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Models with limited dependent variables. Doctoral Program 2006-2007 Katia Campo. Introduction. Discrete Choice Models. Truncated/ Censored Regr.Models. Duration (Hazard) Models. Limited dependent variables. Discrete dependent variable. Continuous dependent variable. Truncated,
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Models with limited dependent variables Doctoral Program 2006-2007 Katia Campo
Discrete Choice Models Truncated/ Censored Regr.Models Duration (Hazard) Models Limited dependent variables Discrete dependent variable Continuous dependent variable Truncated, Censored
Discrete choice models • Choice between different options (j) • Single Choice (binary choice models) e.g. Buy a product or not, follow higher education or not, ... • j=1 (yes/accept) or 0 (no/reject) • Multiple Choice (multinomial choice models), e.g. cars, stores, transportation modes • j=1(opt.1), 2(opt.2), ....., J(opt.J)
Truncated/censored regression models • Truncated variable: observed only beyond a certain threshold level (‘truncation point’) e.g. store expenditures, income • Censored variables: values in a certain range are all transformed to (or reported as) a single value (Greene, p.761) e.g. demand (stockouts, unfullfilled demand), hours worked
Duration/Hazard models • Time between two events, e.g. • Time between two purchases • Time until a consumer becomes inactive/cancels a subscription • Time until a consumer responds to direct mail/ a questionnaire • ...
Need to use adjusted models: Illustration Frances and Paap (2001)
Overview • Part I. Discrete Choice Models • Part II. Censored and Truncated Regression Models • Part III. Duration Models
Recommended Literature • Kenneth Train, Discrete Choice Methods with Simulation, Cambridge University Press, 2003 (Part I) • Ph.H.Franses and R.Paap, Quantitative Models in Market Research, Cambridge University Press, 2001 (Part I-II-III; Data: www.few.eur.nl/few/people/paap) • D.A.Hensher, J.M.Rose and W.H.Greene, Applied Choice Analysis, Cambridge University Press, 2005 (Part I)
Overview Part I, DCM • Properties of DCM • Estimation of DCM • Types of Discrete Choice Models • Binary Logit Model • Multinomial Logit Model • Nested logit model • Probit Model • Ordered Logit Model • Heterogeneity
Notation • n = decision maker • i,j = choice options • y = decision outcome • x = explanatory variables • = parameters • = error term • I[.] = indicator function, equal to 1 if expression within brackets is true, 0 otherwise e.g. I[y=j|x] = 1 if j was selected (given x), equal to 0 otherwise
A. Properties of DCM Kenneth Train • Characteristics of the choice set • Alternatives must be mutually exclusive no combination of choice alternatives (e.g. different brands, combination of diff. transportation modes) • Choice set must be exhaustive i.e., include all relevant alternatives • Finite number of alternatives
A. Properties of DCM Kenneth Train • Random utility maximization Ass: decision maker selects the alternative that provides the highest utility, i.e. Selects i if Uni > Unj j i Decomposition of utility into a deterministic (observed) and random (unobserved) part Unj = Vnj + nj
A. Properties of DCM Kenneth Train • Random utility maximization
A. Properties of DCM Kenneth Train • Identification problems • Only differences in utility matter Choice probabilities do not change when a constant is added to each alternative’s utility • Implication Some parameters cannot be identified/estimatedAlternative-specific constants; Coefficients of variables that change over decision makers but not over alternatives Normalization of parameter(s)
A. Properties of DCM Kenneth Train • Identification problems • Overall scale of utility is irrelevant Choice probabilities do not change when the utility of all alternatives are multiplied by the same factor • Implication Coefficients of models (data sets) are not directly comparable Normalization (var.of error terms)
A. Properties of DCM Kenneth Train • Aggregation Biased estimates when aggregate values of the explanatory variables are used as input Consistent estimates can be obtained by sample enumeration - compute prob./elasticity for each dec.maker - compute (weighted) average of these values Swait and Louvière(1993), Andrews and Currim (2002)
Properties of DCM Keneth Train • Aggregation
B. Estimation DCM • Numerical maximization (ML-estimation) • Simulation-assisted estimation • Bayesian estimation (see Train)
B. ML-estimation • Objective: “find those parameter values most likely to have produced the sample observations” (Judge et al.) • Likelihood for one observation: Pn(X,) • Likelihoodfunction L() = nPn(X,) • Loglikelihood LL() = n ln(Pn(X,))
B. ML Estimation Determine for which LL() reaches its max • First derivative = 0 no closed-form solution • Iterative procedure: • Starting values 0 • Determine new value t+1 for which LL(t+1) > LL(t) • Repeat procedure ii until convergence (small change in LL())
B. ML Estimation - Direction and step size t → t+1 ? based on taylor approximation of LL(t+1) (with base (t)) LL(t+1) = LL(t)+(t+1- t)’gt+1/2(t+1- t)’Ht (t+1- t) [1] with
B. ML Estimation - Direction and step size t → t+1 ? Optimization of [1] leads to: Computation of the Hessian may cause problems
B. ML Estimation Alternatives procedures: • Approximations to the Hessian • Other procedures, such as steepest-ascent See e.g. Train, Judge et al.(1985)
B. ML Estimation Properties ML estimator Consistency Asymptotic Normality Asymptotic Efficiency See e.g. Greene (ch.17), Judge et al.
