Help
Cart
Skip main navigation

Available Issues

April 10, 2013 - May 26, 2026

Available Issues

April 10, 2013 - May 26, 2026

Evolution of Fixed Transit to Microtransit Services: A Case Study in Annapolis, Maryland

Published Online:22 Apr 2026https://doi.org/10.1287/inte.2025.0232

References

  • Amalgamated Transit Union (2024) The false promise of microtransit. Technical report, Amalgamated Transit Union, Silver Spring, MD.Google Scholar
  • Arbex RO, da Cunha CV (2015) Efficient transit network design and frequencies setting multi-objective optimization by alternating objective genetic algorithm. Transportation Res. Part B Methodological 81:355–376.Google Scholar
  • Baklagis DG, Dikas G, Minis I (2016) The team orienteering pick-up and delivery problem with time windows and its applications in fleet sizing. RAIRO Oper. Res. 50(3):503–517.Google Scholar
  • Basciftci B, Van Hentenryck P (2020) Bilevel optimization for on-demand multimodal transit systems. Proc. Internat. Conf. Integration Constraint Programming Artificial Intelligence Oper. Res. (Springer, Cham, Switzerland), 52–68.Google Scholar
  • Bertsimas D, Ng YS, Yan J (2021) Data-driven transit network design at scale. Oper. Res. 69(4):1118–1133.LinkGoogle Scholar
  • Bliss L (2017) Microtransit isn’t dead, even if Bridj is. Bloomberg (May 4), https://www.bloomberg.com/news/articles/2017-05-03/microtransit-isn-t-dead-even-if-bridj-is?utm_source=chatgpt.com.Google Scholar
  • Buics L, Prayogo A, Balassa BE (2024) The role of demand-responsive transport systems in sustainable urban mobility: A systematic literature review and stakeholder analysis. Engrg. Proc. 79(1):40.Google Scholar
  • Chen S, Rahman MH, Marković N, Siddiqui MIY, Mohebbi M, Sun Y (2024) Empowering MetroAccess service with nested decomposition and service type integration. INFORMS J. Appl. Anal.Google Scholar
  • Cipriani E, Gori S, Petrelli M (2012) A bus network design procedure with elastic demand for large urban areas. Public Transportation 4(1):57–76.Google Scholar
  • Cohen J (2019) Seattle’s ‘microtransit’ experiment drives people to light rail. Is it working? Accessed April 14, 2025, https://web.archive.org/web/20191228034616/https://crosscut.com/2019/08/seattles-microtransit-experiment-drives-people-light-rail-it-working.Google Scholar
  • Cummings K (2023) Toward microtransit: Design and operations of reservation-based systems. PhD thesis, Massachusetts Institute of Technology, Cambridge, MA.Google Scholar
  • Cummings K, Jacquillat A, Martin-Iradi B (2024) Deviated fixed-route microtransit: Design and operations. Preprint, submitted February 2, https://arxiv.org/abs/2402.01265.Google Scholar
  • Fan W, Machemehl RB (2006) Optimal transit route network design problem with variable transit demand: Genetic algorithm approach. J. Transportation Engrg. 132(1):40–51.Google Scholar
  • Filgueiras M, Gkiotsalitis K, Yap M, Cats O, Lobo A, Ferreira S (2023) Bus network design and frequency setting in the post-COVID-19 pandemic: The case of London. J. Transportation Engrg. Part A Systems 149(4):04023020.Google Scholar
  • Garcia A, Arbelaitz O, Vansteenwegen P, Souffriau W, Linaza MT (2010) Hybrid approach for the public transportation time dependent orienteering problem with time windows. Proc. Internat. Conf. Hybrid Artificial Intelligence Systems (Springer), 151–158.Google Scholar
  • Gavalas D, Konstantopoulos C, Mastakas K, Pantziou G, Vathis N (2015) Heuristics for the time dependent team orienteering problem: Application to tourist route planning. Comput. Oper. Res. 62:36–50.Google Scholar
  • Golden BL, Levy L, Vohra R (1987) The orienteering problem. Naval Res. Logist. 34(3):307–318.Google Scholar
  • Guo Q, Sun Y, Schonfeld P, Li Z (2021) Time-dependent transit fare optimization with elastic and spatially distributed demand. Transportation Res. Part A Policy Practice 148:353–378.Google Scholar
  • Hawkins AJ (2019) Ford’s Chariot commuter shuttle service is shutting down. The Verge. Accessed January 3, 2025, https://www.theverge.com/2019/1/10/18177378/chariot-out-of-business-shuttle-microtransit-ford.Google Scholar
  • Hosseini SS, Azarbayjani M, Lawrence J, Tabkhi H (2023) Towards understanding the benefits and challenges of demand responsive public transit: A case study in the city of Charlotte, NC Preprint, submitted XX, https://arxiv.org/abs/2304.06467.Google Scholar
  • Hu S, Hyland MF, Saha R, Berkel JJ, Vander Veen G (2024) Flexible agent-based modeling framework to evaluate integrated microtransit and fixed-route transit designs: Mode choice, supernetworks, and fleet simulation. Preprint, submitted XX, https://arxiv.org/abs/2405.19527.Google Scholar
