def request(self, endpoint, parameters):
if parameters["f_std"] != "":
f = UnitValue(parameters["f_std"])
else:
f = UnitValue(parameters["f_user"])
ckdiv8 = "ckdiv8" in parameters
if ckdiv8:
f = UnitValue(f.exact_value / 8)
period = UnitValue(parameters["period"])
bit_width = int(parameters["bit_width"])
if parameters["prescaler"] != "":
user_prescaler = int(parameters["prescaler"])
else:
user_prescaler = None
options = [ ]
for prescaler_value in [ 1, 8, 64, 256, 1024 ]:
option = self._calculate("Prescaler CK / %d" % (prescaler_value), f = f, period = period, bit_width = bit_width, prescaler = prescaler_value)
options.append(option)
options.sort(key = lambda opt: abs(opt["error"]))
if user_prescaler is not None:
option = self._calculate("User choice", f = f, period = period, bit_width = bit_width, prescaler = user_prescaler)
options.insert(0, option)
return {
"options": options,
}
def request(self, endpoint, parameters):
value = UnitValue(parameters["input_value"])
significant_digits = int(parameters["significant_digits"])
return {
"value": value.to_dict(significant_digits=significant_digits),
"significant_digits": significant_digits,
}
def _calculate(name, f, period, bit_width, prescaler):
t_cnt_cycle = 1 / float(f) * prescaler
t_full_overflow = t_cnt_cycle * (2 ** bit_width)
cycles_ideal = round(float(period) / t_cnt_cycle)
# However, we're limited by the counter.
cycles = cycles_ideal
if cycles < 1:
cycles = 1
elif cycles > (2 ** bit_width):
cycles = 2 ** bit_width
preload = (2 ** bit_width) - cycles
actual_period = t_cnt_cycle * cycles
error = (actual_period - float(period)) / float(period)
return {
"name": name,
"prescaler": prescaler,
"t_cnt_cycle": UnitValue(t_cnt_cycle).to_dict(),
"t_full_overflow": UnitValue(t_full_overflow).to_dict(),
"f_full_overflow": UnitValue(1 / t_full_overflow).to_dict(),
"cycles_ideal": cycles_ideal,
"cycles": cycles,
"actual_period": UnitValue(actual_period).to_dict(),
"actual_frequency": UnitValue(1 / actual_period).to_dict(),
"error": error,
"preload": preload,
}
def test_init_unitvalue(self):
x = UnitValue("1.2345")
self.assertEqual(x, x)
y = UnitValue("1.2345")
self.assertEqual(x, y)
y = UnitValue(x)
self.assertEqual(x, y)
def test_str_units(self):
self.assertAlmostEqual(float(UnitValue("12345f")), 12345e-15)
self.assertAlmostEqual(float(UnitValue("12345p")), 12345e-12)
self.assertAlmostEqual(float(UnitValue("12345n")), 12345e-9)
self.assertAlmostEqual(float(UnitValue("12345u")), 12345e-6)
self.assertAlmostEqual(float(UnitValue("12345m")), 12345e-3)
self.assertAlmostEqual(float(UnitValue("12345")), 12345)
self.assertAlmostEqual(float(UnitValue("12345k")), 12345e3)
self.assertAlmostEqual(float(UnitValue("12345M")), 12345e6)
self.assertAlmostEqual(float(UnitValue("12345G")), 12345e9)
self.assertAlmostEqual(float(UnitValue("12345T")), 12345e12)
def from_dict(cls, dict_data):
if not "name" in dict_data:
raise DataMissingException(
"No 'name' attribute in ValueSet definition: %s" %
(str(dict_data)))
if not "type" in dict_data:
raise DataMissingException(
"No 'type' attribute in ValueSet definition: %s" %
