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main ... Lab13

Author SHA1 Message Date
3e7b17abf0 Лаба 13 2024-05-11 05:36:26 +04:00
b0e78b3f6d Лаба 12 сдана 2024-05-11 02:04:28 +04:00
ca3fdf03ca Лаба 11 сдана 2024-04-26 22:02:20 +04:00
d75f598425 Лаба 11 сдана 2024-04-26 22:01:48 +04:00
0fa51fd003 Лаба 10 сдана 2024-04-12 02:25:09 +04:00
b09a9200b1 Лаба 9 сдала 2024-03-15 21:27:00 +04:00
8 changed files with 485 additions and 0 deletions

122
lab10/lab10.py Normal file
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import sys
from PyQt5.QtWidgets import QApplication, QMainWindow, QVBoxLayout, QWidget, QLabel, QLineEdit, QPushButton, QColorDialog, QTableWidget, QTableWidgetItem, QHeaderView
from PyQt5.QtGui import QColor
import pyqtgraph as pg
import random
class FuzzyScaleApp(QMainWindow):
def __init__(self):
super().__init__()
self.setWindowTitle("Оценка прибыли")
self.setGeometry(100, 100, 800, 600)
self.plot_widget = pg.PlotWidget()
self.table_widget = QTableWidget()
self.table_widget.setColumnCount(6)
self.table_widget.setHorizontalHeaderLabels(["Название", "Тип", "a", "b", "c", "d"])
self.table_widget.horizontalHeader().setSectionResizeMode(QHeaderView.Stretch)
self.add_btn = QPushButton("Добавить")
self.remove_btn = QPushButton("Удалить")
self.update_btn = QPushButton("Обновить график")
main_widget = QWidget()
main_layout = QVBoxLayout()
main_layout.addWidget(self.plot_widget)
main_layout.addWidget(self.table_widget)
button_layout = QVBoxLayout()
button_layout.addWidget(self.add_btn)
button_layout.addWidget(self.remove_btn)
button_layout.addWidget(self.update_btn)
main_layout.addLayout(button_layout)
main_widget.setLayout(main_layout)
self.setCentralWidget(main_widget)
self.membership_functions = [
["Низкая", "Треугольная", 10, 20, 30, None],
["Средняя", "Трапециевидная", 15, 25, 35, 45],
["Высокая", "Треугольная", 40, 50, 60, None],
]
self.update_table()
self.update_plot()
self.add_btn.clicked.connect(self.add_function)
self.remove_btn.clicked.connect(self.remove_function)
self.table_widget.cellChanged.connect(self.update_data)
self.update_btn.clicked.connect(self.update_plot)
def update_data(self):
print(self.membership_functions)
for row in range(self.table_widget.rowCount()):
for column in range(6):
index = self.table_widget.model().index(row, column)
data = self.table_widget.model().data(index)
if column == 5:
if self.membership_functions[row][1] == 'Треугольная' and data != '':
self.membership_functions[row][1] = 'Трапециевидная'
elif self.membership_functions[row][column] == 'Трапециевидная' and data == '':
self.membership_functions[row][1] = 'Треугольная'
if data == '':
self.membership_functions[row][column] = None
continue
try:
self.membership_functions[row][column] = int(data)
except ValueError:
self.membership_functions[row][column] = data
print(self.membership_functions)
def add_function(self):
print("чмо")
row_count = self.table_widget.rowCount()
self.table_widget.insertRow(row_count)
self.table_widget.setItem(row_count, 0, QTableWidgetItem("Новая функция"))
self.table_widget.setItem(row_count, 1, QTableWidgetItem("Треугольная"))
self.membership_functions.append(["Новая функция", "Треугольная", 0, 25, 50, None])
self.update_table()
self.update_plot()
def remove_function(self):
selected_rows = self.table_widget.selectionModel().selectedRows()
rows_to_remove = [index.row() for index in selected_rows]
rows_to_remove.sort(reverse=True)
for row in rows_to_remove:
self.table_widget.removeRow(row)
del self.membership_functions[row]
self.update_plot()
def update_table(self):
self.table_widget.setRowCount(len(self.membership_functions))
row = 0
for (name, mf_type, a, b, c, d) in self.membership_functions:
self.table_widget.setItem(row, 0, QTableWidgetItem(name))
self.table_widget.setItem(row, 1, QTableWidgetItem(mf_type))
self.table_widget.setItem(row, 2, QTableWidgetItem(str(a)))
self.table_widget.setItem(row, 3, QTableWidgetItem(str(b)))
self.table_widget.setItem(row, 4, QTableWidgetItem(str(c)))
self.table_widget.setItem(row, 5, QTableWidgetItem(str(d) if d is not None else ""))
row += 1
def update_plot(self):
self.plot_widget.clear()
print('лох')
x = [-10, 110]
y = [0, 0]
self.plot_widget.plot(x, y)
for (name, mf_type, a, b, c, d) in self.membership_functions:
print(name, mf_type, a, b, c, d)
if mf_type == "Треугольная":
x = [a, b, c]
y = [0, 1, 0]
self.plot_widget.plot(x, y, name=name, pen=pg.mkPen(QColor(random.randint(0,255), random.randint(0,255), random.randint(0,255)), width=2))
else:
x = [a, b, c, d]
y = [0, 1, 1, 0]
self.plot_widget.plot(x, y, name=name, pen=pg.mkPen(QColor(random.randint(0,255), random.randint(0,255), random.randint(0,255)), width=2))
if __name__ == "__main__":
app = QApplication(sys.argv)
fuzzy_scale_app = FuzzyScaleApp()
fuzzy_scale_app.show()
sys.exit(app.exec_())

