Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lecture 4 (Chapter 4). Linear Models for Correlated Data We aim to develop a general linear model framework for longitudinal data, in which the inference.

Published byAmie Chandler Modified over 9 years ago

Similar presentations

Presentation on theme: "Lecture 4 (Chapter 4). Linear Models for Correlated Data We aim to develop a general linear model framework for longitudinal data, in which the inference."— Presentation transcript:

1 Lecture 4 (Chapter 4)

2 Linear Models for Correlated Data We aim to develop a general linear model framework for longitudinal data, in which the inference we make about the parameters of interest recognize the likely correlation structure of the data. There are two ways of achieving this: 1. To build explicit parametric models of the covariance structure 2. To use methods of inference which are robust to misspecification of the covariance structure

3 General Linear Models for Correlated Data: Examples Uniform Correlation Model –One-sample repeated measures ANOVA Growth Model Exponential Correlation Model Autoregressive Model of Order 1

4 A simple example Covariance matrix Correlation matrix

5 Notation: Balanced Data

6 Notation: Unbalanced Data Outcome measures on subject “i” repeated ni times 12y white 1 3y white 1 10y white Ex: Values of the covariates for subject “i” in long format Covariance matrix for subject i Regression model for longitudinal data

7 Notation Vector of responses in the super-population Design matrix Vector of regression coefficients

8 Notation We assume (i.e. everyone has the same covariance matrix) Covariance matrix of subject i Covariance matrix between subject “j” and subject “k”

9 Covariates may be:

10 Covariates may be… (cont’d)

11 General Linear Model with Correlated Errors Balanced Data Nx1 (Nxp)x(px1)(NxN)

12 Uniform Correlation Model: Parametric form of the covariance matrix When measurements are equally-spaced and the data are balanced, one assumption is that the correlation between any pair of measurements is always the same (or, “exchangeable”)

13 Example: Weight of Pigs

14 Example: Weight of Pigs (cont’d) What do we see? 1.All pigs gain weight over time. 2.The pigs which are the largest at the beginning are the largest at the end. 3.Variance across pigs increases over time. (Increasing variation in the growth rates of the individual pigs.) Figure 3.1. Data on the weights of 48 pigs over a 9- week period.

15 1.Between: There is heterogeneity between pigs, due for example to natural biological (genetic?) variation (random intercept) 2.Within: There is random variation in the measurement process for a particular unit at any given time. For example, on any given day a particular guinea pig may yield different weight measurements due to differences in scale (equipment) and/or small fluctuations in weight during a day (slope on time) Example: Weight of Pigs For this type of repeated measures study, we recognize two sources of random variation:

16 A) Linear model with random intercept Variance between units (clusters) Variance within units (measurement error variance) Proportion of total variance due to between units variance Random effect Total variance

17 Simulated Data: Non-Clustered Cluster Number (units) Repeated measures within a cluster Total variance = 9.8 Variance within = 9.8 Variance between =0 Within cluster correlation = 0

18 Simulated Data: Clustered Cluster Number (units) Repeated measures within a cluster Total variance = 9.8 Variance within = 3.2 Variance between =6.6 Within cluster correlation = 6.6/9.8=0.67

19 Model for the mean Model for the covariance matrix B) Marginal Model with a Uniform Correlation Structure nxn (nx1)(1xn)nxn

20 Models A and B are equivalent Variance between Variance within

21 Pigs – Independent fit. xtreg weight time, pa i(Id) corr(ind) GEE population-averaged model Number of obs = 432 Group variable: Id Number of groups = 48 Link: identity Obs per group: min = 9 Family: Gaussian avg = 9.0 Correlation: independent max = 9 Wald chi2(1) = 5784.19 Scale parameter: 19.20076 Prob > chi2 = 0.0000 Pearson chi2(432): 8294.73 Deviance = 8294.73 Dispersion (Pearson): 19.20076 Dispersion = 19.20076 ------------------------------------------------------------------------------ weight | Coef. Std. Err. z P>|z| [95% Conf. Interval] -------------+---------------------------------------------------------------- time | 6.209896.0816513 76.05 0.000 6.049862 6.369929 _cons | 19.35561.4594773 42.13 0.000 18.45505 20.25617 ------------------------------------------------------------------------------ Independence correlation model results

