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April 10, 2013 - May 13, 2026

Available Issues

April 10, 2013 - May 13, 2026

Stochastic Projection-Factoring Method Based on Piecewise Stationary Renewal Processes for Mid- and Long-Term Traffic Flow Modeling and Forecasting

Published Online:9 Nov 2015https://doi.org/10.1287/trsc.2015.0607

References

  • AASHTO (1992) Guidelines for traffic data programs, joint task force on traffic monitoring standards of the AASHTO Highway Subcommittee on Traffic Engineering. American Association of State Highway and Transportation Officials, Washington, DC.Google Scholar
  • AASHTO (2004) Mechanistic-Empirical Pavement Design Guide (American Association of State Highway and Transportation Officials, Washington, DC).Google Scholar
  • Ardakani KM, Sun L (2012) Decremental algorithm for adaptive routing incorporating traveler information. Comput. Oper. Res. 39(12):3012–3020.CrossrefGoogle Scholar
  • Ben-Akiva M, Bierlaire M, Burton D, Koutsopoulos HN, Mishalani R (2001) Network state estimation and prediction for real-time traffic management. Networks Spatial Econom. 1(3/4):293–318.CrossrefGoogle Scholar
  • Bendat JS, Piersol AG (1986) Random Data: Analysis and Measurement Procedures (John Wiley & Sons, Inc., New York).Google Scholar
  • Bethea RM, Rhinehart RR (1991) Applied Engineering Statistics (Marcel Dekker, New York).Google Scholar
  • Bhat CR, Koppelman FS (1999) Activity-based modeling for travel demand. Hall RW, ed. The Handbook of Transportation Science (Kluwer Academic Publishers, Norwell, MA), 35–61.CrossrefGoogle Scholar
  • Blumenfeld D (2001) Operations Research Calculations Handbook (CRC Press, Boca Raton, FL), 7.CrossrefGoogle Scholar
  • Box GEP, Jenkins GM, Reinsel GC (1994) Time Series Analysis Forecasting and Control (Prentice Hall, Englewood Cliffs, NJ).Google Scholar
  • Buckley DJ (1962) Road traffic headway distribution. Proc., 1st ARRB Conf. Vol. 1(1), 153–186.Google Scholar
  • Buckley DJ (1968) A semi-Poisson model of traffic flow. Transportation Sci. 2(2):107–132.LinkGoogle Scholar
  • Cambridge Systematics, Inc. (1995) Virginia state traffic monitoring standards. Virginia Department of Transportation, Richmond, VA.Google Scholar
  • Cambridge Systematics, Inc. (1998) Traffic load monitoring and projections. Report DTFH61-95-C-00060, Federal Highway Administration, Washington, DC.Google Scholar
  • Casella G, Berger RL (1990) Statistical Inference, 2nd ed. (Duxbury, Belmont, CA).Google Scholar
  • Chang M, Kim Y (2000) Development of capacity estimation method from statistical distribution of observed traffic flow. Proc. Fourth Internat. Sympos. Highway Capacity, Maui, Hawaii, Transportation Research Board, National Research Council, Washington, DC, 299–309.Google Scholar
  • Cowan JR (1975) Useful headway models. Transportation Res. 9(6):371–375.CrossrefGoogle Scholar
  • Davis GA (1997) Accuracy of estimates of mean daily traffic: A review. Transportation Res. Record 1593:12–16.CrossrefGoogle Scholar
  • Dickey DA, Fuller WA (1979) Distribution of estimators for autoregressive time series with a unit root. J. Amer. Statist. Assoc. 74(366):427–431.CrossrefGoogle Scholar
  • Dickey DA, Fuller WA (1981) Likelihood ratio tests for autoregressive time series with a unit root. Econometrica 49(4):1057–1072.CrossrefGoogle Scholar
  • FHWA (1988) Traffic forecasting for pavement design. Report FHWA-TS-86-225, Federal Highway Administration, Washington, DC.Google Scholar
  • FHWA (1998a) Why does LTPP requires site-specific traffic loading data? LTPP Technical Brief, FHWA-RD-98-103, Washington, DC.Google Scholar
  • FHWA (1998b) WIM scale calibration: A vital activity for LTPP sites. LTPP Technical Brief, FHWA-RD-98-104, Washington, DC.Google Scholar
  • FHWA (1999) Traffic flow theory. Transportation Research Board, National Research Council, Washington, DC.Google Scholar
