loglm package:MASS R Documentation _F_i_t _L_o_g-_L_i_n_e_a_r _M_o_d_e_l_s _b_y _I_t_e_r_a_t_i_v_e _P_r_o_p_o_r_t_i_o_n_a_l _S_c_a_l_i_n_g _D_e_s_c_r_i_p_t_i_o_n: This function provides a front-end to the standard function, 'loglin', to allow log-linear models to be specified and fitted in a manner similar to that of other fitting functions, such as 'glm'. _U_s_a_g_e: loglm(formula, data, subset, na.action, ...) _A_r_g_u_m_e_n_t_s: formula: A linear model formula specifying the log-linear model. If the left-hand side is empty, the 'data' argument is required and must be a (complete) array of frequencies. In this case the variables on the right-hand side may be the names of the 'dimnames' attribute of the frequency array, or may be the positive integers: 1, 2, 3, ... used as alternative names for the 1st, 2nd, 3rd, ... dimension (classifying factor). If the left-hand side is not empty it specifies a vector of frequencies. In this case the data argument, if present, must be a data frame from which the left-hand side vector and the classifying factors on the right-hand side are (preferentially) obtained. The usual abbreviation of a '.' to stand for 'all other variables in the data frame' is allowed. Any non-factors on the right-hand side of the formula are coerced to factor. data: Numeric array or data frame. In the first case it specifies the array of frequencies; in then second it provides the data frame from which the variables occurring in the formula are preferentially obtained in the usual way. This argument may be the result of a call to 'xtabs'. subset: Specifies a subset of the rows in the data frame to be used. The default is to take all rows. na.action: Specifies a method for handling missing observations. The default is to fail if missing values are present. ...: May supply other arguments to the function 'loglm1'. _D_e_t_a_i_l_s: If the left-hand side of the formula is empty the 'data' argument supplies the frequency array and the right-hand side of the formula is used to construct the list of fixed faces as required by 'loglin'. Structural zeros may be specified by giving a 'start' argument with those entries set to zero, as described in the help information for 'loglin'. If the left-hand side is not empty, all variables on the right-hand side are regarded as classifying factors and an array of frequencies is constructed. If some cells in the complete array are not specified they are treated as structural zeros. The right-hand side of the formula is again used to construct the list of faces on which the observed and fitted totals must agree, as required by 'loglin'. Hence terms such as 'a:b', 'a*b' and 'a/b' are all equivalent. _V_a_l_u_e: An object of class '"loglm"' conveying the results of the fitted log-linear model. Methods exist for the generic functions 'print', 'summary', 'deviance', 'fitted', 'coef', 'resid', 'anova' and 'update', which perform the expected tasks. Only log-likelihood ratio tests are allowed using 'anova'. The deviance is simply an alternative name for the log-likelihood ratio statistic for testing the current model within a saturated model, in accordance with standard usage in generalized linear models. _W_a_r_n_i_n_g: If structural zeros are present, the calculation of degrees of freedom may not be correct. 'loglin' itself takes no action to allow for structural zeros. 'loglm' deducts one degree of freedom for each structural zero, but cannot make allowance for gains in error degrees of freedom due to loss of dimension in the model space. (This would require checking the rank of the model matrix, but since iterative proportional scaling methods are developed largely to avoid constructing the model matrix explicitly, the computation is at least difficult.) When structural zeros (or zero fitted values) are present the estimated coefficients will not be available due to infinite estimates. The deviances will normally continue to be correct, though. _R_e_f_e_r_e_n_c_e_s: Venables, W. N. and Ripley, B. D. (2002) _Modern Applied Statistics with S._ Fourth edition. Springer. _S_e_e _A_l_s_o: 'loglm1', 'loglin' _E_x_a_m_p_l_e_s: # The data frames Cars93, minn38 and quine are available # in the MASS package. # Case 1: frequencies specified as an array. sapply(minn38, function(x) length(levels(x))) ## hs phs fol sex f ## 3 4 7 2 0 minn38a <- array(0, c(3,4,7,2), lapply(minn38[, -5], levels)) minn38a[data.matrix(minn38[,-5])] <- minn38$fol fm <- loglm(~1 + 2 + 3 + 4, minn38a) # numerals as names. deviance(fm) ##[1] 3711.9 fm1 <- update(fm, .~.^2) fm2 <- update(fm, .~.^3, print = TRUE) ## 5 iterations: deviation 0.0750732 anova(fm, fm1, fm2) ## Not run: LR tests for hierarchical log-linear models Model 1: ~ 1 + 2 + 3 + 4 Model 2: . ~ 1 + 2 + 3 + 4 + 1:2 + 1:3 + 1:4 + 2:3 + 2:4 + 3:4 Model 3: . ~ 1 + 2 + 3 + 4 + 1:2 + 1:3 + 1:4 + 2:3 + 2:4 + 3:4 + 1:2:3 + 1:2:4 + 1:3:4 + 2:3:4 Deviance df Delta(Dev) Delta(df) P(> Delta(Dev) Model 1 3711.915 155 Model 2 220.043 108 3491.873 47 0.00000 Model 3 47.745 36 172.298 72 0.00000 Saturated 0.000 0 47.745 36 0.09114 ## End(Not run) # Case 1. An array generated with xtabs. loglm(~ Type + Origin, xtabs(~ Type + Origin, Cars93)) ## Not run: Call: loglm(formula = ~Type + Origin, data = xtabs(~Type + Origin, Cars93)) Statistics: X^2 df P(> X^2) Likelihood Ratio 18.362 5 0.0025255 Pearson 14.080 5 0.0151101 ## End(Not run) # Case 2. Frequencies given as a vector in a data frame names(quine) ## [1] "Eth" "Sex" "Age" "Lrn" "Days" fm <- loglm(Days ~ .^2, quine) gm <- glm(Days ~ .^2, poisson, quine) # check glm. c(deviance(fm), deviance(gm)) # deviances agree ## [1] 1368.7 1368.7 c(fm$df, gm$df) # resid df do not! c(fm$df, gm$df.residual) # resid df do not! ## [1] 127 128 # The loglm residual degrees of freedom is wrong because of # a non-detectable redundancy in the model matrix.