3

Eu estava tentando ajustar uma função teórica a uma distribuição de pontos através da função nls2.

No entanto, os erros do ajuste são muito grandes, ou seja, se um parâmetro deve estar entre 2 e 3, o ajuste encontra 2 erro de mais ou menos 16, por exemplo. gostaria de saber se existe alguma maneira de diminuir esse erro (Std. Error) de forma que ele fique, pelo menos, da mesma ordem que o parâmetro encontrado, por exemplo 2 com Std. Error dado pelo ajuste de 1.23.

Segue meu código:

Os dados

library(minpack.lm)
library(magicaxis)

y=c(133129.8,132171.4,131439,130849.8,130359.6,129942.2,129580.6,129263.1,128981.5,128729.6,128498.8,128281.9,128075.8,127878.4,127687.7,127502.7,127322.7,127146.5,126973.2,126802.1,126633.3,126467.2,126303.2,126140.8,125979.4,125810.1,125624.4,125421.6,125201.5,124964.2,124714.1,124455.8,124189.3,123914.4,123631.3,123344.3,123057.8,122772,122486.6,122201.4,121912.2,121614.8,121309,120994.6,120671.7,120342.6,120009.5,119672.4,119331.4,118986.2,118633.9,118271.9,117899.8,117517.8,117125.6,116722.6,116307.9,115881.4,115443.2,114993.2,114532.4,114061.5,113580.5,113089.6,112588.5,112077.1,111554.7,111021.5,110477.4,109922.4,109357.6,108783.8,108201.2,107609.6,107009.2,106400.9,105785.7,105163.6,104534.7,103898.9,103256.2,102606.4,101949.6,101285.7,100614.8,99936.8,99251.7,98559.5,97860.2,97153.8,96441.3,95723.7,95001,94273.3,93540.4,92804.5,92067.2,91328.6,90588.8,89847.8,89106.5,88365.8,87625.7,86886.3,86147.6,85412.2,84682.6,83958.8,83240.9,82528.8,81821,81116,80413.8,79714.3,79017.5,78324.4,77635.7,76951.3,76271.4,75596,74925.8,74261.6,73603.4,72951.2,72305.1,71665.8,71034,70409.8,69793.2,69184,68581,67983,67389.9,66801.6,66218.1,65636.9,65055.4,64473.7,63891.5,63309.1,62727.6,62148.3,61571.3,60996.6,60424,59853.1,59283.2,58714.4,58146.6,57579.9,57014.7,56451.7,55891,55332.4,54776,54222.4,53672.1,53125,52581.2,52040.7,51504,50971.7,50443.6,49919.8,49400.3,48885.7,48376.2,47872.1,47373.2,46879.6,46392.7,45914.1,45443.7,44981.5,44527.5,44081.2,43641.9,43209.7,42784.4,42366.2,41954.4,41548.4,41148.3,40754,40365.4,39982.1,39603.5,39229.4,38860,38495.1,38135.3,37780.6,37431.3,37087.3,36748.5,36415.3,36088,35766.6,35451.1,35141.4,34837,34537.3,34242.3,33952,33666.4,33385.7,33110.1,32839.8,32574.7,32314.7,32059.4,31808,31560.6,31317.2,31077.8,30843.4,30615.1,30392.8,30176.5,29966.4,29762.4,29564.9,29373.9,29189.3,29011.1,28839.1,28673.2,28513.2,28359.2,28211.2,28068.6,27930.7,27797.7,27669.3,27545.7,27425.5,27307.3,27191.1,27077,26964.8,26854.8,26747.1,26641.5,26538.2,26437.2,26339.2,26245.1,26154.8,26068.5,25985.9,25906.6,25829.9,25755.9,25684.4,25615.5,25548.9,25484.4,25421.9,25361.4,25302.9,25246.1,25190.8,25136.8,25084.3,25033.1,24982.7,24932.5,24882.3,24832.3,24782.3,24732.8,24684.1,24636.1,24588.8,24542.3,24496.1,24450.1,24404.1,24358.2,24312.3,24266.1,24219.3,24171.8,24123.6,24074.8,24025.3,23974.9,23923.8,23871.9,23819.2,23765.9,23712.3,23658.3,23603.9,23549.2,23494.1,23438.3,23382,23325.1,23267.7,23210.1,23152.9,23096,23039.5,22983.3,22926.7,22869.1,22810.3,22750.4,22689.5,22627.5,22564.7,22501,22436.4,22371,22305,22238.9,22172.7,22106.3,22039.8,21973.6,21907.8,21842.6,21777.9,21713.8,21650,21586.3,21522.6,21459.1,21395.6,21332.5,21270,21208.2,21147.1,21086.5,21026.9,20968.5,20911.2,20855,20800,20746.2,20693.4,20641.7,20591.1,20541.6,20492.8,20444.6,20396.8,20349.5,20302.7,20256.2,20210.1,20164.3,20118.8,20073.6,20028.9,19984.8,19941.3,19898.4,19856.2,19814.6,19773.9,19734.1,19695.1,19657,19619.8,19583.6,19548.5,19514.4,19481.3,19449.4,19418.6,19389,19360.6,19333.4,19307.3,19282.6,19259.1,19236.8,19215.8,19195.8,19176.7,19158.5,19141,19124.4,19108.6,19093.7,19079.5,19066.2,19053.7,19042,19031.1,19020.9,19011.4,19002.7,18994.7,18987.4,18980.7,18974.6,18969.2,18964.4,18960,18956,18952.5,18949.4,18946.7,18944.5,18942.7,18941.3,18940.3,18939.8,18939.8,18940.1,18940.9 )