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lab11/lab11.py Normal file
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import math
import random
import numpy as np
import matplotlib.pyplot as plt
def get_distance(first: np.ndarray, second: np.ndarray) -> float:
return math.sqrt(sum([(first[i] - second[i]) ** 2 for i in range(first.shape[0])])) + 1e-5
def affiliation_calculation(data: np.ndarray, centers: np.ndarray, k: int, m: int) -> np.ndarray:
data_len = data.shape[0]
u = np.zeros((data_len, k))
for i in range(data_len):
for j in range(k):
total = 0
distance = get_distance(data[i], centers[j])
for c in range(k):
total += (distance / get_distance(data[i], centers[c])) ** (2 / (m - 1))
u[i, j] = 1 / total
return u
def variance_calculation(data: np.ndarray, centers: np.ndarray, u: np.ndarray) -> float:
value = 0
for j in range(k):
for i in range(data.shape[0]):
value += get_distance(data[i], centers[j]) ** 2 * u[i, j]
return value
def center_update(data: np.ndarray, u: np.ndarray, k: int, m: int) -> np.ndarray:
centers = np.zeros((k, data.shape[1]))
for j in range(k):
total = 0
for i in range(data.shape[0]):
total += u[i, j] ** m * data[i]
centers[j] = total / np.sum(u[:, j] ** m)
return centers
def fuzzy_c_means(data: np.ndarray, k: int, m: int, max_iter: int = 100, tol: float = 1e-5) -> (
np.ndarray, np.ndarray, float):
centers = np.array([[random.randint(data.min(), data.max()) for i in range(data.shape[1])] for j in range(k)])
u = None
value = 0
for _ in range(max_iter):
u = affiliation_calculation(data, centers, k, m)
new_value = variance_calculation(data, centers, u)
if abs(new_value - value) <= tol:
return centers, u, value
value = new_value
centers = center_update(data, u, k, m)
return centers, u, value
def visualise_resout(centers: np.ndarray, u: np.ndarray):
center_colors = [[random.random(), random.random(), random.random()] for i in range(k)]
point_colors = []
for i in u:
tmp_color = [0, 0, 0]
for j in range(k):
tmp_color[0] += center_colors[j][0] * i[j]
tmp_color[1] += center_colors[j][1] * i[j]
tmp_color[2] += center_colors[j][1] * i[j]
point_colors.append(tmp_color)
plt.title("Нечёткая кластеризация")
plt.xlabel("Размер зарплаты")
if data.shape[1] == 1:
plt.scatter(data[:, 0], [0] * data.shape[0], c=point_colors)
plt.scatter(centers[:, 0], [0] * centers.shape[0], marker='*', edgecolor='black', s=100, c=center_colors)
plt.gca().axes.get_yaxis().set_visible(False)
else:
plt.scatter(data[:, 0], data[:, 1], c=point_colors)
plt.scatter(centers[:, 0], centers[:, 1], marker='*', edgecolor='black', s=100, c=center_colors)
plt.show()
if __name__ == '__main__':
data: np.ndarray = np.array(
[
[
random.randint(0, 500)
]
for i in range(random.randint(40, 100))
])
k = 3
m = 2
centers, u, value = fuzzy_c_means(data, k, m)
print(f"Значение функции отклонений: {value}")
print("Степени принадлежности первых 10 точек:")
print(*u[:10], sep="\n")
print("Центры всех кластеров:")
print(*centers, sep="\n")
visualise_resout(centers, u)

