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run_simulation.m
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run_simulation.m
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function [mean_wait, median_wait]=run_simulation(horizons)
% Ported from AMoD_congestion on June 1, 2017
%road map specifications:
% - list of node positions
% - list of neighbors for each node
% - link capacities, where each link is defined by the tuple (u,v). The
% link capacities will be implemented as a sparse matrix
% - link freeflow speed
% Congestion model
% travel time function using the BPR formula, gives the travel time as a
% function of how many vehicles are on the link.
% Option 1: The speed of each link at
% each time step is determined by the number of vehicles in that link at
% that time. ---> *use this one*
% **Option 2: The travel time of each
% vehicle is determined upon its arrival to a link. The vehicle's speed is
% then found from its travel time.
% 1. group all vehicles entering a link.
% 2. calculate speeds for all vehicles that just entered the link
% Simulation parameters:
% 1. for each link (u,v)
% - unit vector for the direction of each link
% - number of vehicles in the link
% - current speed for the link (calculated every time step based on the
% utilization/number of vehicles)
% 2. for each vehicle
% - path from origin to destination (path calculated with A*). Path should
% be a list of nodes
% - current position vector
% - current stage of trip (index of which node it most recently passed).
% This also provides the current link the vehicle is on
% 3.
%clear all;
addpath('C:\Program Files\IBM\ILOG\CPLEX_Studio126\cplex\matlab\x64_win64');
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
timeStep = 10; % number of time steps per minute
dt = 60/timeStep; % length of each time step
Tmax = 60*24*timeStep; % simulation time
Thor = 5*timeStep; % rebalancing time horizon (for real-time algorithm) for vehicles
Tthresh = 0; % at what time to start gathering data
v = 5000;
rebPaths = cell(0);
ccTmp = 1;
cc = 1;
PLOTFLAG = 0;
PLOTREBFLAG = 1;
NAIVEFLAG = 1;
rebCount = 1;
MPCFLAG = 1;
look_back = num2str(horizons.lb);
look_forward = num2str(horizons.lf);
suffix = strcat(look_back,'b_',look_forward,'f_np')
SIMNAME = strcat('MPC-LSTM-MILP-', suffix);
if MPCFLAG
% HACKY SHIT: LOADS THE REAL TRIP COUNT BY 5MIN
load('didi.mat')
load(strcat('ignored_assets/predictors/tod_predictions_',suffix,'.mat'))
end
if PLOTFLAG
movieCounter = 1;
writerObj = VideoWriter('mymovie.avi');
writerObj.FrameRate = 30;
open(writerObj);
cars_fig = figure('Position',[10 10 1920 1080],'MenuBar','none','ToolBar','none','resize','off')
roads_fig= figure('Position',[10 10 1920 1080],'MenuBar','none','ToolBar','none','resize','off')
cmap=colormap('jet');
crange=size(cmap,1);
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% variable definitions
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
BuildCityMap;
% N = number of nodes
% RoadGraph = list of neighbors
% NodesLocation = x and y location of each node
% NodesLatLon = lat and lon of each node
%
if MPCFLAG
% MPC variables
predictionStep = 5*timeStep; % number of steps a prediction covers
horizon = 50; % longest travel time is 44 steps...
RoadNetwork.T = horizon;
RoadNetwork.RoadGraph = RoadGraph;
RoadNetwork.TravelTimes = TravelTimes;
Flags.milpflag = 1;
Flags.congrelaxflag = 0;
Flags.sourcerelaxflag = 1;
Flags.cachedAeqflag = 0;
RebWeight = 5.0; % how much more expensive it is to rebalance than to remain idle
end
LoadStateDefinitions;
numStations = length(StationNodeID);
for i = 1:numStations
station(i) = struct('id',i,'carIdle',[], 'custId',[], 'carOnRoad',[],...
'custUnassigned',[],'waitTimes',[], 'arriveHour', [], 'node_id', StationNodeID(i));
end
% for naive rebalancing
if NAIVEFLAG
rebalanceQueue = cell(numStations,1);
% define Tij
%Tij = zeros(numStations, numStations);
%for i = 1:numStations
% for j = 1:numStations
% Tij(i,j) = norm(StationLocation(j,:) - StationLocation(i,:), 1);
% end
%end
Tij=LinkTime;
end
% data collection
avgWaitTimes = zeros(Tmax,1);
cumNumCustomers = zeros(Tmax,1);
numVehiclesBusy = zeros(Tmax, 1);
numVehiclesRebalancing = zeros(Tmax, 1);
numVehiclesDrivingToPickup = numVehiclesRebalancing;
numVehiclesDrivingToDest = numVehiclesRebalancing;
numVehiclesDrivingToStation = numVehiclesRebalancing;
numVehiclesOnSelfLoop = numVehiclesRebalancing;
numVehiclesIdle = numVehiclesRebalancing;
numVehiclesNotRebalancing = zeros(Tmax, 1);
%numCarsOnLink = cell(Tmax);
carsIdlePrint=zeros(Tmax,numStations);
carsOnRoadPrint=zeros(Tmax,numStations);
custUnassigned=zeros(Tmax,numStations);
custWaiting=zeros(Tmax,numStations);
%
numRebTasks = zeros(Tmax,numStations);
%
milpOutputs = zeros(Tmax, 5);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% load demand data
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
fprintf('Loading demand data...')
