Multilevel time series modelling of antenatal care coverage in Bangladesh at disaggregated administrative levels
Section 5. Selected models and model prediction
5.1 MTS model for ANC0
No transformation for the input series of the direct
estimates or the FH estimates is considered. The following fixed effect
components are included in the selected models for MTS-I, MTS-II, and MTS-III:
where denotes the standardized quantitative year
variable, which defines a fixed effect linear trend. Similarly defines a fixed effect linear trend for each
separate division. The random effects part of the three models is shown in Table 5.1.
If multiple varying effects are modeled, then there is a choice between scalar,
diagonal or full covariance matrix in (4.3). For variation over time, second
order random walks and were finally selected. White noise components
are considered but not included in the final model since it did not further
improve the model fit.
Table 5.1
Summary of the random effect components for the selected time series multilevel model for ANC0. The second and third columns refer to the varying effects with covariance matrix
in (4.3), whereas the fourth column refers to the factor variable associated with
in (4.3). The last column contains the total number of random effects for each component
Table summary
This table displays the results of Summary of the random effect components for the selected time series multilevel model for ANC0. The second and third columns refer to the varying effects with covariance matrix (équation) in (4.3). The information is grouped by Model Component (appearing as row headers), Formula V, Variance Structure, Factor A and # of Effects (appearing as column headers).
| Model Component |
Formula V |
Variance Structure |
Factor A |
# of Effects |
| RIS_District |
|
full |
District |
128 |
| RW2_Division |
Division |
scalar |
RW2(yr) |
147 |
| RW2_District |
District |
scalar |
RW2(yr) |
1,344 |
| Spatial_District |
1 |
scalar |
Spatial(District) |
64 |
The linear predictor of the selected model can be
written, element-wise for district and year as
where is the vector of fixed effects corresponding
to the covariates as specified in (5.1), are random intercepts varying by district, denotes the variable for year and are the corresponding random slopes varying by
district. These random intercepts and slopes are jointly distributed as
The second-order random walk effects at district
and division level are distributed as
where should be read as division to which district belongs. Finally, the spatial effects are distributed as
where is the size of the set of neighbouring districts of district Priors for the covariance matrix in (5.3) and
the other variance parameters are chosen as described in Section 4.1. For
identifiability of the model components, the following constraints are
imposed:
Note that RW2 trends are specified at division and
district levels, both with a scalar variance structure. A division level trend
is shared by all underlying districts. Deviations of each district from this
division-level trend is modeled with RW2 trends at district level. This is a
parsimonious alternative to borrow strength over time and space, compared to
modelling RW2 trends at the district level only with a full covariance matrix (Boonstra and van den Brakel,
2019).
5.2 MTS model for ANC4
The square-root transformation is applied to the input
series of the direct and FH estimates of ANC4 for models MTS-I, MTS-II, and
MTS-III. For MTS-I the GVF (3.3) is applied to the transformed standard errors
to obtain the variance matrix as explained at the end of Subsection 3.5.
For the fixed effect component a factor variable called “Region” has been
created based on the degree of urbanization following Rahman, Mohiuddin, Kafy,
Sheel and Di (2019). The
variable has four levels; 1 for three big cities Dhaka, Chittagong
and Gazipur, 2 for other nine regional big cities (Barisal, Bogra,
Comilla, Khulna, Mymensing, Narayanganj, Rajshahi,
Rangpur, Sylhet), 3 for three hilly districts (Bandarban, Khagrachhari
and Rangamati) and 4 for the remaining districts. This variable mainly
helped to adjust the estimates for the three hilly districts which have very
few (even no) information in the considered seven surveys. The final model has
the following fixed effects components:
The interaction between “Division” and “yr.c” (like
in the ANC0 model) was found to be insignificant in the ANC4 model. The random
effect components for ANC4 model shown in Table 5.2 are very similar to
those used for the model of ANC0 (shown in Table 5.1). A local level trend
instead of smooth trend at division level (RW1_Division in Table 5.2) has
been considered since the smooth trend component (RW2_Division, as in Table 5.1)
resulted in some bias in the national and divisional trends. Also, the model
with RW1_Division component gives better scores for the information criteria
compared to the model with RW2_Division component. White noise components are
considered but not included in the final model since it did not further improve
the model fit.
Table 5.2
Summary of the random effect components for the selected multilevel time series model for ANC4. The second and third columns refer to the varying effects with covariance matrix
in (4.3), whereas the fourth column refers to the factor variable associated with
in (4.3). The last column contains the total number of random effects for each term
Table summary
This table displays the results of Summary of the random effect components for the selected multilevel time series model for ANC4. The second and third columns refer to the varying effects with covariance matrix (équation) in (4.3). The information is grouped by Model Component (appearing as row headers), Formula V, Variance Structure, Factor A and # of Effects (appearing as column headers).
| Model Component |
Formula V |
Variance Structure |
Factor A |
# of Effects |
| RIS_District |
|
full |
District |
128 |
| RW1_Division |
Division |
scalar |
RW1(yr) |
147 |
| RW2_District |
District |
scalar |
RW2(yr) |
1,344 |
| Spatial_District |
1 |
scalar |
Spatial(District) |
64 |
Alternatively, the model can be expressed as in (5.2),
where now and correspond to the fixed effects specification
(5.7). The only other difference is that the division-level trends are now
modelled as a first-order random walk:
where for identifiability reasons the constraint is imposed for all division As in the case of ANC0, RW1 trends are
specified at division and RW2 trends at the district levels, both with a scalar
variance structure as a parsimonious way to borrow strength over time and
space.
5.3 Trend estimation
Trend estimates are computed based on the MCMC
simulation results. In a first step, for each MCMC replicate, an -dimensional vector containing predictions at
the most detailed level of all year-district combinations is computed as
where superscript indexes the retained MCMC draws. Note that also includes predictions for the years
without survey observations. Since a square root transformation was applied to
the ANC4 series, initially the following back-transformation for the vectors was considered following Boonstra et al. (2021):
The second term on the right hand side is a
(relatively small) bias correction using the transformed and smoothed standard
errors. The bias correction stems from the fact that the design expectation of
the direct estimates can be written as
where is the vector of sampling errors after
transformation, assumed to be normally distributed with standard errors A difficulty with the data at hand is that the
bias correction can only be applied to the survey years, since standard errors
are only available for those years. Applying the bias correction only for the
survey years distorts the trend estimates, as illustrated in Das,
van den Brakel, Boonstra and Haslett (2021). In case of MTS-I model,
the impact of this bias correction is most clear for those domains with zero
direct estimates particularly for Chittagong hilly districts. The impact
of the bias correction is less in case of MTS-II and MTS-III models since the
estimated standard errors of the FH estimates are already smoothed enough and
consistent. However, at national and division levels this bias correction
causes some overestimation in some survey years for all the trends based on the
MTS models. Therefore, the bias correction for the square root transformation
is not applied in the trend estimates but only used in the calculation of
cross-sectional FH estimates.
Trend estimates with their standard errors at the most
detailed level of districts for all years are obtained by taking the mean and
the standard deviation over the MCMC replications respectively. Trends at the divisional and
national levels are obtained by aggregating each MCMC replication from the most
detailed regional level of districts, using the number of ever-married women as
a weighting variable. Subsequently, trend estimates and their standard errors
are obtained by taking the mean and the standard deviation over these
aggregated MCMC replications.
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