Evangelos Niforatos, Ivan Elhart and Marc Langheinrich in Web Engineering: “Contemporary public display systems hold a significant potential to contribute to in situ crowdsourcing. Recently, public display systems have surpassed their traditional role as static content projection hotspots by supporting interactivity and hosting applications that increase overall perceived user utility. As such, we developed WeatherUSI, a web-based interactive public display application that enables passers-by to input subjective information about current and future weather conditions. In this demo paper, we present the functionality of the app, describe the underlying system infrastructure and present how we combine input streams originating from WeatherUSI app on a public display together with its mobile app counterparts for facilitating user based weather crowdsourcing….(more)”
Time for sharing data to become routine: the seven excuses for not doing so are all invalid
Paper by Richard Smith and Ian Roberts: “Data are more valuable than scientific papers but researchers are incentivised to publish papers not share data. Patients are the main beneficiaries of data sharing but researchers have several incentives not to share: others might use their data to get ahead in the academic rat race; they might be scooped; their results might not be replicable; competitors may reach different conclusions; their data management might be exposed as poor; patient confidentiality might be breached; and technical difficulties make sharing impossible. All of these barriers can be overcome and researchers should be rewarded for sharing data. Data sharing must become routine….(More)”
How to implement “open innovation” in city government
Victor Mulas at the Worldbank: “City officials are facing increasingly complex challenges. As urbanization rates grow, cities face higher demand for services from a larger and more densely distributed population. On the other hand, rapid changes in the global economy are affecting cities that struggle to adapt to these changes, often resulting in economic depression and population drain.
“Open innovation” is the latest buzz word circulating in forums on how to address the increased volume and complexity of challenges for cities and governments in general.
But, what is open innovation?
Traditionally, public services were designed and implemented by a group of public officials. Open innovation allows us to design these services with multiple actors, including those who stand to benefit from the services, resulting in more targeted and better tailored services, often implemented through partnership with these stakeholders. Open innovation allows cities to be more productive in providing services while addressing increased demand and higher complexity of services to be delivered.
New York, Barcelona, Amsterdam and many other cities have been experimenting with this concept, introducing challenges for entrepreneurs to address common problems or inviting stakeholders to co-create new services. Open innovation has gone from being a “buzzword” to another tool in the city officials’ toolbox.
However, even cities that embrace open innovation are still struggling to implement it beyond a few specific areas. This is understandable, as introducing open innovation practically requires a new way of doing things for city governments, which tend to be complex and bureaucratic organizations.
Counting with an engaged mayor is not enough to bring this kind of transformation. Changing the behavior of city officials requires their buy-in, it can’t be done top down
We have been introducing open innovation to cities and governments for the last three years in Chile, Colombia, Egypt and Mozambique. We have addressed specific challenges and iteratively designed and tested a systematic methodology to introduce open innovation in government through both a top-down and a bottom-up approaches. We have tested this methodology in Colombia (Cali, Barranquilla and Manizales) and Chile (metropolitan area of Gran Concepción). We have identified “internal champions” (i.e., government officials who advocate the new methodology), and external stakeholders organized in an “innovation hub” that provides long-term sustainability and scalability of interventions. We believe that this methodology is easily applicable beyond cities to other government entities at the regional and national levels. …To understand how the methodology practically works, we describe in this report the process and its results in its application in the city area of Gran Concepción, in Chile. For this activity, the urban transport sector was selected and the target of intervention were the regional and municipal government departments in charge or urban transport in the area of Gran Concepción. The activity in Chile resulted in a threefold impact:
- It catalyzed the adoption of the bottom-up smart city model following this new methodology throughout Chile; and
- It expanded the implementation and mainstreaming of the methodologies developed and tested through this activity in other World Bank projects.
More information about this activity in Chile can be found in the Smart City Gran Concepcion webpage…(More)”
Teenage scientists enlisted to fight Zika
ShareAmerica: “A mosquito’s a mosquito, right? Not when it comes to Zika and other mosquito-borne diseases.