(str(dict_data)))
vs_type = dict_data["type"]
if vs_type == "explicit":
if not "items" in dict_data:
raise DataMissingException(
"No 'items' attribute in explicit ValueSet definition: %s"
% (str(dict_data)))
return cls(name=dict_data["name"],
values=[UnitValue(v) for v in dict_data["items"]])
elif vs_type == "eseries":
if not "series" in dict_data:
raise DataMissingException(
"No 'series' attribute in eseries ValueSet definition: %s"
% (str(dict_data)))
if not "min" in dict_data:
raise DataMissingException(
"No 'min' attribute in eseries ValueSet definition: %s" %
(str(dict_data)))
if not "max" in dict_data:
raise DataMissingException(
"No 'max' attribute in eseries ValueSet definition: %s" %
(str(dict_data)))
eseries = ESeries.standard(dict_data["series"])
(minval,
maxval) = UnitValue(dict_data["min"]), UnitValue(dict_data["max"])
values = [
UnitValue(v) for v in eseries.from_to(minval.exact_value,
maxval.exact_value,
maxvalue_inclusive=True)
]
return cls(name=dict_data["name"], values=values)
elif vs_type == "union":
if not "groups" in dict_data:
raise DataMissingException(
"No 'groups' attribute in union ValueSet definition: %s" %
(str(dict_data)))
return cls(name=dict_data["name"],
values=None,
additional_data=dict_data["groups"])
else:
raise InvalidDataException(
"Invalid 'type' attribute of ValueSet '%s': %s" %
(vs_type, str(dict_data)))
def _calculate_choice(name, r, v_in, v_load, i):
r_load = v_load / i
actual_v_load = v_in * r_load / (r_load + float(r))
rel_error = (actual_v_load - v_load) / v_load
abs_error = UnitValue(actual_v_load - v_load)
return {
"name": name,
"r": UnitValue(r).to_dict(),
"v_load": UnitValue(actual_v_load).to_dict(),
"rel_error": rel_error,
"abs_error": abs_error.to_dict(),
}
def request(self, endpoint, parameters):
v_in = UnitValue(parameters["v_in"])
v_out = UnitValue(parameters["v_out"])
r_sum = UnitValue(parameters["r_sum"])
r_set = self.config.get_valuesets("r")[parameters["r_set"]]
r_tolerance = float(parameters["r_tolerance"]) / 100
options = []
ideal_r1 = float(r_sum) * (float(v_out)) / float(v_in)
min_r1 = ideal_r1 * (1 - r_tolerance)
max_r1 = ideal_r1 * (1 + r_tolerance)
for r1 in r_set.iter_range(min_r1, max_r1):
ideal_r2 = float(r1) * (float(v_in) - float(v_out)) / float(v_out)
for r2 in r_set.iter_closest(ideal_r2):
opt_v_out = float(v_in) * float(r1) / (float(r1) + float(r2))
opt_r_sum = float(r1) + float(r2)
opt_i = float(v_in) / opt_r_sum
opt_p = (opt_i**2) * opt_r_sum
option = {
"r1": r1.to_dict(),
"r2": r2.to_dict(),
"r_total": UnitValue(opt_r_sum).to_dict(),
"v_out": UnitValue(opt_v_out).to_dict(),
"v_error": (opt_v_out - float(v_out)) / float(v_out),
"r_error": (opt_r_sum - float(r_sum)) / float(r_sum),
"i": UnitValue(opt_i).to_dict(),
"p": UnitValue(opt_p).to_dict(),
}
options.append(option)
options.sort(
key=lambda opt: (abs(opt["v_error"]), abs(opt["r_error"])))
return {
"options": options,
}
def request(self, endpoint, parameters):
diameter = UnitValue(parameters["diameter"])
length = UnitValue(parameters["length"])
turns = int(parameters["turns"])
pitch = float(length) / turns
