def calc_data(self):
x = numpy.array([self.data['list_t']])
y = numpy.array([self.data['list_v_1']])
xx = numpy.linspace(0, 10 * self.data['list_t[1]'], 100)
matplotlib.pyplot.scatter(x, y)
f = scipy.interpolate.interp1d(x, y, kind="cubic")
ynew = f(xx)
matplotlib.pyplot.plot(xx, ynew, "g")
matplotlib.pyplot.show()
ynew1 = f(self.data['list_q[1]'] + 0.001)
ynew2 = f(self.data['list_q[1]'] - 0.001)
v = math.fabs(ynew1 - ynew2) / 0.002
self.data['v'] = v
db = Method.average(self.data['list_db'])
self.data['db'] = db
dp = Method.average(self.data['list_dp'])
self.data['dp'] = dp
hb = Method.average(self.data['list_hb'])
self.data['hb'] = hb
hp = Method.average(self.data['list_hp'])
self.data['hp'] = hp
k = self.data['pl_m'] * 3 * 10**8 * self.data['v'] * (
4 * self.data['hp'] + self.data['dp']
) / (self.data['dp'] + 2 * self.data['hp']) * self.data['hb'] / (
self.data['list_q[0]'] -
self.data['list_q[1]']) * 2 / (math.pi * self.data['db']**2)
self.data['k'] = k
def calc_uncertainty_d(self):
# 计算光程差d的a,b及总不确定度
Ua_2xita1 = Method.a_uncertainty(
self.data['list_d_2xita1']) # 这里容易写错,一定要用原始数据的数组
Ub_2xita1 = 1.679e-4
U_xita1 = sqrt(Ub_2xita1**2 + Ua_2xita1**2) / 2
Ud1 = abs(self.data['d1'] * U_xita1 /
tan(self.data['d_xita1_average']))
Ub_2xita2 = 1.679e-4
Ud2 = abs(self.data['d2'] * Ub_2xita2 /
(2 * tan(3.14 * self.data['d_2xita2'] / 360)))
self.uncertainty.update({
"Ua_2xita1": Ua_2xita1,
"Ub_2xita1": Ub_2xita1,
"Ua_xita1": Ua_2xita1 / 2,
"Ub_xita1": Ub_2xita1 / 2,
"U_xita1": U_xita1,
"Ud1": Ud1,
"Ub_2xita2": Ub_2xita2,
"Ub_xita2": Ub_2xita2 / 2,
"Ud2": Ud2
})
d1 = self.data['d1']
d2 = self.data['d2']
d_av = (d1 / (Ud1**2) + d2 / (Ud2**2)) / (1 / (Ud1**2) + 1 / (Ud2**2))
Ud_av = sqrt((Ud1**2) * (Ud2**2) / (Ud1**2) + (Ud2**2))
self.uncertainty.update({"d_av": d_av, "Ud_av": Ud_av})
self.data['final1'] = Method.final_expression(d_av, Ud_av)
def calc_uncertainty(self):
# 计算一元线性回归的不确定度
num_u_b = self.data['num_b'] * sqrt((1 / (self.data['num_r'] ** 2) - 1) / (8 - 2))
self.data['num_u_b'] = num_u_b
# 计算直径D的不确定度
num_ua_D = Method.a_uncertainty(self.data['list_D'])
num_ub_D = 0.03 / sqrt(3) /1000
num_u_D = sqrt(num_ua_D ** 2 + num_ub_D ** 2)
self.data.update({"num_ua_D":num_ua_D, "num_ub_D":num_ub_D, "num_u_D":num_u_D})
# 电阻率不确定度的合成
num_u_rho_rho = sqrt((num_u_D / self.data['num_D']) ** 2 + (num_u_b / self.data['num_b']) ** 2)
