Interactive Highway Safety Design Model (IHSDM)

1. Interactive Highway Safety Design Model (IHSDM) By Josh Hinds

2. Outline • Background of IHSDM • Description of the Modules • New Features • An IHSDM Project from Start to Finish • Future Developments • Conclusion The Modules

3. What is IHSDM? IHSDM is a suite of software analysis tools that evaluate the safety and operational effects of the geometric design on two-lane rural highways. (www.ihsdm.org) Background

4. What is IHSDM? • Safety analysis tool, not specifically used for designing. • Evaluates the geometric design of the highway. • Two-lane rural highways • Compares user inputted design to designated design standards. Background

5. Why Was IHSDM Needed? • 77% of the Nation’s highways are two-lane rural highways • 41% of all the fatal crashes occur on two-lane rural highways • Citizens demand increased safety on two-lane rural highways The Modules

6. Why Was IHSDM Needed? • The highway network is getting older. • Stakeholders are expecting safer highways on the same budget. • Highway designs need to be checked for safety ‘black spots’. Background

7. How Does IHSDM Help? • Makes use of five software modules that analyze the geometric design of the highway • Policy Review • Crash Prediction • Design Consistency • Traffic Analysis • Intersection Review Background

8. Framework of the IHSDM Program IHSDM is composed of these modules. Background

9. How Does IHSDM Work? • The user inputs the design file. • The five modules compare the inputted design values to the AASHTO policy standard values. • IHSDM determines how far out of range the values are and provides feedback to the user. Background

10. How Can IHSDM Benefit the Designer? • Intended to be used throughout the design process. • Can be used on new construction and existing facilities. • Provides a Quality Assurance check throughout the design process. Background

11. How Can IHSDM Benefit the Designer? • Find ‘Accident Black Spots’ before construction. • Save money by lowering crash rates and eliminating the reconstruction of unsafe areas. • Double check design values. • Uses design software format. Background

12. How Can IHSDM Benefit the Designer? • Helps project developers improve the expected safety performance of the final design. • Justifies and defends geometric design decisions. Background

13. How Can IHSDM Benefit the Designer? • AASHTO A Policy on Geometric Design of Highways and Streets "Green Book" • AASHTO Roadside Design Guide • AASHTO Guide for Development of Bicycle Facilities • Numerous Editions and Metric/English Background

14. How Can IHSDM Benefit the Designer? • Public perception that the roadway is ‘safe’. • Estimates the expected crash frequency for the geometric design. • Analyzes other safety and operation performance measurements. (SSD, superelevation, etc.) (Turner-Fairbank) Background

15. What is ‘Safe’? • Every roadway will have crashes. • ‘Safe’ (past) • Meeting a minimum set of design criteria. • ‘Safe’ (presently) • Comparison of number of crashes to sites with similar characteristics. (FHWA, Paniati) Background

16. The Modules • FHWA was in charge of all the research • FHWA received input from numerous state agencies, consulting firms, and academic institutions. • Based on research received from field data. The Modules

17. Policy Review Module • Automates the process of checking geometric design elements against relevant design policy standards. • Construction or Reconstruction • Quality Assurance / Quality Control The Modules

18. Policy Review Module • Cross Section (traveled-way, auxillary, shoulder) • Horizontal and Vertical Alignment • Sight Distance • Items with an asterisk will be compared to FHWA standards. The Modules

19. Policy Review Module • Summary of what will be analyzed The Modules

20. Policy Review Module Results The Modules

21. Crash Prediction Module • Identifies improvement projects on existing highways • Estimates the frequency and severity of crashes. • Compares the safety performance of design alternatives • Will assess that safety cost effectiveness of design decisions. The Modules

22. Crash Prediction Module • Uses the Empirical Bayes Method • Algorithm for estimating crashes combines base models and accident modification factors • Highway segments and intersections • 3-leg stop control on the minor • 4-leg with stop control on the minor • 4-leg signalized The Modules

23. The Modules

24. Crash Prediction Module - The crash history The Modules

25. Crash Prediction Module • Table • Crash Rate • By Design Element • By Segment • Crash Type • Graph • Expected Frequency • Crash Rate • By Design Element • By Segment The Modules

26. Crash Prediction Modulus • Module provides a comment section to inform the user of any areas not addressed. • Summary of what will be analyzed, and how the results are formatted. • Module runs analysis. The Modules

27. Crash Prediction Modulus Results The Modules

29. Design Consistency Module • Provides a Quality Assurance check on the consistency of the design. • Allows designer to double-check design assumptions. • Some designs conform to policies, but can not be consistent for the drivers. • Heavily focused on Horizontal Curves. The Modules

30. Design Consistency Module • Drivers are more likely to make mistakes at features that violate their human inclination. • Reduction of speed in tangent before horizontal curve. • Design speed vs. 85th percentile speed. • Design conformance vs. driver’s expectations The Modules

31. Design Consistency • Desired Speed = 85th percentile speed • 62 mph was determined by studies in six states. • Tangent Speed The Modules

32. Design Speed Assumption Check Conditions KeyCondition 1: 0 mph <= (V85 - Vdesign) <= 6 mphCondition 2: 6 mph < (V85 - Vdesign) <= 12 mphCondition 3: 12 mph < (V85 - Vdesign)Condition 4: (V85 - Vdesign) < 0 mphwhere:V85 = estimated 85th percentile operating speed (mph)Vdesign = design speed (mph)

34. Traffic Analysis Module • Evaluates the operational effects of the current and future traffic estimates. • Can be used to determine the effects of alternatives. (realignment, cross-section improvements, and additional passing lanes) • Construction or Reconstruction The Modules

35. Traffic Analysis Module • Uses the TWOPAS rural traffic simulation model for two-lane highways. • QC/QA • Provides documentation for design exceptions • Determines the time following other vehicles The Modules

36. Traffic Analysis Module • Traffic Flow • Traffic characteristics • Highway Elements • Time Parameters • Results The Modules

38. Traffic Analysis Module • TWOPAS • Traffic Simulation Model • User can specify traffic demand and vehicle mix. • Also, can specify horizontal and vertical alignment. • Models 13 types of vehicles with performance characteristics for each. The Modules

39. Intersection Review Module • Not currently used in the 2006 edition. • Research and module are complete. • Still in the final testing phase. • Expect the Intersection Review module to be released very soon as an update to the 2006 edition. The Modules

40. Intersection Review Module • Diagnostic review of the expected performance. • Uses the ‘Expert System’ • Stopping Sight Distance • Corner radius and turn lane design. The Modules

41. The future of IHSDM • IHSDM is constantly being updated for the newest standards. • Research and data collection continues for all modules. • Additional modules are being researched and created. (intersection review) • Multi-Lane highways The Modules

42. Conclusion Questions? The Modules