data.loc[part]['fdr']
extra_width, extra_slot = feeder_width[feeder_type][0] + feeder_width[feeder_type][1] - slot_interval, 1
slot_overlap = False
while extra_width > 0:
slot_ = slot + head * interval_ratio + extra_slot
if feeder_base[slot_] != -2 or slot_ > max_slot_index // 2:
slot_overlap = True
break
extra_width -= slot_interval
extra_slot += 1
if not slot_overlap:
feeder_assign[head], feeder_assign_points[head] = part, points
extra_width, extra_head = feeder_width[feeder_type][0] + feeder_width[feeder_type][
1] - head_interval, 1
while extra_width > 0 and head + extra_head < max_head_index:
feeder_assign[head + extra_head] = -1
extra_head += 1
extra_width -= head_interval
else:
# 返还由于机械限位无法分配的,压入元件堆栈中的元素
nozzle = component_data.loc[part]['nz']
tmp_nozzle_component[nozzle].insert(0, part)
tmp_nozzle_component_points[nozzle].insert(0, points)
assign_part_stack.pop(0)
assign_part_stack_points.pop(0)
# 仍然存在由于机械限位,无法进行分配的在堆栈中的元件
while assign_part_stack:
part, points = assign_part_stack[0], assign_part_stack_points[0]
nozzle = component_data.loc[part]['nz']
tmp_nozzle_component[nozzle].insert(0, part)
tmp_nozzle_component_points[nozzle].insert(0, points)
assign_part_stack.pop(0)
assign_part_stack_points.pop(0)
nozzle_change_counter, average_slot = 0, []
for head, feeder_ in enumerate(feeder_assign):
if feeder_ < 0:
continue
average_slot.append(
(mount_center_pos[feeder_] - slotf1_pos[0]) / slot_interval + 1 - head * interval_ratio)
if nozzle_pattern and component_data.loc[feeder_]['nz'] != nozzle_pattern[head]:
nozzle_change_counter += 1
if len(average_slot) == 0:
continue
average_slot = sum(average_slot) / len(average_slot)
assign_value = 0
feeder_assign_points_cpy = feeder_assign_points.copy()
while True:
points_filter = list(filter(lambda x: x > 0, feeder_assign_points_cpy))
if not points_filter:
break
assign_value += e_gang_pick * min(points_filter) * (len(points_filter) - 1)
for head, _ in enumerate(feeder_assign_points_cpy):
if feeder_assign_points_cpy[head] == 0:
continue
feeder_assign_points_cpy[head] -= min(points_filter)
assign_value -= 1e2 * e_nz_change * nozzle_change_counter + 1e-5 * abs(slot - average_slot)
if assign_value >= best_assign_value and sum(feeder_assign_points) != 0:
best_assign_value = assign_value
best_assign = feeder_assign.copy()
best_assign_points = feeder_assign_points.copy()
best_assign_slot = slot
best_nozzle_component, best_nozzle_component_points = tmp_nozzle_component, tmp_nozzle_component_points
if not best_assign_points:
break
if len(nozzle_pattern) == 0:
nozzle_pattern = [''] * max_head_index
for idx, part in enumerate(best_assign):
if part < 0:
continue
# 新安装的供料器
if feeder_base[best_assign_slot + idx * interval_ratio] != part:
# 除去分配给最大化同时拾取周期的项,保留结余项
feeder_base_points[best_assign_slot + idx * interval_ratio] += (
feeder_division_points[part] - min(filter(lambda x: x > 0, best_assign_points)))
feeder_points[part] -= feeder_division_points[part]
feeder_limit[part] -= 1
feeder_arrange[part] += 1
if feeder_limit[part] == 0:
feeder_division_points[part] = 0
for nozzle, components in nozzle_component.items():
if part in components:
index_ = components.index(part)
nozzle_component[nozzle].pop(index_)
nozzle_component_points[nozzle].pop(index_)
break
