I'm trying to build a school scheduling program in prolog. I want to check if a teacher is available at a given time to teach a certain this class; check allowable time slots; etc.
Here's what I've been able to write so far:
teacher(ali, bio).
teacher(sara, math).
teacher(john, lit).
teacher(milton, arabic).
% a, b, c, d, e, f, g
timeslot(a).
timeslot(b).
% class has a name and a grade
class(bio, 1).
class(math, 1).
class(lit, 2).
class(arabic, 2).
How do I establish that a class cannot have two timeslots?
I have used a little bit of Prolog, but I'm not sure how to go about this. Any further tips and indications, like papers or similar problems that are solved more frequently, would be appreciated.
The wording of the Question suggests that a program is to be written that will produce (or at least check) a proposed class schedule.
Inputs to the program appear to be a list of teachers (and their subjects), a list of time slots, and a list of classes (and their subjects/grades).
Presumably there are several "cardinality" restrictions (sometimes called "business rules") that a proper class schedule must meet. A class can only be given once (not two time slots) is the point of the Question, but also a teacher can only teach one class per time slot, etc.
How can these restrictions be indicated? Prolog predicates do not have inherent restrictions of this kind, but they can be implemented either structurally or logically (i.e. in the program's logical checking).
An example of doing things in a structural way would be adding a field to the class predicate to represent the assigned timeslot. Some logic would be involved in how this field is assigned, to insure that value is a valid time slot.
An example of doing the relationship between classes and time slots in a logical fashion would be to define an additional predicate that models the assignment of time slots to classes (presumably something similar applies to assigning classes to teachers). You would have, as illustration, predicate class_timeslot(Class,Timeslot). The rules of your program would enforce the uniqueness of one instance of these (dynamically asserted) facts per Class instance, and the validity of the Timeslot value.
Alternatively, instead of dynamic facts, the class schedule could be constructed as a list of structures similarly pairing classes and time slots. But the point is that program logic needs to implement that this pairing is a functional relationship.
i wrote two years ago a scheduling program for assessment center and used clpfd for that because in normal swi-prolog it would be much more complicated and the problem is scaling exponentional with the complexity so if you have a real school with lots of teachers, lessions etc this will be not really efficient without constraint programming.
Please have a look int clp(fd) at swi-prolog website
Kind regards
solick
I've been wondering if there are known solutions for algorithm of creating a school timetable. Basically, it's about optimizing "hour-dispersion" (both in teachers and classes case) for given class-subject-teacher associations. We can assume that we have sets of classes, lesson subjects and teachers associated with each other at the input and that timetable should fit between 8AM and 4PM.
I guess that there is probably no accurate algorithm for that, but maybe someone knows a good approximation or hints for developing it.
This problem is NP-Complete!
In a nutshell one needs to explore all possible combinations to find the list of acceptable solutions. Because of the variations in the circumstances in which the problem appears at various schools (for example: Are there constraints with regards to classrooms?, Are some of the classes split in sub-groups some of the time?, Is this a weekly schedule? etc.) there isn't a well known problem class which corresponds to all the scheduling problems. Maybe, the Knapsack problem has many elements of similarity with these problems at large.
A confirmation that this is both a hard problem and one for which people perennially seek a solution, is to check this (long) list of (mostly commercial) software scheduling tools
Because of the big number of variables involved, the biggest source of which are, typically, the faculty member's desires ;-)..., it is typically impractical to consider enumerating all possible combinations. Instead we need to choose an approach which visits a subset of the problem/solution spaces.
- Genetic Algorithms, cited in another answer is (or, IMHO, seems) well equipped to perform this kind of semi-guided search (The problem being to find a good evaluation function for the candidates to be kept for the next generation)
- Graph Rewriting approaches are also of use with this type of combinatorial optimization problems.
Rather than focusing on particular implementations of an automatic schedule generator program, I'd like to suggest a few strategies which can be applied, at the level of the definition of the problem.
