Fundamentals of Transportation/Route Choice/Solution

Problem

Example. Given a flow of six (6) units from origin “o” to destination “r”. Flow on each route ab is designated with Qab in the Time Function. Apply Wardrop's Network Equilibrium Principle (Users Equalize Travel Times on all used routes)

A. What is the flow and travel time on each link? (complete the table below) for Network A

These four links are really 2 links O-P-R and O-Q-R, because by conservation of flow Qop = Qpr and Qoq=Qqr.

By Wardrop's Equilibrium Principle, The travel time (cost) on each used route must be equal. So ${\displaystyle C_{opr}=C_{oqr}}$. OR ${\displaystyle 25+6*Q_{opr}=20+7*Q_{oqr}}$ ${\displaystyle 5+6*Q_{opr}=7*Q_{oqr}}$ ${\displaystyle Q_{oqr}=5/7+6/7Q_{opr}}$

By the conservation of flow principle ${\displaystyle Q_{oqr}+Q_{opr}=6}$ ${\displaystyle Q_{opr}=6-Q_{oqr}}$ By substitution ${\displaystyle Q_{oqr}=5/7+6/7(6-Q_{oqr})=41/7-6/7Q_{oqr}}$ ${\displaystyle 13/7Qoqr=41/7}$ ${\displaystyle Q_{oqr}=41/13=3.15}$ ${\displaystyle Q_{opr}=2.84}$ Check ${\displaystyle 42.01=25+6(2.84)?20+7(3.15)=42.05}$ Check (within rounding error)

or expanding back to the original table:

User Equilibrium: Total Delay = 42.01 * 6 = 252.06

B. What is the system optimal assignment?

What is the system optimal assignment for the previous example

Conservation of Flow:

${\displaystyle Q_{oqr}+Q_{opr}=6}$

${\displaystyle TotalDelay=Q_{opr}(25+6*Q_{opr})+Q_{oqr}(20+7*Q_{oqr})}$

${\displaystyle 25Q_{opr}+6Q_{opr}^2+(6-Q_{opr})(62-7Q_{opr})}$

${\displaystyle 25Q_{opr}+6Q_{opr}^2+372-62Q_{opr}-42Q_{opr}+7Q_{opr}^2}$

${\displaystyle 13Q_{opr}^2-79Q_{opr}+372}$

Analytic Solution requires minimizing total delay

${\displaystyle \delta C/\delta Q=26Q_{opr}-79=0}$

${\displaystyle Q_{opr}=79/26=3.04}$

${\displaystyle Q_{oqr}=6-Q_{opr}=2.96}$

And we can compute the SO travel times on each path

${\displaystyle C_{opr,SO}=25+6*3.04=43.24}$

${\displaystyle C_{oqr,SO}=20+7*2.96=40.72}$

Note that unlike the UE solution, ${\displaystyle C_{opr,SO}>C_{oqr,SO}}$

Total Delay = 3.04(25+ 6*3.04) + 2.96(20+7*2.96) = 131.45+120.53= 251.98

Note: one could also use software such as a "Solver" algorithm to find this solution.

C. What is the Price of Anarchy?

User Equilibrium: Total Delay =252.06 System Optimal: Total Delay = 251.98

Price of Anarchy = 252.06/251.98 = 1.0003 < 4/3