filename = 'ignored_assets/MATLAB_orders.csv';
MData = csvread(filename,1,1);
arrivalTimeOffset = (0*3600 + -5*1*60 + 0)/60*timeStep;
arrivalTimes = (MData(:,3)*3600 + MData(:,4)*60 + MData(:,5))/60*timeStep - arrivalTimeOffset;
fprintf('loaded!\n')
% but just start at the arrivalTimeOffset
while arrivalTimes(ccTmp) < 0
ccTmp = ccTmp + 1;
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% declare data structures for cars
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% struct for each car
stationCounter = 1;
for i = 1:v
car(i) = struct('id',i,'passId', 0, 'dstation',stationCounter,'ostation',stationCounter,...
'dpos', [], 'state', IDLE, 'pos', NodesLocation(station(stationCounter).node_id, :),...
'direction',[], 'path', [StationNodeID(stationCounter)], 'time_left', 0, 'speedfactor', 1);
% update station data for this car
station(stationCounter).carIdle = [station(stationCounter).carIdle, i];
if stationCounter == numStations
stationCounter = 1;
else
stationCounter = stationCounter + 1;
end
end
%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% Begin Simulation: main loop
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
for t = 1:Tmax-1
% update LinkTime variable
% go through all the links (i,j)
%No congestion
%for i = 1:N
% for j = RoadGraph{i}
% [tmpLinkTime, tmpLinkSpeed] = getSpeed(LinkNumVehicles(i,j), RoadCap(i,j), LinkFreeFlow(i,j), LinkLength(i,j));
% LinkTime(i,j) = tmpLinkTime;
% LinkSpeed(i,j) = tmpLinkSpeed;
% end
%end
LinkSpeed=LinkFreeFlow;
for i=1:numStations
carsIdlePrint(t,i)=length(station(i).carIdle);
carsOnRoadPrint(t,i)=length(station(i).carOnRoad);
custUnassigned(t,i)=length(station(i).custUnassigned);
custWaiting(t,i)=length(station(i).custUnassigned) + length(station(i).custId);
end
carsIdlePrint(t,:)+carsOnRoadPrint(t,:);
fprintf('Time: %d, Unassigned Customers: %d, Waiting Customers: %d, Total Customers: %d \n', t, sum(custUnassigned(t,:)), sum(custWaiting(t,:)), cc-1)
% vehicle state transitions
for i = 1:v
if car(i).state ~= IDLE && car(i).state ~= SELF_LOOP && length(car(i).path) == 2 % if it's on the last leg of its trip
distToDest = norm(car(i).dpos - car(i).pos,2);
if distToDest < car(i).speedfactor * LinkSpeed(car(i).path(1), car(i).path(2))*dt
% remove car from link
LinkNumVehicles(car(i).path(1), car(i).path(2)) = LinkNumVehicles(car(i).path(1), car(i).path(2)) - 1;
% shrink path to just final destination
car(i).path = car(i).path(2);
% Blurb: if the car is on a self-loop and got to the
% destination, release it as if it was driving_to_dest. If
% the car is driving to pick up and gets a customer and the
% customer is on a self-loop, set travel_time and put in
% status self_loop. Actually, car never drive to a
% customer, since each node is a station: scratch that, go
% easy.
