1 / 25

A Longer Example: Stable Matching

A Longer Example: Stable Matching. Matching Residents to Hospitals. Goal. Given a set of preferences among n hospitals and n medical school students, design a self-reinforcing admissions process. Suppose four doctors q,r,s,t, and four hospitals A,B,C,D rank each other as follows:.

raymondbutler
Télécharger la présentation

A Longer Example: Stable Matching

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. A Longer Example: Stable Matching Z. Guo

  2. Matching Residents to Hospitals • Goal. Given a set of preferences among n hospitals and n medical school students, design a self-reinforcing admissions process. • Suppose four doctors q,r,s,t, and four hospitals A,B,C,D rank each other as follows: Z. Guo

  3. Matching Residents to Hospitals • Goal. Given a set of preferences among n hospitals and n medical school students, design a self-reinforcing admissions process. • Unstable pair: doctor x and hospital A are unstable if: • x prefers A to its assigned hospital, and • A prefers x to its admitted student. • Stable assignment. Assignment with no unstable pairs. • Natural and desirable condition. • Individual self-interest will prevent any applicant/hospital deal from being made. Z. Guo

  4. Example • Suppose four doctors q,r,s,t, and four hospitals A,B,C,D rank each other as follows: • (A, s), (B, t), (C, q), (D, r) (stable) • (A, t), (B, q), (C, s), (D, r) (un-stable pair: (B, t)) Z. Guo

  5. A Simple Approach • Function Simple-Proposal-But-Invalid • Start with some assignment between doctors and hospitals • While unstable pair exists • “swap” to satisfy the pair • end while Z. Guo

  6. Example • Suppose four doctors q,r,s,t, and four hospitals A,B,C,D rank each other as follows: • (A, t), (B, q), (C, s), (D, r) (un-stable pair: (B, t)) • -> (A, q), (B, t), (C, s), (D, r) Z. Guo

  7. A Simple Approach • Function Simple-Proposal-But-Invalid • Start with some assignment between doctors and hospitals • While unstable pair exists • “swap” to satisfy the pair • end while • This will NOT work since a loop can occur.Swaps might continually result in new “dissatisfied” pairs. Z. Guo

  8. The Boston Pool Algorithm • The Boston Pool algorithm proceeds in rounds until every position has been filled. • Each round has two stages: • 1. An arbitrary unassigned hospital A offers its position to the best doctor x (according to the hospital’s preference list) who has not already rejected it. • 2. Each doctor ultimately accepts the best offer that she receives, according to her preference list. Thus, if x is currently unassigned, she (tentatively) accepts the offer from A. If x already has an assignment but prefers A, she rejects her existing assignment and (tentatively) accepts the new offer from A. Otherwise, x rejects the new offer. Z. Guo

  9. Example • Suppose four doctors q,r,s,t, and four hospitals A,B,C,D rank each other as follows: Z. Guo

  10. Example • Suppose four doctors q,r,s,t, and four hospitals A,B,C,D rank each other as follows: • (A, s), (B, t), (C, q), (D, r) Z. Guo

  11. Example • Suppose four doctors q,r,s,t, and four hospitals A,B,C,D rank each other as follows: • (A, s), (B, t), (C, q), (D, r) • The matching (A, r), (B, s), (C, q), (D, t) is also stable Z. Guo

  12. Correctness - Termination • Observation 1. Hospitals propose to doctors in decreasing order of preference. • Observation 2. Once a doctor accepts an offer he/she never becomes unmatched, he/she only "trades up“. • Claim. Algorithm terminates after at most n2 rounds. • Pf. Each hospital makes an offer to each doctor at most once (only make offer to “new” doctor), so the algorithm requires at most n2 rounds. • The average (expected) case is O(n lg n). Z. Guo

  13. Correctness • Claim. The algorithm always computes a matching (to all hospitals and doctors) • Pf. It’s obvious that throughout the process, no doctor can accept more than one position, and no hospital can hire more than one doctor. • Pf. (by contradiction) Suppose that Hospital A is not matched upon termination of algorithm. Then some doctor x is not matched upon termination. By Observation 2, x never received an offer. But, A made offers to everyone, since A ends up unmatched. Z. Guo