Only two of the estimated 3,000 species of mosquitoes are capable of carrying the Zika virus in the United States, but estimates of their precise range remain hazy, according to the U.S. Centers for Disease Control and Prevention.
Scientists could start getting better information about these pesky, but important, insects with the help of plastic cups, brown paper towels and teenage biology students.
As part of the Invasive Mosquito Project from the U.S. Department of Agriculture, secondary-school students nationwide are learning about mosquito populations and helping fill the knowledge gaps.
Simple experiment, complex problem
The experiment works like this: First, students line the cups with paper, then fill two-thirds of the cups with water. Students place the plastic cups outside, and after a week, the paper is dotted with what looks like specks of dirt. These dirt particles are actually mosquito eggs, which the students can identify and classify.
Students then upload their findings to a national crowdsourced database. Crowdsourcing uses the collective intelligence of online communities to “distribute” problem solving across a massive network.
Entomologist Lee Cohnstaedt of the U.S. Department of Agriculture coordinates the program, and he’s already thinking about expansion. He said he hopes to have one-fifth of U.S. schools participate in the mosquito species census. He also plans to adapt lesson plans for middle schools, Scouting troops and gardening clubs.
Already, crowdsourcing has “collected better data than we could have working alone,” he told the Associated Press….
In addition to mosquito tracking, crowdsourcing has been used to develop innovative responses to a number of complex challenges, from climate change to archaeologyto protein modeling….(More)”
The Small World Initiative: An Innovative Crowdsourcing Platform for Antibiotics
Ana Maria Barral et al in FASEB Journal: “The Small World Initiative™ (SWI) is an innovative program that encourages students to pursue careers in science and sets forth a unique platform to crowdsource new antibiotics. It centers around an introductory biology course through which students perform original hands-on field and laboratory research in the hunt for new antibiotics. Through a series of student-driven experiments, students collect soil samples, isolate diverse bacteria, test their bacteria against clinically-relevant microorganisms, and characterize those showing inhibitory activity. This is particularly relevant since over two thirds of antibiotics originate from soil bacteria or fungi. SWI’s approach also provides a platform to crowdsource antibiotic discovery by tapping into the intellectual power of many people concurrently addressing a global challenge and advances promising candidates into the drug development pipeline. This unique class approach harnesses the power of active learning to achieve both educational and scientific goals…..We will discuss our preliminary student evaluation results, which show the compelling impact of the program in comparison to traditional introductory courses. Ultimately, the mission of the program is to provide an evidence-based approach to teaching introductory biology concepts in the context of a real-world problem. This approach has been shown to be particularly impactful on underrepresented STEM talent pools, including women and minorities….(More)”
BeMyEye: Crowdsourcing is making it easier to gather data fast
Jack Torrance at Management Today: “The era of big data is upon us. Dozens of well-funded start-ups have sprung up of late claiming to be able to turn raw data into ‘actionable insights’ that would have been unimaginable a few years ago. But the process of actually collecting data is still not always straightforward….
London-based start-up BeMyEye (not to be confused with Be My Eyes, an iPhone app that claims to ‘help the blind see’) has built an army of casual data gatherers that report back via their phones. ‘For companies that sell their product to high street retailers or supermarkets, being able to verify the presence of their product, the adequacy of the promotions, the positioning in relation to competitors, this is all invaluable intelligence,’ CEO Luca Pagano tells MT. ‘Our crowd is able to observe and feed this information back to these brands very, very quickly.’…
They can do more than check prices in shops. Some of its clients (which include Heineken, Illy and Three) have used the service to check billboards they are paying for have actually been put up correctly. ‘We realised the level of [billboard] compliance is actually below 90%,’ says Pagano. It can also be used to generate sales leads….