diameter_inch = UnitValue(diameter.exact_value * 10000 / 254)
reference = Thread(diameter=float(diameter), pitch=pitch)
candidates = list(self.config.thread_db.closest(reference))
candidates = [{
"group":
candidate.group,
"name":
candidate.name,
"usage":
candidate.usage,
"diameter":
UnitValue(candidate.diameter).to_dict(),
"diameter_frac":
FractionalRepresentation(candidate.diameter * 10000 / 254,
max_abs_fractional_error=0.01).to_dict(),
"pitch":
UnitValue(candidate.pitch).to_dict(),
"pitch_tpi":
candidate.pitch_tpi,
"diameter_err":
(candidate.diameter - float(diameter)) / float(diameter),
"pitch_err": (candidate.pitch - pitch) / pitch,
} for candidate in candidates]
return {
"diameter":
diameter.to_dict(),
"diameter_inch":
diameter_inch.to_dict(),
"diameter_frac":
FractionalRepresentation(diameter_inch.exact_value,
max_abs_fractional_error=0.01).to_dict(),
"pitch":
UnitValue(pitch).to_dict(),
"pitch_tpi":
0.0254 / pitch,
"candidates":
candidates,
}
def to_dict(self, repr_callback=None):
return {
"name":
self.name,
"values": [
UnitValue(element, repr_callback=repr_callback).to_dict()
for element in self._values
],
}
def find_closest(self, value):
value = UnitValue(value)
index = bisect.bisect(self._values, value) - 1
if index >= 0:
smaller = self._values[index]
else:
smaller = None
if index + 1 < len(self._values):
larger = self._values[index + 1]
else:
larger = None
return (smaller, larger)
def request(self, endpoint, parameters):
if parameters["f_std"] != "":
f = UnitValue(parameters["f_std"])
else:
f = UnitValue(parameters["f_user"])
ckdiv8 = "ckdiv8" in parameters
u2x = "u2x" in parameters
if ckdiv8:
f = UnitValue(f.exact_value / 8)
ckdivisor = 8 if u2x else 16
result_items = []
for baudrate in self.config.get_valuesets(
"baudrate")["Standard"].values.ordered_tuple:
ubrr = max(0, round(float(f) / (ckdivisor * float(baudrate))) - 1)
act_baudrate = float(f) / (ckdivisor * (ubrr + 1))
error = (act_baudrate - float(baudrate)) / float(baudrate)
ideal_freq = float(baudrate) * (ckdivisor * (ubrr + 1))
if ckdiv8:
ideal_freq *= 8
result_items.append({
"baudrate":
baudrate.to_dict(include_repr=True),
"act_baudrate":
act_baudrate,
"ubrr":
ubrr,
"error":
error,
"ideal_freq":
UnitValue(
ideal_freq,
repr_callback=lambda value: value.format(
significant_digits=6)).to_dict(include_repr=True),
})
return {
"items": result_items,
}
def request(self, endpoint, parameters):
marking = parameters["marking"].strip()
try:
int_marking = int(marking)
except ValueError:
int_marking = None
try:
flt_marking = float(marking)
except ValueError:
flt_marking = None
if (int_marking is not None) and (int_marking >= 100):
(base, exponent) = divmod(int_marking, 10)
value = base * (10**exponent)
(r, c, l) = (1, 1e-12, 1e-6)
elif flt_marking is not None:
value = flt_marking
(r, c, l) = (1, 1e-12, None)
else:
replacers = {
"r": (1, None, 1e-6),
"u": (None, 1e-6, 1e-6),
"n": (None, 1e-9, 1e-9),
"p": (None, 1e-12, None),
}
lmarking = marking.lower()
for (character, (r, c, l)) in replacers.items():
if character in lmarking:
value = float(lmarking.replace(character, "."))