num_rho = self.data['num_rho']
num_u_rho = num_u_rho_rho * num_rho
self.data.update({"num_u_rho_rho": num_u_rho_rho, "num_u_rho": num_u_rho})
# 输出带不确定度的最终结果: 不确定度保留一位有效数字, 物理量结果与不确定度首位有效数字对齐
self.data['final_1'] = Method.final_expression(self.data['num_rho'], self.data['num_u_rho'])
# 单电桥测电阻
# 灵敏度分析
num_S = self.data['num_delta_n'] / self.data['num_delta_R_3']
num_delta_lmd = 0.2 / num_S
num_u_lmd = num_delta_lmd / sqrt(3)
self.data.update({"num_S": num_S, "num_delta_lmd":num_delta_lmd, "num_u_lmd":num_u_lmd})
# 仪器误差
num_delta_yi = InstrumentError.dc_bridge(self.data['num_a_pct'], self.data['num_R_3'],self.data['num_R_0'])
num_u_yi = num_delta_yi / sqrt(3)
num_u_R_x = sqrt(num_u_yi ** 2 + num_u_lmd ** 2)
self.data.update({"num_delta_yi": num_delta_yi, "num_u_yi": num_u_yi, "num_u_R_x": num_u_R_x})
# 输出带不确定度的最终结果: 不确定度保留一位有效数字, 物理量结果与不确定度首位有效数字对齐
self.data['final_2'] = Method.final_expression(self.data['num_R_3'], self.data['num_u_R_x'])
print(self.data['final_2'])
def calc_uncertainty(self):
# 计算不确定度
ub_d = 0.001 / sqrt(3)
ua_d0 = Method.a_uncertainty(self.data['ld']) # 这里容易写错,一定要用原始数据的数组
u_d0 = sqrt(ua_d0**2 + ub_d**2)
ua_dy = Method.a_uncertainty(self.data['yd'])
u_dy = sqrt(ua_dy**2 + ub_d**2)
u_lambda_y = self.data['lambda_y'] * sqrt(
(u_dy / self.data['yd_avg'])**2 + (u_d0 / self.data['ld_avg'])**2)
self.data.update({
"ub_d": ub_d,
"ua_d0": ua_d0,
"u_d0": u_d0,
"ua_dy": ua_dy,
"u_dy": u_dy,
"u_lambda_y": u_lambda_y
})
ua_dg = Method.a_uncertainty(self.data['gd'])
u_dg = sqrt(ua_dg**2 + ub_d**2)
u_lambda_g = self.data['lambda_g'] * sqrt(
(u_dg / self.data['gd_avg'])**2 + (u_d0 / self.data['ld_avg'])**2)
ua_dp = Method.a_uncertainty(self.data['pd'])
u_dp = sqrt(ua_dp**2 + ub_d**2)
u_lambda_p = self.data['lambda_p'] * sqrt(
(u_dp / self.data['pd_avg'])**2 + (u_d0 / self.data['ld_avg'])**2)
self.data.update({
"ua_dg": ua_dg,
"u_dg": u_dg,
"u_lambda_g": u_lambda_g,
"ua_dp": ua_dp,
"u_dp": u_dp,
"u_lambda_p": u_lambda_p
})
def calc_uncertainty_detail(data_list, result_list):
sunc = Simplified()
uncertain_data = {}
ua_10delta_x = Method.a_uncertainty(result_list['diff_10delta_x'])
ub_10delta_x = sunc.micrometer / sqrt(3)
u_10delta_x = sqrt(ua_10delta_x**2 + ub_10delta_x**2)
u_delta_x = u_10delta_x / 10
ub_S = sqrt((sunc.steel_ruler / 10 / sqrt(3))**2 +
(data_list['delta_s'] / sqrt(3))**2)
ub_b = sqrt((sunc.micrometer / sqrt(3))**2 +