22 xtreg weight time, pa i(Id) corr(exch) Iteration 1: tolerance = 5.585e-15 GEE population-averaged model Number of obs = 432 Group variable: Id Number of groups = 48 Link: identity Obs per group: min = 9 Family: Gaussian avg = 9.0 Correlation: exchangeable max = 9 Wald chi2(1) = 25337.48 Scale parameter: 19.20076 Prob > chi2 = 0.0000 ------------------------------------------------------------------------------ weight | Coef. Std. Err. z P>|z| [95% Conf. Interval] -------------+---------------------------------------------------------------- time | 6.209896.0390124 159.18 0.000 6.133433 6.286359 _cons | 19.35561.5974055 32.40 0.000 18.18472 20.52651 ------------------------------------------------------------------------------ “Population Average”, Marginal Model with Exchangeable Correlation structure results Pigs – Marginal Model

23 Marginal Model E[ Y i ] = β 0 + β 1 time

24 Pigs – RE model xtreg weight time, re i(Id) mle Random-effects ML regression Number of obs = 432 Group variable (i): Id Number of groups = 48 Random effects u_i ~ Gaussian Obs per group: min = 9 avg = 9.0 max = 9 LR chi2(1) = 1624.57 Log likelihood = -1014.9268 Prob > chi2 = 0.0000 ------------------------------------------------------------------------------ weight | Coef. Std. Err. z P>|z| [95% Conf. Interval] -------------+---------------------------------------------------------------- time | 6.209896.0390124 159.18 0.000 6.133433 6.286359 _cons | 19.35561.5974055 32.40 0.000 18.18472 20.52651 -------------+---------------------------------------------------------------- /sigma_u | 3.84935.4058114 3.130767 4.732863 /sigma_e | 2.093625.0755471 1.95067 2.247056 rho |.771714.0393959.6876303.8413114 ------------------------------------------------------------------------------ Linear model with a random intercept - “conditional model” std between std within

25 Random Effects Model E[ Y i | U i ] = β 0 + β 1 time  + U i E[ Y i ] = β 0 + β 1 time

26 Pigs – GEE Fit. xtgee weight time, i(Id) corr(exch) Iteration 1: tolerance = 5.585e-15 GEE population-averaged model Number of obs = 432 Group variable: Id Number of groups = 48 Link: identity Obs per group: min = 9 Family: Gaussian avg = 9.0 Correlation: exchangeable max = 9 Wald chi2(1) = 25337.48 Scale parameter: 19.20076 Prob > chi2 = 0.0000 ------------------------------------------------------------------------------ weight | Coef. Std. Err. z P>|z| [95% Conf. Interval] -------------+---------------------------------------------------------------- time | 6.209896.0390124 159.18 0.000 6.133433 6.286359 _cons | 19.35561.5974055 32.40 0.000 18.18472 20.52651 ------------------------------------------------------------------------------ GEE fit – Marginal Model with Exchangeable Correlation structure results

27 Pigs – GEE Fit. xtgee weight time, i(Id) corr(exch). xtcorr Estimated within-Id correlation matrix R: c1 c2 c3 c4 c5 c6 c7 c8 c9 r1 1.0000 r2 0.7717 1.0000 r3 0.7717 0.7717 1.0000 r4 0.7717 0.7717 0.7717 1.0000 r5 0.7717 0.7717 0.7717 0.7717 1.0000 r6 0.7717 0.7717 0.7717 0.7717 0.7717 1.0000 r7 0.7717 0.7717 0.7717 0.7717 0.7717 0.7717 1.0000 r8 0.7717 0.7717 0.7717 0.7717 0.7717 0.7717 0.7717 1.0000 r9 0.7717 0.7717 0.7717 0.7717 0.7717 0.7717 0.7717 0.7717 1.0000 GEE fit – Marginal Model with Exchangeable Correlation structure results

28 One sample repeated measures ANOVA

29 One sample repeated measures ANOVA (cont’d)

30 One group polynomial growth curve model

31 Cov(Y i ) can be uniform or exponential

32 Pigs – RE model, quadratic trend. gen timesq = time*time. xtreg weight time timesq, re i(Id) mle Random-effects ML regression Number of obs = 432 Group variable (i): Id Number of groups = 48 Random effects u_i ~ Gaussian Obs per group: min = 9 avg = 9.0 max = 9 LR chi2(2) = 1625.32 Log likelihood = -1014.5524 Prob > chi2 = 0.0000 ------------------------------------------------------------------------------ weight | Coef. Std. Err. z P>|z| [95% Conf. Interval] -------------+---------------------------------------------------------------- time | 6.358818.1763799 36.05 0.000 6.01312 6.704516 timesq | -.0148922.017202 -0.87 0.387 -.0486075.0188231 _cons | 19.08259.675483 28.25 0.000 17.75867 20.40651 -------------+---------------------------------------------------------------- /sigma_u | 3.849473.4057983 3.130909 4.732951 /sigma_e | 2.091585.0754733 1.948769 2.244866 rho |.7720686.0393503.6880712.8415775 ------------------------------------------------------------------------------ Exchangeable Correlation structure results