The general rationale is that in most real world scheduling problems, some compromises will be required, not all constraints, expressed and implied: will be satisfied fully. Therefore we help ourselves by:
Defining and ranking all known constraints
Reducing the problem space, by manually, providing a set of additional constraints.This may seem counter-intuitive but for example by providing an initial, partially filled schedule (say roughly 30% of the time-slots), in a way that fully satisfies all constraints, and by considering this partial schedule immutable, we significantly reduce the time/space needed to produce candidate solutions. Another way additional constraints help is for example "artificially" adding a constraint which prevent teaching some subjects on some days of the week (if this is a weekly schedule...); this type of constraints results in reducing the problem/solution spaces, without, typically, excluding a significant number of good candidates.
Ensuring that some of the constraints of the problem can be quickly computed. This is often associated with the choice of data model used to represent the problem; the idea is to be able to quickly opt-for (or prune-out) some of the options.
Redefining the problem and allowing some of the constraints to be broken, a few times, (typically towards the end nodes of the graph). The idea here is to either remove some of constraints for filling-in the last few slots in the schedule, or to have the automatic schedule generator program stop shy of completing the whole schedule, instead providing us with a list of a dozen or so plausible candidates. A human is often in a better position to complete the puzzle, as indicated, possibly breaking a few of the contraints, using information which is not typically shared with the automated logic (eg "No mathematics in the afternoon" rule can be broken on occasion for the "advanced math and physics" class; or "It is better to break one of Mr Jones requirements than one of Ms Smith ... ;-) )
In proof-reading this answer , I realize it is quite shy of providing a definite response, but it none the less full of practical suggestions. I hope this help, with what is, after all, a "hard problem".
It's a mess. a royal mess. To add to the answers, already very complete, I want to point out my family experience. My mother was a teacher and used to be involved in the process.
Turns out that having a computer to do so is not only difficult to code per-se, it is also difficult because there are conditions that are difficult to specify to a pre-baked computer program. Examples:
a teacher teaches both at your school and at another institute. Clearly, if he ends the lesson there at 10.30, he cannot start at your premises at 10.30, because he needs some time to commute between the institutes.
two teachers are married. In general, it's considered good practice not to have two married teachers on the same class. These two teachers must therefore have two different classes
two teachers are married, and their child attends the same school. Again, you have to prevent the two teachers to teach in the specific class where their child is.
the school has separate facilities, like one day the class is in one institute, and another day the class is in another.
the school has shared laboratories, but these laboratories are available only on certain weekdays (for security reasons, for example, where additional personnel is required).
some teachers have preferences for the free day: some prefer on Monday, some on Friday, some on Wednesday. Some prefer to come early in the morning, some prefer to come later.
you should not have situations where you have a lesson of say, history at the first hour, then three hours of math, then another hour of history. It does not make sense for the students, nor for the teacher.
you should spread the arguments evenly. It does not make sense to have the first days in the week only math, and then the rest of the week only literature.
you should give some teachers two consecutive hours to do evaluation tests.
As you can see, the problem is not NP-complete, it's NP-insane.
So what they do is that they have a large table with small plastic insets, and they move the insets around until a satisfying result is obtained. They never start from scratch: they normally start from the previous year timetable and make adjustments.
The International Timetabling Competition 2007 had a lesson scheduling track and exam scheduling track. Many researchers participated in that competition. Lots of heuristics and metaheuristics were tried, but in the end the local search metaheuristics (such as Tabu Search and Simulated Annealing) clearly beat other algorithms (such as genetic algorithms).
Take a look at the 2 open source frameworks used by some of the finalists:
JBoss OptaPlanner (Java, open source)
Unitime (Java, open source) - more for universities
One of my half-term assignments was an genetic-algorithm school table generation.