    x=c(0.003,0.004,0.005,0.006,0.007,0.008,0.009,0.01,0.011,0.012,0.013,0.014,0.015,0.016,0.017,0.018,0.019,0.02,0.021,0.022,0.023,0.024,0.025,0.026,0.027,0.028,0.029,0.03,0.031,0.032,0.033,0.034,0.035,0.036,0.037,0.038,0.039,0.04,0.041,0.042,0.043,0.044,0.045,0.046,0.047,0.048,0.049,0.05,0.051,0.052,0.053,0.054,0.055,0.056,0.057,0.058,0.059,0.06,0.061,0.062,0.063,0.064,0.065,0.066,0.067,0.068,0.069,0.07,0.071,0.072,0.073,0.074,0.075,0.076,0.077,0.078,0.079,0.08,0.081,0.082,0.083,0.084,0.085,0.086,0.087,0.088,0.089,0.09,0.091,0.092,0.093,0.094,0.095,0.096,0.097,0.098,0.099,0.1,0.101,0.102,0.103,0.104,0.105,0.106,0.107,0.108,0.109,0.11,0.111,0.112,0.113,0.114,0.115,0.116,0.117,0.118,0.119,0.12,0.121,0.122,0.123,0.124,0.125,0.126,0.127,0.128,0.129,0.13,0.131,0.132,0.133,0.134,0.135,0.136,0.137,0.138,0.139,0.14,0.141,0.142,0.143,0.144,0.145,0.146,0.147,0.148,0.149,0.15,0.151,0.152,0.153,0.154,0.155,0.156,0.157,0.158,0.159,0.16,0.161,0.162,0.163,0.164,0.165,0.166,0.167,0.168,0.169,0.17,0.171,0.172,0.173,0.174,0.175,0.176,0.177,0.178,0.179,0.18,0.181,0.182,0.183,0.184,0.185,0.186,0.187,0.188,0.189,0.19,0.191,0.192,0.193,0.194,0.195,0.196,0.197,0.198,0.199,0.2,0.201,0.202,0.203,0.204,0.205,0.206,0.207,0.208,0.209,0.21,0.211,0.212,0.213,0.214,0.215,0.216,0.217,0.218,0.219,0.22,0.221,0.222,0.223,0.224,0.225,0.226,0.227,0.228,0.229,0.23,0.231,0.232,0.233,0.234,0.235,0.236,0.237,0.238,0.239,0.24,0.241,0.242,0.243,0.244,0.245,0.246,0.247,0.248,0.249,0.25,0.251,0.252,0.253,0.254,0.255,0.256,0.257,0.258,0.259,0.26,0.261,0.262,0.263,0.264,0.265,0.266,0.267,0.268,0.269,0.27,0.271,0.272,0.273,0.274,0.275,0.276,0.277,0.278,0.279,0.28,0.281,0.282,0.283,0.284,0.285,0.286,0.287,0.288,0.289,0.29,0.291,0.292,0.293,0.294,0.295,0.296,0.297,0.298,0.299,0.3,0.301,0.302,0.303,0.304,0.305,0.306,0.307,0.308,0.309,0.31,0.311,0.312,0.313,0.314,0.315,0.316,0.317,0.318,0.319,0.32,0.321,0.322,0.323,0.324,0.325,0.326,0.327,0.328,0.329,0.33,0.331,0.332,0.333,0.334,0.335,0.336,0.337,0.338,0.339,0.34,0.341,0.342,0.343,0.344,0.345,0.346,0.347,0.348,0.349,0.35,0.351,0.352,0.353,0.354,0.355,0.356,0.357,0.358,0.359,0.36,0.361,0.362,0.363,0.364,0.365,0.366,0.367,0.368,0.369,0.37,0.371,0.372,0.373,0.374,0.375,0.376,0.377,0.378,0.379,0.38,0.381,0.382,0.383,0.384,0.385,0.386,0.387,0.388,0.389,0.39,0.391,0.392,0.393,0.394,0.395,0.396,0.397,0.398,0.399,0.4,0.401,0.402,0.403,0.404,0.405,0.406,0.407,0.408,0.409,0.41,0.411,0.412,0.413,0.414,0.415,0.416 )