  14. Correctness • Claim. No unstable pair. • Pf. Suppose doctor x is assigned to hospital A in the final matching, but prefers B. Because every doctor accepts the best offer she receives, x received no offer she liked more than A. In particular, B never made an offer to x. On the other hand, B made offers to every doctor they like more than y. Thus, B prefers y to x, and so there is no instability. Z. Guo

  15. More properties • Def. x is a feasible doctor for A if there exists a stable matching that assigns doctor x to hospital A. • Claim. Each hospital A is rejected only by doctors that are infeasible for A. (Hospital-Optimal) • Pf. (by induction) Consider an arbitrary round of the algorithm, in which doctor x rejects A for B (B is offering x, x prefers B to A). Every doctor that appears higher than x in B’s preference list has already rejected B and therefore is infeasible for B (why?).Now consider an arbitrary matching that assigns x to A: B prefers x to its partner => unstable. B prefers its partner to x => its partner is infeasible (why?), and again the matching is unstable. Z. Guo

  16. More properties • Def. x is a feasible doctor for A if there exists a stable matching that assigns doctor x to hospital A. • Claim. Each hospital A is rejected only by doctors that are infeasible for A. (Hospital-Optimal) • Claim. Each doctor x prefers every other feasible match to its final assignment A. (Doctor-Pessimal) • Pf. Consider an arbitrary stable matching where A is not matched with x but with another doctor y.The previous Claim implies that A prefers x to y (why?). Because the matching is stable, x must therefore prefer her assigned hospital to A. Z. Guo

  17. More properties • No matter which unassigned hospital makes an offer in each round, the algorithm always computes the same matching ( why?) • A doctor can potentially improve her assignment by lying about her preferences • NRMP reversed its matching algorithm in 1998 • So that potential residents offer to work for hospitals in preference order, and each hospital accepts its best offer. • The precise effect of this change on the patients is an open problem. Z. Guo

  18. About its history • Until 1950’s • Competition among hospitals for the best doctors led to earlier and earlier offers of internships, along with tighter deadlines for acceptance. • In the 1940s, medical schools agreed not to release information until a common date during their students’ fourth year. In response, hospitals began demanding faster decisions. • Interns were forced to gamble if their third-choice hospital called first. Z. Guo

  19. In Academia • For graduate school admission, we have the “April 15 Resolution”. • However, the academic job market involves similar gambles, at least in computer science. • Some departments start making offers in February with two-week decision deadlines; others don’t even start interviewing until late March; • MIT notoriously waits until May, when all its interviews are over, before making any faculty offer. Z. Guo

  20. About its history • In the early 1950’s • A central clearinghouse for internship assignments, now called the National Resident Matching Program (NRMP), was established • Each year, doctors submit a ranked list of all hospitals where they would accept an internship, and each hospital submits a ranked list of doctors they would accept as interns. • The NRMP then computes astable assignment of interns to hospitals. Z. Guo

  21. It’s not the end of the story • In reality, most hospitals offer multiple internships, each doctor ranks only a subset of the hospitals and vice versa, and • There are typically more internships than interested doctors. • And then it starts getting complicated, moreover, e.g., • There are couples that willing to stay in the same city/hospital whenever possible… Z. Guo

  22. This course • This class is ultimately about learning two skills that are crucial for all computer scientists: • Intuition: How to think about abstract computation. Z. Guo

  23. This course • This class is ultimately about learning two skills that are crucial for all computer scientists: • Intuition: How to think about abstract computation. • Language: How to talk about abstract computation. Z. Guo

  24. This course • This class is ultimately about learning two skills that are crucial for all computer scientists: • Intuition: How to think about abstract computation. • Language: How to talk about abstract computation. • You can only develop good problem solving skills by solving problems. You can only develop good communication skills by communicating. Z. Guo

  25. Example - Process • Suppose four doctors q,r,s,t, and four hospitals A,B,C,D rank each other as follows: • (A,t); (A,t)(B,r); (C,t)(B,r); (C,t)(B,r)(D,s);(A,s)(C,t)(B,r); (A,s)(C,t)(D,r); (A,s)(B,t)(D,r);+(C,r?);+(C,s?); (A,s)(B,t)(D,r)(C,q); Z. Guo

More Related