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lab12/FuzzyRule.py Normal file
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class FuzzyRule:
def __init__(self):
self.condition: dict[str, str] = {}
self.resout: (str, str) = None
def add_condition(self, variable: str, value: str):
self.condition[variable] = value
return self
def add_resout(self, variable: str, value: str):
self.resout = (variable, value)
return self
def calculate_res(self, variables: dict[str, dict[str, float]]) -> (str, str, float):
res = 1
for i in self.condition:
res = min(res, variables[i][self.condition[i]])
return self.resout[0], self.resout[1], res

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lab12/FuzzySet.py Normal file
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class FuzzySet:
def __init__(self, name: str, a: float, b: float, c: float, d: float):
self.name = name
self.a = a
self.b = b
self.c = c
self.d = d
def affiliation(self, x: float) -> float:
if x <= self.a or x >= self.d:
return 0
if self.b <= x <= self.c:
return 1
if x <= self.b:
return (x - self.a) / (self.b - self.a)
else:
return (self.d - x) / (self.d - self.c)
def defuzzification(self) -> float:
return (self.c + self.b) / 2

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from FuzzySet import FuzzySet
class LinguisticVariable:
def __init__(self, name: str):
self.name = name
self.fuzzy_sets: dict[str, FuzzySet] = {}
def add_fuzzy_set(self, name: str, a: float, b: float, c: float, d: float):
if not (a <= b <= c <= d):
return
if name in self.fuzzy_sets:
fuzzy = self.fuzzy_sets[name]
fuzzy.a = a
fuzzy.b = b
fuzzy.c = c
fuzzy.d = d
else:
self.fuzzy_sets[name] = FuzzySet(name, a, b, c, d)
return self
def get_all_supplies(self, x: float) -> dict[str, float]:
return {i: self.fuzzy_sets[i].affiliation(x) for i in self.fuzzy_sets}

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lab12/main.py Normal file
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from FuzzyRule import FuzzyRule
from LinguisticVariable import LinguisticVariable
def get_linguistic_data(vars: list[LinguisticVariable], x: dict[str, float]) -> dict[str, dict[str, float]]:
return {i.name: i.get_all_supplies(x[i.name]) for i in vars}
def get_rule_table_res(rules: list[FuzzyRule], vars: list[LinguisticVariable], x: dict[str, float]) \
-> (str, str, float):
res = [i.calculate_res(get_linguistic_data(vars, x)) for i in rules]
return sorted(res, key=lambda y: -y[2])[0]
if __name__ == '__main__':
variables: list[LinguisticVariable] = [
LinguisticVariable("Часы эксплуатации")
.add_fuzzy_set("мало", 0, 0, 100, 200)
.add_fuzzy_set("средне", 100, 300, 500, 700)
.add_fuzzy_set("много", 500, 800, 1000, 1000),
LinguisticVariable("Срок последней проверки")
.add_fuzzy_set("недавно", 0, 0, 3, 6)
.add_fuzzy_set("давно", 3, 6, 12, 18)
.add_fuzzy_set("очень давно", 12, 18, 24, 24),
LinguisticVariable("Риск поломки")
.add_fuzzy_set("низкий", 0, 0, 20, 40)
.add_fuzzy_set("средний", 20, 40, 60, 80)
.add_fuzzy_set("высокий", 60, 80, 100, 100)
]
rules: list[FuzzyRule] = [
FuzzyRule()
.add_condition("Часы эксплуатации", 'мало')
.add_condition("Срок последней проверки", 'недавно')
.add_resout("Риск поломки", 'низкий'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'мало')
.add_condition("Срок последней проверки", 'давно')
.add_resout("Риск поломки", 'низкий'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'мало')
.add_condition("Срок последней проверки", 'очень давно')
.add_resout("Риск поломки", 'средний'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'средне')
.add_condition("Срок последней проверки", 'недавно')
.add_resout("Риск поломки", 'низкий'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'средне')
.add_condition("Срок последней проверки", 'давно')
.add_resout("Риск поломки", 'средний'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'средне')
.add_condition("Срок последней проверки", 'очень давно')
.add_resout("Риск поломки", 'высокий'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'много')
.add_condition("Срок последней проверки", 'недавно')
.add_resout("Риск поломки", 'средний'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'много')
.add_condition("Срок последней проверки", 'давно')
.add_resout("Риск поломки", 'высокий'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'много')
.add_condition("Срок последней проверки", 'очень давно')
.add_resout("Риск поломки", 'высокий'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'мало')
.add_condition("Срок последней проверки", 'недавно')
.add_resout("Риск поломки", 'низкий'),
FuzzyRule()
.add_condition("Часы эксплуатации", 'много')
.add_condition("Срок последней проверки", 'недавно')
.add_resout("Риск поломки", 'средний')
]
input_data: dict[str, float] = {
"Часы эксплуатации": 550,
"Срок последней проверки": 15
}
varz = []
for i in variables:
if i.name in input_data:
varz.append(i)
name, value, confidence = get_rule_table_res(rules, varz, input_data)
print(name, value)
for i in variables:
if i.name == name:
print(i.fuzzy_sets[value].defuzzification())