if car(i).state == DRIVING_TO_PICKUP
% pick up customer
if customer(car(i).passId).onode == customer(car(i).passId).dnode
car(i).state = SELF_LOOP;
car(i).dpos = customer(car(i).passId).dpos;
car(i).dstation = customer(car(i).passId).dstation;
car(i).ostation = customer(car(i).passId).ostation;
car(i).time_left = customer(car(i).passId).traveltime * 60;
customer(car(i).passId).pickedup = 1;
% remove customer from the origin station
tmpindex = find(station(customer(car(i).passId).ostation).custId == car(i).passId);
station(customer(car(i).passId).ostation).custId = [station(customer(car(i).passId).ostation).custId(1:tmpindex-1), station(customer(car(i).passId).ostation).custId(tmpindex+1:end)];
else
car(i).state = DRIVING_TO_DEST;
car(i).pos = car(i).dpos;
if isnan(car(i).pos)
'Error: car position is NaN'
end
car(i).dpos = customer(car(i).passId).dpos;
customer(car(i).passId).pickedup = 1;
% remove customer from the origin station
tmpindex = find(station(customer(car(i).passId).ostation).custId == car(i).passId);
station(customer(car(i).passId).ostation).custId = [station(customer(car(i).passId).ostation).custId(1:tmpindex-1), station(customer(car(i).passId).ostation).custId(tmpindex+1:end)];
%
car(i).path = findRoute(car(i).path(1), customer(car(i).passId).dnode, LinkTime);
car(i).speedfactor = LinkTime(customer(car(i).passId).onode,customer(car(i).passId).dnode) / (customer(car(i).passId).traveltime * 60);
LinkNumVehicles(car(i).path(1), car(i).path(2)) = LinkNumVehicles(car(i).path(1), car(i).path(2)) + 1;
car(i).direction = (NodesLocation(car(i).path(2),:) - NodesLocation(car(i).path(1),:)); car(i).direction=car(i).direction/norm(car(i).direction);
end
elseif car(i).state == DRIVING_TO_DEST
% drop off customer
car(i).state = DRIVING_TO_STATION;
car(i).pos = customer(car(i).passId).dpos;
if isnan(car(i).pos)
'Error: car position is NaN'
end
car(i).dpos = StationLocation(customer(car(i).passId).dstation, :);
% route car to station
car(i).path = findRoute(car(i).path(1), station(customer(car(i).passId).dstation).node_id, LinkTime);
% car is now free to receive assignments from station
customer(car(i).passId).delivered = 1;
car(i).passId = 0;
% return to normal speed
car(i).speedfactor = 1;
% if the destination was already a station
if length(car(i).path) == 1
car(i).state = IDLE;
car(i).ostation = car(i).dstation;
station(car(i).ostation).carIdle = [station(car(i).ostation).carIdle, car(i).id];
else
station(car(i).dstation).carOnRoad = [station(car(i).dstation).carOnRoad, car(i).id];
LinkNumVehicles(car(i).path(1), car(i).path(2)) = LinkNumVehicles(car(i).path(1), car(i).path(2)) + 1;
car(i).direction = (NodesLocation(car(i).path(2),:) - NodesLocation(car(i).path(1),:)); car(i).direction=car(i).direction/norm(car(i).direction);
end
elseif car(i).state == DRIVING_TO_STATION
% arrived back to station
car(i).state = IDLE;
car(i).pos = car(i).dpos;
if isnan(car(i).pos)
'Error: car position is NaN'
end
car(i).ostation = car(i).dstation;
% add car to idle car list
station(car(i).ostation).carIdle = [station(car(i).ostation).carIdle, car(i).id];
tmpindex = find(station(car(i).ostation).carOnRoad == car(i).id);
% remove car from caronroad list
station(car(i).ostation).carOnRoad = [station(car(i).ostation).carOnRoad(1:tmpindex-1), station(car(i).ostation).carOnRoad(tmpindex+1:end)];
elseif car(i).state == REBALANCING
% finished rebalancing to station
car(i).state = IDLE;
car(i).pos = car(i).dpos;
if isnan(car(i).pos)
'Error: car position is NaN'
end
car(i).ostation = car(i).dstation;
% add car to idle car list
station(car(i).ostation).carIdle = [station(car(i).ostation).carIdle, car(i).id];
tmpindex = find(station(car(i).ostation).carOnRoad == car(i).id);
% remove car from caronroad list
if ~isempty(tmpindex)
station(car(i).ostation).carOnRoad = [station(car(i).ostation).carOnRoad(1:tmpindex-1), station(car(i).ostation).carOnRoad(tmpindex+1:end)];
end
end
end
end
if car(i).state == SELF_LOOP && car(i).time_left < dt
car(i).state = DRIVING_TO_STATION;
car(i).pos = customer(car(i).passId).dpos;
if isnan(car(i).pos)
'Error: car position is NaN'
end
car(i).dpos = StationLocation(customer(car(i).passId).dstation, :);
% route car to station
car(i).path = findRoute(car(i).path(1), station(customer(car(i).passId).dstation).node_id, LinkTime);
% car is now free to receive assignments from station
customer(car(i).passId).delivered = 1;
car(i).passId = 0;
% return to normal speed
car(i).speedfactor = 1;
% if the destination was already a station
if length(car(i).path) == 1
car(i).state = IDLE;
car(i).ostation = car(i).dstation;
station(car(i).ostation).carIdle = [station(car(i).ostation).carIdle, car(i).id];
else
station(car(i).dstation).carOnRoad = [station(car(i).dstation).carOnRoad, car(i).id];
LinkNumVehicles(car(i).path(1), car(i).path(2)) = LinkNumVehicles(car(i).path(1), car(i).path(2)) + 1;
car(i).direction = (NodesLocation(car(i).path(2),:) - NodesLocation(car(i).path(1),:)); car(i).direction=car(i).direction/norm(car(i).direction);
end
end
end
% new customer arrivals
if ccTmp <= max(size(arrivalTimes))
while arrivalTimes(ccTmp) < t
%customer arrival and destination locations
tmpCust = [MData(ccTmp,6:7); MData(ccTmp,8:9)]*60;
% find the nearest nodes
tmpNodes = dsearchn(NodesLocation, tmpCust);
%if tmpNodes(1) ~= tmpNodes(2)
% find the stations
tmpStations = dsearchn(StationLocation, tmpCust);
% make customer structure
customer(cc) = struct('opos',NodesLocation(tmpNodes(1),:), 'dpos', NodesLocation(tmpNodes(2),:),...