(data_list['delta_b_b'] * result_list['b'] / sqrt(3))**2)
ub_b1 = sqrt((sunc.micrometer / sqrt(3))**2 +
(data_list['delta_b_b'] * result_list['b1'] / sqrt(3))**2)
u_lbd_lbd = sqrt((u_delta_x / result_list['delta_x'])**2 +
(ub_b / result_list['b'] / 2)**2 +
(ub_b1 / result_list['b1'] / 2)**2 + 2 *
((ub_S / (result_list['S'] + result_list['S1']))**2))
u_lbd = u_lbd_lbd * result_list['result_lambda']
final_lbd = Method.final_expression(result_list['result_lambda'],
u_lbd)
uncertain_data['ua_10delta_x'] = ua_10delta_x
uncertain_data['ub_10delta_x'] = ub_10delta_x
uncertain_data['u_10delta_x'] = u_10delta_x
uncertain_data['u_delta_x'] = u_delta_x
uncertain_data['u_S'] = ub_S
uncertain_data['u_b'] = ub_b
uncertain_data['u_b1'] = ub_b1
uncertain_data['u_lbd_lbd'] = u_lbd_lbd
uncertain_data['u_lbd'] = u_lbd
uncertain_data['final'] = final_lbd
return uncertain_data
def calc_uncertainty3(self):
# 计算顶角A的a,b及总不确定度
ua_delta = Method.a_uncertainty(
self.data['list_delta']) # 这里容易写错,一定要用原始数据的数组
ub_delta = (1 / 60) / sqrt(3)
u_delta = sqrt(ua_delta**2 + ub_delta**2)
self.data.update({
"ua_delta": ua_delta,
"ub_delta": ub_delta,
"u_delta": u_delta
})
part_1 = -1 / sin(self.data['aver_A'] / 180 * pi) - sin(
self.data['aver_delta'] / 180 * pi) * cos(
self.data['aver_A'] / 180 * pi) / (sin(
self.data['aver_A'] / 180 * pi)**2)
part_4 = (cos(self.data['aver_A'] / 180 * pi) +
sin(self.data['aver_delta'] / 180 * pi)) / sin(
self.data['aver_A'] / 180 * pi)
n_delta = cos(
self.data['aver_delta'] / 180 * pi) * part_4 / self.data['n2']
n_A = part_1 * part_4 / self.data['n2']
u_n2 = sqrt((n_delta * u_delta / 180 * pi)**2 +
(n_A * self.data['u_A'] / 180 * pi)**2)
self.data['u_n2'] = u_n2
self.data['final_n2'] = Method.final_expression(self.data['n2'], u_n2)
def __init__(self):
self.data = {} # 存放实验中的各个物理量
self.uncertainty = {} # 存放物理量的不确定度
self.report_data = {} # 存放需要填入实验报告的
print("1081 光的干涉实验\n1. 实验预习\n2. 数据处理")
while True:
try:
oper = input("请选择: ").strip()
except EOFError:
sys.exit(0)
if oper != '1' and oper != '2':
print("输入内容非法!请输入一个数字1或2")
else:
break
if oper == '1':
print("现在开始实验预习")
print("正在打开预习报告......")
Method.start_file(self.PREVIEW_FILENAME)
elif oper == '2':
print("该实验没有自动数据处理")
print("正在生成实验报告......")
# 生成实验报告
self.fill_report()
print("实验报告生成完毕,正在打开......")
Method.start_file(self.REPORT_OUTPUT_FILENAME)
print("Done!")