  • FHWA (2001) Traffic Monitoring Guide. Federal Highway Administration, Washington, DC.Google Scholar
  • Florida Department of Transportation (2002) Project Traffic Forecasting Handbook. Accessed December 2009, http://www.dot.state.fl.us/planning/statistics/pdfs/ptf.pdf.Google Scholar
  • Gibbons JD (1985) Nonparametric Methods for Quantitative Analysis (American Sciences Press, Columbus, OH).Google Scholar
  • Haas R, Hudson WR, Zniewski J (1994) Modern Pavement Management (Krieger Publishing Company, Malabar, FL).Google Scholar
  • Hallenbeck M (1996) Results of the empirical analysis of alternative data collection sampling plans for estimating annual vehicle loads at LTPP sites. Washington State Transportation Center for FHWA, Olympia, WA.Google Scholar
  • Hallenbeck M, Cornell-Martinez C (1998) Accuracy of LTPP traffic loading estimates. LTPP Technical Brief, FHWA-RD-98-124, Washington, DC.Google Scholar
  • Hallenbeck ME, Bowman LA (1984) Development of a statewide traffic counting program based on the highway performance monitoring system. FHWA, Washington, DC.Google Scholar
  • Hamilton JD (1994) Time Series Analysis (Princeton University Press, Princeton, NJ).CrossrefGoogle Scholar
  • Harvey AC (1990) The Econometric Analysis of Time Series, 2nd ed. (MIT Press, Cambridge, MA).Google Scholar
  • Huang YH (1993) Pavement Analysis and Design (Prentice-Hall, Englewood Cliffs, NJ).Google Scholar
  • Idaho Department of Transportation (2004) The effects of errors in annual average daily traffic forecasting: Study of highways in rural Idaho. Final Report KLK253, National Institute for Advanced Transportation Technology, University of Idaho, Moscow, ID.Google Scholar
  • Jarema Fet al. (1997) European traffic monitoring programs and technologies. Federal Highway Administration, Washington, DC.Google Scholar
  • Kosonen I, Bargiela A (1999) A distributed traffic monitoring and information system. J. Geographic Inform. Decision Anal. 3(1):31–40.Google Scholar
  • Kulkarni VG (1995) Modeling and Analysis of Stochastic Systems (Chapman & Hall, New York).Google Scholar
  • Lemer AC, Moavenzadeh F (1971) Reliability of highway pavements. Highway Research Record No. 362, Highway Research Board, Washington, DC.Google Scholar
  • Mahmassani HS (2001) Dynamic network traffic assignment and simulation methodology for advanced system management application. Networks Spatial Econom. 1:267–292.CrossrefGoogle Scholar
  • May AD (1990) Traffic Flow Fundamentals (Prentice Hall, Englewood Cliffs, NJ).Google Scholar
  • Mei M, Bullen AGR (1993) Lognormal distribution for high traffic flows. Transportation Res. Record: J. Transportation Res. Board 1389:125–128.Google Scholar
  • Memmott J (1983) Factors that affect traffic growth rates and projection of traffic count for use in highway economic models. Transportation Res. Records 912:11–15.Google Scholar
  • NCHRP (2002) Development of the 2002 Guide for the design of new and rehabilitated pavement structures. Report 1-37, Washington, DC.Google Scholar
  • NCHRP (2005) Traffic data collection, analysis, and forecasting for mechanistic pavement design, National Cooperative Highway Research Program. Report 538, Transportation Research Board, Washington, DC.Google Scholar
  • NGSIM (2009) The next generation simulation. Federal Highway Administration. Accessed December 2009, http://ops.fhwa.dot.gov/trafficanalysistools/ngsim.htm.Google Scholar
  • Pan Y, Sun L (2012) Characterizing heterogeneity in vehicular traffic speed using two-step cluster analysis. J. Southeast Univ. 28(4):480–484.Google Scholar
  • Pignataro LJ (1973) Traffic Engineering: Theory and Practice (Prentice-Hall, Englewood Cliffs, NJ), 143–163.Google Scholar
  • Robichaud K, Gordon M (2003) An assessment of data collection techniques for highway agencies. J. Transportation Res. Board 1855:129–135.CrossrefGoogle Scholar
