Empirical Analysis of Ambulance Travel Times: The Case of Calgary Emergency Medical Services
Published Online:15 Mar 2010https://doi.org/10.1287/mnsc.1090.1142
References
- Approximating vehicle dispatch probabilities for emergency service systems with location-specific service times and multiple units per location. Oper. Res. (2009) 57(1):251–255Link, Google Scholar
- Locating an ambulance on the Amherst campus of the State University of New York at Buffalo. Interfaces (1990) 20(5):43–49Link, Google Scholar
- A simulation and statistical analysis of stochastic vehicle routing with timing constraints. Decision Sci. (1978) 9(4):673–687Crossref, Google Scholar
- Department of Health Ambulances. (2008) . Accessed November 1, http://www.dh.gov.uk/en/Healthcare/Emergencycare/Modernisingemergencycare/DH_4063824Google Scholar
- Ambulance deployment for maximum survival. Naval Res. Logist. (2008) 55(1):42–58Crossref, Google Scholar
- Response times: Myths, measurement and management. J. Emergency Medical Services (2005) 30(9):46–56Crossref, Google Scholar
- Improving emergency responsiveness with management science. Management Sci. (2004) 50(8):1001–1014Link, Google Scholar
- , Buckley D. J. Trip characteristics of journeys to and from work. Transportation and Traffic Theory: Proc. 6th Internat. Sympos. Transportation and Traffic Flow (1974) (A. W. & A. W. Reed, Sidney, Australia) 57–85Google Scholar
- Time saved with the use of emergency warning lights and sirens during response to requests for emergency medical aid in an urban environment. Ann. Emergency Medicine (1998) 32(5):585–588Crossref, Google Scholar
- Is ambulance transport time with lights and siren faster than that without? Ann. Emergency Medicine (1995) 25(4):507–511Crossref, Google Scholar
- Simulation of single start station for Edmonton EMS. J. Oper. Res. Soc. (2003) 54(7):736–746Crossref, Google Scholar
- Continuous Univariate Distributions (1994) 22nd ed.(Wiley, New York) Google Scholar
- Stochastic vehicle routing with random travel times. Transportation Sci. (2003) 37(1):69–82Link, Google Scholar
- Goodness of fit and related inference processes for quantile regression. J. Amer. Statist. Assoc. (1999) 94(448):1296–1310Crossref, Google Scholar
- , Walker W. E., Chaiken J. M., Ignall E. J. Travel time and travel distance models. Fire Department Deployment Analysis: A Public Policy Analysis Case Study—The Rand Fire Project (1979) (Elsevier North-Holland, New York) 157–201Chap. 6Google Scholar
- Determining the relation between fire engine travel times and travel distances in New York City. Oper. Res. (1975) 23(4):614–627Link, Google Scholar
- Robust statistical modeling using the t distribution. J. Amer. Statist. Assoc. (1989) 84(408):881–896Google Scholar
- National Fire Protection Association NFPA 1710: Standard for the organization and deployment of fire suppression operations, emergency medical operations, and special operations to the public, by career fire departments. (2004) . National Fire Protection Assocation, Quincy, MAGoogle Scholar
- Estimating traveling time/speed. J. Bus. Logist. (1999) 20(2):121–139Google Scholar
- Using the Box-Cox t distribution in GAMLSS to model skewness and kurtosis. Statist. Model. (2006) 6(3):209–229Crossref, Google Scholar
- Price and time competition for service delivery. Manufacturing Service Oper. Management (2000) 2(4):392–409Link, Google Scholar
- Generalized additive models for location scale and shape (GAMLSS) in R. J. Statist. Software (2007) 23(7). Accessed September 1, 2008, http://www.jstatsoft.org/v23/i07Crossref, Google Scholar
- A parallelizable dynamic fleet management model with random travel times. Eur. J. Oper. Res. (2006) 175(2):782–805Crossref, Google Scholar