def calc_uncertainty1(self):
# 计算顶角A的a,b及总不确定度
ua_A = Method.a_uncertainty(self.data['list_A']) # 这里容易写错,一定要用原始数据的数组
ub_A = (1 / 60) / sqrt(3) / 2
u_A = sqrt(ua_A**2 + ub_A**2)
self.data.update({"ua_A": ua_A, "ub_A": ub_A, "u_A": u_A})
self.data['final_A'] = Method.final_expression(self.data['aver_A'],
u_A)
def calc_data(self):
# list_dif_d 长度为x折半的数组,为逐差相减的结果
# num_d 逐差法求得的平均值
list_dtx = []
for i in range(0, 10):
list_dtx.append(
(self.data['list_d2'][i] - self.data['list_d1'][i]) / 30)
num_d = Method.average(list_dtx)
num_dt_l = 30 * num_d
num_lbd = 2 * num_d
self.data['list_dtx'] = list_dtx
self.data['num_d'] = num_d
# num_lbd = round(num_lbd,5)
num_ave_f = (float(
(self.data['list_f'][0] + self.data['list_f'][1]) / 2.0))
num_delta_f = abs(self.data['list_f'][0] -
self.data['list_f'][1]) / 2.0
num_f = num_ave_f
num_c = num_lbd * num_f
self.data['num_lbd'] = num_lbd
self.data['num_ave_f'] = num_ave_f
self.data['num_delta_f'] = num_delta_f
self.data['num_u_f'] = num_delta_f / sqrt(3)
self.data['num_c'] = num_c
self.data['num_f'] = num_f
def calc_data_detail(data_list):
result_data = {}
diff_10delta_x, aver_10delta_x = Method.successive_diff(
data_list['exp_data'])
delta_x = aver_10delta_x / 10
b = abs(data_list['bL'] - data_list['bR'])
b1 = abs(data_list['b1L'] - data_list['b1R'])
a = sqrt(b * b1)
S = abs(data_list['K'] - data_list['L2'])
S1 = abs(data_list['K'] - data_list['L1'])
D = S + S1
result_lambda = a / D * delta_x * 100000
error = abs(result_lambda -
data_list['lambda_0']) / data_list['lambda_0'] * 100
result_data['diff_10delta_x'] = diff_10delta_x
result_data['aver_10delta_x'] = aver_10delta_x
result_data['delta_x'] = delta_x
result_data['b'] = b
result_data['b1'] = b1
result_data['a'] = a
result_data['S'] = S
result_data['S1'] = S1
result_data['D'] = D
result_data['result_lambda'] = result_lambda
result_data['error'] = error
return result_data
def calc_uncertainty(self):
# 计算线性拟合的A类不确定度
Sigma = 0
for i in range(0, len(self.data['X'])):
Sigma += (self.data['Y'][i] - (self.data['b'] + self.data['a'] * self.data['X'][i]))**2
k = len(self.data['X'])
ua_B = (Sigma / (k - 2))**(1 / 2)
ua_a = self.data['b'] * (((1 / self.data['r']**2 - 1) / (k - 2))**(1 / 2))
X_square = []
for i in range(0, k):
X_square[i] = self.data['X'][i]**2
ua_b = ua_a * (Method.average(X_square)**(1 / 2))
self.data.update({"ua_B":ua_B, "ua_a":ua_a, "ua_b":ua_b})
# 求theta的B类不确定度,分别合成不同V的不确定度,计算加权平均后V_avg的不确定度
ub_theta = 1 / math.sqrt(3) * math.pi / 180
u_V = []
for i in range(0, 4):
u_V.append(self.data['V'][i] * math.sqrt(1 / self.data['Theta'][i]**2 * ub_theta**2 + 1 / self.data['Magnetic_induction2'][i]**2 * ua_B**2))
u_V1 = u_V[0]
u_V2 = u_V[1]
u_V3 = u_V[2]
u_V4 = u_V[3]
u2_Vavg = 1 / (u_V1**(-2) + u_V2**(-2) + u_V3**(-2) + u_V4**(-2))
u_Vavg = math.sqrt(u2_Vavg)
