Each model’s key features have been

Each model’s key features have been summarized, its theoretical
basis has been discussed and any relationship between the model
and other models are identified. A systematic performance assessment
for the 68 of the reviewed models is then presented. Based on
this study, the following observations and conclusions can be
drawn:
1. In the predictions of ultimate conditions, in general, the designoriented
models perform better than analysis-oriented models.
Furthermore, in general, the performance of the design-oriented
models increase with the size of the database used in
their development and the analysis-oriented models with
explicitly derived dilation relationships perform better than
those with implicitly adopted dilation relationships.
2. Of the 68 FRP-confined concrete stress–strain models assessed,
those by Lam and Teng [12] and Tamuzs et al. [80] are the most
accurate for the predictions of the ultimate strength and strain
enhancement ratios, respectively. Both of these models are
design-oriented.
3. The common modeling issues that compromises model accuracies
include: the use of relatively small test databases in the
development of design-oriented models (e.g. [1,9,52]) and the
use of implicitly determined dilation relationships in the development
of analysis-oriented models (e.g. [11,67,68]).
4. Accuracy of the models that make use of the hoop rupture
strains (eh,rup) are, in general, significantly higher than the models
that directly use the ultimate tensile strain of fibers (ef). The
performance difference between these models is particularly in
the prediction of the ultimate strain enhancement ratios, and
most of the better performing models employe rupture strain
efficiency factors (ke) in their expressions.
5. Through the analysis of the results in the database, the average
values of the hoop strain reduction factors based on fiber and
FRP properties (ke,f and ke,frp) are determined as 0.641 and
0.685, respectively. The observed variation of the average ke values
with fiber type points to the possible influence of the type
of fibers on the strain reduction factor.
6. The model prediction errors associated with the prediction of
ultimate axial strains (ecu) are significantly larger than those
of ultimate strengths f 0
cu
 
. These higher prediction errors are
partly caused by the sensitivity of the ultimate strains to the
type of FRP used as confinement, and the inability of the majority
of the models to accurately predict this influence.
There is no doubt that the great number of studies conducted
in the past two decades has led to a good understanding of the
behavior of FRP-confined normal-strength concrete in circular
sections. However, there are still a number of areas where further
research is required. One such area involves the study of
the influence of the type of FRP on the ultimate conditions of
FRP-confined concrete and on the strain reduction factor (ke) of
the FRP jacket.
The model assessment that has been presented herein clearly
indicates the important influence of the size and reliability of the
test databases used in the model development on the overall
performance of the models, especially for the design-oriented
models. Therefore, it is recommended that a carefully chosen
selection criteria is applied in the future database development
efforts. Although the analysis-oriented models with explicitly derived
dilation relationships (e.g. [62,107]) perform reasonably
well, in the future, accuracies of these models can be further improved
through better modeling of the lateral-to-axial strain
behavior of FRP-confined concrete. Furthermore, in future analysis-
oriented model development efforts, due attention should be
given to the implications of the path dependency assumption
discussed in detail in Section 3.2