Incentive Mechanisms for Social Computing

Human participation in hybrid collective adaptive systems (hCAS) is overgrowing conventional social computing where humans solve simple, independent tasks. Novel systems are attempting to leverage humans for more intellectually challenging tasks, involving longer lasting worker engagement and complex collaboration patterns. This poses the problem of finding, engaging, motivating, retaining and assessing workers, thus adapting the participating workforce. Existing incentive management techniques in use in socio-technical platforms are not suitable for the more intellectually-challenging tasks. In addition, each platform currently develops custom solutions and implements them anew. This approach is not portable, and effectively prevents reuse of common incentive logic and reputation transfer. Consequently, this prevents workers from comparing different platforms, hindering the competitiveness of the virtual labor market and making it less attractive to skilled workers. This research attempts to develop an end-to-end solution for programmable incentive management for hybrid CASs. In particular, it presents a model and framework for execution of programmable incentive mechanisms, and a high-level domain-specific language for encoding complex incentive strategies for socio-technical systems, encouraging a modular approach in building incentive strategies, cutting down development and adjustment time and creating a basis for development of standardized but tweak able incentives. The presented contributions are based on a comprehensive, multidisciplinary review of existing literature on incentives and real-world incentive practices in social computing milieu.

[1]  Bruno Ribeiro,et al.  The socio-monetary incentives of online social network malware campaigns , 2014, Conference on Online Social Networks.

[2]  G. Nigel Gilbert,et al.  Simulation for the social scientist , 1999 .

[3]  Eytan Adar Why I Hate Mechanical Turk Research (and Workshops) , 2011 .

[4]  Marco Zamarian,et al.  Analyzing Crowd Labor and Designing Incentives for Humans in the Loop , 2012, IEEE Internet Computing.

[5]  Øystein Haugen,et al.  Evaluating Domain-Specific Modelling Solutions , 2010, ER Workshops.

[6]  Canice Prendergast The Provision of Incentives in Firms , 1999 .

[7]  Andrew McGregor,et al.  AutoMan: a platform for integrating human-based and digital computation , 2012, OOPSLA '12.

[8]  Rex B. Kline,et al.  Usability measurement and metrics: A consolidated model , 2006, Software Quality Journal.

[9]  Fabio Casati,et al.  Modeling, Enacting, and Integrating Custom Crowdsourcing Processes , 2015, TWEB.

[10]  Michael J. North,et al.  Tutorial on agent-based modelling and simulation , 2005, Proceedings of the Winter Simulation Conference, 2005..

[11]  Mahmood Hosseini,et al.  The four pillars of crowdsourcing: A reference model , 2014, 2014 IEEE Eighth International Conference on Research Challenges in Information Science (RCIS).

[12]  Abraham Bernstein,et al.  CrowdLang: A Programming Language for the Systematic Exploration of Human Computation Systems , 2012, SocInfo.

[13]  Lydia B. Chilton,et al.  Exploring iterative and parallel human computation processes , 2010, HCOMP '10.

[14]  Francisco J. Miguel Quesada Gilbert, Nigel; Troitzsch, Klaus (2005). Simulation for the Social Scientist , 2006 .

[15]  Ya'akov Gal,et al.  A study of computational and human strategies in revelation games , 2014, Autonomous Agents and Multi-Agent Systems.

[16]  Dennis D. Fehrenbacher Design of Incentive Systems , 2013 .

[17]  Martin Bichler,et al.  Design science in information systems research , 2006, Wirtschaftsinf..

[18]  Schahram Dustdar,et al.  Simulation-Based Modeling and Evaluation of Incentive Schemes in Crowdsourcing Environments , 2013, OTM Conferences.

[19]  Michael S. Bernstein,et al.  The future of crowd work , 2013, CSCW.

[20]  Alexis Battle,et al.  The jabberwocky programming environment for structured social computing , 2011, UIST.

[21]  Anton Nijholt,et al.  Computational Social Sciences , 2022, Encyclopedia of Big Data.

[22]  Schahram Dustdar,et al.  Programming Incentives in Information Systems , 2013, CAiSE.

[23]  Alessandro Bozzon,et al.  Modeling CrowdSourcing Scenarios in Socially-Enabled Human Computation Applications , 2013, Journal on Data Semantics.

[24]  Alessandro Bozzon,et al.  Pattern-Based Specification of Crowdsourcing Applications , 2014, ICWE.

[25]  Wai-Tat Fu,et al.  What Will Others Choose? How a Majority Vote Reward Scheme Can Improve Human Computation in a Spatial Location Identification Task , 2013, HCOMP.

[26]  Schahram Dustdar,et al.  Managing Incentives in Social Computing Systems with PRINGL , 2014, WISE.

[27]  Edward J. Lusk,et al.  Country-Compatible Incentive Design , 2009 .

[28]  Charles M. Macal,et al.  Tutorial on agent-based modelling and simulation , 2005, Proceedings of the Winter Simulation Conference, 2005..

[29]  Duncan J. Watts,et al.  Financial incentives and the "performance of crowds" , 2009, HCOMP '09.

[30]  G. Milkovich,et al.  The Relationship Between Risk, Incentive Pay, and Organizational Performance , 1997 .

[31]  David C. Parkes,et al.  Dwelling on the Negative: Incentivizing Effort in Peer Prediction , 2013, HCOMP.

[32]  Schahram Dustdar,et al.  Incentives and rewarding in social computing , 2013, CACM.

[33]  Sarvapali D. Ramchurn,et al.  Collabmap: crowdsourcing maps for emergency planning , 2013, WebSci.

[34]  Tobias Hoßfeld,et al.  Analyzing costs and accuracy of validation mechanisms for crowdsourcing platforms , 2013, Math. Comput. Model..