BeMyEyes isn’t the only company that’s exploring this business model. San Francisco company Premise is using a similar network of data gatherers to monitor food prices and other metrics in developing countries for NGOs and governments as well as commercial organisations. It’s not hard to see why they would be an attractive proposition for clients, but the challenge for both of these businesses will be ensuring they can find enough reliable and effective data gatherers to keep the information flowing in at a high enough quality….(More)”
Twelve principles for open innovation 2.0
Martin Curley in Nature: “A new mode of innovation is emerging that blurs the lines between universities, industry, governments and communities. It exploits disruptive technologies — such as cloud computing, the Internet of Things and big data — to solve societal challenges sustainably and profitably, and more quickly and ably than before. It is called open innovation 2.0 (ref. 1).
Such innovations are being tested in ‘living labs’ in hundreds of cities. In Dublin, for example, the city council has partnered with my company, the technology firm Intel (of which I am a vice-president), to install a pilot network of sensors to improve flood management by measuring local rain fall and river levels, and detecting blocked drains. Eindhoven in the Netherlands is working with electronics firm Philips and others to develop intelligent street lighting. Communications-technology firm Ericsson, the KTH Royal Institute of Technology, IBM and others are collaborating to test self-driving buses in Kista, Sweden.
Yet many institutions and companies remain unaware of this radical shift. They often confuse invention and innovation. Invention is the creation of a technology or method. Innovation concerns the use of that technology or method to create value. The agile approaches needed for open innovation 2.0 conflict with the ‘command and control’ organizations of the industrial age (see ‘How innovation modes have evolved’). Institutional or societal cultures can inhibit user and citizen involvement. Intellectual-property (IP) models may inhibit collaboration. Government funders can stifle the emergence of ideas by requiring that detailed descriptions of proposed work are specified before research can begin. Measures of success, such as citations, discount innovation and impact. Policymaking lags behind the market place….
Keys to collaborative innovation
- Purpose. Efforts and intellects aligned through commitment rather than compliance deliver an impact greater than the sum of their parts. A great example is former US President John F. Kennedy’s vision of putting a man on the Moon. Articulating a shared value that can be created is important. A win–win scenario is more sustainable than a win–lose outcome.
- Partner. The ‘quadruple helix’ of government, industry, academia and citizens joining forces aligns goals, amplifies resources, attenuates risk and accelerates progress. A collaboration between Intel, University College London, Imperial College London and Innovate UK’s Future Cities Catapult is working in the Intel Collaborative Research Institute to improve people’s well-being in cities, for example to enable reduction of air pollution.
- Platform. An environment for collaboration is a basic requirement. Platforms should be integrated and modular, allowing a plug-and-play approach. They must be open to ensure low barriers to use, catalysing the evolution of a community. Challenges in security, standards, trust and privacy need to be addressed. For example, the Open Connectivity Foundation is securing interoperability for the Internet of Things.
- Possibilities. Returns may not come from a product but from the business model that enabled it, a better process or a new user experience. Strategic tools are available, such as industrial designer Larry Keeley’s breakdown of innovations into ten types in four categories: finance, process, offerings and delivery.
- Plan. Adoption and scale should be the focus of innovation efforts, not product creation. Around 20% of value is created when an innovation is established; more than 80% comes when it is widely adopted7. Focus on the ‘four Us’: utility (value to the user); usability; user experience; and ubiquity (designing in network effects).
- Pyramid. Enable users to drive innovation. They inspired two-thirds of innovations in semiconductors and printed circuit boards, for example. Lego Ideas encourages children and others to submit product proposals — submitters must get 10,000 supporters for their idea to be reviewed. Successful inventors get 1% of royalties.
- Problem. Most innovations come from a stated need. Ethnographic research with users, customers or the environment can identify problems and support brainstorming of solutions. Create a road map to ensure the shortest path to a solution.
- Prototype. Solutions need to be tested and improved through rapid experimentation with users and citizens. Prototyping shows how applicable a solution is, reduces the risks of failures and can reveal pain points. ‘Hackathons’, where developers come together to rapidly try things, are increasingly common.