  • Schuhl A (1955) The probability theory applied to the distribution of vehicles on two-lane highways. Poisson and Traffic, The Eno Foundation for Highway Traffic Control, Sangatuck, CT.Google Scholar
  • Smith WL (1954) Asymptotic renewal theorems. Proc. Roy. Soc. Edinb., A, 64:9–48.Google Scholar
  • Smith WL (1958) Renewal theory and its ramifications. J. Royal Statist. Soc., B 20:243–302.Google Scholar
  • Stamatiadis N, Allen DL (1997) Seasonal factors using vehicle classification data. Transportation Res. Record 1593:23–28.CrossrefGoogle Scholar
  • Sun L (2014) Spectral and time-frequency analyses of freeway traffic flow. J. Advanced Transportation 48(7):821–857.CrossrefGoogle Scholar
  • Sun L, Deng X (1998) Predicting vertical dynamic loads caused by vehicle-pavement interaction. J. Transportation Engrg. 126(5):470–478.CrossrefGoogle Scholar
  • Sun L, Hudson WR (2005) Probabilistic approaches for pavement fatigue cracking prediction based on cumulative damage using Miner’s law. J. Engrg. Mech. 131(5):546–549.CrossrefGoogle Scholar
  • Sun L, Zhou J (2005) Developing multi-regime speed-density relationships using cluster analysis. J. Transportation Res. Board 1934:64–71.CrossrefGoogle Scholar
  • Sun L, Gu W, Mahmassani H (2011a) Estimation of expected travel time using moment approximation. Canadian J. Civil Engrg. 38(2):154–165.CrossrefGoogle Scholar
  • Sun L, Hudson WR, Zhang Z (2003) Empirical-mechanistic method based stochastic modeling of fatigue damage to predict flexible pavement fatigue cracking for transportation infrastructure management. J. Transportation Engrg. 129(2):109–117.CrossrefGoogle Scholar
  • Sun L, Pan Y, Gu W (2014) Data mining using regularized adaptive B-splines regression with penalization for multi-regime traffic flow models. J. Advanced Transportation 48:876–890.Google Scholar
  • Sun L, Yang J, Mahmassani H (2008) Travel time estimation based on piecewise truncated quadratic speed trajectory. Transportation Res. Part A: Policy Practice 42(1):173–186.CrossrefGoogle Scholar
  • Sun L, Ge M, Gu W, Xu B (2012) Characterizing uncertainty in pavement performance prediction. J. Southeast Univ. 28(1):85–93.Google Scholar
  • Sun L, Zhang H, Gu W, Xu B (2011b) Gaussian mixture models for clustering and classifying traffic flow in real-time for traffic operation and management. J. Southeast Univ. 27(2):174–179.Google Scholar
  • Sun L, Yang J, Mahmassani H, Gu W, Kim BJ (2010) Data mining based adaptive regression for developing equilibrium static traffic speed-density relationships. Canadian J. Civil Engrg. 37(3):389–400.CrossrefGoogle Scholar
  • Texas Department of Transportation (2009) TransGuide. Accessed December 24, 2009, http://www.transguide.dot.state.tx.us/.Google Scholar
  • Texas Transportation Institute (2003) Overview of TxDOT’s traffic data collection and load forecasting process. Research Project Summary Report 1801-S, Texas Transportation Institute, Texas A&M University, College Station, TX, http://tti.tamu.edu/documents/1801-S.pdf.Google Scholar
  • Waddell P, Outwater M, Bhat C (2001) Land use and travel Meand forecasting models. Final Report Prepared for Puget Sound Regional Council, Cambridge Systematics Inc., Boston.Google Scholar
  • Weinblatt H (1996) Using seasonal and day-of-week factoring to improve estimates of truck VMT. Transportation Res. Record 1522:1–8.CrossrefGoogle Scholar
  • Wolff RW (1989) Stochastic Modeling and the Theory of Queues (Prentice Hall, Englewood Cliffs, NJ).Google Scholar
  • Wright T, Hu P, Young J, Lu A (1997) Variability in traffic monitoring data. Final Summary Report, Oak Ridge National Laboratory, Oak Ridge, TN.Google Scholar
  • Xiong W, Sun L, Zhou J (2010) Spline-based multi-regime traffic stream models. J. Southeast Univ. 26(1):122–125.Google Scholar
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