Created ZIP

2022-09-29 21:00:21 +02:00 · 2022-09-29 21:00:21 +02:00 · 969878593e
parent 1bf96cbdb0
commit 969878593e
5 changed files with 205 additions and 0 deletions
--- a/Abgabe_Schenk_Brandenberger_Serie1.zip
+++ b/Abgabe_Schenk_Brandenberger_Serie1.zip
--- a/Abgabe_Schenk_Brandenberger_Serie1/schenk_brandeberger_S1_Aufg1.py
+++ b/Abgabe_Schenk_Brandenberger_Serie1/schenk_brandeberger_S1_Aufg1.py
@ -0,0 +1,50 @@
+import numpy as np
+import matplotlib.pyplot as plt
+
+xmin, xmax, xsteps = -10, 10, 0.1
+plotLegend = []
+
+def showPlot():
+    plt.xlim(-11, 11)
+    plt.xticks(np.arange(xmin, xmax + xsteps, 1.0))
+    plt.xlabel("x")
+    plt.ylim(-1300, 1300)
+    plt.ylabel("y")
+    plt.grid(markevery=1)
+    plt.legend(plotLegend)
+    plt.title("Aufgabe 1")
+    plt.show()
+
+def function_f(x):
+    return x ** 5 - 5 * x ** 4 - 30 * x ** 3 + 110 * x ** 2 + 29 * x - 105
+
+def derivative_f(x):
+    return 5 * x ** 4 - 20 * x ** 3 - 90 * x ** 2 + 220 * x + 29
+
+def integral_f(x):
+    c = 0
+    return (1/6) * x ** 6 - x ** 5 - (30/4) * x ** 4 + (110/3) * x ** 3 + (29/2) * x ** 2 - 105 * x + c
+
+def plot_function_f():
+    x = np.arange(xmin, xmax + xsteps, xsteps)
+    f = np.array(function_f(x))
+    plt.plot(x, f)
+    plotLegend.append('f(x)')
+
+def plot_derivative_f():
+    x = np.arange(xmin, xmax + xsteps, xsteps)
+    f = np.array(derivative_f(x))
+    plt.plot(x, f)
+    plotLegend.append('f\'(x)')
+
+def plot_integral_f():
+    x = np.arange(xmin, xmax + xsteps, xsteps)
+    f = np.array(integral_f(x))
+    plt.plot(x, f)
+    plotLegend.append('F(x)')
+
+if __name__ == "__main__":
+    plot_function_f()
+    plot_derivative_f()
+    plot_integral_f()
+    showPlot()
--- a/Abgabe_Schenk_Brandenberger_Serie1/schenk_brandeberger_S1_Aufg2.py
+++ b/Abgabe_Schenk_Brandenberger_Serie1/schenk_brandeberger_S1_Aufg2.py
@ -0,0 +1,61 @@
+import numpy as np
+import matplotlib.pyplot as plt
+
+plotLegend = []
+
+def showPlot(xmin, xmax, xsteps):
+    plt.xlim(xmin - 1, xmax + 1)
+    plt.xticks(np.arange(xmin, xmax + xsteps, 1.0))
+    plt.xlabel("x")
+    plt.ylim(-1300, 1300)
+    plt.ylabel("y")
+    plt.grid(markevery=1)
+    plt.legend(plotLegend)
+    plt.title("Aufgabe 2")
+    plt.show()
+
+def polynom_function(a, x): #a = coefficients, x = values to calculate
+    a = np.squeeze(np.asarray(a))
+    p = np.array([])
+    for x_value in x:
+        result = 0
+        for power, coefficient in enumerate(a):
+            result += coefficient * x_value ** power
+        p = np.append(p, result)
+    return p
+
+def derivative_f(a):
+    a = np.squeeze(np.asarray(a))
+    result = np.array([])
+    for i in range(1, len(a)):
+        result = np.append(result, a[i] * i)
+    return result
+
+def integral_f(a):
+    a = np.squeeze(np.asarray(a))
+    c = 0
+    result = np.array([c])
+    for i in range(0, len(a)):
+        result = np.append(result, a[i] / (i + 1))
+    return result
+
+def plot_function(x, y, legendString):
+    plt.plot(x, y)
+    plotLegend.append(legendString)
+
+def is_valid_vector(vector):
+    shape = np.shape(vector)
+    if(len(shape) == 2):
+        return (shape[0] == 1 and shape[1] >= 1) or (shape[0] >= 1 and shape[1] == 1)
+    else:
+        return False
+
+def schenk_brandeberger_Aufg2(a, xmin, xmax):
+    if not is_valid_vector(a):
+        raise Exception('Fehler! a ist kein gültiger Spalten- oder Zeilenvektor!')
