I am conducting LTA analyses with three continuous variables, each measured at three measurement points. Q1: Is there any literature about "LPTA" at all? Can I use this name in the publication of the results? Q2: Is a multivariate normal distribution of the nine class indicators necessary/important in LPTA? If so, for what parts of the results? Is there literature about this? Q3: Are the AIC, the BIC, and the likelihood-ratio chi-square difference tests tests valid for determining the number of classes in LPTA? Who can I cite on this in my article?
Q1: I don't know of any. Perhaps a literature search would yield something. Q2: No. The model assumes normality within classes not for the mixture of the classes. I know of no literature for this. Q3: Yes. No citation that I know offhand.
I am trying to figure out the model that best matches and can test a set of hypotheses, and I am hoping that you or discussion board readers might have some ideas - including how to implement them in MPlus. I have a identical sets of variables completed by both children and mothers (e.g., mother's religiosity and child's religiosity). The hypotheses involve testing whether consnance/dissonance btw these sets of variables (latent profiles) predicts child development. Separately for children and mothers, I have conducted a LPA and found support for 3 and 4 classes, respectively. Therefore, there is a maximum of 12 possible mother-child combinations - but not all of which will probably be observed with any substantial frequency. I am looking for ideas on how to model jointly child and mother profiles such that I have a single latent class factor that can be regressed on predictors. I can think of two approaches: (1) to specify a single latent class factor with all child and mother variables as indicators, or (2) model two '1st-order' latent class variables (one for mothers, and one for children) and also a '2nd-order' latent class variable with the two 1st-order latent class variables as indicators. Do you have any suggestions on which approach or other approaches I should explore and, if the 'higher-order' model, guidance on the Mplus specification of the model? Thank you!
I would probably not vote for gettting into the second-order modeling. I would choose between having 2 latent class variables, that your correlate using c1# WITH c2#, versus having a single latent class variable. The second alternative would be good if you believe that meaningful classes are define by item profiles involving both child and mother - for example, if a child has a high profile and a mother a low profile.
Thank you Bengt for your advice. I thought that the second-order model would work in a similar way to that of the Mover-Stayer model (8.14 in the User's guide) where the 2nd order latent class factor captures the movers and stayers (in my model, which would not have a direct path connecting 1st order mother/child latent class factors, the 2nd order latent class factor would capture the mom profile and child profile combinations.
I tried the model with 2 latent class variables, but could not get the model to terminate normally (multiple warnings - including that of an ill-conditioned fisher information matrix. I notice that results are provided for every mother by child class cell. (1) What if not all cells have a non-zero frequency. How do I represent that in syntax. (2) Would you recommend the Loglinear or the logistic parameterization? (3) Since I ultimately want to see if a particular combination of mother and child profiles predicts different outcomes, how can I represent that in syntax (e.g., mother/child dyads where moms are in M-class 1 and children are in C-class 2 have higher means on outcome Y than do mother/child dyads in M-class 2 and C-class 3? Thank you!
(1) zero cells are handled automatically by Mplus fixing logits. (2) For the model with 2 latent class variables, you want to correlate them by using parameterization=loglinear and say c1# with c2#. (3) The outcome means/probabilities vary across the combined classes.
I think the single latent class variable approach might be most likely to capture what you look for because it operates directly on the outcomes for mother and child and therefore looks for profile combinations across mother-child. Second best approach is the 2 latent class variables. The second-order modeling only structures the 1st-order latent class variables and therefore can't "see" the observed profile combinations. But I may be wrong.
I am using Mplus 4.1 to find latent classes at three points in time, and then LTA for T1 to T2, and T2 to T3.
I have the same four symptoms (continuous vars) at each time. I have found four latent classes at time 1, and three latent classes at times 2 and 3. Unfortunately, I have a small sample (101, with some missing data at T2 & T3), so I am getting warnings and failures when I try to examine the LTA from T1 to T2, and then from T2 to T3. (I know there is no hope of combining all three times into a single model with so few cases.)
I have reduced the number of parameters to be estimated by holding the correlation matrices equal at each pair of times, and I have specified realistic starting values for the two LTA from the prior LCA analyses. I have found it necessary to specify a large number of random starts in order to get solutions for the LCA at each time, I assume because of the small sample, and also because there is at least one small latent class at each time (e.g., n=5 for the smallest class at time 1, n=16 for the smallest class at T2 and T3).
Finally, the question: I'd like to be able to set some cells to zero for the T1 to T2 LTA, likewise for the T2 to T3 LTA, but I can't figure out how to do it. I'm hoping that would help eliminate the warnings. What MODEL statement can I use to set latent class cell combination to zero?
The warnings may not be fatal, but merely refer to fixing extreme values for parameters corresponding to zero or unit probabilities. Ask for Tech1 and see if the fixed parameters are those with large values - then you are fine. Fixing transition probabilities to zero requires Model Constraint because a zero probability is obtained as a function of several logit parameters - see UG Chapter 13.
The part about extreme values is true; I believe the warnings cascade from it. I have specified 3 LC at each of 2 times, based on fatigue, sleep disorder, depression, & worst pain scores.
Some LT classes do not exist or are unlikely from T1 - T2. For example, a small class at T1 reports very high levels on all symptoms. After undergoing chemotherapy, this group would not be likely to report no or very low symptoms at T2, a structural zero. Another group of patients, who all reported very high sleep disturbance and moderate fatigue at T1, but only some pain and no depression, might not be expected to report no or very low symptoms T2, a sampling zero.