feeder_division_points[part] = 0
else:
# 已有的供料器
feeder_base_points[best_assign_slot + idx * interval_ratio] -= min(
filter(lambda x: x > 0, best_assign_points))
# 更新供料器基座信息
feeder_base[best_assign_slot + idx * interval_ratio] = part
feeder_type, extra_slot = component_data.loc[part]['fdr'], 0
extra_width = feeder_width[feeder_type][0] + feeder_width[feeder_type][1] - slot_interval
while extra_width > 0:
extra_slot += 1
if feeder_base[best_assign_slot + idx * interval_ratio + extra_slot] == -2:
feeder_base[best_assign_slot + idx * interval_ratio + extra_slot] = -1 # 标记槽位已占用
extra_width -= slot_interval
# 更新吸嘴信息
nozzle_pattern[idx] = component_data.loc[part]['nz']
# 更新头分配的先后顺序
head_assign_indexes = np.array(best_assign_points).argsort().tolist()
nozzle_component, nozzle_component_points = copy.deepcopy(best_nozzle_component), copy.deepcopy(
best_nozzle_component_points)
if sum(best_assign_points) > optimal_nozzle_points:
optimal_nozzle_points = sum(best_assign_points)
optimal_nozzle_pattern = nozzle_pattern.copy()
assert not list(filter(lambda x: x < 0, feeder_limit.values())) # 分配供料器数目在限制范围内
# 若所有供料器均安装在基座上,重新对基座进行扫描,确定最优吸嘴模式(有序)
if not optimal_nozzle_points:
feeder_base, feeder_base_points = [-2] * max_slot_index, [0] * max_slot_index
for _, feeder in feeder_data.iterrows():
slot, part = feeder['slot'], feeder['part']
part_index = component_data[component_data['part'] == part].index.tolist()[0]
# 供料器基座分配位置和对应贴装点数
feeder_base[slot], feeder_base_points[slot] = part_index, feeder_division_points[part_index]
# 前基座 TODO: 后基座
for slot in range(max_slot_index // 2 - (max_head_index - 1) * interval_ratio):
sum_scan_points = 0
for head in range(max_head_index):
sum_scan_points += feeder_base_points[slot + head * interval_ratio]
if sum_scan_points > optimal_nozzle_points:
optimal_nozzle_pattern = ['' for _ in range(max_head_index)]
for head in range(max_head_index):
if part := feeder_base[slot + head * interval_ratio] == -2:
continue
optimal_nozzle_pattern[head] = part_nozzle[part]
# 更新供料器占位信息
for _, data in feeder_data.iterrows():
feeder_base[data['slot']] = -1
for slot, feeder in enumerate(feeder_base):
if feeder < 0:
continue
part = component_data.loc[feeder]['part']
feeder_data.loc[len(feeder_data.index)] = [slot, part, 0]
if figure:
# 绘制供料器位置布局
for slot in range(max_slot_index // 2):
plt.scatter(slotf1_pos[0] + slot_interval * slot, slotf1_pos[1], marker='x', s=12, color='black', alpha=0.5)
plt.text(slotf1_pos[0] + slot_interval * slot, slotf1_pos[1] - 45, slot + 1, ha='center', va='bottom',
size=8)
feeder_assign_range = []
for feeder in feeder_data.iterrows():
slot, part = feeder[1]['slot'], feeder[1]['part']
part_index = component_data[component_data['part'] == part].index.tolist()[0]
feeder_type = component_data.loc[part_index]['fdr']
width = feeder_width[feeder_type][0] + feeder_width[feeder_type][1]
start = slotf1_pos[0] + slot_interval * (slot - 1) - slot_interval / 2
end = slotf1_pos[0] + slot_interval * (slot - 1) - slot_interval / 2 + width
rec_x = [start, end, end, start]
rec_y = [slotf1_pos[1] - 40, slotf1_pos[1] - 40, slotf1_pos[1] + 10, slotf1_pos[1] + 10]
c = 'red' if feeder[1]['arg'] == 0 else 'black' # 黑色表示已分配,红色表示新分配
plt.text(slotf1_pos[0] + slot_interval * (slot - 1), slotf1_pos[1] + 12,