'onode', tmpNodes(1), 'dnode', tmpNodes(2), 'ostation',tmpStations(1), 'dstation', tmpStations(2), ...
'waitTime',0,'serviceTime',0,'pickedup',0,'delivered',0, 'traveltime', MData(ccTmp,10));
% add this customer to the station
station(customer(cc).ostation).custId = [station(customer(cc).ostation).custId cc];
station(customer(cc).ostation).custUnassigned = [station(customer(cc).ostation).custUnassigned cc];
cc = cc + 1;
ccTmp = ccTmp + 1;
%else
% ccTmp = ccTmp + 1;
%end
if ccTmp > max(size(arrivalTimes))
break
end
end
end
% assign vehicles to new customers
for i = 1:numStations
% as long as there are cars left or customers waiting
while ~isempty(station(i).custUnassigned) && (~isempty(station(i).carIdle) || ~isempty(station(i).carOnRoad))
custInd = station(i).custUnassigned(1);
% get distance from customer
distToStation = norm(customer(custInd).opos - StationLocation(i,:));
% get distance to nearest car on road
if ~isempty(station(i).carIdle)
assignedCarID = station(i).carIdle(1);
shortestDistance = distToStation;
else
shortestDistance = inf;
end
carOnRoadIndex = 0;
if ~isempty(station(i).carOnRoad)
for j = 1:length(station(i).carOnRoad)
distToCar = norm(customer(custInd).opos - car(station(i).carOnRoad(j)).pos);
if distToCar < shortestDistance
shortestDistance = distToCar;
assignedCarID = station(i).carOnRoad(j);
carOnRoadIndex = j;
end
end
end
if shortestDistance == inf
%'ERROR: inf shortest distance (could not find a vehicle for the customer)'
end
% assign pax to car
car(assignedCarID).passId = custInd;
tmpPath = car(assignedCarID).path;
car(assignedCarID).path = findRoute(tmpPath(1), customer(custInd).onode, LinkTime);
alreadyAtPickup = 0;
if length(tmpPath) == 1 && length(car(assignedCarID).path) == 1
% TODO: APPLIES TO SELFLOOP
% vehicle is not initially in motion (at a station)
% go straight to routing delivery
alreadyAtPickup = 1;
if customer(custInd).onode==customer(custInd).dnode
car(assignedCarID).state = SELF_LOOP;
car(assignedCarID).dpos = customer(custInd).dpos;
car(assignedCarID).time_left = customer(custInd).traveltime * 60;
else
car(assignedCarID).state = DRIVING_TO_DEST;
car(assignedCarID).dpos = customer(custInd).dpos;
% route the new path using the customer speed
car(assignedCarID).path = findRoute(tmpPath(1), customer(custInd).dnode, LinkTime);
car(assignedCarID).speedfactor = LinkTime(customer(custInd).onode,customer(custInd).dnode) / (customer(custInd).traveltime * 60);
end
customer(custInd).pickedup = 1;
% remove customer from the origin station
tmpindex = find(station(customer(custInd).ostation).custId == car(assignedCarID).passId);
station(customer(car(assignedCarID).passId).ostation).custId = [station(customer(car(assignedCarID).passId).ostation).custId(1:tmpindex-1), station(customer(car(assignedCarID).passId).ostation).custId(tmpindex+1:end)];
else
% TODO: APPLIES TO SELFLOOP
% vehicle is in motion.
if length(car(assignedCarID).path) == 1
car(assignedCarID).path = [tmpPath(2) tmpPath(1)];
elseif length(tmpPath) > 1
if car(assignedCarID).path(2) ~= tmpPath(2)
% go a different way - make U-turn
car(assignedCarID).path = [tmpPath(2) car(assignedCarID).path];
end
end
end
% TODO: APPLIES TO SELFLOOP
if length(car(assignedCarID).path) > 1
LinkNumVehicles(car(assignedCarID).path(1), car(assignedCarID).path(2)) = LinkNumVehicles(car(assignedCarID).path(1), car(assignedCarID).path(2))+1;
end
if length(tmpPath) > 1
LinkNumVehicles(tmpPath(1), tmpPath(2)) = LinkNumVehicles(tmpPath(1), tmpPath(2))-1;
end
% TODO: APPLIES TO SELFLOOP
% assign the car to the customer
car(assignedCarID).dstation = customer(custInd).dstation;
car(assignedCarID).ostation = i;
if ~alreadyAtPickup
car(assignedCarID).state = DRIVING_TO_PICKUP;
car(assignedCarID).dpos = customer(custInd).opos;
end
% direction vector
if length(car(assignedCarID).path) > 1
tmpNode2 = car(assignedCarID).path(2);
tmpNode1 = car(assignedCarID).path(1);
car(assignedCarID).direction = (NodesLocation(tmpNode2,:) - NodesLocation(tmpNode1,:)); car(assignedCarID).direction=car(assignedCarID).direction/norm(car(assignedCarID).direction);
