1. Agenda: Tuesday, Jan 25 Reports from the Field: –Friendster, Love and Money : Monday NY Times (Katy Keenan)Friendster, Love and Money –That’s Soooo High School : Monday MSNBC (Jake Wiseman)That’s Soooo High School –BitTorrent: Today’s DP Updates on course web page –TA office hours –New readings Quick tips on NW Construction task –search and automation tools –”inherently pairwise” edges –try to avoid complete networks –recall Task 1 write-up due start of Thursday’s class ~10 minutes for a little Lifester “social interaction” –you need to remember your Lifester UserID! come up front if you forgot –must have registered and created 3 links by 6 PM today Contagion, Tipping and Networks: Lecture 1 of 2 –based on Gladwell and supplementary material

2. Contagion, Tipping and Networks Networked Life CSE 112 Spring 2005 Prof. Michael Kearns

3. Gladwell, page 7: “The Tipping Point is the biography of the idea… that the best way to understand the emergence of fashion trends, the ebb and flow of crime waves, or the rise in teen smoking… is to think of them as epidemics. Ideas and products and messages and behaviors spread just like viruses do…” …on networks.

4. Some Tipping Examples Hush Puppies: –almost dead in 1994; > 10x sales increase by ’96 –no advertising or marketing budget –claim: “viral” fashion spread from NY teens to designers –must be certain connectivity and individuals NYC Crime: –1992: > 2K murders; < 770 five years later –standard socio-economic explanations: police performance, decline of crack, improved economy, aging… –but these all changed incrementally –alternative: small forces provoked anti-crime “virus” Technology tipping: fax machines, email, cell phones “Tipping” origins: 1970’s “white flight”

5. Key Characteristics of Tipping (according to Gladwell) Contagion: –“viral” spread of disease, ideas, knowledge, etc. –spread is determined by network structure –network structure will influence outcomes who gets “infected”, infection rate, number infected Amplification of the incremental: –small changes can have large, dramatic effects network topology, infectiousness, individual behavior Sudden, not gradual change: –phase transitions and non-linear phenomena

6. size of police force crime rate linear size of police force crime rate linear size of police force crime rate size of police force crime rate nonlinear, gradual decay nonlinear, tipping Rates of Growth and Decay

7. Gladwell’s Three Sources of Tipping The Law of the Few (Messengers): –Connectors, Mavens and Salesman –Hubs and Authorities The Stickiness Factor (Message): –The “infectiousness” of the “message” itself –Still largely treated as a crude property of transmission The Power of Context: –global influences affecting messenger behavior

8. Case Study: Baltimore Syphilis Epidemic Mid-90’s: sudden increase in syphilis in Baltimore Three plausible explanations: –increased crack usage  altered sexual behavior an incremental change in overall context of behavior –diminished medical services  longer time to treatment an incremental change in the stickiness of the disease –housing project demolition  migration of infected an incremental change in connectivity (law of the few) Any or all could be right

9. Agenda: Thursday, Jan 27 Turn Network Construction Project Task 1 write-up now Examination of initial Lifester network –in-class experiment on Tuesday Completion of “Contagion, Tipping and Networks”

10. diameter: worst-case: 5 average: 2.86

12. The Small World of Lifester So already you have managed to create a network with small diameter But can you find the short paths? Tuesday’s class: –please print out and bring the profiles of all your Lifester neighbors –please review those profiles before coming to class –we’ll do an in-class experiment on distributed navigation in networks

13. “Epidemos” [Thanks to Sangkyum Kim] Forest fire simulation:Forest fire simulation –grid of forest and vacant cells –fire always spreads to adjacent four cells “perfect” stickiness or infectiousness –connectivity parameter: probability of forest –fire will spread to connected component of source –tip when forest ~ 0.6 –clean mathematical formalization (e.g. fraction burned) Viral spread simulation:Viral spread simulation –population on a grid network, each with four neighbors –stickiness parameter: probability of passing disease –connectivity parameter: probability of adding random (long-distance) connections –no long distance connections: tip at stickiness ~ 0.3 –at rewiring = 0.5, often tip at stickiness ~ 0.2

14. Some Remarks on the Demos Connectivity patterns were either local or random –will eventually formalize this model –what about other/more realistic structure? Tipping was inherently a statistical phenomenon –probabilistic nature of disease spread –probabilistic nature of connectivity patterns –model likely properties of a large set of possible outcomes –can model either inherent randomness or variability Formalizing tipping in the forest fire demo: –might let grid size N  infinity, look at fixed values of p –is there a threshold value q: p < q  expected fraction burned < 1/10 p > q  expected fraction burned > 9/10

15. Small Worlds and the Law of the Few Gladwell’s “Law of the Few”: –a “small” number of “highly” connected vertices (  heavy tails) –inordinate importance for global connectivity (  small diameter) Travers & Milgram 1969: classic early social network study –destination: a Boston stockbroker; lived in Sharon, MA –sources: Nebraska stockbrokers; Nebraska and Boston “randoms” –forward letter to a first-name acquaintance “closer” to target –target information provided: name, address, occupation, firm, college, wife’s name and hometown navigational value? Basic findings: –64 of 296 chains reached the target –average length of completed chains: 5.2 interaction of chain length and navigational difficulties –main approach routes: home (6.1) and work (4.6) –Boston sources (4.4) faster than Nebraska (5.5) –no advantage for Nebraska stockbrokers