I have looked at the sections you suggested in Ch.13, as well as looking over the examples in Ch.8 (esp. 8.13), but I have not been able to figure out how to specify fixed zeros for likely structural or sampling zeros, to see if the model would run without the dire warnings.
I have included a portion of the output for the cell sizes for the LC and LT patterns below, if you care to look at it.
If the warnings stem from extreme values, then that is ignorable. These extreme values give you the zeros you observe for some latent class patterns. In other words, you don't have to bother with imposing structural zeroes.
Structural zeros can be imposed by looking at Chapter 13's loglinear parameterization. You want a zero cell and get it by fixing a "b" coefficient to a low value such as -15.
I have questions concerning the merger of Latent Profile Analysis (LPA) and Latent Transition Analysis (LTA).
I have a dataset with 6 continuous variables measured at 2 timepoints. I conducted LPA’s at both timepoints and 3 classes/subpopulations were supported at each timepoint.
Now what I want to do is estimate the probability of moving from each of the classes at time 1 to each of the classes at time 2 (c1 to c1, c1 to c2, c1 to c3, c2 to c1, and so on).
1)I thought this would be a merger of LPA and LTA. Does that sound correct? If so, can MPLUS handle this (what manual example is it)? Do you know of any published examples? If the merger of LPA and LTA is not the technique I should be looking for, what is?
2)Almost all examples of LTA I find use categorical variables. Two papers (Dolan, Jansen, van der Mass, 2004; Schittmann, Dolan, van der Mass & Neal, 2005) used continuous variables to model transition. They call this the Mixed Markov latent class (MMLC) model for continuous data. They explain that this model “can be viewed as finite mixture models, where each unique sequence of latent classes represent a distinct mixture component” (p. 462). Therefore, I wasn’t certain if this was equivalent to the combination of LPA and LTA. Is it? Also, does the MMLC model for continuous data correspond to any examples in the MPLUS manual?
1) It is indeed a merger of LPA and LTA and it can be done in Mplus. Start with UGex8.13 and instead of having thresholds change over the classes you have the means of the items changing over classes. Mplus can use any type of observed item scale in combination with any other (dichotomous and continuous combined for example).
2) It sounds like MMLC is exactly what I describe in 1).
Bengt, Thanks for the response about LTA and LPA. I had thought 8.13 best matched our research question.
Just to be clear, will running a model like 8.13 but with continuous variables produce (1) classes at Time1, (2) classes at Time2, and (3) classes for the various types of change (sequence of latent class membership across time which are transition probabilities)?
*Or* if I found 3 classes at each time point using LPA should I use those results to set the time specific class parameters, and just freely estimate the transition probabilities when running the LTA?
Also, the difference between 8.13 and both 8.12 and 8.14 seem slight and I feel like I may be missing something.
Is the difference between Hidden Markov Model (8.12) and LTA (8.13) simply the fact that LTA can have multiple indicators creating the classes? It seems that LTA is a type of Markov model.
Also the only difference between 8.13 and 8.14 is the addition of the "c" categorical latent variable. Does this variable use the transition probabilities to form overarching groups of "movers" and "stayers" (levels of C)?
I was trying to understand some of the applications in LTA and noticed that almost always the number of latent states is equal to the number of time points in the data. Moreover, the transition probabilities are modeled as a function of intercepts and means as you state above. My questions are: 1) Does mplus allow a model in which number of hidden states is different from number of time points? 2) the transition probabilities are a function of time-varying covariates ?
Julia Lee posted on Friday, September 30, 2011 - 8:25 am
I am analyzing my data using LTA (mover-stayer model). The data set is comprised of continuous variables. In order to make sense of the interpretation of classes, I am guessing that requesting for confidence interval is a good way to deal with the issue at the moment. 1) Is there a way I could request for confidence interval for LTA? 2) On page 647 UG Version 6, CINTERVAL is available for 3 settings. Which settings do I use if CI can be done for LTA? 3) What is the main difference between BOOTSTRAP, and BCBOOTSTRAP? Do I choose either one if I think there is nonnormality? I would appreciate some input on papers to read.
I don't think you need confidence intervals to interpret the classes. You can look at the item profiles for each class. If you want confidence intervals, you can use the CINTERVAL option. You can use BOOTSTRAP or BCBOOTSTRAP if you think the parameter has a non-normal distribution. I don't think you need to worry about this non-normality to interpret classes. See the Efron and MacKinoon 2004 references in the user's guide.
Joan Reid posted on Friday, October 05, 2012 - 2:49 am
I have a question regarding the best model to use with multi-informant data. I have information from youth and parent regarding youth behavior and would like to examine whether the latent class variables resulting from the 2 sources are similar or dissimilar, and if youth are placed in similar or dissimilar classes based on informant. I have found a 4-class solution for both sets of data.
Next, I followed example 7.14 in the user's guide to correlate two latent variables (resulting in 16 possible class combinations from the latent variables with 4 classes).
Based on your responses above (to Scott Weaver on August 5/6, 2006), I think this is the best way to investigate and model the multi-informant data. Is this an appropriate approach?
I am wondering if it is possible to do a LPTA with continuous latent variables as indicators. That is, a second order categorical latent variable with continuous first order factors as indicators.
If yes, should strong measurement invariance restrictions be imposed on the continuous LV measurement models? (because the categorical LV compares the latent means of subpopulations)
If no, one could estimate factor scores for the continuous LVs and use these as LPTA indicators in subsequent analyses. Should these factor scores be estimated from a model with strong measurement invariance restrictions?