break
else:
raise InputDataException("Unable to interpret \"%s\"." %
(marking))
return {
"r": UnitValue(value * r).to_dict() if r else None,
"c": UnitValue(value * c).to_dict() if c else None,
"l": UnitValue(value * l).to_dict() if l else None,
}
def request(self, endpoint, parameters):
r = UnitValue(parameters["r"])
r_set = self.config.get_valuesets("r")[parameters["r_set"]]
options = []
for r1 in r_set:
if r1 == r:
continue
ideal_r2 = 1 / ((1 / float(r)) - (1 / float(r1)))
for r2 in r_set.iter_closest(ideal_r2):
if r2 < r1:
continue
r_total = 1 / ((1 / float(r1)) + (1 / float(r2)))
error = (r_total - float(r)) / float(r)
if abs(error) > 0.75:
continue
option = {
"r1":
UnitValue(r1).to_dict(),
"r2":
UnitValue(r2).to_dict(),
"r":
UnitValue(
r_total,
repr_callback=lambda v: v.format(
significant_digits=4)).to_dict(include_repr=True),
"error":
error,
"ratio":
float(r2) / float(r1),
}
options.append(option)
options.sort(key=lambda o: (abs(o["error"]), o["ratio"]))
return {
"options": options[:15],
}
def request(self, endpoint, parameters):
f_in = UnitValue(parameters["f_in"])
f_out = UnitValue(parameters["f_out"])
multipliers = self._parse_ckfield(parameters["mul"])
dividers = SortedList(self._parse_ckfield(parameters["div"]))
results = []
ratio = float(f_out) / float(f_in)
for multiplier in multipliers:
ideal_divider = multiplier / ratio
for divider in dividers.less_more_list(ideal_divider):
f_result = float(f_in) * multiplier / divider
error = (f_result - float(f_out)) / float(f_out)
result = {
"multiplier": multiplier,
"divider": divider,
"f_out": UnitValue(f_result).to_dict(),
"error": error,
}
results.append(result)
results.sort(key=lambda result: abs(result["error"]))
return results
def request(self, endpoint, parameters):
v_out = UnitValue(parameters["v_out"])
r_set = self.config.get_valuesets("r")[parameters["r_set"]]
l = UnitValue(parameters["l"]) if (parameters["l"] != "") else None
v_in = UnitValue(
parameters["v_in"]) if (parameters["v_in"] != "") else None
i_out = UnitValue(
parameters["i_out"]) if (parameters["i_out"] != "") else None
f = 325e3
options = []
for r2 in r_set.iter_range(500, 50000):
ideal_r1 = (float(v_out) / 0.925 * float(r2)) - float(r2)
for r1 in r_set.iter_closest(ideal_r1):
actual_v_out = 0.925 * (float(r1) + float(r2)) / float(r2)
error = (actual_v_out - float(v_out)) / float(v_out)
option = {
"r1": r1.to_dict(),
"r2": r2.to_dict(),
"v_out": UnitValue(actual_v_out).to_dict(),
"error": error,
}
if (v_in is not None) and (l is not None):
# Inductor and V_IN also given, calculate Delta I_L
option["delta_i_load"] = UnitValue(
((float(v_in) * float(v_out)) - (float(v_out)**2)) /
(f * float(l) * float(v_in))).to_dict()
if (v_in is not None) and (l is not None) and (i_out
is not None):
option["max_inductor_i"] = UnitValue(
float(i_out) +
(float(v_out) / (2 * f * float(l)) *
(1 - (float(v_out) / float(v_in))))).to_dict()
options.append(option)
options.sort(key=lambda opt: abs(opt["error"]))
return {
"show_other": (v_in is not None) and (l is not None),
"options": options[:15],
}
def test_str_init(self):
self.assertAlmostEqual(float(UnitValue("1.23456")), 1.23456)
self.assertAlmostEqual(float(UnitValue(".23456")), .23456)
self.assertAlmostEqual(float(UnitValue("0000.23456")), .23456)
def request(self, endpoint, parameters):
v_in = UnitValue(parameters["v_in"])
v_load = UnitValue(parameters["v_load"])
i = UnitValue(parameters["i"])
if v_in < v_load:
raise InputDataException("Input voltage is lower than load voltage.")