V_avg = u2_Vavg * (self.data['V'][0] / u_V1**2 + self.data['V'][1] / u_V2**2 + self.data['V'][2] / u_V3**2 + self.data['V'][3] / u_V4**2)
self.data.update({"ub_theta":ub_theta, "u_V1":u_V1, "u_V2":u_V2, "u_V3":u_V3, "u_V4":u_V4, "u_Vavg":u_Vavg, "V_avg":V_avg})
def calc_data_2(self):
i = 0
self.data['x_1'] = list_x_1 = []
self.data['x_2'] = list_x_2 = []
self.data["list_f"] = list_f = []
while i<5 :
list_f[i] = (list_x_1[i] + list_x_2[i])/2 - pl_x
i = i + 1
self.data["num_f"] = num_f = Method.average(self.data['list_f'])
def calc_uncertainty(self):
# 计算光程差d的a,b及总不确定度
ua_d = Method.a_uncertainty(self.data['list_d']) # 这里容易写错,一定要用原始数据的数组
ub_d = 0.00005 / sqrt(3)
u_d = sqrt(ua_d**2 + ub_d**2)
self.uncertainty.update({"ua_d": ua_d, "ub_d": ub_d, "u_d": u_d})
# 计算圈数N的不确定度
N = self.data['N']
u_N = 1 / sqrt(3)
self.uncertainty['u_N'] = u_N
d, N = self.data['d'], self.data['N']
# 波长的不确定度合成
u_lbd_lbd = sqrt((u_d / d)**2 + (u_N / N)**2)
lbd = self.data['lbd']
u_lbd = u_lbd_lbd * lbd
self.uncertainty.update({"u_lbd_lbd": u_lbd_lbd, "u_lbd": u_lbd})
# 输出带不确定度的最终结果: 不确定度保留一位有效数字, 物理量结果与不确定度首位有效数字对齐
self.data['final'] = Method.final_expression(lbd, u_lbd)
def calc_data1(self):
list_A = []
for rows in self.data['list_data'][0]:
row = []
for item in rows:
value_degree = Method.degree_trans(item)
if (value_degree > 1000) | (value_degree < -1000):
print('数据出现错误,请检查实验表格第' +
str(self.data['list_data'].index(rows) + 4) + '行第' +
str(rows.index(item) + 2) + '列的度和分是否以空格分隔')
else:
row.append(value_degree)
value_A = (row[3] + row[2] - row[1] - row[0]) / 4
if value_A < 0:
value_A = value_A + 90
list_A.append(value_A)
aver_A = Method.average(list_A)
self.data['list_A'] = list_A
self.data['aver_A'] = aver_A
def calc_data(self):
# 求直径D的平均值
num_D = Method.average(self.data['list_D'])
self.data['num_D'] = num_D
# 一元线性回归求电阻率
num_b, num_a, num_r = Fitting.linear(self.data['list_l'], self.data['list_R_x'])
self.data['num_b'] = num_b
self.data['num_r'] = num_r
num_rho = math.pi * num_D * num_D * num_b / 4
self.data['num_rho']=num_rho
def calc_data_3(self):
i = 0
self.data['list_3_f'] = list_3_f = []
self.data['list_a'] = list_a = []
self.data['list_b'] = list_b = []
self.data['overline_3_f'] = overline_3_f
while i<5 :
list_3_f[i] = ( list_a[i]^2 - list_b[i]^2 ) / 4*list_b[i]
i = i + 1
overline_3_f = Method.average(self.data['list_3_f'])
def calc_uncertainty2(self):
# 计算顶角A的a,b及总不确定度
ua_delta_m = Method.a_uncertainty(
self.data['list_delta_m']) # 这里容易写错,一定要用原始数据的数组
ub_delta_m = (1 / 60) / sqrt(3)
u_delta_m = sqrt(ua_delta_m**2 + ub_delta_m**2)
self.data.update({
"ua_delta_m": ua_delta_m,
"ub_delta_m": ub_delta_m,
"u_delta_m": u_delta_m
})
part_1 = cos((self.data['aver_delta_m'] / 180 * pi +
self.data['aver_A'] / 180 * pi) / 2)
part_4 = sin(self.data['aver_A'] / 180 * pi / 2)
n_delta_m = 0.5 * part_1 / part_4
n_A = -sin(self.data['aver_delta_m'] / 180 * pi / 2) / 2 / (part_4**2)