end
% remove assigned car from station
if ~isempty(station(i).carIdle) && assignedCarID == station(i).carIdle(1)
station(i).carIdle = station(i).carIdle(2:end);
else
station(i).carOnRoad = [station(i).carOnRoad(1:carOnRoadIndex-1), station(i).carOnRoad(carOnRoadIndex+1:end)];
end
% remove unassigned customer from station
station(i).custUnassigned = station(i).custUnassigned(2:end);
end
end
% update global road network capacity matrix
% rebalancing
if rebCount >= Thor
rebCount = 1;
vown = zeros(numStations,1);
vexcess = zeros(numStations,1);
vdesired = zeros(numStations,1);
totalCustomers = 0;
if NAIVEFLAG
% clear rebalanceQueue
for i = 1:numStations
rebalanceQueue{i} = [];
end
end
for i = 1:numStations
vown(i) = length(station(i).carIdle) + length(station(i).carOnRoad);
end
for i = 1:v
% if the car is in the process of pickup or dropoff
if car(i).state == DRIVING_TO_DEST || car(i).state == DRIVING_TO_PICKUP || car(i).state == SELF_LOOP
vown(car(i).dstation) = vown(car(i).dstation) + 1;
end
end
% find excess vehicles of each station
for i = 1:numStations
vexcess(i) = vown(i) - length(station(i).custUnassigned);
% find total customers
totalCustomers = totalCustomers + length(station(i).custUnassigned);
end
% vehicles desired for each station
vdesired = floor((sum(vown) - totalCustomers)/numStations)*ones(numStations,1);
if NAIVEFLAG
if ~MPCFLAG
numStations2=numStations;
% car optimization
cvx_begin
variable numij2(numStations2,numStations2)
minimize (sum(sum(Tij.*numij2)));
subject to
vexcess + sum((numij2' - numij2)')' >= vdesired;
% sum(numij')' <= rown;
% trace(numij) == 0;
numij2 >= 0;
cvx_end
% make sure numij is integer
numij2 = round(numij2);
% add rebalancing vehicles to queues
for i = 1:numStations
for j = 1:numStations
for k = 1:numij2(i,j)
rebalanceQueue{i} = [rebalanceQueue{i} j];
numRebTasks(t,i) = numRebTasks(t,i) + 1;
end
end
end
else
% MPC stuff
% load passenger predictions into FlowsOut + FlowsIn
% predictions are in 5 min intervals
currentTime = t / predictionStep;
Passengers.FlowsOut = predictDemand(currentTime, horizon, numStations, predictor);
RoadNetwork.Starters = zeros(horizon,numStations);
% load current trips/rebalancing into Starters
for i = 1:v
% if the car is in the process of pickup or dropoff
if car(i).state == DRIVING_TO_DEST || car(i).state == DRIVING_TO_STATION || car(i).state == REBALANCING
distToDest = norm(car(i).dpos - car(i).pos,2);
eta = distToDest / car(i).speedfactor;
tin = ceil(eta / (predictionStep * dt));
if tin < horizon && tin > 0
RoadNetwork.Starters(tin,car(i).dstation) = RoadNetwork.Starters(tin,car(i).dstation) + 1;
elseif tin < horizon
RoadNetwork.Starters(1,car(i).dstation) = RoadNetwork.Starters(1,car(i).dstation) + 1;
end
elseif car(i).state == SELF_LOOP
eta = car(i).time_left;
tin = ceil(eta / (predictionStep * dt));
if tin < horizon && tin > 0
RoadNetwork.Starters(tin,car(i).dstation) = RoadNetwork.Starters(tin,car(i).dstation) + 1;
elseif tin < horizon
RoadNetwork.Starters(1,car(i).dstation) = RoadNetwork.Starters(1,car(i).dstation) + 1;
end
elseif car(i).state == IDLE
RoadNetwork.Starters(1,car(i).ostation) = RoadNetwork.Starters(1,car(i).ostation) + 1;
elseif car(i).state == DRIVING_TO_PICKUP
distToDest = norm(car(i).dpos - car(i).pos,2);
eta1 = distToDest / car(i).speedfactor;
cus = customer(car(i).passId);
if cus.ostation == cus.dstation
eta2 = 1;
else
eta2 = LinkTime(cus.ostation, cus.dstation);
end
tin = ceil(eta / (predictionStep * dt));
if tin < horizon && tin > 0
RoadNetwork.Starters(tin,car(i).dstation) = RoadNetwork.Starters(tin,car(i).dstation) + 1;
elseif tin < horizon
RoadNetwork.Starters(1,car(i).dstation) = RoadNetwork.Starters(1,car(i).dstation) + 1;
end
end
end
% load waiting customers into FlowsOut
for st=1:numStations
for cu=1:length(station(st).custUnassigned)
custInd = station(st).custUnassigned(cu);
tout = 1;
Passengers.FlowsOut{tout}(customer(custInd).onode,customer(custInd).dnode) = Passengers.FlowsOut{tout}(customer(custInd).onode,customer(custInd).dnode) + 1;
end
end
% run!