  • Hu H, Zhang Y, Wei J, Zhan Y, Zhang X, Huang S, Ma G, et al. (2022) Alibaba vehicle routing algorithms enable rapid pick and delivery. INFORMS J. Appl. Anal. 52(1):27–41.LinkGoogle Scholar
  • Jaw J-J, Odoni AR, Psaraftis HN, Wilson NH (1986) A heuristic algorithm for the multi-vehicle advance request dial-a-ride problem with time windows. Transportation Res. Part B Methodological 20(3):243–257.Google Scholar
  • Jin K, Xia C (2021) Data-driven design of microtransit services via optimal transport and simulated annealing. Proc. 22nd Internat. Workshop Mobile Computing Systems Appl., 179–181.Google Scholar
  • Kaufman B, Burke M, Leung A (2021) Evaluating demand responsive transit services using a density-based trip rate metric. J. Transportation Land Use 14(1):499–519.Google Scholar
  • KCATA (2017) Final report: Bridj pilot evaluation. Technical report, Kansas City Area Transportation Authority, Kansas City, MO.Google Scholar
  • Krishnan V, Iglesias R, Martin S, Wang S, Pattabhiraman V, Van Ryzin G (2022) Solving the ride-sharing productivity paradox: Priority dispatch and optimal priority sets. INFORMS J. Appl. Anal. 52(5):433–445.LinkGoogle Scholar
  • Li H, Lei Z, Ukkusuri SV (2024) Flexible microtransit scheduling with time sensitive travelers. Proc. IEEE 27th Internat. Conf. Intelligent Transportation Systems (IEEE), 2832–2837.Google Scholar
  • Madsen OB, Ravn HF, Rygaard JM (1995) A heuristic algorithm for a dial-a-ride problem with time windows, multiple capacities, and multiple objectives. Ann. Oper. Res. 60(1):193–208.Google Scholar
  • Mayaud J, Ward F, Andrews J (2021) Microtransit has the potential to flip transit on its head. Transportation Res. Rec. 2675(11):77–88.Google Scholar
  • Mitchell S, OSullivan M, Dunning I (2011) Pulp: A linear programming toolkit for python. University Auckland 65(25):2011.Google Scholar
  • Nayeem MA, Rahman MK, Rahman MS (2014) Transit network design by genetic algorithm with elitism. Transportation Res. Part C Emerging Technologies 46:30–45.Google Scholar
  • Ostrowski K (2017) Evolutionary algorithm for the time-dependent orienteering problem. Proc. Conf. Comput. Inform. Systems Industrial Management (Springer), 50–62.Google Scholar
  • Ostrowski K (2018) An effective metaheuristic for tourist trip planning in public transport networks. Appl. Comput. Sci. 14(2):5–19.Google Scholar
  • Pavia S, Rogers D, Sivagnanam A, Wilbur M, Edirimanna D, Kim Y, Mukhopadhyay A, et al. (2024) Smarttransit AI: A dynamic paratransit and microtransit application. Proc. 33rd Internat. Joint Conf. Artificial Intelligence, 8767–8770.Google Scholar
  • Qin Z, Tang X, Jiao Y, Zhang F, Xu Z, Zhu H, Ye J (2020) Ride-hailing order dispatching at DiDi via reinforcement learning. INFORMS J. Appl. Anal. 50(5):272–286.LinkGoogle Scholar
  • Shaheen S, Cohen A (2019) Shared ride services in North America: Definitions, impacts, and the future of pooling. Transportation Rev. 39(4):427–442.Google Scholar
  • Shaheen S, Chan N, Bansal A, Cohen A (2015) Shared mobility: Definitions, industry developments, and early understanding. Technical report, University of California, Berkeley.Google Scholar
  • Shaheen S, Cohen A, Chan N, Bansal A (2020) Sharing strategies: Carsharing, shared micromobility (bikesharing and scooter sharing), transportation network companies, microtransit, and other innovative mobility modes. Transportation, Land Use, and Environmental Planning (Elsevier, Amsterdam), 237–256.Google Scholar
  • Shared-Use Mobility Center (2024) Bridj microtransit shutdown. Technical report, Shared-Use Mobility Center, Chicago.Google Scholar
  • Truden C, Ruthmair M, Kollingbaum MJ (2021) Analysis of schedules for rural first and last mile microtransit services. Proc. Internat. Conf. Comput. Logistics (Springer), 332–346.Google Scholar
  • Veve C, Chiabaut N (2022) Demand-driven optimization method for microtransit services. Transportation Res. Rec. 2676(3):58–70.Google Scholar
  • Wilbur M, Coursey M, Koirala P, Al-Quran Z, Pugliese P, Dubey A (2023) Mobility-on-demand transportation: A system for microtransit and paratransit operations. Proc. ACM/IEEE 14th Internat. Conf. Cyber-Physical Systems, 260–261.Google Scholar
  • Zipper D (2024) Kansas City is a microtransit pioneer and a cautionary tale. Accessed January 3, 2025, https://www.bloomberg.com/news/articles/2024-12-05/kansas-city-is-a-microtransit-pioneer-and-a-cautionary-tale?utm_source=chatgpt.com.Google Scholar
Previous
Back to Top
Next
INFORMS site uses cookies to store information on your computer. Some are essential to make our site work; Others help us improve the user experience. By using this site, you consent to the placement of these cookies. Please read our Privacy Statement to learn more.
Agree