v_r = float(v_in) - float(v_load)
r = v_r / float(i)
p_r = float(i) * v_r
p_load = float(i) * float(v_load)
eta = float(v_load) / float(v_in)
choices = [ ]
if parameters["r_user"] != "":
r_user = UnitValue(parameters["r_user"])
choices.append(self._calculate_choice("User choice", r = r_user, v_in = float(v_in), v_load = float(v_load), i = float(i)))
if parameters["r_set"] != "":
r_set = self.config.get_valuesets("r")[parameters["r_set"]]
(smaller, larger) = r_set.find_closest(r)
if smaller is not None:
choices.append(self._calculate_choice("Smaller in set", r = smaller, v_in = float(v_in), v_load = float(v_load), i = float(i)))
if larger is not None:
choices.append(self._calculate_choice("Larger in set", r = larger, v_in = float(v_in), v_load = float(v_load), i = float(i)))
return {
"v_in": v_in.to_dict(),
"v_load": v_load.to_dict(),
"i": i.to_dict(),
"v_r": UnitValue(v_r).to_dict(),
"r": UnitValue(r).to_dict(),
"p_r": UnitValue(p_r).to_dict(),
"p_load": UnitValue(p_load).to_dict(),
"p_total": UnitValue(p_r + p_load).to_dict(),
"eta": eta,
"choices": choices,
}
def test_format(self):
self.assertEqual(UnitValue("0").format(significant_digits = 1), "0 ")
self.assertEqual(UnitValue("0").format(significant_digits = 2), "0.0 ")
self.assertEqual(UnitValue("0").format(significant_digits = 3), "0.00 ")
self.assertEqual(UnitValue("0").format(significant_digits = 4), "0.000 ")
self.assertEqual(UnitValue("1").format(significant_digits = 1), "1 ")
self.assertEqual(UnitValue("1").format(significant_digits = 2), "1.0 ")
self.assertEqual(UnitValue("1").format(significant_digits = 3), "1.00 ")
self.assertEqual(UnitValue("1").format(significant_digits = 4), "1.000 ")
self.assertEqual(UnitValue("-1").format(significant_digits = 1), "-1 ")
self.assertEqual(UnitValue("-1").format(significant_digits = 2), "-1.0 ")
self.assertEqual(UnitValue("-1").format(significant_digits = 3), "-1.00 ")
self.assertEqual(UnitValue("-1").format(significant_digits = 4), "-1.000 ")
self.assertEqual(UnitValue("1").format(significant_digits = 3), "1.00 ")
self.assertEqual(UnitValue("12").format(significant_digits = 3), "12.0 ")
self.assertEqual(UnitValue("123").format(significant_digits = 3), "123 ")
self.assertEqual(UnitValue("1").format(significant_digits = 4), "1.000 ")
self.assertEqual(UnitValue("12").format(significant_digits = 4), "12.00 ")
self.assertEqual(UnitValue("123").format(significant_digits = 4), "123.0 ")
self.assertEqual(UnitValue("1234").format(significant_digits = 4), "1.234 k")
self.assertEqual(UnitValue("12345").format(significant_digits = 4), "12.35 k")
self.assertEqual(UnitValue("123456").format(significant_digits = 4), "123.5 k")
self.assertEqual(UnitValue("123456").format(significant_digits = 5), "123.46 k")
def request(self, endpoint, parameters):
t1 = UnitValue(parameters["t1"])
v1 = UnitValue(parameters["v1"])
t2 = UnitValue(parameters["t2"])
v2 = UnitValue(parameters["v2"])
if t1 > t2:
(t1, v1, t2, v2) = (t2, v2, t1, v1)
if v2 < v1:
# Capacitor is discharging
# v(t) = v0 * exp(-t / tau)
# v1 = v0 * exp(-t1 / tau) -> v0 = v1 / exp(-t1 / tau)
# v2 = v0 * exp(-t2 / tau) -> v0 = v2 / exp(-t2 / tau)
# v1 / exp(-t1 / tau) = v2 / exp(-t2 / tau)
# v1 / v2 = exp(-t1 / tau) / exp(-t2 / tau) = exp((-t1 - (-t2)) / tau) = exp((t2 - t1) / tau)
# (t2 - t1) / tau = ln(v1 / v2)
# tau = (t2 - t1) / ln(v1 / v2)
tau = (float(t2) - float(t1)) / math.log(float(v1) / float(v2))
v0 = float(v1) / math.exp(-float(t1) / tau)
else:
# Capacitor is charging, here we need to rely on numeric solution.
# v(t) = v0 * (1 - exp(-t / tau))
# v1 = v0 * exp(-t1 / tau)
# v2 = v0 * exp(-t2 / tau)
# v1 / v2 = exp(-t1 / tau) / exp(-t2 / tau)
# Substitute: d = v1 / v2
# d = exp(-t1 / tau) / exp(-t2 / tau)
# d - exp(-t1 / tau) / exp(-t2 / tau) = 0
# Solve this by Newton's method.
d = float(v1) / float(v2)
function = _ChargingCapFunction(d=float(v1) / float(v2),
t1=float(t1),
t2=float(t2))
try:
tau = NewtonSolver(function).solve(x0=1)
v0 = float(v1) / (1 - math.exp(-float(t1) / tau))
except ZeroDivisionError:
raise InputDataException(
"Result is numerically instable, cannot solve.")
if tau < 0:
raise InputDataException(
"Result is numerically instable, tau was negative.")