[rebalanceQueue, integral, output, fval, rfval, fval2, rfval2, rconstr] = MPC_MCF_testing(RoadNetwork,RebWeight,Passengers,Flags);
milpOutputs(t,:) = [output.time, output.iterations, output.delivered, output.dropped, output.waiting];
for i=1:length(rebalanceQueue)
numRebTasks(t,i) = numRebTasks(t,i) + length(rebalanceQueue{i});
end
end
else
% calculate difference between the floor value and the actual
% number
vdesiredDifference = (sum(vown) - totalCustomers) - numStations*vdesired(1);
[~, sortedIndex] = sort(vown);
for i = 1:vdesiredDifference
vdesired(sortedIndex(i)) = vdesired(sortedIndex(i)) + 1;
end
% form the sets S and T (sources and sinks) and the flows in/out
sources = [];
sinks = [];
flowOut = [];
flowIn = [];
for i = 1:numStations
tmpFlow = vexcess(i) - vdesired(i);
if tmpFlow > 0
for j = 1:tmpFlow
% source
sources = [sources, StationNodeID(i)];
flowOut = [flowOut, 1];
end
elseif tmpFlow < 0
for j = 1:-tmpFlow
% sink
sinks = [sinks, StationNodeID(i)];
flowIn = [flowIn, 1];
end
end
end
%sum(flowOut)
% find the link capacity left
LinkCapacityLeft = max(RoadCap - LinkNumVehicles, 0);
% call the single-commodity flow solver
RebOutput = TIMulticommodityFlow(RoadGraph, LinkCapacityLeft, LinkTime , sources, sinks, flowIn, flowOut, 0, 0, 1);
if PLOTREBFLAG
TIPlotRebFlows(1,N,RoadGraph,NodesLocation,RebOutput,sources,sinks,0,1)
end
%This modifies the sources and sinks so the path planner knows that
%some paths were modified
S=length(sources);
M=1;
SoRelaxkl=@(k,l) N*N*M + N*N + S*(k-1) + l;
SiRelaxkl=@(k,l) N*N*M + N*N + M*S + S*(k-1) + l;
relFlowIn = flowIn -RebOutput(SoRelaxkl(1,1):SoRelaxkl(1,S))';
relFlowOut= flowOut-RebOutput(SiRelaxkl(1,1):SiRelaxkl(1,S))';
numVehiclesNotRebalancing(t) = sum(RebOutput(SoRelaxkl(1,1):SoRelaxkl(1,S)));
rebPaths = TIRebPathDecomposition(RebOutput, length(RoadGraph), 1, sources, sinks, relFlowIn, relFlowOut);
disp('how much didnt rebalance')
sum(flowOut) - length(rebPaths)
end
else
rebCount = rebCount + 1;
end
% assign rebalancing vehicles
if NAIVEFLAG
for i = 1:numStations
% rebalance cars as long as the station has cars available
while ~isempty(rebalanceQueue{i}) && (~isempty(station(i).carIdle) || ~isempty(station(i).carOnRoad))
currDest = rebalanceQueue{i}(1);
% remove current destination from rebalanceQueue
rebalanceQueue{i} = rebalanceQueue{i}(2:end);
distToStation = norm(StationLocation(i,:) - StationLocation(currDest,:));
if ~isempty(station(i).carIdle)
assignedCarID = station(i).carIdle(1);
shortestDistance = distToStation;
else
shortestDistance = inf;
end
carOnRoadIndex = 0;
if ~isempty(station(i).carOnRoad)
for j = 1:length(station(i).carOnRoad)
distToCar = norm(StationLocation(currDest,:) - car(station(i).carOnRoad(j)).pos);
if distToCar < shortestDistance
shortestDistance = distToCar;
assignedCarID = station(i).carOnRoad(j);
carOnRoadIndex = j;
end
end
end
if shortestDistance == inf
'ERROR: inf shortest distance in rebalancing'
end
% remove assigned car from station
if ~isempty(station(i).carIdle) && assignedCarID == station(i).carIdle(1)
station(i).carIdle = station(i).carIdle(2:end);
else
station(i).carOnRoad = [station(i).carOnRoad(1:carOnRoadIndex-1), station(i).carOnRoad(carOnRoadIndex+1:end)];
end
% remove car from station
car(assignedCarID).dstation = currDest;
car(assignedCarID).ostation = i;
car(assignedCarID).state = REBALANCING;
car(assignedCarID).dpos = StationLocation(currDest,:);
tmpPath = car(assignedCarID).path;
car(assignedCarID).path = findRoute(tmpPath(1), StationNodeID(currDest), LinkTime);
if length(tmpPath) > 1 && length(car(assignedCarID).path) > 1
if car(assignedCarID).path(2) ~= tmpPath(2)
% go a different way - make U-turn
car(assignedCarID).path = [tmpPath(2) car(assignedCarID).path];
end
end
if length(car(assignedCarID).path) > 1