u_n1 = sqrt((n_delta_m * u_delta_m / 180 * pi)**2 +
(n_A * self.data['u_A'] / 180 * pi)**2)
self.data['u_n1'] = u_n1
self.data['final_n1'] = Method.final_expression(self.data['n1'], u_n1)
def calc_data(self):
N = 100
self.data['N'] = N
# 逐差法计算100圈光程差d
dif_d_arr, d = Method.successive_diff(self.data['d_arr'])
self.data['dif_d_arr'] = dif_d_arr
self.data['d'] = d
# 按公式计算待测光的波长
lbd = 2 * d / (len(dif_d_arr) * N)
lbd = lbd * 1e6
self.data['lbd'] = lbd
def calc_data(self):
N = 100
self.data['N'] = N
# 逐差法计算100圈光程差d
list_dif_d, d = Method.successive_diff(self.data['list_d'])
self.data['list_dif_d'] = list_dif_d
self.data['d'] = d
# 按公式计算待测光的波长
lbd = 2 * d / (len(list_dif_d) * N)
lbd = lbd * 1e6
self.data['lbd'] = lbd
def calc_uncertainty(self):
# 计算光程差d的a,b及总不确定度
ua_d = Method.a_uncertainty(self.data['d_arr']) # 这里容易写错,一定要用原始数据的数组
ub_d = 0.00005 / sqrt(3)
u_d = sqrt(ua_d**2 + ub_d**2)
self.data.update({"ua_d": ua_d, "ub_d": ub_d, "u_d": u_d})
# 计算圈数N的不确定度
N = self.data['N']
u_N = 1 / sqrt(3)
self.data['u_N'] = u_N
d, N = self.data['d'], self.data['N']
# 波长的不确定度合成
u_lbd_lbd = sqrt((u_d / d)**2 + (u_N / N)**2)
lbd = self.data['lbd']
u_lbd = u_lbd_lbd * lbd
self.data.update({"u_lbd_lbd": u_lbd_lbd, "u_lbd": u_lbd})
# 输出带不确定度的最终结果
# TODO: 输出最终结果的修约方法稍稍有点问题,待修改
bse, pwr = Method.scientific_notation(u_lbd)
lbd_f = int(lbd * (10**pwr)) / (10**pwr) # 保留有效数字,截断处理
self.data['final'] = "%.0f±%.0f" % (lbd_f, bse)
def calc_uncertainty(self):
num_sum = 0
for i in range(0, 8):
num_sum += (self.data['list_Y'][i] -
self.data['list_X'][i] * self.data['num_a'])**2
num_u_A = sqrt(num_sum / (48 * 21))
num_u_E = num_u_A * self.data['num_para']
num_eta = abs(self.data['num_E'] - 70 * 1e9) / (70 * 1e9) * 100
self.data['num_u_A'] = num_u_A
self.data['num_u_E'] = num_u_E
self.data['num_eta'] = num_eta
self.data['final'] = Method.final_expression(
self.data['num_E'] / 1e9, self.data['num_u_E'] / 1e9)
def calc_data(self):
# 计算间距
yd = [], gd = [], pd = [], ld = []
for i in range(0, 6):
yd[i] = self.data['yl'][i] - self.data['yr'][i]
gd[i] = self.data['gl'][i] - self.data['gr'][i]
pd[i] = self.data['pl'][i] - self.data['pr'][i]
ld[i] = self.data['ll'][i] - self.data['lr'][i]
self.data['yd'] = yd, self.data['gd'] = gd, self.data[
'pd'] = pd, self.data['ld'] = ld
yd_avg = Method.average(yd)
gd_avg = Method.average(gd)
pd_avg = Method.average(pd)
ld_avg = Method.average(ld)
self.data['yd_avg'] = yd_avg, self.data['gd_avg'] = gd_avg, self.data[
'pd_avg'] = pd_avg, self.data['ld_avg'] = ld_avg
# 计算波长
lambda_y = yd_avg / ld_avg * self.data['lambda_0']
lambda_g = gd_avg / ld_avg * self.data['lambda_0']
lambda_p = pd_avg / ld_avg * self.data['lambda_0']
self.data['lambda_y'] = lambda_y, self.data[
'lambda_g'] = lambda_g, self.data['lambda_p'] = lambda_p
def calc_uncertainty(self):
list_tmp = []
for i in self.data['list_dtx']:
list_tmp.append(i * 0.001 / 15)