Ajuste:

mod <- nlsLM(y ~ o/(x*(x+t)^k),
             start = c(t = 0.1, o =10, k = 2),
             trace = TRUE, 
             na.action = na.exclude, 
# control= nls.lm.control(nprint=0,
#                                  ftol=.Machine$double.eps^2,
#                                  ptol=.Machine$double.eps^2,
#                                 maxfev=10000, maxiter=2024) 
 lower=c(0.1, 10, 2),
             upper=c(1,1000, 3)

)

summary(mod)

Resultado:

> Formula: y ~ o/(x * (x + t)^k)

Parameters:
  Estimate Std. Error t value Pr(>|t|)
t    0.368      5.739   0.064    0.949
o   162.416    714.204   0.227   0.820
k    2.000     27.427   0.073    0.942



 Residual standard error: 56290 on 411 degrees of freedom

Number of iterations till stop: 50 
Achieved convergence tolerance: 1.49e-08
Reason stopped: Number of iterations has reached `maxiter' == 50.

Figura:

magplot(x,y,log='xy',pch=16,col="black",cex=1 )

De acordo com o modelo o ajuste sobre estes dados tem que dar valores de k entre 2 e 3 e t entre 0.1 e 1 o que o ajuste consegue encontrar (ainda bem!), mas com Std. Error de 27.427 para k e de 5.739 para t, ou seja, com ordens de grandeza muito maiores que os intervalos q os valores devem variar, acredito que o ajuste perca a confiabilidade.

Gostaria de saber se existe uma maneira de de diminuir esse Std. Error para os parâmetros sem que eles saiam desses intervalos ?

Agradeço

2 Respostas 2

5

Os erros-padrão são altos porque o ajuste do modelo aos dados é muito ruim, em função da definição da função não-linear e dos limites impostos para os valores dos parâmetros. Não é possível reduzir os erros-padrão sem alterar a definição do modelo não-linear ou alterando os limites para os valores dos parâmetros.

No exemplo dado, o modelo sequer converge no número padrão de iterações (50); aumentar esse número permite a convergência, sem mudar muito os resultados do ajuste. Podemos conferir o ajuste visualmente:

plot(x, y)
coefs <- coef(mod)
curve(coefs['o']/(x * (x + coefs['t'])^coefs['k']), add=T)

inserir a descrição da imagem aqui

Se você retirar os limites impostos para os valores dos parâmetros, retirando os argumentos upper e lower da função de ajuste, obterás resultados com erros-padrão melhores, ainda que o ajuste permaneça questionável.

4

A resposta do Erikson K. é muito boa. Ele levantou um ponto excelente: a forma da função que tu está tentando ajustar aos dados não é boa. Eu vou tentar expandir um pouco o que ele fez, comentando sobre ajuste de funções a dados.