LinkNumVehicles(car(assignedCarID).path(1), car(assignedCarID).path(2)) = LinkNumVehicles(car(assignedCarID).path(1), car(assignedCarID).path(2))+1;
end
% direction vector
if length(car(assignedCarID).path) > 1
tmpNode2 = car(assignedCarID).path(2);
tmpNode1 = car(assignedCarID).path(1);
car(assignedCarID).direction = (NodesLocation(tmpNode2,:) - NodesLocation(tmpNode1,:)); car(assignedCarID).direction=car(assignedCarID).direction/norm(car(assignedCarID).direction);
end
% destination station add this car
station(currDest).carOnRoad = [station(currDest).carOnRoad, assignedCarID];
end
end
else
% give the rebPaths to the vehicles
nextRebPaths = cell(0);
c_reb = 1;
for i = 1:length(rebPaths)
if isempty(rebPaths{i})
continue
end
orig = rebPaths{i}{1,1}(1,1);
stationId = find(StationNodeID == orig,1);
%dest = rebPaths{1}(end);
if ~isempty(station(stationId).carIdle)
% assign car to rebalance path
tmpCar = station(stationId).carIdle(1);
car(tmpCar).state = REBALANCING;
car(tmpCar).path = rebPaths{i}{1,1}(:,1)';
car(tmpCar).dpos = NodesLocation(rebPaths{i}{1,1}(end,1),:);
car(tmpCar).direction = (NodesLocation(car(tmpCar).path(2),:) - NodesLocation(car(tmpCar).path(1),:)); car(tmpCar).direction=car(tmpCar).direction/norm(car(tmpCar).direction);
car(tmpCar).dstation = find(StationNodeID == car(tmpCar).path(end),1);
station(stationId).carIdle = station(stationId).carIdle(2:end);
LinkNumVehicles(car(tmpCar).path(1), car(tmpCar).path(2)) = LinkNumVehicles(car(tmpCar).path(1), car(tmpCar).path(2))+1;
station(car(tmpCar).dstation).carOnRoad = [station(car(tmpCar).dstation).carOnRoad tmpCar];
else
% save this for next time
nextRebPaths{c_reb} = rebPaths{i};
c_reb = c_reb + 1;
end
end
rebPaths = nextRebPaths;
end
% move vehicles
for i = 1:v
if car(i).state == SELF_LOOP
car(i).time_left=car(i).time_left-dt;
else
if length(car(i).path) > 1
if norm(NodesLocation(car(i).path(2),:)-car(i).pos) < car(i).speedfactor * LinkSpeed(car(i).path(1), car(i).path(2))*dt
% need to go to the next node (or stop)
residualDistance = car(i).speedfactor * LinkSpeed(car(i).path(1), car(i).path(2))*dt - norm(NodesLocation(car(i).path(2),:)-car(i).pos);
if length(car(i).path) > 2
LinkNumVehicles(car(i).path(1), car(i).path(2)) = LinkNumVehicles(car(i).path(1), car(i).path(2)) - 1;
car(i).path = car(i).path(2:end);
car(i).direction = (NodesLocation(car(i).path(2),:) - NodesLocation(car(i).path(1),:)); car(i).direction=car(i).direction/norm(car(i).direction);
car(i).pos = NodesLocation(car(i).path(1),:) + car(i).direction*residualDistance;
if isnan(car(i).pos)
'ERROR: car position is NaN'
end
LinkNumVehicles(car(i).path(1), car(i).path(2)) = LinkNumVehicles(car(i).path(1), car(i).path(2)) + 1;
else
car(i).pos = NodesLocation(car(i).path(2),:);
if isnan(car(i).pos)
'Error: car position is NaN'
end
end
else
% don't need to go to the next node
car(i).pos = car(i).pos + car(i).direction * car(i).speedfactor * LinkSpeed(car(i).path(1), car(i).path(2))*dt;
if isnan(car(i).pos)
'Error: car position is NaN'
end
end
end
end
end
% update customer waiting/service times
for i = 1:cc-1
if customer(i).pickedup == 0
customer(i).waitTime = customer(i).waitTime + dt;
elseif customer(i).pickedup == 1 && customer(i).delivered == 0
customer(i).serviceTime = customer(i).serviceTime + dt;
end
end
% collect customer travel time data
for i = 1:numStations
for j = 1:length(station(i).custId)
if customer(station(i).custId(j)).pickedup == 0
avgWaitTimes(t) = avgWaitTimes(t) + customer(station(i).custId(j)).waitTime;
cumNumCustomers(t) = cumNumCustomers(t) + 1;
end
end
end
if cumNumCustomers(t) > 0
avgWaitTimes(t) = avgWaitTimes(t)./cumNumCustomers(t);
end
% collect number of vehicles doing stuff
for i = 1:v
if car(i).state ~= IDLE
numVehiclesBusy(t) = numVehiclesBusy(t) + 1;
