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_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_data(self):
# 实验一
# TODO ua_rx和ub_rx的计算方式有点问题 (不知道那个k是个什么物理量啊)
num_b, num_a, num_r = Fitting.linear(self.data['list_x'],
self.data['list_y'], False)
self.data['num_a'] = num_a
self.data['num_b'] = num_b
self.data['num_r'] = num_r
num_rx = num_b
list_k = []
for i in range(0, 8):
list_k.append(self.data['list_x'][i] / self.data['list_y'][i])
# num_ua_b = Method.a_uncertainty(list_k)
num_k = 8
num_ave_x = Method.average(self.data['list_x'])
num_ave_y = Method.average(self.data['list_y'])
num_ua_b = num_b * (1 / (num_k - 2) * ((1 / num_r)**2 - 1))**(1 / 2)
num_u_u = 0.00433
num_u_i = 0.0000433
num_ub_rx_rx = sqrt((num_u_u / num_ave_y)**2 +
(num_u_i / num_ave_x)**2)
num_ub_rx = num_ub_rx_rx * num_rx
num_u_rx = (num_ub_rx**2 + num_ua_b**2)**(1 / 2)
num_u_rx_1bit, pwr = Method.scientific_notation(num_u_rx)
num_fin_rx = int(num_rx * (10**pwr)) / (10**pwr)
self.data['num_ave_y'] = num_ave_y
self.data['num_ave_x'] = num_ave_x
self.data['num_ub_rx'] = num_ub_rx
self.data['num_ub_rx_rx'] = num_ub_rx_rx
self.data['num_u_u'] = num_u_u
self.data['num_u_i'] = num_u_i
self.data['num_rx'] = num_rx
self.data['num_ua_b'] = num_ua_b
self.data['num_u_rx'] = num_u_rx
self.data['str_fin_rx'] = "%.0f±%.0f" % (num_fin_rx, num_u_rx_1bit)
# 实验二
num_2r1 = self.data['list_2'][0]
num_2u = self.data['list_2'][1]
num_2r0 = self.data['list_2'][2]
num_2d = self.data['list_2'][3]
num_2r2 = self.data['list_2'][4]
num_2rg = num_2r2
num_2ki = (num_2r1 * num_2u) / ((num_2r0 + num_2r1) * num_2rg * num_2d)
num_dt_2r0 = InstrumentError.resistance_box(self.data['list_a0'],
self.data['list_r0'],
self.data['list_rbox0'][0])
num_dt_2r1 = InstrumentError.resistance_box(self.data['list_a1'],
self.data['list_r1'],
self.data['list_rbox0'][1])
num_dt_2r2 = InstrumentError.resistance_box(self.data['list_a2'],
self.data['list_r2'],
self.data['list_rbox0'][2])
num_u_2r0 = num_dt_2r0 / sqrt(3)
num_u_2r1 = num_dt_2r1 / sqrt(3)
num_u_2r2 = num_dt_2r2 / sqrt(3)
num_u_2u = 0.005 * 3 / sqrt(3)
num_u_2d = 1 / sqrt(3)
num_u_2r1_2r0 = sqrt((num_u_2r1)**2 + (num_u_2r0)**2)
num_u_2ki_2ki = sqrt((num_u_2r1 / num_2r1)**2 +
(num_u_2r1_2r0 / (num_2r0 + num_2r1))**2 +
(num_u_2u / num_2u)**2 +
(num_u_2r2 / num_2r2)**2 + (num_u_2d / num_2d)**2)
num_u_2ki = num_u_2ki_2ki * num_2ki
num_u_2rg_1bit, pwr = Method.scientific_notation(num_u_2r2)
num_fin_rg = int(num_rx * (10**pwr)) / (10**pwr)
num_u_2ki_1bit, pwr = Method.scientific_notation(num_u_2ki)
num_fin_ki = int(num_rx * (10**pwr)) / (10**pwr)
self.data['str_fin_ki'] = "%.3f±%.3f" % (num_fin_ki, num_u_2ki_1bit)
self.data['str_fin_rg'] = "%.0f±%.0f" % (num_fin_rg, num_u_2rg_1bit)
self.data['num_dt_2r0'] = num_dt_2r0
self.data['num_dt_2r1'] = num_dt_2r1
self.data['num_dt_2r2'] = num_dt_2r2
self.data['num_2r1'] = num_2r1
self.data['num_2r2'] = num_2r2
self.data['num_2r0'] = num_2r0
self.data['num_2d'] = num_2d
self.data['num_2u'] = num_2u
self.data['num_u_2u'] = num_u_2u
self.data['num_u_2d'] = num_u_2d
self.data['num_u_2r1_2r0'] = num_u_2r1_2r0
self.data['num_u_2ki_2ki'] = num_u_2ki_2ki
self.data['num_u_2ki'] = num_u_2ki
self.data['num_2ki'] = num_2ki
# 实验三
num_3rs = self.data['list_3'][0]
num_3v = self.data['list_3'][1]
num_3d = self.data['list_3'][2]
num_3rg = self.data['list_3'][3]
num_3ki = self.data['list_3'][4]
num_u3_Nm1 = self.data['list_3'][7]
num_u3_Nm2 = self.data['list_3'][8]
num_u3_d = self.data['list_3'][9]
num_u3_a1 = self.data['list_3'][5]
num_u3_a2 = self.data['list_3'][6]
num_u3_rg = self.data['list_3'][10]
num_u3_ki = self.data['list_3'][11]
num_3rxh = num_3rs / ((num_3rg + num_3rs) * num_3ki) * num_3v / num_3d
num_u3_rs = InstrumentError.electromagnetic_instrument(
num_u3_a1, num_u3_Nm1) / sqrt(3)
num_u3_v = InstrumentError.electromagnetic_instrument(
num_u3_a2, num_u3_Nm2) / sqrt(3)
num_u3_r = (num_u3_rg**2 + num_u3_rs**2)**(1 / 2)
num_u3_rxh_rxh = ((num_u3_rs / num_3rs)**2 + (num_u3_r / num_3rs)**2 +
(num_u3_v / num_3v)**2 + (num_u3_ki / num_3ki)**2 +
(num_u3_d / num_3d)**2)**(1 / 2)
num_u3_rxh = num_u3_rxh_rxh * num_3rxh
num_u3_rxh_1bit, pwr = Method.scientific_notation(num_u3_rxh)
num_fin_rxh = int(num_3rxh * (10**pwr)) / (10**pwr)
self.data['str_fin_rxh'] = "%.3f±%.3f" % (num_fin_rxh, num_u3_rxh_1bit)
self.data['num_3rxh'] = num_3rxh
self.data['num_u3_rs'] = num_u3_rs
self.data['num_u3_v'] = num_u3_v
self.data['num_u3_r'] = num_u3_r
self.data['num_u3_rxh_rxh'] = num_u3_rxh_rxh
self.data['num_u3_rxh'] = num_u3_rxh
self.data['num_3rs'] = num_3rs
self.data['num_3v'] = num_3v
self.data['num_3d'] = num_3d
self.data['num_3rg'] = num_3rg
self.data['num_3ki'] = num_3ki
self.data['num_u3_Nm1'] = num_u3_Nm1
self.data['num_u3_Nm2'] = num_u3_Nm2
self.data['num_2ki'] = num_2ki
self.data['num_u3_d'] = num_u3_d
self.data['num_u3_a1'] = num_u3_a1
self.data['num_u3_a2'] = num_u3_a2
self.data['num_u3_rg'] = num_u3_rg
self.data['num_u3_ki'] = num_u3_ki