part + ': ' + str(feeder_points[part_index]), ha='center', size=7, rotation=90, color=c)
plt.fill(rec_x, rec_y, facecolor='yellow', alpha=0.4)
feeder_assign_range.append([start, end])
# 记录重叠区间
feeder_assign_range.sort(key=lambda x: x[0])
for i in range(1, len(feeder_assign_range)):
if feeder_assign_range[i][0] < feeder_assign_range[i - 1][1]:
start, end = feeder_assign_range[i][0], feeder_assign_range[i - 1][1]
rec_x = [start, end, end, start]
rec_y = [slotf1_pos[1] - 40, slotf1_pos[1] - 40, slotf1_pos[1] + 10, slotf1_pos[1] + 10]
plt.fill(rec_x, rec_y, facecolor='red')
plt.plot([slotf1_pos[0] - slot_interval / 2, slotf1_pos[0] + slot_interval * (max_slot_index // 2 - 1 + 0.5)],
[slotf1_pos[1] + 10, slotf1_pos[1] + 10], color='black')
plt.plot([slotf1_pos[0] - slot_interval / 2, slotf1_pos[0] + slot_interval * (max_slot_index // 2 - 1 + 0.5)],
[slotf1_pos[1] - 40, slotf1_pos[1] - 40], color='black')
for counter in range(max_slot_index // 2 + 1):
pos = slotf1_pos[0] + (counter - 0.5) * slot_interval
plt.plot([pos, pos], [slotf1_pos[1] + 10, slotf1_pos[1] - 40], color='black', linewidth=1)
plt.ylim(-10, 100)
plt.show()
return optimal_nozzle_pattern
@timer_wrapper
def feeder_base_scan(component_data, pcb_data, feeder_data, nozzle_pattern):
feeder_assign_check = set()
for feeder in feeder_data.iterrows():
feeder_assign_check.add(feeder[1]['part'])
component_points = [0] * len(component_data)
for step in pcb_data.iterrows():
part = step[1]['part']
part_index = component_data[component_data['part'] == part].index.tolist()[0]
component_points[part_index] += 1
nozzle_type = component_data.loc[part_index]['nz']
if nozzle_type not in nozzle_limit.keys() or nozzle_limit[nozzle_type] <= 0:
info = 'there is no available nozzle [' + nozzle_type + '] for the assembly process'
raise ValueError(info)
assert len(feeder_assign_check) == len(component_points) - component_points.count(0) # 所有供料器均已分配槽位
feeder_part = [-1] * max_slot_index
for feeder in feeder_data.iterrows():
part, slot = feeder[1]['part'], feeder[1]['slot']
part_index = component_data[component_data['part'] == part].index.tolist()
if len(part_index) != 1:
print('unregistered component: ', part, ' in slot', slot)
continue
part_index = part_index[0]
feeder_part[slot] = part_index
component_result, cycle_result, feeder_slot_result = [], [], [] # 贴装点索引和拾取槽位优化结果
nozzle_mode = [nozzle_pattern] # 吸嘴匹配模式
with tqdm(total=len(pcb_data)) as pbar:
pbar.set_description('feeder scan process')
pbar_prev = 0
value_increment_base = 0
while True:
# === 周期内循环 ===
assigned_part = [-1 for _ in range(max_head_index)] # 当前扫描到的头分配元件信息
assigned_cycle = [0 for _ in range(max_head_index)] # 当前扫描到的元件最大分配次数
assigned_slot = [-1 for _ in range(max_head_index)] # 当前扫描到的供料器分配信息
best_assigned_eval_func = -float('inf')
nozzle_insert_cycle = 0
for cycle_index, nozzle_cycle in enumerate(nozzle_mode):
scan_eval_func_list = [] # 若干次扫描得到的最优解
# nozzle_cycle 吸嘴模式下,已扫描到的最优结果
cur_scan_part = [-1 for _ in range(max_head_index)]
cur_scan_cycle = [0 for _ in range(max_head_index)]
cur_scan_slot = [-1 for _ in range(max_head_index)]
cur_nozzle_limit = copy.deepcopy(nozzle_limit)
while True:
best_scan_part, best_scan_cycle = [-1 for _ in range(max_head_index)], [-1 for _ in