Whole table is one "organism". There were some changes and caveats to the generic genetic algorithms approach:
Rules were made for "illegal tables": two classes in the same classroom, one teacher teaching two groups at the same time etc. These mutations were deemed lethal immediately and a new "organism" was sprouted in place of the "deceased" immediately. The initial one was generated by a series of random tries to get a legal (if senseless) one. Lethal mutation wasn't counted towards count of mutations in iteration.
"Exchange" mutations were much more common than "Modify" mutations. Changes were only between parts of the gene that made sense - no substituting a teacher with a classroom.
Small bonuses were assigned for bundling certain 2 hours together, for assigning same generic classroom in sequence for the same group, for keeping teacher's work hours and class' load continuous. Moderate bonuses were assigned for giving correct classrooms for given subject, keeping class hours within bonds (morning or afternoon), and such. Big bonuses were for assigning correct number of given subject, given workload for a teacher etc.
Teachers could create their workload schedules of "want to work then", "okay to work then", "doesn't like to work then", "can't work then", with proper weights assigned. Whole 24h were legal work hours except night time was very undesired.
The weight function... oh yeah. The weight function was huge, monstrous product (as in multiplication) of weights assigned to selected features and properties. It was extremely steep, one property easily able to change it by an order of magnitude up or down - and there were hundreds or thousands of properties in one organism. This resulted in absolutely HUGE numbers as the weights, and as a direct result, need to use a bignum library (gmp) to perform the calculations. For a small testcase of some 10 groups, 10 teachers and 10 classrooms, the initial set started with note of 10^-200something and finished with 10^+300something. It was totally inefficient when it was more flat. Also, the values grew a lot wider distance with bigger "schools".
Computation time wise, there was little difference between a small population (100) over a long time and a big population (10k+) over less generations. The computation over the same time produced about the same quality.
The calculation (on some 1GHz CPU) would take some 1h to stabilize near 10^+300, generating schedules that looked quite nice, for said 10x10x10 test case.
The problem is easily paralellizable by providing networking facility that would exchange best specimens between computers running the computation.
The resulting program never saw daylight outside getting me a good grade for the semester. It showed some promise but I never got enough motivation to add any GUI and make it usable to general public.
This problem is tougher than it seems.
As others have alluded to, this is a NP-complete problem, but let's analyse what that means.
Basically, it means you have to look at all possible combinations.
But "look at" doesn't tell you much what you need to do.
Generating all possible combinations is easy. It might produce a huge amount of data, but you shouldn't have much problems understanding the concepts of this part of the problem.
The second problem is the one of judging whether a given possible combination is good, bad, or better than the previous "good" solution.
For this you need more than just "is it a possible solution".
For instance, is the same teacher working 5 days a week for X weeks straight? Even if that is a working solution, it might not be a better solution than alternating between two people so that each teacher does one week each. Oh, you didn't think about that? Remember, this is people you're dealing with, not just a resource allocation problem.
Even if one teacher could work full-time for 16 weeks straight, that might be a sub-optimal solution compared to a solution where you try to alternate between teachers, and this kind of balancing is very hard to build into software.
To summarize, producing a good solution to this problem will be worth a lot, to many many people. Hence, it's not an easy problem to break down and solve. Be prepared to stake out some goals that aren't 100% and calling them "good enough".
My timetabling algorithm, implemented in FET (Free Timetabling Software, http://lalescu.ro/liviu/fet/ , a successful application):
The algorithm is heuristic. I named it "recursive swapping".
Input: a set of activities A_1...A_n and the constraints.
Output: a set of times TA_1...TA_n (the time slot of each activity. Rooms are excluded here, for simplicity). The algorithm must put each activity at a time slot, respecting constraints. Each TA_i is between 0 (T_1) and max_time_slots-1 (T_m).
Constraints:
C1) Basic: a list of pairs of activities which cannot be simultaneous (for instance, A_1 and A_2, because they have the same teacher or the same students);
C2) Lots of other constraints (excluded here, for simplicity).