33 Pigs – Marginal model, quadratic trend. xtgee weight time timesq, i(Id) corr(exch) GEE population-averaged model Number of obs = 432 Group variable: Id Number of groups = 48 Link: identity Obs per group: min = 9 Family: Gaussian avg = 9.0 Correlation: exchangeable max = 9 Wald chi2(2) = 25387.68 Scale parameter: 19.19317 Prob > chi2 = 0.0000 ------------------------------------------------------------------------------ weight | Coef. Std. Err. z P>|z| [95% Conf. Interval] -------------+---------------------------------------------------------------- time | 6.358818.1763801 36.05 0.000 6.013119 6.704517 timesq | -.0148922.017202 -0.87 0.387 -.0486076.0188231 _cons | 19.08259.6754833 28.25 0.000 17.75867 20.40651 ------------------------------------------------------------------------------ Exchangeable Correlation structure results

34 Exponential Correlation / Autoregressive Model STATA: xtgee corr(ar1) “Auto-correlated Errors”

35 Autoregressive

36 Pigs – Marginal model: AR(1) xtgee weight time, i(Id) corr(AR1) t(time) GEE population-averaged model Number of obs = 432 Group and time vars: Id time Number of groups = 48 Link: identity Obs per group: min = 9 Family: Gaussian avg = 9.0 Correlation: AR(1) max = 9 Wald chi2(1) = 6254.91 Scale parameter: 19.26754 Prob > chi2 = 0.0000 ------------------------------------------------------------------------------ weight | Coef. Std. Err. z P>|z| [95% Conf. Interval] -------------+---------------------------------------------------------------- time | 6.272089.0793052 79.09 0.000 6.116654 6.427524 _cons | 18.84218.6745715 27.93 0.000 17.52004 20.16431 ------------------------------------------------------------------------------ GEE-fit Marginal Model with AR1 Correlation structure

37 Pigs – RE model: AR(1) xtregar weight time RE GLS regression with AR(1) disturbances Number of obs = 432 Group variable (i): Id Number of groups = 48 R-sq: within = 0.9851 Obs per group: min = 9 between = 0.0000 avg = 9.0 overall = 0.9305 max = 9 Wald chi2(2) = 12688.55 corr(u_i, Xb) = 0 (assumed) Prob > chi2 = 0.0000 ------------------------------------------------------------------------------ weight | Coef. Std. Err. z P>|z| [95% Conf. Interval] -------------+---------------------------------------------------------------- time | 6.257651.0555527 112.64 0.000 6.14877 6.366533 _cons | 19.00945.6281622 30.26 0.000 17.77827 20.24062 -------------+---------------------------------------------------------------- rho_ar |.73091237 (estimated autocorrelation coefficient) sigma_u | 3.583343 sigma_e | 1.5590851 rho_fov |.84082696 (fraction of variance due to u_i) theta |.60838037 ------------------------------------------------------------------------------ Random Effects Model with AR1 Correlation structure

38 Marginal Model

39

40 Important Points Modelling the correlation in longitudinal data is important to be able to obtain correct inferences on regression coefficients β There are correspondences between random effect and marginal models in the linear case because the interpretation of the regression coefficients is the same as that in cross-sectional data Correlation can be formulated in terms of subject-specific models and/or transition models Exchangeable correlation model: subject-specific formulation Exponential correlation model: transition model formulation

41 (Still More) Important Points Three basic elements of correlation structure: Random effects Autocorrelation or serial dependence Noise, measurement error Incorporating correlation into estimation of regression models is achieved via weighted least squares

42 (Still More) Important Points There are many ways of estimating correlation parameters. We will study some of these. Correlation models can be approximate We will call these working correlation models (“our best shot”) Regression coefficients estimates will still be correct We will see how to “fix up” standard errors to account for inaccuracies in correlation models

Download ppt "Lecture 4 (Chapter 4). Linear Models for Correlated Data We aim to develop a general linear model framework for longitudinal data, in which the inference."