range(max_head_index)]
best_scan_slot = [-1 for _ in range(max_head_index)]
best_scan_nozzle_limit = copy.deepcopy(cur_nozzle_limit)
scan_eval_func, search_break = -float('inf'), True
# 前供料器基座扫描
for slot in range(1, max_slot_index // 2 - (max_head_index - 1) * interval_ratio + 1):
scan_cycle, scan_part, scan_slot = cur_scan_cycle.copy(), cur_scan_part.copy(), cur_scan_slot.copy()
scan_nozzle_limit = copy.deepcopy(cur_nozzle_limit)
# 预扫描确定各类型元件拾取数目(前瞻)
preview_scan_part = defaultdict(int)
for head in range(max_head_index):
part = feeder_part[slot + head * interval_ratio]
# 贴装头和拾取槽位满足对应关系
if scan_part[head] == -1 and part != -1 and component_points[part] > 0 and scan_part.count(
part) < component_points[part]:
preview_scan_part[part] += 1
component_counter = 0
for head in range(max_head_index):
part = feeder_part[slot + head * interval_ratio]
# 1.匹配条件满足: 贴装头和拾取槽位满足对应关系
if scan_part[head] == -1 and part != -1 and component_points[part] > 0 and scan_part.count(
part) < component_points[part]:
# 2.匹配条件满足:不超过可用吸嘴数的限制
nozzle = component_data.loc[part]['nz']
if scan_nozzle_limit[nozzle] <= 0:
continue
# 3.增量条件满足: 引入新的元件类型不会使代价函数的值减少(前瞻)
if scan_cycle.count(0) == max_head_index:
gang_pick_change = component_points[part]
else:
prev_cycle = min(filter(lambda x: x > 0, scan_cycle))
# 同时拾取数的提升
gang_pick_change = min(prev_cycle, component_points[part] // preview_scan_part[part])
# 4.拾取移动距离条件满足: 邻近元件进行同时抓取,降低移动路径长度
# reference_slot = -1
# for head_, slot_ in enumerate(scan_slot):
# if slot_ != -1:
# reference_slot = slot_ - head_ * interval_ratio
# if reference_slot != -1 and abs(reference_slot - slot) > (max_head_index - 1) * interval_ratio:
# continue
# 5.同时拾取的增量 和 吸嘴更换次数比较
prev_nozzle_change = 0
if cycle_index + 1 < len(nozzle_mode):
prev_nozzle_change = 2 * (nozzle_cycle[head] != nozzle_mode[cycle_index + 1][head])
# 避免首个周期吸杆占用率低的问题
if nozzle_cycle[head] == '':
nozzle_change = 0
else:
nozzle_change = 2 * (nozzle != nozzle_cycle[head])
if cycle_index + 1 < len(nozzle_mode):
nozzle_change += 2 * (nozzle != nozzle_mode[cycle_index + 1][head])
nozzle_change -= prev_nozzle_change
val = e_gang_pick * gang_pick_change - e_nz_change * nozzle_change
if val < value_increment_base:
continue
component_counter += 1
scan_part[head] = part
scan_cycle[head] = component_points[part] // preview_scan_part[part]
scan_slot[head] = slot + head * interval_ratio
scan_nozzle_limit[nozzle] -= 1
nozzle_counter = 0 # 吸嘴更换次数
# 上一周期
for head, nozzle in enumerate(nozzle_cycle):
if scan_part[head] == -1:
continue
if component_data.loc[scan_part[head]]['nz'] != nozzle and nozzle != '':
nozzle_counter += 2
# 下一周期(额外增加的吸嘴更换次数)
if cycle_index + 1 < len(nozzle_mode):
for head, nozzle in enumerate(nozzle_mode[cycle_index + 1]):
if scan_part[head] == -1:
continue
prev_counter, new_counter = 0, 0
if nozzle_cycle[head] != nozzle and nozzle_cycle[head] != '' and nozzle != '':
prev_counter += 2
if component_data.loc[scan_part[head]]['nz'] != nozzle and nozzle != '':
new_counter += 2
nozzle_counter += new_counter - prev_counter
else:
for head, nozzle in enumerate(nozzle_mode[0]):
if scan_part[head] == -1:
continue
prev_counter, new_counter = 0, 0
if nozzle_cycle[head] != nozzle and nozzle_cycle[head] != '' and nozzle != '':
prev_counter += 2