The timetabling algorithm (which I named "recursive swapping"):
Sort activities, most difficult first. Not critical step, but speeds up the algorithm maybe 10 times or more.
Try to place each activity (A_i) in an allowed time slot, following the above order, one at a time. Search for an available slot (T_j) for A_i, in which this activity can be placed respecting the constraints. If more slots are available, choose a random one. If none is available, do recursive swapping:
a. For each time slot T_j, consider what happens if you put A_i into T_j. There will be a list of other activities which don't agree with this move (for instance, activity A_k is on the same slot T_j and has the same teacher or same students as A_i). Keep a list of conflicting activities for each time slot T_j.
b. Choose a slot (T_j) with lowest number of conflicting activities. Say the list of activities in this slot contains 3 activities: A_p, A_q, A_r.
c. Place A_i at T_j and make A_p, A_q, A_r unallocated.
d. Recursively try to place A_p, A_q, A_r (if the level of recursion is not too large, say 14, and if the total number of recursive calls counted since step 2) on A_i began is not too large, say 2*n), as in step 2).
e. If successfully placed A_p, A_q, A_r, return with success, otherwise try other time slots (go to step 2 b) and choose the next best time slot).
f. If all (or a reasonable number of) time slots were tried unsuccessfully, return without success.
g. If we are at level 0, and we had no success in placing A_i, place it like in steps 2 b) and 2 c), but without recursion. We have now 3 - 1 = 2 more activities to place. Go to step 2) (some methods to avoid cycling are used here).
UPDATE: from comments ... should have heuristics too!
I'd go with Prolog ... then use Ruby or Perl or something to cleanup your solution into a prettier form.
teaches(Jill,math).
teaches(Joe,history).
involves(MA101,math).
involves(SS104,history).
myHeuristic(D,A,B) :- [test_case]->D='<';D='>'.
createSchedule :- findall(Class,involves(Class,Subject),Classes),
predsort(myHeuristic,Classes,ClassesNew),
createSchedule(ClassesNew,[]).
createSchedule(Classes,Scheduled) :- [the actual recursive algorithm].
I am (still) in the process of doing something similar to this problem but using the same path as I just mentioned. Prolog (as a functional language) really makes solving NP-Hard problems easier.
Genetic algorithms are often used for such scheduling.
Found this example (Making Class Schedule Using Genetic Algorithm) which matches your requirement pretty well.
Here are a few links I found:
School timetable - Lists some problems involved
A Hybrid Genetic Algorithm for School Timetabling
Scheduling Utilities and Tools
This paper describes the school timetable problem and their approach to the algorithm pretty well: "The Development of SYLLABUS—An Interactive, Constraint-Based Scheduler for Schools and Colleges."[PDF]
The author informs me the SYLLABUS software is still being used/developed here: http://www.scientia.com/uk/
I work on a widely-used scheduling engine which does exactly this. Yes, it is NP-Complete; the best approaches seek to approximate an optimal solution. And, of course there are a lot of different ways to say which one is the "best" solution - is it more important that your teachers are happy with their schedules, or that students get into all their classes, for instance?
The absolute most important question you need to resolve early on is what makes one way of scheduling this system better than another? That is, if I have a schedule with Mrs Jones teaching Math at 8 and Mr Smith teaching Math at 9, is that better or worse than one with both of them teaching Math at 10? Is it better or worse than one with Mrs Jones teaching at 8 and Mr Jones teaching at 2? Why?
The main advice I'd give here is to divide the problem up as much as possible - maybe course by course, maybe teacher by teacher, maybe room by room - and work on solving the sub-problem first. There you should end up with multiple solutions to choose from, and need to pick one as the most likely optimal. Then, work on making the "earlier" sub-problems take into account the needs of later sub-problems in scoring their potential solutions. Then, maybe work on how to get yourself out of painted-into-the-corner situations (assuming you can't anticipate those situations in earlier sub-problems) when you get to a "no valid solutions" state.