Em geral, quando definimos uma forma paramétrica para uma função que se ajuste aos nossos dados, precisamos ter uma justificativa teórica para a forma desta função. Por exemplo, se eu estiver interessado em determinar a função que melhor descreve a força aplicada quando uma mola é esticada, faz sentido usar uma função do tipo

F = k*x,

em que

F: força aplicada na mola k: parâmetro específico para cada mola x: deslocamento aplicado à mola

Isto está bem definido na Lei de Hooke.

No teu caso, tu deveria ter perguntar porque ajustar uma função do tipo y ~ o/(x*(x+t)^k). Por que esta relação faria sentido nos teus dados? Aparentemente, ela não faz, pois a função estimada não está se ajustando bem aos dados.

Olhando o gráfico, parece que uma função do tipo 1/y ~ x se ajusta bem melhor aos teus dados:

y <- c(133129.8,132171.4,131439,130849.8,130359.6,129942.2,129580.6,129263.1,128981.5,128729.6,128498.8,128281.9,128075.8,127878.4,127687.7,127502.7,127322.7,127146.5,126973.2,126802.1,126633.3,126467.2,126303.2,126140.8,125979.4,125810.1,125624.4,125421.6,125201.5,124964.2,124714.1,124455.8,124189.3,123914.4,123631.3,123344.3,123057.8,122772,122486.6,122201.4,121912.2,121614.8,121309,120994.6,120671.7,120342.6,120009.5,119672.4,119331.4,118986.2,118633.9,118271.9,117899.8,117517.8,117125.6,116722.6,116307.9,115881.4,115443.2,114993.2,114532.4,114061.5,113580.5,113089.6,112588.5,112077.1,111554.7,111021.5,110477.4,109922.4,109357.6,108783.8,108201.2,107609.6,107009.2,106400.9,105785.7,105163.6,104534.7,103898.9,103256.2,102606.4,101949.6,101285.7,100614.8,99936.8,99251.7,98559.5,97860.2,97153.8,96441.3,95723.7,95001,94273.3,93540.4,92804.5,92067.2,91328.6,90588.8,89847.8,89106.5,88365.8,87625.7,86886.3,86147.6,85412.2,84682.6,83958.8,83240.9,82528.8,81821,81116,80413.8,79714.3,79017.5,78324.4,77635.7,76951.3,76271.4,75596,74925.8,74261.6,73603.4,72951.2,72305.1,71665.8,71034,70409.8,69793.2,69184,68581,67983,67389.9,66801.6,66218.1,65636.9,65055.4,64473.7,63891.5,63309.1,62727.6,62148.3,61571.3,60996.6,60424,59853.1,59283.2,58714.4,58146.6,57579.9,57014.7,56451.7,55891,55332.4,54776,54222.4,53672.1,53125,52581.2,52040.7,51504,50971.7,50443.6,49919.8,49400.3,48885.7,48376.2,47872.1,47373.2,46879.6,46392.7,45914.1,45443.7,44981.5,44527.5,44081.2,43641.9,43209.7,42784.4,42366.2,41954.4,41548.4,41148.3,40754,40365.4,39982.1,39603.5,39229.4,38860,38495.1,38135.3,37780.6,37431.3,37087.3,36748.5,36415.3,36088,35766.6,35451.1,35141.4,34837,34537.3,34242.3,33952,33666.4,33385.7,33110.1,32839.8,32574.7,32314.7,32059.4,31808,31560.6,31317.2,31077.8,30843.4,30615.1,30392.8,30176.5,29966.4,29762.4,29564.9,29373.9,29189.3,29011.1,28839.1,28673.2,28513.2,28359.2,28211.2,28068.6,27930.7,27797.7,27669.3,27545.7,27425.5,27307.3,27191.1,27077,26964.8,26854.8,26747.1,26641.5,26538.2,26437.2,26339.2,26245.1,26154.8,26068.5,25985.9,25906.6,25829.9,25755.9,25684.4,25615.5,25548.9,25484.4,25421.9,25361.4,25302.9,25246.1,25190.8,25136.8,25084.3,25033.1,24982.7,24932.5,24882.3,24832.3,24782.3,24732.8,24684.1,24636.1,24588.8,24542.3,24496.1,24450.1,24404.1,24358.2,24312.3,24266.1,24219.3,24171.8,24123.6,24074.8,24025.3,23974.9,23923.8,23871.9,23819.2,23765.9,23712.3,23658.3,23603.9,23549.2,23494.1,23438.3,23382,23325.1,23267.7,23210.1,23152.9,23096,23039.5,22983.3,22926.7,22869.1,22810.3,22750.4,22689.5,22627.5,22564.7,22501,22436.4,22371,22305,22238.9,22172.7,22106.3,22039.8,21973.6,21907.8,21842.6,21777.9,21713.8,21650,21586.3,21522.6,21459.1,21395.6,21332.5,21270,21208.2,21147.1,21086.5,21026.9,20968.5,20911.2,20855,20800,20746.2,20693.4,20641.7,20591.1,20541.6,20492.8,20444.6,20396.8,20349.5,20302.7,20256.2,20210.1,20164.3,20118.8,20073.6,20028.9,19984.8,19941.3,19898.4,19856.2,19814.6,19773.9,19734.1,19695.1,19657,19619.8,19583.6,19548.5,19514.4,19481.3,19449.4,19418.6,19389,19360.6,19333.4,19307.3,19282.6,19259.1,19236.8,19215.8,19195.8,19176.7,19158.5,19141,19124.4,19108.6,19093.7,19079.5,19066.2,19053.7,19042,19031.1,19020.9,19011.4,19002.7,18994.7,18987.4,18980.7,18974.6,18969.2,18964.4,18960,18956,18952.5,18949.4,18946.7,18944.5,18942.7,18941.3,18940.3,18939.8,18939.8,18940.1,18940.9 )