B.Diagnostics and Model Selection • Goodness-of-Fit • Joint significance of explanatory var’s LR-test : LR = -2(LL(0) - LL()) LR ~ ²(k) • Pseudo R² = 1 - LL() LL(0)
B.Diagnostics and Model Selection • Goodness-of-Fit • Akaike Information Criterion AIC = 1/N (-2LL() +2k) • CAIC = -2LL() + k(log(N)+1) • BIC = 1/N (-2LL() + k log(N)) • sometimes conflicting results
B.Diagnostics and Model Selection • Model selection based on GoF • Nested models : LR-test LR = -2(LL(r) - LL(ur)) r=restricted model; ur=unrestricted (full) model LR ~ ²(k) (k=difference in # of parameters) • Non-nested models AIC, CAIC, BIC lowest value
C. Discrete Choice Models • Binary Logit Model • Multinomial Logit Model • Nested logit model • Probit Model • Ordered Logit Model
1. Binary Logit Model • Choice between 2 alternatives • Often ‘accept/reject’ or ‘yes/no’ decisions • E.g. Purchase incidence: make a purchase in the category or not • Dep. var. yn = 1, if option is selected = 0, if option is not selected • Model: P(yn=1| xn)
1. Binary Logit Model • Based on the general RUM-model • Ass.: error terms are iid and follow an extreme value or Gumbel distribution
1. Binary Logit Model • Based on the general RUM-model • Pn = I[β’xn + εn > 0] f(ε) dε = I[εn > -β’xn] f(ε) dε = ε=-β’x f(ε) dε = 1 – F(- β’xn) = 1 – 1/(1+exp(β’xn)) = exp(β’xn)/(1+exp(β’xn)) Ass.: error terms are iid and follow an extreme value/Gumbel distr.
1. Binary Logit Model • Leads to the following expression for the logit choice probability
1. Binary Logit Model Properties • Nonlinear effect of explanatory var’s on dependent variable • Logistic curve with inflection point at P=0.5
1. Binary Logit Model Effect of explanatory variables ? For Quasi-elasticity
1. Binary Logit Model Effect of explanatory variables ? For Odds ratio is equal to
1. Binary Logit Model Estimation: ML • Likelihoodfunction L() = nP(yn=1|x,)yn (1- P(yn=1|x,))1-yn • Loglikelihood LL() = n yn ln(P(yn=1|x,) )+ (1-yn) ln(1- P(yn=1|x,))
1. Binary Logit Model • Forecasting accuracy • Predictions : yn=1 if F(Xn ) > c (e.g. 0.5) yn=0 if F(Xn ) c • Compute hit rate = % of correct predictions
1. Binary Logit Model Example: Purchase Incidence Model ptn(inc) = probability that household n engages in a category purchase in the store on purchase occasion t, Wtn = the utility of the purchase option. Bucklin and Gupta (1992)
1. Binary Logit Model Example: Purchase Incidence Model With CRn = rate of consumption for household n INVnt = inventory level for household n, time t CVnt= category value for household n, time t Bucklin and Gupta (1992)
1. Binary Logit Model • Data • A.C.Nielsen scanner panel data • 117 weeks: 65 for initialization, 52 for estimation • 565 households: 300 selected randomly for estimation, remaining hh = holdout sample for validation • Data set for estimation: 30.966 shopping trips, 2275 purchases in the category (liquid laundry detergent) • Estimation limited to the 7 top-selling brands (80% of category purchases), representing 28 brand-size combinations (= level of analysis for the choice model) Bucklin and Gupta (1992)
1. Binary Logit Model Goodness-of-Fit
1. Binary Logit Model Parameter estimates
Variable Coefficient Std. Error z-Statistic Prob. C 0.222121 0.668483 0.332277 0.7397 DISPLHEINZ 0.573389 0.239492 2.394186 0.0167 DISPLHUNTS -0.557648 0.247440 -2.253674 0.0242 FEATHEINZ 0.505656 0.313898 1.610896 0.1072 FEATHUNTS -1.055859 0.349108 -3.024445 0.0025 FEATDISPLHEINZ 0.428319 0.438248 0.977344 0.3284 FEATDISPLHUNTS -1.843528 0.468883 -3.931748 0.0001 PRICEHEINZ -135.1312 10.34643 -13.06066 0.0000 PRICEHUNTS 222.6957 19.06951 11.67810 0.0000 Binary Logit Model (Franses and Paap: www.few.eur.nl/few/people/paap)
Binary Logit Model (Franses and Paap: www.few.eur.nl/few/people/paap) Mean dependent var 0.890279 S.D. dependent var 0.312598 S.E. of regression 0.271955 Akaike info criterion 0.504027 Sum squared resid 206.2728 Schwarz criterion 0.523123 Log likelihood -696.1344Hannan-Quinn criter. 0.510921 Restr. log likelihood -967.918Avg. log likelihood -0.248797 LR statistic (8 df) 543.5673 McFadden R-squared 0.280792 Probability(LR stat) 0.000000 Obs with Dep=0 307 Total obs 2798 Obs with Dep=1 2491
Binary Logit Model (Franses and Paap: www.few.eur.nl/few/people/paap)
Binary Logit Model (Franses and Paap: www.few.eur.nl/few/people/paap)