eatATA
FunctionalityeatATA
efficiently
translates test design requirements for Automated Test Assembly
(ATA
) into constraints for a Mixed Integer Linear
Programming Model (MILP). A number of user-friendly functions are
available that translate conceptual test assembly constraints to
constraint objects for MILP solver. Currently, GLPK
,
lpSolve
, SYMPHONY
, and Gurobi
are
supported as solvers. In the remainder of this vignette we provide an
overview of the functionality of eatATA
. A minimal
ATA
example can be found in the vignette Typical Use of eatATA
: a
Minimal Example, a more complex use case for a pilot study can be
found in the vignette Typical Use of
eatATA
: a Pilot Study Example.
The eatATA
package can be installed from
CRAN
.
As a default solver, we recommend GLPK
, which is
automatically installed alongside this package. lpSolve
and
SYMPHONY
are also freely available open source solvers. If
you want to use Gurobi
as a solver (the most powerful and
efficient solver currently supported by eatATA
), an
external software installation and licensing is required. This means,
you need to install the Gurobi
solver and its corresponding
R
package. A detailed vignette on the installation process
can be found here.
eatATA
provides functions to prepare the item pool for
test assembly:
calculateIIF()
calculatExpectedRT()
dummiesToFactor()
computeTargetValues()
These functions can be used to calculate the item information
function (calculateIIF()
) and expected response times
(calculatExpectedRT()
). dummiesToFactor()
allows the transformation of a variable coded as multiple dummy
variables into a single factor. computeTargetValues()
allows the calculation of target values for test form constraints, but
this functionality is also contained in the
autoItemValuesMinMax()
function.
There also a number of example item pools included in the package: *
items_mini
: A small minimal example item pool *
items_diao
: An item pool modeled after the first problem in
Diao & van der Linden (2011) * items_pilot
: An item
pool for a calibration study * items_lsa
: An item pool for
the block assembly of a large-scale assessment *
items_vera
: An item pool similar to a
Vergleichsarbeiten
item pool
Constraints defining the optimization goal of the automated test assembly:
maxObjective()
minObjective()
maximinObjective()
minimaxObjective()
cappedMaximinObjective()
Here is a list of functions that can be used to set constraints:
Constraints controlling how often an item should or can be used:
depletePoolConstraint()
itemUsageConstraint()
Constraints controlling number of items per test forms:
itemUsageConstraint()
itemsPerFormConstraint()
Constraints controlling categorical properties of items per test forms:
itemCategoryConstraint()
itemCategoryDeviationConstraint()
itemCategoryMaxConstraint()
itemCategoryMinConstraint()
itemCategoryRangeConstraint()
Constraints controlling metric properties of items per test forms:
autoItemValuesMinMaxConstraint()
itemValuesConstraint()
itemValuesDeviationConstraint()
itemValuesMaxConstraint()
itemValuesMinConstraint()
itemValuesRangeConstraint()
Constraints controlling metric properties of items across test forms:
acrossFormsConstraint()
Constraints controlling item inclusions or exclusions within test forms:
itemExclusionConstraint()
itemInclusionConstraint()
Input for the inclusion and exclusion function can be prepared using:
itemTuples()
matrixExclusionTuples()
stemInclusionTuples()
After defining all required constraints using the functions above,
useSolver()
can be used to call the desired solver.
Optionally, constraints can be combined beforehand using the
combineConstraint()
function.
useSolver()
structures the output consistently,
independent of the solver used. This output can be further processed by
inspectSolution()
(to inspect the assembled booklets) and
appendSolution()
(to append the assembly information to the
existing item data.frame
).
Test form assembly might be performed in a two stage process, first
assembling booklets from items and then assembling test forms from
booklets. In this case, item exclusions might translate to exclusions on
booklets level. Booklet exclusions can exist between booklets of one
automated booklet assembly run or between booklets of multiple automated
booklet assembly runs. For the first case,
analyzeBlockExclusion()
can be used to inspect booklet
exclusions. For the second case,
analyzeComplexBlockExclusion()
can be used to inspect
booklet exclusions.