if component_data.loc[scan_part[head]]['nz'] != nozzle and nozzle != '':
new_counter += 2
nozzle_counter += new_counter - prev_counter
if component_counter == 0: # 当前情形下未扫描到任何元件
continue
search_break = False
scan_part_head = defaultdict(list)
for head, part in enumerate(scan_part):
if part == -1:
continue
scan_part_head[part].append(head)
for part, heads in scan_part_head.items():
part_cycle = component_points[part] // len(heads)
for head in heads:
scan_cycle[head] = part_cycle
# 计算扫描后的代价函数,记录扫描后的最优解
# 短期收益
cycle = min(filter(lambda x: x > 0, scan_cycle))
gang_pick_counter, gang_pick_slot_set = 0, set()
for head, pick_slot in enumerate(scan_slot):
gang_pick_slot_set.add(pick_slot - head * interval_ratio)
eval_func_short_term = e_gang_pick * (max_head_index - scan_slot.count(-1) - len(
gang_pick_slot_set)) * cycle - e_nz_change * nozzle_counter
# 长期收益
gang_pick_slot_dict = defaultdict(list)
for head, pick_slot in enumerate(scan_slot):
if pick_slot == -1:
continue
gang_pick_slot_dict[pick_slot - head * interval_ratio].append(scan_cycle[head])
eval_func_long_term = 0
for pick_cycle in gang_pick_slot_dict.values():
while pick_cycle:
min_cycle = min(pick_cycle)
eval_func_long_term += e_gang_pick * (len(pick_cycle) - 1) * min(pick_cycle)
pick_cycle = list(map(lambda c: c - min_cycle, pick_cycle))
pick_cycle = list(filter(lambda c: c > 0, pick_cycle))
eval_func_long_term -= e_nz_change * nozzle_counter
ratio = 0.5
eval_func = (1 - ratio) * eval_func_short_term + ratio * eval_func_long_term
if eval_func >= scan_eval_func:
scan_eval_func = eval_func
best_scan_part, best_scan_cycle = scan_part.copy(), scan_cycle.copy()
best_scan_slot = scan_slot.copy()
best_scan_nozzle_limit = copy.deepcopy(scan_nozzle_limit)
if search_break:
break
scan_eval_func_list.append(scan_eval_func)
cur_scan_part = best_scan_part.copy()
cur_scan_slot = best_scan_slot.copy()
cur_scan_cycle = best_scan_cycle.copy()
cur_nozzle_limit = copy.deepcopy(best_scan_nozzle_limit)
if len(scan_eval_func_list) != 0:
if sum(scan_eval_func_list) >= best_assigned_eval_func:
best_assigned_eval_func = sum(scan_eval_func_list)
assigned_part = cur_scan_part.copy()
assigned_slot = cur_scan_slot.copy()
assigned_cycle = cur_scan_cycle.copy()
nozzle_insert_cycle = cycle_index
# 从供料器基座中移除对应数量的贴装点
nonzero_cycle = [cycle for cycle in assigned_cycle if cycle > 0]
if not nonzero_cycle:
value_increment_base -= max_head_index
continue
for head, slot in enumerate(assigned_slot):
if assigned_part[head] == -1:
continue
component_points[feeder_part[slot]] -= min(nonzero_cycle)
component_result.insert(nozzle_insert_cycle, assigned_part)
cycle_result.insert(nozzle_insert_cycle, min(nonzero_cycle))
feeder_slot_result.insert(nozzle_insert_cycle, assigned_slot)
# 更新吸嘴匹配模式
cycle_nozzle = nozzle_mode[nozzle_insert_cycle].copy()
for head, component in enumerate(assigned_part):
if component == -1:
continue
cycle_nozzle[head] = component_data.loc[component]['nz']
nozzle_mode.insert(nozzle_insert_cycle + 1, cycle_nozzle)
pbar.update(len(pcb_data) - sum(component_points) - pbar_prev)
pbar_prev = len(pcb_data) - sum(component_points)
if sum(component_points) == 0:
break
return component_result, cycle_result, feeder_slot_result
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