def test_close_values_at_limit(self):
resistors = get_resistors("E12", ORDERS_RESISTOR)
r0_9 = EngineerNumber(0.9, ONE)
M101 = EngineerNumber(10.1, MEGA)
self.assertEqual(EngineerNumber(1), close_values(r0_9, "up", resistors))
self.assertEqual(EngineerNumber("10M"), close_values(M101, "down", resistors))
def test_close_values_out_of_range(self):
resistors = get_resistors("E12", ORDERS_RESISTOR)
r0_9 = EngineerNumber(0.9, ONE)
M101 = EngineerNumber(10.1, MEGA)
self.assertIsNone(close_values(r0_9, "down", resistors))
self.assertIsNone(close_values(M101, "up", resistors))
def test_make_resistors(self):
resistors = get_resistors("E12", ORDERS_RESISTOR)
resistors_ = tuple(str(x) for x in resistors)
expected = (
"1.000", "1.200", "1.500", "1.800", "2.200", "2.700", "3.300",
"3.900", "4.700", "5.600", "6.800", "8.200", "10.000", "12.000",
"15.000", "18.000", "22.000", "27.000", "33.000", "39.000",
"47.000", "56.000", "68.000", "82.000", "100.000", "120.000",
"150.000", "180.000", "220.000", "270.000", "330.000", "390.000",
"470.000", "560.000", "680.000", "820.000", "1.000k", "1.200k",
"1.500k", "1.800k", "2.200k", "2.700k", "3.300k", "3.900k",
"4.700k", "5.600k", "6.800k", "8.200k", "10.000k", "12.000k",
"15.000k", "18.000k", "22.000k", "27.000k", "33.000k", "39.000k",
"47.000k", "56.000k", "68.000k", "82.000k", "100.000k", "120.000k",
"150.000k", "180.000k", "220.000k", "270.000k", "330.000k",
"390.000k", "470.000k", "560.000k", "680.000k", "820.000k",
"1.000M", "1.200M", "1.500M", "1.800M", "2.200M", "2.700M",
"3.300M", "3.900M", "4.700M", "5.600M", "6.800M", "8.200M",
"10.000M")
for x in resistors:
self.assertIsInstance(x, EngineerNumber)
self.assertEqual(expected, resistors_)
def brute_force_to_look_for_rc(c2=None,
e_series_resistors="E12",
e_series_capacitors="E6",
orders_resistor=ORDERS_RESISTOR,
orders_capacitor=ORDERS_CAPACITOR):
resistors = get_resistors(e_series_resistors, orders_resistor)
if not c2:
capacitors = get_capacitors(e_series_capacitors, orders_capacitor)
else:
capacitors = (c2, )
r_combinations_with_replacement = list(
combinations_with_replacement(resistors, 3))
parameters = [None] * (len(r_combinations_with_replacement) *
len(resistors) * len(capacitors))
i = 0
for c2, r4 in product(capacitors, resistors):
for r5, r3, r1 in r_combinations_with_replacement:
le = c2 * (r1 * r3 * r5) / r4
kwds = {}
for name in NAMES:
kwds[name] = locals()[name]
si = SimlatedInductor(**kwds)
# print("i =", i)
parameters[i] = si
i += 1
return parameters
def brute_force_LMC555(resistor_e_sesires, capacitor_e_sesires):
resistors = get_resistors(resistor_e_sesires, ORDERS_RESISTOR)
capacitors = get_capacitors(capacitor_e_sesires, ORDERS_CAPACITOR)
combi_rbra = tuple(product(resistors, resistors))
len_combinations = len(combi_rbra) * len(capacitors)
# print("len(resistors) ** 2 =", len(resistors) ** 2)
# print("len(combi_rbra) =", len(combi_rbra))
# print("len(capacitors) =", len(capacitors))
# print("len_combinations =", len_combinations)
# print("len(resistors) ** 2 * len(capacitors) / len_combinations =", len(resistors) ** 2 * len(capacitors) / len_combinations)
tf = [None] * len_combinations
i = 0
for rbra, c in product(combi_rbra, capacitors):
rb, ra = rbra
tL, tH, t, f = lmc555(ra, rb, c)
dutyL = tL / t
dutyH = 1 - dutyL
kwds = {}
for name in NAMES:
kwds[name] = locals()[name]
l555 = LMC555(**kwds)
tf[i] = l555
i += 1
tf = tf[:i]
return tf
def brute_force_LMC555(resistor_e_sesires, capacitor_e_sesires):
resistors = get_resistors(resistor_e_sesires, ORDERS_RESISTOR)
capacitors = get_capacitors(capacitor_e_sesires, ORDERS_CAPACITOR)
len_combinations = len(resistors) * len(capacitors)
# print("len(resistors) =", len(resistors))
# print("len(capacitors) =", len(capacitors))
# print("len_combinations =", len_combinations)
tf = [None] * len_combinations
i = 0
for rc, c in product(resistors, capacitors):
t, f = lmc555_fifty_duty(rc, c)
duty = EngineerNumber("0.5")
kwds = {}
for name in NAMES:
kwds[name] = locals()[name]
l555 = LMC555(**kwds)
tf[i] = l555
i += 1
tf = tf[:i]
return tf
def brute_force_to_look_for(c3=None,
e_series_resistors="E12",
e_series_capacitors="E6",
orders_resistor=ORDERS_RESISTOR,
orders_capacitor=ORDERS_CAPACITOR):
resistors = get_resistors(e_series_resistors, orders_resistor)
if not c3:
capacitors = get_capacitors(e_series_capacitors, orders_capacitor)
else:
capacitors = c3
r_combinations_with_replacement = list(
combinations_with_replacement(resistors, 2))
parameters = [None] * (len(r_combinations_with_replacement)**2 *
len(capacitors))
i = 0
for r1r5, r2r4 in product(r_combinations_with_replacement,
r_combinations_with_replacement):
r1, r5 = r1r5
r2, r4 = r2r4
for c3 in capacitors:
ce = c3 * (r1 * r5) / (r2 * r4)
kwds = {}
for name in NAMES:
kwds[name] = locals()[name]
cm = CapacitanceMultiplier(**kwds)
# print("i =", i)
parameters[i] = cm
i += 1
return parameters
def test_close_values_same_exponent(self):
k47 = EngineerNumber(47, 3)
k50 = EngineerNumber(50, 3)
k56 = EngineerNumber(56, 3)
resistors = get_resistors("E12", ORDERS_RESISTOR)
self.assertEqual(k56, close_values(k50, "up", resistors))
self.assertEqual(k47, close_values(k50, "down", resistors))
def test_close_values_transfer_next_exponent(self):
resistors = get_resistors("E12", ORDERS_RESISTOR)
r83 = EngineerNumber(8.3, 1)
r100 = EngineerNumber(1.0, 2)
self.assertEqual(r100, close_values(r83, "up", resistors))
k094 = EngineerNumber(0.94, 3)
r820 = EngineerNumber(8.2, 2)
self.assertEqual(r820, close_values(k094, "down", resistors))
def brute_force_to_look_for_gain_and_Pce(Vcc, ic, hfe, e_series, orders=ORDERS_RESISTOR):
resistors = get_resistors(e_series, orders)
combi_RcRe = tuple(combinations_with_replacement(resistors, 2))
parameters = [None] * len(combi_RcRe)
# print("len(resistors)={}".format(len(resistors)))
# print("len(resistors) ** 2 ={}".format(len(resistors) ** 2))
# print("len(combi_RcRe)={}".format(len(combi_RcRe)))
# print("len(resistors) ** 2 / len(combi_RcRe) ={}".format(len(resistors) ** 2 / len(combi_RcRe)))
i = 0
for Rc, Re in combi_RcRe:
eca = _emitter_common_amplifier(Vcc, ic, hfe, Rc, Re, resistors)
if eca:
parameters[i] = eca
i += 1
return parameters[:i]
def brute_force_umeppi(resistor_e_sesires, capacitor_e_sesires):
orders_resistor = range(KILO, MEGA + 1)
orders_capacitor = range(PICO, MICRO + 3)
resistors = get_resistors(resistor_e_sesires, orders_resistor)
capacitors = get_capacitors(capacitor_e_sesires, orders_capacitor)
len_combinations = (len(resistors)**2) * len(capacitors)
# print("len(resistors) =", len(resistors))
# print("len(capacitors) =", len(capacitors))
# print("len_combinations =", len_combinations)
uc = [None] * len_combinations
i = 0
for c in capacitors:
c_0693 = 0.693 * c
for rb in resistors:
tb = c_0693 * rb
if not tb > TB:
continue
for ra in resistors:
if not ra / rb > RARB:
continue
ta = c_0693 * ra + tb
if not ta <= TA:
continue
T = ta + tb
kwds = {}
for name in NAMES:
kwds[name] = locals()[name]
ucs = UmeppiConstants(**kwds)
uc[i] = ucs
i += 1
uc = uc[:i]
return uc
def look_for_optimized_gain(gain, ic, Vcc, hfe=200, e_series="E12", orders=ORDERS_RESISTOR):
resistors = get_resistors(e_series, orders)
gain_ = gain
parameters = []
# print("resistors =", resistors)
for Rc in resistors:
d = {}
ie = ic + ic / hfe
Vc = Rc * ic # 6
Re = Rc / gain_
Re_ = close_values(Re, "up", resistors)
if not Re_:
continue
Re = Re_
Ve = Re * ie
# 注意
# must be Vc + Ve <= Vcc
if Vc + Ve > Vcc:
# raise ValueError("invalid Vc and Ve combination compare Vcc.")
# print("added(Vc={}, Ve={})={} is greater ghan Vcc={}.".format(Vc, Ve, Vc + Ve, Vcc))
continue
gain = Vc / Ve
Vce = Vcc - (Vc + Ve) # 7
Pce = Vce * ic # 8
# Pce は小さきこと。
# 2SC1815 の場合,
# Pce < 400mW(=PD)
Vb = Ve + 0.6 # 9
Vcb = Vcc - Vb
# hfe = 200 # 10
ib = ic / hfe # ?
ibias = 10 * ib # 11
Rb2 = Vb / ibias # 12
Rb1 = Vcb / ibias # 13
Rb2_ = close_values(Rb2, "down", resistors)
Rb1_ = close_values(Rb1, "down", resistors)
Rb2, Rb1 = Rb2_, Rb1_
if (not Rb2) or (not Rb1):
# print("--")
# print("Rb2={}, Rb2_={}".format(Rb2, Rb2_))
# print("Rb1={}, Rb1_={}".format(Rb1, Rb1_))
continue
Radd = Rb1 + Rb2
# print("Radd =", Radd)
ibias = Vcc / Radd
kwds = {}
for name in NAMES:
kwds[name] = locals()[name]
eca = EmitterCommonAmp(**kwds)
parameters.append(eca)
parameters.sort(key=lambda parameter: math.fabs(gain_ - parameter.gain))
# print("parameters =")
# print(parameters)
return parameters
def test_close_values_eq_down(self):
resistors = get_resistors("E24", ORDERS_RESISTOR)
k15 = EngineerNumber(15, 3)
self.assertEqual(EngineerNumber(15, 3), close_values(k15, "down", resistors))