ÿÿ!´ÿÿ’!Ã5×  00<!<&00‹wG0U=220000000008A:?D>RU„P¦üR¨þTßW>L ; *¡nÄpÆrî²qp]k‡!÷$ü Start Time  c. c   Stop Time c. c  Censor  c. c  Freq  c. c   Temp in C  c. c  Volt  c. c  1/kT cc/'Formula(11605 / ( :Temp in C + 273.16))ÿÿÿÿ c  ln V cPFormula(Log( :Volt))ÿÿÿÿ c  Loss (w/o Stress) c¿‹ƒFormula(Parameter({charlife = 220.740881686207, Shape = 0.677505224351048}, w1 = IfMZ( :Start Time > 0, Shape * (Log( :Start Time) - Log(charlife)), -Exp(20)); w2 = Shape * (Log( :Stop Time) - Log(charlife)); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Shape) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c   Loss (w/Temp) c沪Formula(Parameter({DELTAH = 1, Con = -25, Shape = 1}, w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - (Con + :Name("1/kT") * Abs(DELTAH))), -Exp(20)); w2 = Abs(Shape) * (Log( :Stop Time) - (Con + :Name("1/kT") * Abs(DELTAH))); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c  Loss (w/Ln Volt) cÇ“‹Formula(Parameter({Con = 10, Shape = 1, BETA = 1}, w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - (Con + :ln V * -BETA)), -Exp(20)); w2 = Abs(Shape) * (Log( :Stop Time) - (Con + :ln V * -BETA)); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c   Loss (w/Volt) cÇ“‹Formula(Parameter({Con = 10, Shape = 1, BETA = 1}, w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - (Con + :Volt * -BETA)), -Exp(20)); w2 = Abs(Shape) * (Log( :Stop Time) - (Con + :Volt * -BETA)); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c  Loss (Temp/Ln Volt) cOFormula(Parameter({DELTAH = 0.822238406123016, Con = 20.7265255726042, Shape = 1.16221780578203, BETA = 45.1097569934255}, w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - (Con + :Name("1/kT") * Abs(DELTAH) + :ln V * -BETA)), -Exp(20)); w2 = Abs(Shape) * (Log( :Stop Time) - (Con + ( :Name("1/kT") * Abs(DELTAH) + :ln V * -BETA))); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c  Loss (Temp/Volt) cOFormula(Parameter({DELTAH = 0.819223752271796, Con = 24.5730061218271, Shape = 1.16184324218172, BETA = 18.0304725458447}, w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - (Con + :Name("1/kT") * Abs(DELTAH) + :Volt * -BETA)), -Exp(20)); w2 = Abs(Shape) * (Log( :Stop Time) - (Con + ( :Name("1/kT") * Abs(DELTAH) + :Volt * -BETA))); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c  Use Time c. c  Use Temp c. c   Use Volts c. c  constant c. c  Delta H c. c  Beta c. c  Shape c. c  Use CDF (no Model) cKCFormula(1 - Exp(- :Use Time ^ :Shape / Exp( :constant) ^ :Shape))ÿÿÿÿ c  Use CDF (Temp) c­yqFormula(1 - Exp(- :Use Time ^ :Shape / Exp( :constant + ( :Delta H * 11605) / ( :Use Temp + 273.16)) ^ :Shape))ÿÿÿÿ c  Use CDF (Ln Volt) cœh`Formula(1 - Exp(- :Use Time ^ :Shape / Exp( :constant + - :Beta * Log( :Use Volts)) ^ :Shape))ÿÿÿÿ c  Use CDF (Volt) c—c[Formula(1 - Exp(- :Use Time ^ :Shape / Exp( :constant + - :Beta * :Use Volts) ^ :Shape))ÿÿÿÿ c  Use CDF (T/Ln Volt) c×£›Formula(Local({t1}, 1 - Exp(- :Use Time ^ :Shape / Exp( :constant + - :Beta * Log( :Use Volts) + ( :Delta H * 11605) / ( :Use Temp + 273.16)) ^ :Shape)))ÿÿÿÿ c  Use CDF (T/Voltl) cÅ‘‰Formula(1 - Exp(- :Use Time ^ :Shape / Exp( :constant + - :Beta * :Use Volts + ( :Delta H * 11605) / ( :Use Temp + 273.16)) ^ :Shape))ÿÿÿÿ c  CDF Bds (No Model) c沪Formula(Parameter({Shape = 1, CDF = 0.01}, usetme = :Use Time[1]; con = Log(usetme) - Log(-Log(1 - CDF)) / Abs(Shape); w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - con), -Exp(20)); w2 = Abs(Shape) * (Log( :Stop Time) - con); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c  CDF Bds (Temp Model) c„PHFormula(Parameter({DELTAH = 1, Shape = 1, CDF = 0.01}, usetme = :Use Time[1]; usetmp = :Use Temp[1]; con = (Log(usetme) + (-((Abs(DELTAH) * 11605) / (usetmp + 273.16)))) - Log(-Log(1 - Abs(CDF))) / Abs(Shape); w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - (con + :Name("1/kT") * Abs(DELTAH))), -Exp(20)); w2 = Abs(Shape) * (Log( :Stop Time) - ( :Name("1/kT") * Abs(DELTAH) + con)); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c  CDF Bds (Ln Volt Model) cH Formula(Parameter({Shape = 1, CDF = 0.01, BETA = 2}, usetme = :Use Time[1]; usevolt = :Use Volts[1]; con = (Log(usetme) + BETA * Log(usevolt)) - Log(-Log(1 - Abs(CDF))) / Abs(Shape); w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - (con + :ln V * -BETA)), -Exp(20)); w2 = Shape * (Log( :Stop Time) - ( :ln V * -BETA + con)); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c  CDF Bds (Volt Model) cH Formula(Parameter({Shape = 1, CDF = 0.01, BETA = 2}, usetme = :Use Time[1]; usevolt = :Use Volts[1]; con = (Log(usetme) + BETA * usevolt) - Log(-Log(1 - Abs(CDF))) / Abs(Shape); w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - (con + :Volt * -BETA)), -Exp(20)); w2 = Abs(Shape) * (Log( :Stop Time) - ( :Volt * -BETA + con)); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c  CDF Bds (T/Ln Volt Model) cÝ©¡Formula(Parameter({DELTAH = 1, Shape = 1, CDF = 0.01, BETA = 2}, usetme = :Use Time[1]; usetmp = :Use Temp[1]; usevolt = :Use Volts[1]; con = (Log(usetme) + (BETA * Log(usevolt) - (Abs(DELTAH) * 11605) / (usetmp + 273.16))) - Log(-Log(1 - Abs(CDF))) / Abs(Shape); w1 = IfMZ( :Start Time > 0, Abs(Shape) * (Log( :Start Time) - (con + :Name("1/kT") * Abs(DELTAH) + :ln V * -BETA)), -Exp(20)); w2 = Abs(Shape) * (Log( :Stop Time) - ( :Name("1/kT") * Abs(DELTAH) + :ln V * -BETA + con)); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Shape)) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c  CDF Bds (T/Volt Model) c6úFormula(Parameter({DELTAH = 0.819223928250557, Shape = 1.16184339591204, CDF = 0.0736091220864291, BETA = 18.030475470068}, usetme = :Use Time[1]; usetmp = :Use Temp[1]; usevolt = :Use Volts[1]; con = (Log(usetme) + (BETA * usevolt - (Abs(Abs(DELTAH)) * 11605) / (usetmp + 273.16))) - Log(-Log(1 - Abs(CDF))) / Abs(Abs(Shape)); w1 = IfMZ( :Start Time > 0, Abs(Abs(Shape)) * (Log( :Start Time) - (con + :Name("1/kT") * Abs(Abs(DELTAH)) + :Volt * -BETA)), -Exp(20)); w2 = Abs(Abs(Shape)) * (Log( :Stop Time) - ( :Name("1/kT") * Abs(Abs(DELTAH)) + :Volt * -BETA + con)); w3 = Exp(-Exp(w1)); w4 = Exp(-Exp(w2)); IfMZ( :Censor == 0, :Freq * ((Exp(w1) + Log( :Start Time)) - Log(Abs(Abs(Shape))) - w1), :Censor == 1, :Freq * Exp(w1), :Freq * -Log(w3 - w4))))ÿÿÿÿ c