x <- c(0.003,0.004,0.005,0.006,0.007,0.008,0.009,0.01,0.011,0.012,0.013,0.014,0.015,0.016,0.017,0.018,0.019,0.02,0.021,0.022,0.023,0.024,0.025,0.026,0.027,0.028,0.029,0.03,0.031,0.032,0.033,0.034,0.035,0.036,0.037,0.038,0.039,0.04,0.041,0.042,0.043,0.044,0.045,0.046,0.047,0.048,0.049,0.05,0.051,0.052,0.053,0.054,0.055,0.056,0.057,0.058,0.059,0.06,0.061,0.062,0.063,0.064,0.065,0.066,0.067,0.068,0.069,0.07,0.071,0.072,0.073,0.074,0.075,0.076,0.077,0.078,0.079,0.08,0.081,0.082,0.083,0.084,0.085,0.086,0.087,0.088,0.089,0.09,0.091,0.092,0.093,0.094,0.095,0.096,0.097,0.098,0.099,0.1,0.101,0.102,0.103,0.104,0.105,0.106,0.107,0.108,0.109,0.11,0.111,0.112,0.113,0.114,0.115,0.116,0.117,0.118,0.119,0.12,0.121,0.122,0.123,0.124,0.125,0.126,0.127,0.128,0.129,0.13,0.131,0.132,0.133,0.134,0.135,0.136,0.137,0.138,0.139,0.14,0.141,0.142,0.143,0.144,0.145,0.146,0.147,0.148,0.149,0.15,0.151,0.152,0.153,0.154,0.155,0.156,0.157,0.158,0.159,0.16,0.161,0.162,0.163,0.164,0.165,0.166,0.167,0.168,0.169,0.17,0.171,0.172,0.173,0.174,0.175,0.176,0.177,0.178,0.179,0.18,0.181,0.182,0.183,0.184,0.185,0.186,0.187,0.188,0.189,0.19,0.191,0.192,0.193,0.194,0.195,0.196,0.197,0.198,0.199,0.2,0.201,0.202,0.203,0.204,0.205,0.206,0.207,0.208,0.209,0.21,0.211,0.212,0.213,0.214,0.215,0.216,0.217,0.218,0.219,0.22,0.221,0.222,0.223,0.224,0.225,0.226,0.227,0.228,0.229,0.23,0.231,0.232,0.233,0.234,0.235,0.236,0.237,0.238,0.239,0.24,0.241,0.242,0.243,0.244,0.245,0.246,0.247,0.248,0.249,0.25,0.251,0.252,0.253,0.254,0.255,0.256,0.257,0.258,0.259,0.26,0.261,0.262,0.263,0.264,0.265,0.266,0.267,0.268,0.269,0.27,0.271,0.272,0.273,0.274,0.275,0.276,0.277,0.278,0.279,0.28,0.281,0.282,0.283,0.284,0.285,0.286,0.287,0.288,0.289,0.29,0.291,0.292,0.293,0.294,0.295,0.296,0.297,0.298,0.299,0.3,0.301,0.302,0.303,0.304,0.305,0.306,0.307,0.308,0.309,0.31,0.311,0.312,0.313,0.314,0.315,0.316,0.317,0.318,0.319,0.32,0.321,0.322,0.323,0.324,0.325,0.326,0.327,0.328,0.329,0.33,0.331,0.332,0.333,0.334,0.335,0.336,0.337,0.338,0.339,0.34,0.341,0.342,0.343,0.344,0.345,0.346,0.347,0.348,0.349,0.35,0.351,0.352,0.353,0.354,0.355,0.356,0.357,0.358,0.359,0.36,0.361,0.362,0.363,0.364,0.365,0.366,0.367,0.368,0.369,0.37,0.371,0.372,0.373,0.374,0.375,0.376,0.377,0.378,0.379,0.38,0.381,0.382,0.383,0.384,0.385,0.386,0.387,0.388,0.389,0.39,0.391,0.392,0.393,0.394,0.395,0.396,0.397,0.398,0.399,0.4,0.401,0.402,0.403,0.404,0.405,0.406,0.407,0.408,0.409,0.41,0.411,0.412,0.413,0.414,0.415,0.416)