if car(i).state == REBALANCING
numVehiclesRebalancing(t) = numVehiclesRebalancing(t) + 1;
end
if car(i).state == DRIVING_TO_PICKUP
numVehiclesDrivingToPickup(t) = numVehiclesDrivingToPickup(t)+1;
end
if car(i).state == DRIVING_TO_DEST
numVehiclesDrivingToDest(t) = numVehiclesDrivingToDest(t)+1;
end
if car(i).state == DRIVING_TO_STATION
numVehiclesDrivingToStation(t) = numVehiclesDrivingToStation(t)+1;
end
if car(i).state == SELF_LOOP
numVehiclesOnSelfLoop(t) = numVehiclesOnSelfLoop(t)+1;
end
else
numVehiclesIdle(t) = numVehiclesIdle(t)+1;
end
end
% collect number of vehicles on each link
%numCarsOnLink{t} = LinkNumVehicles;
% plot things
if PLOTFLAG
figure(cars_fig)
plot(1000,1000)
axis equal
set(gca,'nextplot','replacechildren');
hold on;
axis equal;
plot(NodesLocation(1:N,1), NodesLocation(1:N,2), '.b')
for i = 1:N
% text(NodesLocation(i,1), NodesLocation(i,2), int2str(i));
for j = RoadGraph{i}
if j <= N
plot([NodesLocation(i,1) NodesLocation(j,1)], [NodesLocation(i,2) NodesLocation(j,2)]);
end
end
end
% plot each car
pv = 0;
rv = 0;
rrv = 0;
for i = 1:v
if car(i).state ~= IDLE
%This code plots a car with color based on its speed
%carFFSpeed = LinkFreeFlow(cars(v).path(1),cars(v).path(2));
%carSpeed = LinkSpeed(cars(v).path(1),cars(v).path(2));
%carColorIdx = round(carSpeed/carFFSpeed *(crange-1)+1);
%plot(car(i).pos(1),car(i).pos(2),'.','Color',cmap(carColorIdx,:));
car_offset=[0 -1; 1 0]*car(i).direction'*0.01;
if car(i).state == DRIVING_TO_DEST
pv = pv+1;
plot(car(i).pos(1)+car_offset(1), car(i).pos(2)+car_offset(2), 'rd', 'MarkerFaceColor', 'r', 'MarkerSize', 4)
elseif car(i).state ~= DRIVING_TO_DEST && car(i).state ~= REBALANCING
rv = rv+1;
plot(car(i).pos(1)+car_offset(1), car(i).pos(2)+car_offset(2), 'rd', 'MarkerFaceColor', 'r', 'MarkerSize', 4)
elseif car(i).state == REBALANCING
plot(car(i).pos(1)+car_offset(1), car(i).pos(2)+car_offset(2), 'cd', 'MarkerFaceColor', 'c', 'MarkerSize', 4)
rrv = rrv + 1;
end
end
end
rrv
%hold all
%I strongly suggest saving as png and compositing the video later
Movie(movieCounter) = getframe;
writeVideo(writerObj,Movie(movieCounter));
hold off
movieCounter = movieCounter + 1;
end
%keyboard;
% if PLOTFLAG
% maxroadcap=full(max(max(RoadCap)));
% figure(roads_fig)
% hold all
% for i=1:N
% for j=RoadGraph{i}
% road_dir = [NodesLocation(j,1); NodesLocation(j,2)]-[NodesLocation(i,1); NodesLocation(i,2)];
% road_dir=road_dir./norm(road_dir);
% road_offset = [0 -1;1 0]*road_dir*0.01;
% road_thickness=full(RoadCap(i,j)/maxroadcap*8);
% if road_thickness
% plot([NodesLocation(i,1)+road_offset(1) NodesLocation(j,1)+road_offset(1)], [NodesLocation(i,2)+road_offset(2) NodesLocation(j,2)+road_offset(2)],'LineWidth',road_thickness)
% end
% end
% end
%
% end
end
if PLOTFLAG
close(writerObj);
end
%%
numDelivered = 0;
totalServiceTime = 0;
totalWaitTime = 0;
for i = 1:cc-1
if customer(i).delivered
numDelivered = numDelivered + 1;
totalServiceTime = totalServiceTime + customer(i).serviceTime;
totalWaitTime = totalWaitTime + customer(i).waitTime;
end
end
meanServiceTime = totalServiceTime/numDelivered;
% histogram of waiting times
allWaitTimes = zeros(numDelivered, 1);
ccc = 1;
for i = 1:cc-1
if customer(i).delivered
allWaitTimes(ccc) = customer(i).waitTime;
ccc = ccc+1;
end
end
mean_wait = mean(allWaitTimes);
median_wait = median(allWaitTimes);
fprintf('Mean wait time: %f\nMedian wait time: %f\n',mean_wait,median_wait)
allServiceTimes = zeros(numDelivered, 1);
ccc = 1;
for i = 1:cc-1
if customer(i).delivered
allServiceTimes(ccc) = customer(i).serviceTime;
ccc = ccc+1;
end
end
fprintf('Mean service time: %f\nMedian service time: %f\n',mean(allServiceTimes),median(allServiceTimes))
savename = ['ignored_assets/',SIMNAME,num2str(v),'v_rev3'];
save(savename);
end