def Beta(B, n, margin, x0):
"""
this function executes a recursion with the aid of a for-loop
ON INPUT:
*B (float):
it is very important that we keep the star.
ON OUTPUT:
x (list)
or
x[-1] (float)
or
conv: {x[-1]} (string)
"""
c, x = [0.2, 5], [x0]
for i in range(n):
x_new = c[0] * x[-1] - B * (x[-1]**2 - c[1])
x.append(x_new)
if np.abs(x[-1] - x[-2]) < margin:
break
if p == "x_lastval_sring":
return f"""conv: {x[-1]}"""
elif p == "x_lastval":
return x[-1]
elif p == "x":
return x
def test_lin(num_pwle= 5):
def FuelCell(El_prod):
return 0.11 + 1.2 * El_prod + 0.99 * El_prod ** 2
def Electrolysis(Output):
return (Output/(-0.0498658434302489*Output**3 + 0.302140545845083*Output**2 + 0.715060196682739*Output + 0.0326651009024266))*0.629761721491849*Output
def Sin_test(test_in):
return math.cos((test_in*math.pi))
x = list()
y = list()
pwlm = {}
breakpoints = [i/num_pwle for i in range(num_pwle+1)]
for i in np.linspace(0,1.6,num_pwle+1):
x.append(i)
y.append(Electrolysis(i)) ######### hier Funktion einfügen
for i in range(len(x)-1):
pwlm["Lin_el" + str(i)] = {}
pwlm["Lin_el"+ str(i)]["start/endpoint"] = [x[i],x[i+1]]
pwlm["Lin_el" + str(i)]["slope"] = (y[i + 1]-y[i])/(x[i + 1]-x[i])
pwlm["Lin_el" + str(i)]["intersect"] = y[i] - x[i]*pwlm["Lin_el" + str(i)]["slope"]
fig, ax = plt.subplots()
ax.plot(x, y)
plt.show()
return pwlm
def iter_(f, max_iter, margin=1.e-9):
x = [f(0)]
for i in range(1, max_iter):
x_new = f(i)
x.append(x_new)
if np.abs(x[-1]) < margin:
break
return x, min(x), len(x)
def Beta_moderator(B, max_iter=30):
"""
denna funktion genomför n rekusrion under en for-loop
ON INPUT:
B (float)
"""
for i in range(max_iter + 1):
x_new = c[0] * x[-1] - B * (x[-1]**2 - c[1])
x.append(x_new)
if np.abs(x[-1] - x[-2]) < margin:
break
return True
else:
return False
def solve_congruence_set(a: list, b: list, m: list, silent=True):
"""
同余方程组求解
.. math::
a_i x ≡ b_i mod m_i
若有解 x0 mod m0 则返回(x0, m0);若无解则返回None
"""
k = min([len(a), len(b), len(m)])
x = []
new_m = []
for i in range(k):
d_i = gcd(a[i], m[i])
if b[i] % d_i != 0:
if not silent:
print(f"{a}x ≡ {b} mod {m} 无解")
return None
else:
x_i, m_i = solve_congruence(a[i], b[i], m[i])
x.append(x_i)
new_m.append(m_i)
def solve_2(x_i, x_j, m_i, m_j):
"""解两个方程的方程组,返回解 x≡x_ij mod m_ij 或 None(无解)"""
m_ij, k_i, k_j = euclidean_algorithm(m_i, m_j)
k_i = -k_i
c_i = m_i // m_ij
# c_j=m_j//m_ij
if (x_i - x_j) % m_ij != 0:
return None
else:
return (x_i - x_j
) * k_i * c_i + x_i, m_i * m_j // m_ij # 第二项即lcm(m_i,m_j)
x0, m0 = x[0], new_m[0]
for i in range(1, k):
# 可以用functool.reduce(),这里手动实现
tmp = solve_2(x0, x[i], m0, new_m[i])
if tmp:
x0, m0 = tmp[0], tmp[1]
else:
if not silent:
print(f"{a}x ≡ {b} mod {m} 无解")
return None
x0 = x0 % m0 # 取0~m0-1之间的主值
if not silent:
print(f"{a}x ≡ {b} mod {m} 解集为 {x0} mod {m0}")
return x0, m0
def newton(f,
fp,
x0,
max_iter=400,
div_deterrent=10**(10),
margin=1.e-9,
slope_near_zero=1.e-9,
step=10**9,
climb_steps=10**(4)):
x = [x0]