# Now, plausibilize values.
if v2 < v1:
calc_v1 = v0 * math.exp(-float(t1) / tau)
calc_v2 = v0 * math.exp(-float(t2) / tau)
else:
calc_v1 = v0 * (1 - math.exp(-float(t1) / tau))
calc_v2 = v0 * (1 - math.exp(-float(t2) / tau))
error_v1 = abs(calc_v1 - float(v1))
error_v2 = abs(calc_v2 - float(v2))
max_error = max(error_v1, error_v2)
if (max_error > 1e-3):
raise InputDataException(
"Result is numerically instable and diverged. Refusing to give a completely wrong answer. Absolute error was %.2e"
% (max_error))
# Cutoff frequency
f = 1 / (2 * math.pi * tau)
return {
"tau": tau,
"v0": UnitValue(v0).to_dict(),
"f": UnitValue(f).to_dict(),
}
def request(self, endpoint, parameters):
if parameters["v"].strip() == "":
i = UnitValue(parameters["i"])
r = UnitValue(parameters["r"])
v = UnitValue(float(i) * float(r))
elif parameters["i"].strip() == "":
r = UnitValue(parameters["r"])
v = UnitValue(parameters["v"])
i = UnitValue(float(v) / float(r))
elif parameters["r"].strip() == "":
v = UnitValue(parameters["v"])
i = UnitValue(parameters["i"])
r = UnitValue(float(v) / float(i))
else:
raise InputDataException(
"Exactly one of V, I, R must be left empty.")
p = UnitValue((float(i)**2) * float(r))
return {
"v": v.to_dict(),
"i": i.to_dict(),
"r": r.to_dict(),
"p": p.to_dict(),
}
def test_format_units(self): self.assertEqual(UnitValue(1.23e-17).format(significant_digits = 3), "0.0123 f") self.assertEqual(UnitValue(1.23e-16).format(significant_digits = 3), "0.123 f") self.assertEqual(UnitValue(1.23e-15).format(significant_digits = 3), "1.23 f") self.assertEqual(UnitValue(1.23e-14).format(significant_digits = 3), "12.3 f") self.assertEqual(UnitValue(1.23e-13).format(significant_digits = 3), "123 f") self.assertEqual(UnitValue(1.23e-12).format(significant_digits = 3), "1.23 p") self.assertEqual(UnitValue(1.23e-11).format(significant_digits = 3), "12.3 p") self.assertEqual(UnitValue(1.23e-10).format(significant_digits = 3), "123 p") self.assertEqual(UnitValue(1.23e-9).format(significant_digits = 3), "1.23 n") self.assertEqual(UnitValue(1.23e-8).format(significant_digits = 3), "12.3 n") self.assertEqual(UnitValue(1.23e-7).format(significant_digits = 3), "123 n") self.assertEqual(UnitValue(1.23e-6).format(significant_digits = 3), "1.23 µ") self.assertEqual(UnitValue(1.23e-5).format(significant_digits = 3), "12.3 µ") self.assertEqual(UnitValue(1.23e-4).format(significant_digits = 3), "123 µ") self.assertEqual(UnitValue(1.23e-3).format(significant_digits = 3), "1.23 m") self.assertEqual(UnitValue(1.23e-2).format(significant_digits = 3), "12.3 m") self.assertEqual(UnitValue(1.23e-1).format(significant_digits = 3), "123 m") self.assertEqual(UnitValue(1.23e0).format(significant_digits = 3), "1.23 ") self.assertEqual(UnitValue(1.23e1).format(significant_digits = 3), "12.3 ") self.assertEqual(UnitValue(1.23e2).format(significant_digits = 3), "123 ") self.assertEqual(UnitValue(1.23e3).format(significant_digits = 3), "1.23 k") self.assertEqual(UnitValue(1.23e4).format(significant_digits = 3), "12.3 k") self.assertEqual(UnitValue(1.23e5).format(significant_digits = 3), "123 k") self.assertEqual(UnitValue(1.23e6).format(significant_digits = 3), "1.23 M") self.assertEqual(UnitValue(1.23e7).format(significant_digits = 3), "12.3 M") self.assertEqual(UnitValue(1.23e8).format(significant_digits = 3), "123 M") self.assertEqual(UnitValue(1.23e9).format(significant_digits = 3), "1.23 G") self.assertEqual(UnitValue(1.23e10).format(significant_digits = 3), "12.3 G") self.assertEqual(UnitValue(1.23e11).format(significant_digits = 3), "123 G") self.assertEqual(UnitValue(1.23e12).format(significant_digits = 3), "1.23 T") self.assertEqual(UnitValue(1.23e13).format(significant_digits = 3), "12.3 T") self.assertEqual(UnitValue(1.23e14).format(significant_digits = 3), "123 T") self.assertEqual(UnitValue(1.23e15).format(significant_digits = 3), "1.23 E") self.assertEqual(UnitValue(1.23e16).format(significant_digits = 3), "12.3 E") self.assertEqual(UnitValue(1.23e17).format(significant_digits = 3), "123 E") self.assertEqual(UnitValue(1.23e18).format(significant_digits = 3), "1230 E") self.assertEqual(UnitValue(1.23e19).format(significant_digits = 3), "12300 E")
def iter_range(self, min_value, max_value):
min_index = bisect.bisect(self._values, UnitValue(min_value)) - 1
max_index = bisect.bisect(self._values, UnitValue(max_value))
for index in range(min_index, max_index + 1):
if 0 <= index < len(self._values):
yield self._values[index]
def request(self, endpoint, parameters):
r1 = UnitValue(parameters["r1"])
r2 = UnitValue(parameters["r2"])
c1 = UnitValue(parameters["c1"])
t_on = 0.693 * (float(r1) + float(r2)) * float(c1)
t_off = 0.693 * float(r2) * float(c1)
t = t_on + t_off
f = 1 / t
duty = t_on / t
return {
"r1": r1.to_dict(),
"r2": r2.to_dict(),
"c1": c1.to_dict(),
"t": UnitValue(t).to_dict(),
"t_on": UnitValue(t_on).to_dict(),
"t_off": UnitValue(t_off).to_dict(),
"f": UnitValue(f).to_dict(),
"duty": duty,
}
def request(self, endpoint, parameters):
if parameters.get("i", "") != "":
i = UnitValue(parameters["i"])
else:
i = None
if parameters.get("thickness", "") != "":
thickness = UnitValue(parameters["thickness"])
thickness_unit = parameters["thickness_unit"]
uc = UnitConversion.lengths()
uc.add(1, "oz", 35, "um")
thickness_mil = uc.convert(float(thickness), thickness_unit, "mil")
else:
thickness_mil = None
if parameters.get("tempdelta", "") != "":
tempdelta = UnitValue(parameters["tempdelta"])
tempdelta_unit = parameters["tempdelta_unit"]
uc = UnitConversion.temperatures()
t = uc.convert_delta(float(tempdelta), tempdelta_unit, "K")
else:
t = None
if parameters.get("trace_width", "") != "":
trace_width = UnitValue(parameters["trace_width"])
trace_width_unit = parameters["trace_width_unit"]
uc = UnitConversion.lengths()
trace_width_mil = uc.convert(float(trace_width), trace_width_unit,
"mil")
else:
trace_width_mil = None
inner_layer = (int(parameters.get("inner_layer", "0")) == 1)
if parameters.get("trace_length", "") != "":
trace_length = UnitValue(parameters["trace_length"])
else:
trace_length = None
k = 0.024 if inner_layer else 0.048
# IPC-2221A, pg. 50
# k = 0.048 for outer, 0.024 for inner layers
# I = k * T^0.44 * A^0.725
# A = Cross section in mil²
# T = Temperature delta in °C
# A = (I / k / T^0.44)^(1 / 0.725)
# T = (I / k / A^0.725)^ (1 / 0.44)
def unit_temperature(tempdelta_kelvin):
