Abstract:
In Sri Lanka, there is about 156,000 km length of roads and among those about 92% are
considered as rural roads (LVRRs). These roads are playing a pivotal role in community
development, transport of people, goods, and services in the rural areas by providing
connectivity between residential, agricultural areas and the national road network. In the
future, with rapid motorization takes place, it is expected the traffic volume on these roads will
increase significantly. Limited funding, subjective and ad-hoc maintenance decision making
has resulted in suboptimal maintenance level for these road networks. Moreover, the inability
to collect extensive data which are needed to run most of the existing pavement management
systems (PMSs) and the technical expertise required has resulted in the low usage of such
systems by local road agencies. Therefore, there is a need to develop a cost-effective simplified
approach for network-level decision-making to assist in pavement maintenance management.
The study explored the applicability of smartphone-based roughness data to assess the
pavement condition of LVRRs as a novel pavement performance evaluating criteria by
validating its accuracy compared with a Class III type roughness measurement equipment. The
correlation value between the two measurements was high as 0.84. Even though, the
relationship has shown that smartphone roughness slightly underestimates road roughness still
it can apply to LVRRs as a cost-effective, accurate method. Moreover, it was assessed whether
roughness results represent pavement distress conditions in the LVRRs. Regression models
were developed to find the relationship between International Roughness Index (IRI) and key
distress types. It was found that Raveling, Edge Breaking, Pothole, Edge Breaking, Edge Gap
has shown a good correlation with IRI as 0.61, 0.56, 0.55, 0.52 respectively. Further, to
evaluate the combined effect of distress on IRI progression, stepwise multiple regression
analysis was conducted by considering the roadway width and the model for narrow roads had
an R-squared of 0.89. For the wider roads the model accuracy is high as with R-squared of
0.86. Interestingly, pothole was identified as the key distress type in both models while edge
breaking and edge gap only relevant in narrow roads. Finally, IRI progression was evaluated
with the Pavement Condition Index (PCI) and a non-linear relationship was found with an Rsquared
of 0.75 from the sigmoidal function. Moreover, relationship between IRI with
Pavement Serviceability Rating (PSR) was evaluated and found that a good relationship with
R-squared of 0.76 for the model.
The relevant maintenance strategies used for LVRRs were identified by establishing threshold
and trigger values based on the works of literature and current practice in the Sri Lankan
context. To support the decision-making criteria, an analysis scheme was developed by using
a defined decision tree. The objective function was established as the minimization of the
average network IRI value which represents the maximum network condition. Two analysis
systems were developed; one with Integer Programming and the other with a Genetic
Algorithm (GA) based system. In addition to that, Engineer’s judgment was compared with the
two methods by using an illustrative example. From the results, it was found that GA is always
provided the optimum work program while Integer Programming merged into a suboptimal
level. Although Engineer’s objective decision-making has shown significant variation when
there is a budgetary constraint. However, when there is a sufficient amount of budget available
most of the Engineer’s judgments were also close to the optimum solution.
Further, in this study socio-economic importance was incorporated in the maintenance
planning decision-making scheme by using the multi-objective optimization analysis. A socioeconomic
priority index was developed by using the priority factors namely traffic volume,
land use, community importance & accessibility to the road network. In there, a network-level
maintenance strategy budget estimation tool will also be introduced by considering different
road surface conditions and maintenance strategies used in LVRRs. The set of optimal
solutions for the multi-objective problem generated using the ‘Pareto Optimality’ concept. A
case study was performed and found that the method would be useful in prioritizing the roads
having socio-economic importance. Furthermore, another illustrative example was performed
by incorporating safety performance in decision criteria using a predefined parameter called
Cumulative Safety Index (CSI). The study has also shown that rather than spending money on
optimizing a single objective, optimization of multiple objectives at a time would be a better
option since the improvement of the existing network is higher in that case. Moreover, the
multi-objective optimization approach would provide ability to include objective functions
which cannot be incorporated in single objective optimization approach.
The core attributes of the proposed system are, reduced the data requirements, simplified the
analytical tools and allowing users to customize considering the resource constraints in
prioritization and optimization and that would allow road agencies to make objective decisions
and optimize the road maintenance process. The finding from this research can be used for maintenance planning for local road authorities in Sri Lanka as well as for other developing
countries by adopting the parameter defining for their local context.
Citation:
Sandamal, R.M.K. (2021). Development of network level pavement management system for low volume rural roads [Master's theses, University of Moratuwa]. Institutional Repository University of Moratuwa. http://dl.lib.uom.lk/handle/123/21360