Similar presentations

Longitudinal Data Analysis for Social Science Researchers Introduction to Panel Models www.longitudinal.stir.ac.uk.

Longitudinal Data Analysis for Social Science Researchers Introduction to Panel Models
Lecture 11 (Chapter 9).

Lecture 11 (Chapter 9).
GENERAL LINEAR MODELS: Estimation algorithms

GENERAL LINEAR MODELS: Estimation algorithms
6-1 Introduction To Empirical Models 6-1 Introduction To Empirical Models.

6-1 Introduction To Empirical Models 6-1 Introduction To Empirical Models.
SC968: Panel Data Methods for Sociologists Random coefficients models.

SC968: Panel Data Methods for Sociologists Random coefficients models.
Lecture 6 (chapter 5) Revised on 2/22/2008. Parametric Models for Covariance Structure We consider the General Linear Model for correlated data, but assume.

Lecture 6 (chapter 5) Revised on 2/22/2008. Parametric Models for Covariance Structure We consider the General Linear Model for correlated data, but assume.
1 Results from hsb_subset.do. 2 Example of Kloeck problem Two-stage sample of high school sophomores 1 st school is selected, then students are picked,

1 Results from hsb_subset.do. 2 Example of Kloeck problem Two-stage sample of high school sophomores 1 st school is selected, then students are picked,
1 FE Panel Data assumptions. 2 Assumption #1: E(u it |X i1,…,X iT,  i ) = 0.

1 FE Panel Data assumptions. 2 Assumption #1: E(u it |X i1,…,X iT,  i ) = 0.
Repeated Measures, Part 3 May, 2009 Charles E. McCulloch, Division of Biostatistics, Dept of Epidemiology and Biostatistics, UCSF.

Repeated Measures, Part 3 May, 2009 Charles E. McCulloch, Division of Biostatistics, Dept of Epidemiology and Biostatistics, UCSF.
Analysis of Clustered and Longitudinal Data Module 3 Linear Mixed Models (LMMs) for Clustered Data – Two Level Part A 1 Biostat 512: Module 3A - Kathy.

Analysis of Clustered and Longitudinal Data Module 3 Linear Mixed Models (LMMs) for Clustered Data – Two Level Part A 1 Biostat 512: Module 3A - Kathy.
1 Nonlinear Regression Functions (SW Chapter 8). 2 The TestScore – STR relation looks linear (maybe)…

1 Nonlinear Regression Functions (SW Chapter 8). 2 The TestScore – STR relation looks linear (maybe)…
Advanced Panel Data Techniques

Advanced Panel Data Techniques
Sociology 601, Class17: October 27, 2009 Linear relationships. A & F, chapter 9.1 Least squares estimation. A & F 9.2 The linear regression model (9.3)

Sociology 601, Class17: October 27, 2009 Linear relationships. A & F, chapter 9.1 Least squares estimation. A & F 9.2 The linear regression model (9.3)
Multilevel Models 4 Sociology 8811, Class 26 Copyright © 2007 by Evan Schofer Do not copy or distribute without permission.

Multilevel Models 4 Sociology 8811, Class 26 Copyright © 2007 by Evan Schofer Do not copy or distribute without permission.
Lecture 6: Repeated Measures Analyses Elizabeth Garrett Child Psychiatry Research Methods Lecture Series.

Lecture 6: Repeated Measures Analyses Elizabeth Garrett Child Psychiatry Research Methods Lecture Series.
1-1 Regression Models  Population Deterministic Regression Model Y i =  0 +  1 X i u Y i only depends on the value of X i and no other factor can affect.

1-1 Regression Models  Population Deterministic Regression Model Y i =  0 +  1 X i u Y i only depends on the value of X i and no other factor can affect.
Shall we take Solow seriously?? Empirics of growth Ania Nicińska Agnieszka Postępska Paweł Zaboklicki.

Shall we take Solow seriously?? Empirics of growth Ania Nicińska Agnieszka Postępska Paweł Zaboklicki.

Linear Regression with One Regression

Linear Regression with One Regression
Multilevel Models 2 Sociology 8811, Class 24

Multilevel Models 2 Sociology 8811, Class 24

Similar presentations

Ads by Google