- Pilot. Projects need to be implemented in the real world on small scales first. The Intel Collaborative Research Institute runs research projects in London’s parks, neighbourhoods and schools. Barcelona’s Laboratori — which involves the quadruple helix — is pioneering open ‘living lab’ methods in the city to boost culture, knowledge, creativity and innovation.
- Product. Prototypes need to be converted into viable commercial products or services through scaling up and new infrastructure globally. Cloud computing allows even small start-ups to scale with volume, velocity and resilience.
- Product service systems. Organizations need to move from just delivering products to also delivering related services that improve sustainability as well as profitability. Rolls-Royce sells ‘power by the hour’ — hours of flight time rather than jet engines — enabled by advanced telemetry. The ultimate goal of open innovation 2.0 is a circular or performance economy, focused on services and reuse rather than consumption and waste.
- Process. Innovation is a team sport. Organizations, ecosystems and communities should measure, manage and improve their innovation processes to deliver results that are predictable, probable and profitable. Agile methods supported by automation shorten the time from idea to implementation….(More)”
Crowdsourcing corruption in India’s maternal health services
Joan Okitoi-Heisig at DW Akademie: “…The Mera Swasthya Meri Aawaz (MSMA) project is the first of its kind in India to track illicit maternal fees demanded in government hospitals located in the northern state of Uttar Pradesh.
MSMA (“My Health, My Voice”) is part of SAHAYOG, a non-governmental umbrella organization that helped launch the project. MSMA uses an Ushahidi platform to map and collect data on unofficial fees that plague India’ ostensibly “free” maternal health services. It is one of the many projects showcased in DW Akademie’s recently launched Digital Innovation Library. SAHAYOG works closely with grassroots organizations to promote gender equality and women’s health issues from a human rights perspective…
SAYAHOG sees women’s maternal health as a human rights issue. Key to the MSMA project is exposing government facilities that extort bribes from among the poorest and most vulnerable in society.
Sandhya and her colleagues are convinced that promoting transparency and accountability through the data collected can empower the women. If they’re aware of their entitlements, she says, they can demand their rights and in the process hold leaders accountable.
“Information is power,” Sandhya explains. Without this information, she says, “they aren’t in a position to demand what is rightly theirs.”
Health care providers hold a certain degree of power when entrusted with taking care of expectant mothers. Many give into bribes for fear of being otherwise neglected or abused.
With the MSMA project, however, poor rural women have technology that is easy to use and accessible on their mobile phones, and that empowers them to make complaints and report bribes for services that are supposed to be free.
MSMA is an innovative data-driven platform that combines a toll free number, an interactive voice response system (IVRS) and a website that contains accessible reports. In addition to enabling poor women to air their frustrations anonymously, the project aggregates actionable data which can then be used by the NGO as well as the government to work towards improving the situation for mothers in India….(More)”
Citizen Generated Data In Practice
DataShift: “No-one can communicate the importance of citizen-generated data better than those who are actually working with it. At DataShift, we want to highlight the civil society organisations who have told us about the tangible results they have achieved through innovative approaches to harnessing data from citizens.
Each essay profiles the objectives, challenges and targets of an organisation using data generated by citizens to achieve their goals. We hope that the essays in this collection can help more people feel more confident about asking questions of the data that affects their lives, and taking a hands-on approach to creating it. (More)”
Insights On Collective Problem-Solving: Complexity, Categorization And Lessons From Academia
Part 3 of an interview series by Henry Farrell for the MacArthur Research Network on Opening Governance: “…Complexity theorists have devoted enormous energy and attention to thinking about how complex problems, in which different factors interact in ways that are hard to predict, can best be solved. One key challenge is categorizing problems, so as to understand which approaches are best suited to addressing them.