# num_ua_d = sqrt( (Method.variance(self.data['list_d'])) / (10 * 9) )
num_ua_d = Method.a_uncertainty(list_tmp)
# print(num_ua_d)
num_ub1_d = 0.005 / sqrt(3)
num_ub2_d = 0.1 / sqrt(3)
num_u_d = sqrt(num_ua_d**2 + num_ub1_d**2 + num_ub2_d**2)
self.data.update({
"num_ua_d": num_ua_d,
"num_ub1_d": num_ub1_d,
"num_ub2_d": num_ub2_d,
"num_u_d": num_u_d
})
num_d = self.data['num_d']
num_lbd = self.data['num_lbd']
num_c = self.data['num_c']
num_f = self.data['num_f']
num_u_f = self.data['num_u_f']
num_u_lbd = 2 * num_u_d
num_u_c_c = sqrt((num_u_lbd / num_lbd)**2 + (num_u_f / num_f)**2)
num_u_c = num_u_c_c * num_c
self.data['num_u_c'] = num_u_c
self.data['num_u_c_c'] = num_u_c_c
self.data.update({"num_u_lbd": num_u_lbd})
num_u_lbd_1bit, pwr = Method.scientific_notation(num_u_lbd)
num_u_f_1bit, pwr = Method.scientific_notation(
num_u_f) # 将不确定度转化为只有一位有效数字的科学计数法
num_u_c_1bit, pwr = Method.scientific_notation(
num_u_c) # 将不确定度转化为只有一位有效数字的科学计数法
num_fin_lbd = int(num_lbd * (10**pwr)) / (10**pwr) # 对物理量保留有效数字,截断处理
num_fin_f = int(num_f * (10**pwr)) / (10**pwr)
num_fin_c = int(num_c * (10**pwr)) / (10**pwr)
self.data['num_fin_c'] = "%.2f±%.2f" % (num_fin_c, num_u_c_1bit)
self.data['num_fin_f'] = "%.0f±%.0f" % (num_fin_f, num_u_f_1bit)
self.data['num_fin_lbd'] = "%.0f±%.0f" % (num_fin_lbd, num_u_lbd_1bit)
def calc_data(self):
x = arr_k = asarray(self.data['arr_k'])
y = arr_D_sq = asarray(self.data['arr_D_sq'])
b, a, r = Fitting.linear(x, y)
self.data['b'] = b
self.data['a'] = a
self.data['r'] = r
x_mean = Method.average(x)
y_mean = Method.average(y)
x_sq_mean = Method.average(x ** 2)
y_sq_mean = Method.average(y ** 2)
xy_mean = Method.average(x * y)
self.data['x_mean'] = x_mean
self.data['y_mean'] = y_mean
self.data['x_sq_mean'] = x_sq_mean
self.data['y_sq_mean'] = y_sq_mean
self.data['xy_mean'] = xy_mean
lbd = self.data['lambda'] * 1e-6
R = b / (4 * lbd)
self.data['R'] = R
pass
def calc_data2(self):
list_delta_m = []
for rows in self.data['list_data'][1]:
row = []
for item in rows:
value_degree = Method.degree_trans(item)
if (value_degree > 1000) | (value_degree < -1000):
print('数据出现错误,请检查实验表格第' +
str(self.data['list_data'].index(rows) + 4) + '行第' +
str(rows.index(item) + 8) + '列的度和分是否以空格分隔')
else:
row.append(value_degree)
value_delta_m = (row[3] + row[2] - row[1] - row[0]) / 2
if value_delta_m < 0:
value_delta_m = value_delta_m + 180
list_delta_m.append(value_delta_m)
delta_m = Method.average(list_delta_m)
n1 = float(
sin((delta_m + self.data['aver_A']) / 360 * pi) /
sin(self.data['aver_A'] / 360 * pi))
self.data['list_delta_m'] = list_delta_m
self.data['aver_delta_m'] = delta_m
self.data['n1'] = n1
def calc_uncertainty(self):
Ua = Method.a_uncertainty(self.data['list_dif_d']) # a类不确定度
Ub = 0.1 / (numpy.sqrt(3)) # b类不确定度
U = numpy.sqrt(numpy.square(Ua) + numpy.square(Ub)) # 总的不确定度