16. The Connectors to the Target T & M found that many of the completed chains passed through a very small number of penultimate individualsT & M –Mr. G, Sharon merchant: 16/64 chains –Mr. D and Mr. P: 10 and 5 chains Connectors are individuals with extremely high degree –why should connectors exist? –how common are they? –how do they get that way? (see Gladwell for anecdotes) Connectors can be viewed as the “hubs” of social traffic Note: no reason target must be a connector for small worlds Two ways of getting small worlds (low diameter): –truly random connection pattern  dense network –a small number of well-placed connectors in a sparse network Let’s revisit our Gladwell estimate of class connectivity and MK’s NWGladwell estimate MK’s NW

17. A Mathematical Digression We’ve been bouncing around the idea that connectors (~high degree vertices) lead to small diameter Obviously, if everyone is connected to everyone else… But there’s often a limit to the largest possible degree –you can’t have an unbounded number of friends, colleagues, etc. May be constraints on the mere existence of certain NWs –let  be the largest degree allowed why? e.g. because there is a limit to how many friends you can have –suppose we are interested in NWs with diameter D (or less) why? because many have claimed that D is often small –let N(  D) = size of the largest possible NW obeying  and D Exact form of N( ,D) is notoriously elusive –but known that it is between (  /2)^D and 2  ^D So, for example, if we want N ~ 300M (U.S. population): –if  = 150 (e.g. see Gladwell) and D = 6 (6 degrees): NW exists –D = 6, N = 300M, solve 2  ^D > N: get  > 23

18. Small Worlds: A Modern Experiment The Columbia Small Worlds Project:Columbia Small Worlds Project –considerably larger subject pool, uses email –subject of Dodds et al. assigned paper Basic methodology: –18 targets from 13 countries –on-line registration of initial participants, all tracking electronic –99K registered, 24K initiated chains, 384 reached targets Some findings: –< 5% of messages through any penultimate individual –large “friend degree” rarely (< 10%) cited –Dodds et al:  no evidence of connectors! (but could be that connectors are not cited for this reason…) –interesting analysis of reasons for forwardingreasons for forwarding –interesting analysis of navigation method vs. chain lengthnavigation method vs. chain length

19. Agenda: Tuesday, Feb 1 In-class Lifester network experiment Finishing up Gladwell Start on graph theory

20. Navigation in Social Networks: A Controlled Experiment

21. diameter: worst-case: 5 average: 2.86

22. Description of the Experiment Participation is mandatory and for credit If you don’t have your Lifester neighbor profiles, you cannot participate –unless you have memorized your neighbor info We will play two rounds In each round, each of you will be the source of a navigation chain You will be given a destination user to route a form to Give the form to one of your Lifester neighbors who you think is “closer” to the target Write your Lifester UserID on forms you receive, and continue to forward them towards their destinations Points will be deducted for violations of the neighborhood structure In one round, you will be given the Lifester profile of the destination In the other round, you will not be given the destination profile Then we’ll do some brief analysis with more detail to follow

23. The Strength of Weak Ties Not all links are of equal importance Granovetter 1974: study of job searches –56% found current job via a personal connection –of these, 16.7% saw their contact “often” –the rest saw their contact “occasionally” or “rarely” Your “closest” contacts might not be the most useful –similar backgrounds and experience –they may not know much more than you do –connectors derive power from a large fraction of weak ties Further evidence in Dodds et al. paper T&M, Granovetter, Gladwell: multiple “spaces” & “distances” –geographic, professional, social, recreational, political,… –we can reason about general principles without precise measurement

24. Quantifying Connectors What does it mean to have “high” degree? –is it relative to others, or absolute? –how many connectors should we expect to see? –how is it related to overall network size? Are connectors a good thing? –information spread vs. disease spread –robustness vs. vulnerability Is being a connector enough? –“second order” structure and beyond We’ll get to all this, and more

25. Mavens and Salesmen Connectors will be present in every network we study Mavens and Salesmen: –more particular to human social networks –Mavens: voracious gatherers of information and expertise –Salesmen: persuasive individual personalities induce others to adopt ideas, products, fashions, etc. A hypothetical Gladwellian scenario: –a fashion maven “discovers” Hush Puppies –their hip persuader friend begins wearing them too –which are then seen by the persuader’s connector friend –which causes Hush Puppies to tip –connector was not the source of the idea, persuader did not cause the “broadcast”, maven did not persuade, etc.

26. Stickiness Generalizes the notion of infectiousness A common marketing term How likely is the idea, fashion, etc. to be transmitted? Can also view as the “failure probability” of a link Some examples: –“Winston tastes good…” –Columbia Record Club Gold Box –Sesame Street and Blues Clues In modern times, stickiness may trump raw exposure –supplementary readings on “viral” and “word-of-mouth” marketing Persuasion (messenger) and stickiness (message) related Making technology sticky: –“The Media Equation”, by Nass and Reeves –human reaction to technology design and interface

27. The Power of Context Transmission on a network (social or otherwise) can be modulated by subtle changes in global influences –heat waves: crime, the power grid, and Amtrak Broken Windows and the NYC squeegee crackdown Gladwell: “…the premise that an epidemic can be reversed, can be tipped, by tinkering with the smallest details of the immediate environment.” Human behavior strongly and subtly influenced by context The Stanford Prison ExperimentStanford Prison Experiment The Good Samaritans of Princeton

28. The Magic Number 150 Social channel capacity –correlation between neocortex size and group size –Dunbar’s equation: neocortex ratio  group size Clear implications for many kinds of social networks Again, a topological constraint on typical degree From primates to military units to Gore-Tex

29. Next up: let’s make some of these ideas more precise –graph theory: the mathematical language of networks –social network theory