Scott Page is the Leonid Hurwicz Collegiate Professor of Complex Systems at the University of Michigan, Ann Arbor, and one of the world’s foremost experts on diversity and problem-solving. I asked him a series of questions about how we might use insights from academic research to think better about how problem solving works.
Henry: One of the key issues of collective problem-solving is what you call the ‘problem of problems’ – the question of identifying which problems we need to solve. This is often politically controversial – e.g., it may be hard to get agreement that global warming, or inequality, or long prison sentences are a problem. How do we best go about identifying problems, given that people may disagree?
Scott: In a recent big think paper on the potential of diversity for collective problem solving in Scientific American, Katherine Phillips writes that group members must feel validated, that they must share a commitment to the group, and they must have a common goal if they are going to contribute. This implies that you won’t succeed in getting people to collaborate by setting an agenda from on high and then seeking to attract diverse people to further that agenda.
One way of starting to tackle the problem of problems is to steal a rule of thumb from Getting to Yes, by getting to think people about their broad interests rather than the position that they’re starting from. People often agree on their fundamental desires but disagree on how they can be achieved. For example, nearly everyone wants less crime, but they may disagree over whether they think the solution to crime involves tackling poverty or imposing longer prison sentences. If you can get them to focus on their common interest in solving crime rather than their disagreements, you’re more likely to get them to collaborate usefully.
Segregation amplifies the problem of problems. We live in towns and neighborhoods segregated by race, income, ideology, and human capital. Democrats live near Democrats and Republicans near Republicans. Consensus requires integration. We must work across ideologies. Relatedly, opportunity requires more than access. Many people grow up not knowing any engineers, dentists, doctors, lawyers, and statisticians. This isolation narrows the set of careers they consider and it reduces the diversity of many professions. We cannot imagine lives we do not know.
Henry: Once you get past the problem of problems, you still need to identify which kind of problem you are dealing with. You identify three standard types of problems: solution problems, selection problems and optimization problems. What – very briefly – are the key differences between these kinds of problems?
Scott: I’m constantly pondering the potential set of categories in which collective intelligence can emerge. I’m teaching a course on collective intelligence this semester and the undergraduates and I developed an acronym SCARCE PIGS to describe the different types of domains. Here’s the brief summary:
- Predict: when individuals combine information, models, or measurements to estimate a future event, guess an answer, or classify an event. Examples might involve betting markets, or combined efforts to guess a quantity, such as Francis Galton’s example of people at a fair trying to guess the weight of a steer.
- Identify: when individuals have local, partial, or possibly erroneous knowledge and collectively can find an object. Here, an example is DARPA’s Red Balloon project.
- Solve: when individuals apply and possibly combine higher order cognitive processes and analytic tools for the purpose of finding or improving a solution to a task. Innocentive and similar organizations provide examples of this.
- Generate: when individuals apply diverse representations, heuristics, and knowledge to produce something new. An everyday example is creating a new building.
- Coordinate: when individuals adopt similar actions, behaviors, beliefs, or mental frameworks by learning through local interactions. Ordinary social conventions such as people greeting each other are good examples.
- Cooperate: when individuals take actions, not necessarily in their self interest, that collectively produce a desirable outcome. Here, think of managing common pool resources (e.g. fishing boats not overfishing an area that they collectively control).
- Arrange: when individuals manipulate items in a physical or virtual environment for their own purposes resulting in an organization of that environment. As an example, imagine a student co-op which keeps twenty types of hot sauce in its pantry. If each student puts whichever hot sauce she uses in the front of the pantry, then on average, the hot sauces will be arranged according to popularity, with the most favored hot sauces in the front and the least favored lost in the back.
- Respond: when individuals react to external or internal stimuli creating collective responses that maintains system level functioning. For example, when yellow jackets attack a predator to maintain the colony, they are displaying this kind of problem solving.
- Emerge: when individual parts create a whole that has categorically distinct and new functionalities. The most obvious example of this is the human brain….(More)”