self.data.update({"Ua": Ua, "Ub": Ub, "U": U})
ave_d = self.data['ave_d']
#res_final, unc_final, pwr = Method.final_expression(ave_d,U)
#self.data['final'] = "(%s±%s)*10e(%s)"%(res_final,unc_final,pwr)
#base_U, pwr = Method.scientific_notation(U) #将不确定度转化为只有一位有效数字的科学计数法
#volt_final = int(ave_d *(10**pwr))/(10 ** pwr) #对物理量保留有效数字,截断处理
self.data['final'] = "%.1f±%.1f" % (ave_d, U)
self.data['relative_error'] = abs(
(float(int(ave_d * 10) / 10 - 11.55)) / 11.55)
def calc_data3(self):
list_delta = []
for rows in self.data['list_data'][2]:
row = []
for item in rows:
value_degree = Method.degree_trans(item)
if (value_degree > 1000) | (value_degree < -1000):
print('数据出现错误,请检查实验表格第' +
str(self.data['list_data'].index(rows) + 4) + '行第' +
str(rows.index(item) + 14) + '列的度和分是否以空格分隔')
else:
row.append(value_degree)
value_delta = (row[0] + row[1] - row[2] - row[3]) / 2
if value_delta < 0:
value_delta = value_delta + 180
list_delta.append(value_delta)
delta = Method.average(list_delta)
n2 = float(
sqrt((
(cos(self.data['aver_A'] / 180 * pi) + sin(delta / 180 * pi)) /
sin(self.data['aver_A'] / 180 * pi))**2 + 1))
self.data['list_delta'] = list_delta
self.data['aver_delta'] = delta
self.data['n2'] = n2
def calc_uncertainty(self):
b = self.data['b']
n = len(self.data['arr_D'])
r = self.data['r']
lbd = self.data['lambda'] * 1e-6
ua_b = b * sqrt((1 / (n - 2)) * ((1 / (r ** 2)) - 1))
ub_b = 0.005 / sqrt(3)
u_b = sqrt(ua_b ** 2 + ub_b ** 2)
u_R = u_b / (4 * lbd)
R = self.data['R']
res, unc, pwr = Method.final_expression(R, u_R)
self.uncertainty['ua_b'] = ua_b
self.uncertainty['ub_b'] = ub_b
self.uncertainty['u_b'] = u_b
self.uncertainty['u_R'] = u_R
self.data['final'] = "(%.0f ± %.0f)e%d" % (res, unc, int(pwr))
pass
def calc_data(self):
list_phi_1 = []
i = 0
while i < 8:
list_phi_1[i] = asin(sin(list_phi_0[i]) / num_n)
i = i + 1
self.data['list_phi_1'] = list_phi_1
list_num_b = []
list_num_b = Method.linear(list_f_s , list_phi_1)
num_b = list_num_b[0]
self.data['num_b'] = num_b
num_v_s = num_lambda_0 * num_b / num_n
self.data[' num_v_s'] = num_v_s
num_percent = abs( num_v_s - num_v_0 ) / num_v_0 * 100
self.data[' num_percent'] = num_percent
def calc_uncertainty(self):
list_a = []
list_x = self.data['list_x']
list_y = self.data['list_y']
list_graph2 = self.data['list_graph2']
voltage_begin = self.data['voltage_begin']
voltage_end = self.data['voltage_end']
resitence = self.data['resitence']
c1 = self.data['c1']
c0 = self.data['c0']
list_weight = self.data['list_weight']
m_water = list_weight[1] - list_weight[0]
for i in range(len(list_x)):
list_a.append(list_y[i] - list_graph2[1] * list_x[i])
self.data['list_a'] = list_a
Ua = Method.a_uncertainty(self.data['list_a'])
self.data['Ua'] = Ua
UJ = abs(
((voltage_begin + voltage_end) / 2)**2 /
(Ua * resitence *
(c0 * m_water * 0.001 + c1 * list_weight[3] * 0.001 + 64.38)))
self.data['UJ'] = UJ