dados <- data.frame(x, y)

library(ggplot2)
ggplot(dados, aes(x=x, y=y)) +
  geom_point()

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fit <- lm(1/y ~ x, data=dados)
summary(fit)
Call:
lm(formula = 1/y ~ x, data = dados)

Residuals:
Min         1Q     Median         3Q        Max 
-4.399e-06 -2.534e-06  5.228e-07  1.999e-06  6.352e-06 

Coefficients:
Estimate Std. Error t value Pr(>|t|)    
(Intercept) 7.524e-07  2.714e-07   2.773  0.00581 ** 
x           1.357e-04  1.125e-06 120.596  < 2e-16 ***
---
Signif. codes:  0 ‘***’ 0.001 ‘**’ 0.01 ‘*’ 0.05 ‘.’ 0.1 ‘ ’ 1

Residual standard error: 2.736e-06 on 412 degrees of freedom
Multiple R-squared:  0.9725,    Adjusted R-squared:  0.9724 
F-statistic: 1.454e+04 on 1 and 412 DF,  p-value: < 2.2e-16

dados <- data.frame(dados, ajuste=1/fit$fitted.values)

ggplot(dados, aes(x=x, y=y)) +
  geom_point() +
  geom_line(aes(x=x, y=ajuste, col="red"))

inserir a descrição da imagem aqui

De fato, os erros padrão estão melhores. Eles estão, ao menos, na mesma ordem de magnitude. Entretanto, se avaliarmos o ajuste feito, representado pela curva em vermelho, ele não consegue captar bem o comportamento dos dados quando x < 0.05. Portanto, este ajuste, embora melhor que o inicial, ainda não é bom o suficiente, mesmo com o R^2 alto como ficou.

Portanto, minhas sugestões são duas:

1) Se tu quiser fazer inferência sobre os parâmetros da equação que melhor se ajusta aos dados (i.e., fazer os testes de hipóteses associados e encontrar os p-valores correspondentes), vai ser necessário definir uma nova relação entre estes dados. Aparentemente, y ~ o/(x*(x+t)^k) e 1/y ~ x não são boas. Qual relação seria a ideal? Boa pergunta. Consulte a literatura da área de onde estes dados vieram e tente localizar se alguém já passou por um problema parecido. A partir de um problema similar já resolvido, ajuste um modelo paramétrico similar.

2) Se tu quer fazer previsões (i.e., prever o valor particular de y dado x), tente ajustar um modelo não-paramétrico aos dados. Pode ser algo mais clássico, como LOESS, ou algo mais recente na literatura, como SVM, Random Forest etc.

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