+    xsteps =  abs(xmax/100.0)
+    x = np.arange(xmin, xmax + xsteps, xsteps)
+    p = polynom_function(a, x)
+    dp = polynom_function(derivative_f(a), x)
+    pint = polynom_function(integral_f(a), x)
+    return(x,p,dp,pint)
--- a/Abgabe_Schenk_Brandenberger_Serie1/schenk_brandeberger_S1_Aufg2_skript.py
+++ b/Abgabe_Schenk_Brandenberger_Serie1/schenk_brandeberger_S1_Aufg2_skript.py
@ -0,0 +1,21 @@
+import numpy as np
+from schenk_brandeberger_S1_Aufg2 import schenk_brandeberger_Aufg2, plot_function, showPlot
+
+if __name__ == "__main__":
+    #coefficients_task_1 = np.array([-105, 29, 110, -30, -5, 1]) #falsches Format
+    #coefficients_task_1 = np.array([[-105, 29, 110, -30, -5, 1]])  #Zeilenvektor
+    coefficients_task_1 = np.array([[-105], [29], [110], [-30], [-5], [1]]) #Spalten Vektor
+    xmin = -10
+    xmax = 10
+    [x,p,dp,pint] = schenk_brandeberger_Aufg2(coefficients_task_1, xmin, xmax)
+
+    print("x:\n", x)
+    print("p:\n", p)
+    print("dp:\n", dp)
+    print("pint:\n", pint)
+
+    plot_function(x, p, 'f(x)')
+    plot_function(x, dp, 'f\'(x)')
+    plot_function(x, pint, 'F(x)')
+
+    showPlot(xmin, xmax, abs(xmax/100.0))
--- a/Abgabe_Schenk_Brandenberger_Serie1/schenk_brandeberger_S1_Aufg3.py
+++ b/Abgabe_Schenk_Brandenberger_Serie1/schenk_brandeberger_S1_Aufg3.py
@ -0,0 +1,73 @@
+import timeit
+import numpy as np
+
+def fact_rec(n):
+    # y = fact_rec(n) berechnet die Fakultät von n als fact_rec(n) = n * fact_rec(n -1) mit fact_rec(0) = 1
+    # Fehler, falls n < 0 oder nicht ganzzahlig
+    if n < 0 or np.trunc(n) != n:
+        raise Exception('The factorial is defined only for positive integers')
+    if n <=1:
+        return 1
+    else:
+        return n*fact_rec(n-1)
+
+def fact_for(n):
+    if n < 0 or np.trunc(n) != n:
+        raise Exception('The factorial is defined only for positive integers')
+    result = 1
+    for i in range(1, n + 1):
+        result *= i
+    return result
+
+def test_same_value(maxn):
+    test_successful = True
+    for n in range(maxn + 1):
+        if(fact_rec(n)) != fact_for(n):
+            print("Test (same value) failed at: ", n)
+            test_successful = False
+    if test_successful:
+        print("Test (same value) successful. Max n: ", maxn)
+    return test_successful
+
+def compaire_execution_times(n, execution_count):
+    print("Starting Test to comaire execution times:")
+    time_rec = np.mean(np.array(timeit.repeat("fact_rec(" + str(n) + ")", "from __main__ import fact_rec", number=execution_count)))
+    time_for = np.mean(np.array(timeit.repeat("fact_for(" + str(n) + ")", "from __main__ import fact_for", number=execution_count)))
+    factor = time_rec / time_for
+    print("time recursively: ", time_rec)
+    print("time with for loop: ", time_for)
+    print("execution with for loop is ", factor, " times faster.")
+
+    # mit einer For-Schleife ist die Ausführung etwa 9 mal schneller. Wenn die Fakultät rekursiv berechnet wird muss die Funktion n mal aufgerufen werden
+    # und es müssen entsprechend viele zwischenergebnisse gespeichert werden bis die Berechnung abgeschlossen ist.
+    # Mit einer For-Schleife kann jeweils das letzte zwischenergebnis verworfen / überschrieben werden.
+
+def find_upper_limit_int(min_n, max_n):
+    print("Starting Test upper Limit with int:")
+    for n in range(min_n, max_n + 1):
+        try:
+            print(n, ": ", fact_for(n))
+        except Exception as e:
+            print("Failed at n = ", n, "Error Message:\n", str(e))
+
+    # Für Integer gibt es keine Obergrenze. Die Werte werden berechnet.
+
+def find_upper_limit_float(min_n, max_n):
+    print("Starting Test upper Limit with float:")
+    for n in range(min_n, max_n + 1):
+        try:
+            print(n, ": ", float(fact_for(n)))
+        except Exception as e:
+            print("Failed at n = ", n, "Error Message:\n", str(e))
+
+    # Für Float gibt es eine Obergrenze. Wird diese überschritten können die Werte nicht mehr als Float ausgegeben werden.
+
+
+
+if __name__ == "__main__":
+    test_same_value(50)
+    compaire_execution_times(500, 100)
+    find_upper_limit_int(190, 200)
+    find_upper_limit_float(170, 171)
+
+