# big buildings' elevator (number and work process)

Yesterday when i was high, i thought about big buildings and their elevators.

Number and way of work of elevators was the problem.

When i think about the worst case:

(for the tallest building in the world - Burj Khalifa in Dubai, United Arab Emirates)

• HEIGHT: 829.8 m, 160 flats,

A man take the lift up to 160th floor (GGuy- going guy), when another one just misses the elevator (WGuy-waiting guy).

First guy goes to the 160th floor and the other one waits for the elevator to come.

TOTAL TIME : 160 flats up, the guy's getting off the elevator duration (i will call it GOED), 160 flats down and ALSO in each flat another person gets in and/or off (also i will call GOED) elevator.

160FlatElevatorDuration*2+GOED+320*GOED

(In fact it is not the worst case, WGuy can wait for his whole life, elevator is going up and down continuously without stopping at floor 1, but optimization 0 handles this problem)

Some optimizations that i searched and saw:

0- Elevators goes up and down, there is two separate buttons, for waiting for going up and down. So it makes two groups of people and guarantees that at most 160 loor-stops later elevator will come to your floor.

1. Burj khalifa has the fastest elevator of the world. (speed 64 km/hour) It makes the total time ~2 mins+321*GOED

2. Using more elevators (the limit is "more elevators means less free space to sell as house or office")

3. building's each flat is so big that user has to walk to reach her/his final place. Solution: using another elevator moving horizontally, using several elevators in middle space partitions (merge sort) .

4. Elevators' waiting floors has to be set like merge sort. For ex. if we have 3 elevators, and when none of them is working their waiting flats can be 40th,80th,120th floors.

5. when i first thought about this problem i thought that if elevators work between specified flat interspace, total waiting time of all people will be shortened.

For ex. 0-80 meters 1 elevator, 80-160 another elevator. This makes waiting time ~1 min+GOED for WGuy. But for GGuy has to get off and on another elevator. So it will add +~2*GOED* time for WGuy's process time

As i read in wiki, the building has World's longest travel distance elevators: 504m record. It makes my assumption correct, There is at least 2 separate elevators. One from 0-504m. (~100 flats) , and the other one (225.8-829.8m) (~between 60th-160th flats)

6- Another optimization is the most optimization that "nothing is optimized any more" EHUEHEUHEUHEUEH Ohom, being serious again, elevators can work for 1 floor up&down.

So WGuy's waiting duration is

Each floor's elevator go up or down process duration: (((829.8/160)*60*60)/6400)*2=6sec

6sec+GOED*2*whichFloor

if guy is going to 160th floor (worst case) it will be 6 sec+320*GOED* So if GOED is less then 114 sec.s this solution is better that one elevator goes 1 to 160th floor. But if we use statistics we will see that it is rare that a person gets in /off in every flat. So this solution sucks of course.

7- But if a mechanism is used for switching the elevators horizontally. It can be used to change the elevators automatically, like switchyards, GOED time will be shortened.

Also the #of people for each floor and their in-out entrance rate are two important issues.

My question is, what is the optimum solution (pseudo code) for the number of elevators and its working?

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i think you need to be even more explicit on your criteria and constraints. the actual behavior of the elevator will depend on passenger numbers and behavior, therefore you're optimizing statistically. do you aim at minimizing weighted/unweighted (eg. by start floor and/or time of the day) expected/maximum waiting time (eg. minimizing overall waiting time might be unacceptable when the variation becomes too large) ? is speedy servicing (no stops) more/less acceptable than extended waiting time? do/don't you want fairness guarantees? do secondary considerations apply, eg. energy consumption? –  collapsar Apr 18 '13 at 12:09
my primary goal is to minimize the time (between a person gets into the building and reaches the door of house/office etc.). and statistics can be used to estimate the # of people for each floor and the whole building. –  Mihriban Minaz Apr 18 '13 at 12:19
you need an estimator for the distribution of people by floors as a funciton of time, i think. the solution to your unconstrained problem is simple, however: #elevators = max # of people arriving at the building during an interval whose length matches the max time for an elevator to move from the 1st to the top floor and back + goed. this way, there always is an unused elevator waiting at ground floor -> no waiting time for incoming people -> minimum. and there is an interval in which all elevators will be used -> optimum. –  collapsar Apr 18 '13 at 12:35
good approach but as i mentioned in the question before, i also want to minimize the # of elevators because i don't want to waste so much space. genetic algorithm and giving points (adding another elevator is minus point, waiting time is a minus point etc.) to the solutions might be useful. This question is also asked for determining the requirements and other constraints for the question. Like minimizing the energy consumption -it also can be minus point to use so much energy-, and some other small improvements like determining the waiting floors -most used/last used/middle floors- etc. –  Mihriban Minaz Apr 18 '13 at 12:49
you are working at an inherently multidimensional optimization problem (at least servicing times and # of elevators) from which you most certainly cannot isolate individual diomensions. eg. the solution for minimizing the number of elevators is easy, too: exactly 1 elevator. you need to trade-off servicing times vs. # of elevators and therefore you need to quantify both (and possibly other) dimensions in common terms. no insult intended, but scoring elevator count and [+- waiting time] with 1 each seems to be far too simplistic and far too coarse a measure for getting useful results. –  collapsar Apr 18 '13 at 13:02