def check_slope(fp, X, Where_):
SLOPE = fp(X)
if np.abs(SLOPE) < slope_near_zero:
for j in range(climb_steps):
X += step
Yp = fp(X)
if Yp > slope_near_zero:
x[-1] = X
return x
if Where_ == "start of code":
raise Exception("slope near zero at initial evaluation")
elif Where_ == "middle of code":
raise Exception("slope near zero at later evaluations")
check_slope(fp, x0, Where_="start_of_code")
for i in range(max_iter):
x_new = x[-1] - f(x[-1]) / fp(x[-1])
x.append(x_new)
delta = np.abs(x[-1] - x[-2])
travel_len = np.abs(x[0] - x[-1])
check_slope(fp, x[-1], Where_="middle of code")
if travel_len < div_deterrent:
if i < max_iter:
if delta < margin:
return x[-1], f"convergent, {x[-1]} = x[-1] < margin"
elif i == max_iter:
if delta > margin:
return f"divergent, {x[-1]} = x[-1] > margin"
elif travel_len >= div_deterrent:
raise Exception(f"x-values are travelling too far away {x[-1]}")
return x[-1]
def Newton(f, fp, x0, max_iter=400, div_deterrent=10**(10), margin=1.e-9):
x = [x0]
for i in range(max_iter):
x_new = x[-1] - f(x[-1]) / fp(x[-1])
x.append(x_new)
delta = np.abs(x[-1] - x[-2])
travel_len = np.abs(x[0] - x[-1])
if travel_len < div_deterrent:
if i < max_iter:
if delta < margin:
return x[-1], "convergent, x[-1] < margin"
elif i == max_iter:
if delta > margin:
return x[-1], "divergent, x[-1] > margin"
elif travel_len > div_deterrent:
raise Exception("x-values are travelling too far away")
def Beta_bool(B, n, max_iter=30, margin=1.e-9, x0=1):
"""
denna funktion genomför n rekusrion under en for-loop
ON INPUT:
B (float)
"""
c = [0.2, 5]
x = [x0]
for i in range(n):
x_new = c[0] * x[-1] - B * (x[-1]**2 - c[1])
x.append(x_new)
delta = np.abs(x[-1] - x[-2])
if i < max_iter:
if delta < margin:
return True, x
elif i == max_iter:
if delta > margin:
return False, x
def Beta(B):
"""
denna funktion genomför n rekusrion under en for-loop
ON INPUT:
B (float)
"""
for i in range(n):
x_new = c[0] * x[-1] - B * (x[-1]**2 - c[1])
x.append(x_new)
if np.abs(x[-1] - x[-2]) < margin:
break
if p == "x_lastval_sring":
return f"""conv: {x[-1]}"""
elif p == "x_lastval":
return x[-1]
elif p == "x":
return x
def fix_point(f, x0, max_iter, margin=1.e-10, MARGIN=1.e-7, min_iter=30):
"""
This function takes a function and an initiat guess on the the first x-value and returns a fixed point
with the property x = f(x)
"""
N = max_iter * 2
x = [x0]
if c == "index":
for i in range(max_iter):
x.append((f(x[i - 1])))
delta = np.abs(x[-1] - x[-2])
if delta <= margin and i > min_iter:
break
return x[-1], delta, f"""delta < {margin}""".format(margin=margin)
elif c == "claus_method":
for i in range(max_iter):
x_new = f(x[-1])
x.append(x_new)
DELTA = np.abs(x[-1] - x[-2])
if margin <= DELTA <= MARGIN:
for i in range(max_iter, N):
x.append((f(x[i - 1])))
D = np.abs(x[-1] - x[-2])
if D < margin and i > min_iter:
break
return x[-1], """fixed DELTA to delta""", D
elif DELTA >= MARGIN:
return x[-1], DELTA, "DELTA"
else:
D = np.abs(x[-1] - x[-2])
return x, D, "D"