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lab13/main.py Normal file
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import math
import time
import pymystem3
from collections import defaultdict
def filter_stop_words(text):
m = pymystem3.Mystem()
analysis = m.analyze(text)
filtered_words = [word for word in analysis if
'analysis' in word and word['analysis'] and word['analysis'][0]['gr'] not in ['PR', 'INTJ', 'NUM', 'PART']]
return filtered_words
def count_feminine_nouns(analysis):
feminine_nouns = 0
for word in analysis:
if 'analysis' in word and 'жен' in word['analysis'][0]['gr'] and 'S' in word['analysis'][0]['gr']:
feminine_nouns += 1
return feminine_nouns
def find_significant_bigrams(analysis):
bigrams = defaultdict(int)
for i in range(len(analysis) - 1):
word1 = analysis[i]['analysis'][0]['lex']
word2 = analysis[i + 1]['analysis'][0]['lex']
bigrams[(word1, word2)] += 1
significant_bigrams = []
for bigram, count in bigrams.items():
word1_count = sum(1 for word in analysis if word['analysis'][0]['lex'] == bigram[0])
word2_count = sum(1 for word in analysis if word['analysis'][0]['lex'] == bigram[1])
expected_count = (word1_count * word2_count) / len(analysis)
mi = count * math.log(count / expected_count, 2)
significant_bigrams.append((bigram, mi))
return sorted(significant_bigrams, key=lambda x: x[1], reverse=True)
if __name__ == '__main__':
text = open('input.txt', encoding='utf8').read()
start = time.time()
analysis = filter_stop_words(text)
print(f"{time.time() - start} sec.")
print(count_feminine_nouns(analysis))
print(find_significant_bigrams(analysis))

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lab9/lab9.py Normal file
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import matplotlib.pyplot as plt
print("Введите минимальное значение (первое основание треугольника) :")
min_value = float(input())
print("Введите максимальное значение (второе основание треугольника) :")
max_value = float(input())
if max_value < min_value:
max_value, min_value = min_value, max_value
print("Введите центральное значение (вершина треугольника) :")
center_value = float(input())
print("Введите значение объекта для проверки степени принадлежности:")
x = float(input())
if min_value <= x <= center_value:
membership = (x - min_value) / (center_value - min_value)
elif center_value < x <= max_value:
membership = (max_value - x) / (max_value - center_value)
elif x < min_value or x > max_value:
membership = 0
else:
membership = -1
if membership == -1:
print("Не удалось рассчитать степень принадлежности объекта")
print(f"Минимум: {min_value}")
print(f"Максимум: {max_value}")
print(f"Центр: {center_value}")
print(f"Степень принадлежности {x}: {membership:.2f}")
X = [min_value, center_value, max_value]
Y = [0, 1, 0]
plt.plot(X, Y)
plt.plot(x, membership, 'ro')
plt.show()