return {
"kelvin": tempdelta_kelvin,
}
def unit_length_mil(length_mil):
return {
"mil": length_mil,
}
def unit_area_sqrmil(area_sqrmil):
return {
"sqrmil": area_sqrmil,
"mm2": area_sqrmil / ((1000 / 25.4)**2),
}
def unit_copper_thickness(length_mil):
uc = UnitConversion.lengths()
uc.add(1, "oz", 35, "um")
return {
"mil": length_mil,
"oz": uc.convert(length_mil, "mil", "oz"),
"mm": uc.convert(length_mil, "mil", "mm"),
}
results = []
if (i is not None) and (t is not None) and (thickness_mil is not None):
# Calculate trace width
calc_A_sqrmil = (float(i) / k / (t**0.44))**(1 / 0.725)
calc_trace_width_mil = calc_A_sqrmil / thickness_mil
result = {
"given": {
"i": i.to_dict(),
"t": unit_temperature(t),
"thickness": unit_copper_thickness(thickness_mil),
},
"calculated": {
"A": unit_area_sqrmil(calc_A_sqrmil),
"width": unit_length_mil(calc_trace_width_mil),
},
}
results.append(result)
if (trace_width_mil is not None) and (t is not None) and (thickness_mil
is not None):
# Calculate current
calc_A_sqrmil = trace_width_mil * thickness_mil
calc_i = UnitValue(k * (t**0.44) * (calc_A_sqrmil**0.725))
result = {
"given": {
"width": unit_length_mil(calc_trace_width_mil),
"t": unit_temperature(t),
"thickness": unit_copper_thickness(thickness_mil),
},
"calculated": {
"A": unit_area_sqrmil(calc_A_sqrmil),
"i": calc_i.to_dict(),
},
}
results.append(result)
if (trace_width_mil is not None) and (t is not None) and (i
is not None):
# Calculate copper thickness
calc_A_sqrmil = (float(i) / k / (t**0.44))**(1 / 0.725)
calc_copper_height_mil = calc_A_sqrmil / trace_width_mil
result = {
"given": {
"i": i.to_dict(),
"t": unit_temperature(t),
"width": unit_length_mil(trace_width_mil),
},
"calculated": {
"A": unit_area_sqrmil(calc_A_sqrmil),
"thickness": unit_copper_thickness(calc_copper_height_mil),
},
}
results.append(result)
if (trace_width_mil is not None) and (i is not None) and (thickness_mil
is not None):
# Calculate temperature rise
calc_A_sqrmil = trace_width_mil * thickness_mil
calc_t = (float(i) / k / (calc_A_sqrmil**0.725))**(1 / 0.44)
result = {
"given": {
"i": i.to_dict(),
"width": unit_length_mil(trace_width_mil),
"thickness": unit_copper_thickness(thickness_mil),
},
"calculated": {
"A": unit_area_sqrmil(calc_A_sqrmil),
"t": unit_temperature(calc_t),
},
}
results.append(result)
for result in results:
cu_resistivity = 1.68e-8 # Ohm-meters
area_sqrm = result["calculated"]["A"]["mm2"] / 1e6
resistance_per_meter = cu_resistivity / area_sqrm
result["calculated"]["R_per_cm"] = UnitValue(resistance_per_meter /
100).to_dict()
if trace_length is not None:
result["given"]["l"] = trace_length.to_dict()
result["calculated"]["R"] = UnitValue(
resistance_per_meter * float(trace_length)).to_dict()
if ("i" in result["given"]):
i = result["given"]["i"]["flt"]
else:
i = result["calculated"]["i"]["flt"]
P = (i**2) * result["calculated"]["R"]["flt"]
result["calculated"]["P"] = UnitValue(P).to_dict()
return results
def test_reformat_1u(self):
value = UnitValue("1u")
self.assertEqual(value.format(significant_digits = 3), "1.00 µ")