| Title | Data mining the Kansas traffic-crash database : final report. |
|---|---|
| Record ID | 31206 |
| Personal Name Creator |
Najjar, Yacoub M.; Mandavilli, Srinivas |
| Source | 165p. in various pagings |
| Corporate Creator | Kansas State University. Civil Engineering Dept. |
| Corporate Contributor |
Kansas. Dept. of Transportation. Bureau of Materials & Research |
| Publisher | Kansas. Dept. of Transportation. Bureau of Materials & Research |
| Publication Date | 20090800 |
| Language | English |
| Abstract | Traffic crashes results from the interaction of different parameters which includes highway geometrics, traffic characteristics and human factors. Geometric variables include number of lanes, lane width, median width, shoulder width, roadway section length, and shoulder width while traffic characteristics include AADT, Percentage of Heavy Vehicles and Speed. The effect of these parameters can be correlated by crash prediction models that predict crash rates at particular roadway section. Transportation Agencies and State Departments of Transportation are continuously faced with decisions concerning the safety of highways. The evaluation and comparison of alternative long-range highway plans should include the safety implications of respective plans. The commonly available models for safety analysis are crash prediction models. By performing an in-depth analysis of crash databases and developing crash rate prediction models, better decisions can be taken in regard to future traffic planning operations. The main objective of this study is to utilize artificial neural network techniques and develop crash rate prediction models for Kansas road networks. Six networks have been studied and crash prediction models for each network have been developed. The models developed for each of the road networks are unique and show that geometric variables and traffic have a significant impact on the crash behavior. The models developed in this study would be utilized by Kansas Department of Transportation in evaluating roadway design features, reconstruction impacts and to make decisions in regard to future traffic planning operations. Sensitivity analysis was performed on all the geometric variables in the models. It has been found that all the continuous variables have different effects on different networks. It is very difficult to generalize the behavior of a particular variable. The same results were observed for categorical variables, too. Vehicle Type, Driver age and seat belt use by drivers have also been studied and it has been found that Driver Age Group (18-20) has the highest involvement in crashes on all road networks. Passenger cars have the highest crash involvement among vehicle types and among all vehicle types; bus drivers have the highest seat belt compliance for all networks. This research serves as a starting point to demonstrate the use of artificial neural networks to develop crash rate prediction models that could present useful insight to the potential corresponding safety and traffic operation performance. |
| Rosap ID | dot:5667 |
| Rosap URL | https://rosap.ntl.bts.gov/view/dot/5667 |
| TRT Terms | Crash analysis; Highway safety; Crashes |
| General Subjects | Traffic accidents--Statistical methods; Traffic safety--Statistical methods; Data mining--Kansas; Information storage and retrieval systems--Traffic accidents |
| Classification | NTL - SAFETY AND SECURITY - Accidents; NTL - SAFETY AND SECURITY - Highway Safety |
| Geographical Coverage |
Kansas |
| OCLC | 456694580 |
| Contract Number | C1532 |
| Report Number | K-TRAN: KSU-05-6 |
| Resource type | Tech Report |
| URL | https://ntlrepository.blob.core.windows.net/lib/31000/31200/31206/KSU-05-6_FinalReport.pdf |
| Alternative URL | http://www.ksdot.org/PublicLib/publicDoc.asp?ID=003794662 |
| Format | |
| Database | NTL Digital Repository |