A local-search optimization pass is often used to "polish" the end answer for better results.
Note that typically we are dealing with highly resource-constrained systems in school scheduling. Schools don't go through the year with a lot of empty rooms or teachers sitting in the lounge 75% of the day. Approaches which work best in solution-rich environments aren't necessarily applicable in school scheduling.
Generally, constraint programming is a good approach to this type of scheduling problem. A search on "constraint programming" and scheduling or "constraint based scheduling" both within stack overflow and on Google will generate some good references. It's not impossible - it's just a little hard to think about when using traditional optimization methods like linear or integer optimization. One output would be - does a schedule exist that satisfies all the requirements? That, in itself, is obviously helpful.
Good luck !
I have designed commercial algorithms for both class timetabling and examination timetabling. For the first I used integer programming; for the second a heuristic based on maximizing an objective function by choosing slot swaps, very similar to the original manual process that had been evolved. They main things in getting such solutions accepted are the ability to represent all the real-world constraints; and for human timetablers to not be able to see ways to improve the solution. In the end the algorithmic part was quite straightforward and easy to implement compared with the preparation of the databases, the user interface, ability to report on statistics like room utilization, user education and so on.
You can takle it with genetic algorithms, yes. But you shouldn't :). It can be too slow and parameter tuning can be too timeconsuming etc.
There are successful other approaches. All implemented in open source projects:
Constraint based approach
Implemented in UniTime (not really for schools)
You could also go further and use Integer programming. Successfully done at Udine university and also at University Bayreuth (I was involved there) using the commercial software (ILOG CPLEX)
Rule based approach with heuristisc - See Drools planner
Different heuristics - FET and my own
See here for a timetabling software list
I think you should use genetic algorithm because:
It is best suited for large problem instances.
It yields reduced time complexity on the price of inaccurate answer(Not the ultimate best)
You can specify constraints & preferences easily by adjusting fitness punishments for not met ones.
You can specify time limit for program execution.
The quality of solution depends on how much time you intend to spend solving the program..
Genetic Algorithms Definition
Genetic Algorithms Tutorial
Class scheduling project with GA
Also take a look at :a similar question and another one
This problem is MASSIVE where I work - imagine 1800 subjects/modules, and 350 000 students, each doing 5 to 10 modules, and you want to build an exam in 10 weeks, where papers are 1 hour to 3 days long... one plus point - all exams are online, but bad again, cannot exceed the system's load of max 5k concurrent. So yes we are doing this now in cloud on scaling servers.
The "solution" we used was simply to order modules on how many other modules they "clash" with descending (where a student does both), and to "backpack" them, allowing for these long papers to actually overlap, else it simply cannot be done.
So when things get too large, I found this "heuristic" to be practical... at least.
I don't know any one will agree with this code but i developed this code with the help of my own algorithm and is working for me in ruby.Hope it will help them who are searching for it
in the following code the periodflag ,dayflag subjectflag and the teacherflag are the hash with the corresponding id and the flag value which is Boolean.
Any issue contact me.......(-_-)
periodflag.each do |k2,v2|
if(TimetableDefinition.find(k2).period.to_i != 0)
subjectflag.each do |k3,v3|
if (v3 == 0)
if(getflag_period(periodflag,k2))
#teachers=EmployeesSubject.where(subject_name: #subjects.find(k3).name, division_id: division.id).pluck(:employee_id)
#teacherlists=Employee.find(#teachers)
teacherflag=Hash[teacher_flag(#teacherlists,teacherflag,flag).to_a.shuffle]
teacherflag.each do |k4,v4|
if(v4 == 0)
if(getflag_subject(subjectflag,k3))
subjectperiod=TimetableAssign.where("timetable_definition_id = ? AND subject_id = ?",k2,k3)
if subjectperiod.blank?
issubjectpresent=TimetableAssign.where("section_id = ? AND subject_id = ?",section.id,k3)
if issubjectpresent.blank?
isteacherpresent=TimetableAssign.where("section_id = ? AND employee_id = ?",section.id,k4)
if isteacherpresent.blank?
#finaltt=TimetableAssign.new
#finaltt.timetable_struct_id=#timetable_struct.id
#finaltt.employee_id=k4
#finaltt.section_id=section.id
#finaltt.standard_id=standard.id
#finaltt.division_id=division.id
#finaltt.subject_id=k3
#finaltt.timetable_definition_id=k2
#finaltt.timetable_day_id=k1
set_school_id(#finaltt,current_user)
if(#finaltt.save)
setflag_sub(subjectflag,k3,1)
setflag_period(periodflag,k2,1)
setflag_teacher(teacherflag,k4,1)
end
end
else
#subjectdetail=TimetableAssign.find_by_section_id_and_subject_id(#section.id,k3)
#finaltt=TimetableAssign.new
#finaltt.timetable_struct_id=#subjectdetail.timetable_struct_id
#finaltt.employee_id=#subjectdetail.employee_id
#finaltt.section_id=section.id
#finaltt.standard_id=standard.id
#finaltt.division_id=division.id
#finaltt.subject_id=#subjectdetail.subject_id
#finaltt.timetable_definition_id=k2
#finaltt.timetable_day_id=k1
set_school_id(#finaltt,current_user)
if(#finaltt.save)
setflag_sub(subjectflag,k3,1)
setflag_period(periodflag,k2,1)
setflag_teacher(teacherflag,k4,1)
end
end
end
end
end
end
end
end
end
end
end
I'm writing a small software application that needs to serve as a simple planning tool for a local school. The 'problem' it needs to solve is fairly basic. Namely, the teachers need to talk with the parents of all children. However, some children have, of course, brothers and sisters in different groups, so these talks need to be scheduled next to eachother, to avoid the situations were parents have a talk at 6 pm and another one at 10 pm. Thus in short, given a collection of n children, where some children have 1 or more brothers or sisters, generate a schedule where all the talks of these children are planned next to each other.
Now, maybe the problem can be solved extremely easy, but on the other I have a feeling this can be a pretty complicated problem, that needs and can be solved with some sort of algorithm. Elegantly. But am I right? Is there? I've looked at the Hungarian alorithm but it doesn't quite apply to this particular problem.
Edit: I forgot to mention, that all talks take the same amount of time.
Thanks!
I think it is quite easy.
First group the kids which belong together because they share parents. Schedule the children inside a group consecutively, schedule the rest as random.
Another way to abstract it and make the problem easier is to look from the parent perspective, see brothers and sister as "child" and give them more time. Then you can just schedule the parents at random, but some need more time (because they have multiple childeren).
One approach woul dbe to define the problem in a declarative constraint language and then let it solve the problem for you. The last time I did this, I used ECLiPSe, which is a nifty little language where you define your problem space by constraints, and then let it find allowable values that satisfy those constraints.
For example, I believe you have two classes of constraints:
A teacher may only have one
conference at a time
All students in the same family must
have consecutive slots
Once you define these in ECLiPSe, it will calculate values for each student that satisfy the requirements. If you go this way, you can also easily add constraints as you need to. For example, it's easy to say that a teach is unavailable for slot Y, or teachers must take turns doing administrative work, etc.
This sorts feels like a "backpack algorithm" type of problem. You need to group the family members together then fill slots appropriately.
If you google "backpack algorithm", you'll see enough write-ups to make your head spin and also some good coded solutions.
I think if each talk could be reduced to "activities" where each activity has a start time and an end time you could use the activity-selection algorithm studied in computer science. It is based on a greedy approach and could be solved in O(n) (where n is the number of activities). You could find more information here. I am sure you will need to have to do a pre-processing here to be able to reduce the brother/sister issue as activities of the same type.