From open assessment to shared understanding: practical experiences

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From insight network to open policy practice: practical experiences is a manuscript of a scientific article. The main point is to offer a comprehensive summary of the methods developed at THL/environmental health to support informed societal decision making, and evaluate their use and usability in practical examples in 2006-2018. Manuscript was submitted to Health Research Policy and Systems. Thank you for your interest.

Title page

From insight network to open policy practice: practical experiences

Short title: From insight network to open policy practice

Jouni T. Tuomisto1* ORCID 0000-0002-9988-1762, Mikko Pohjola1,2 0000-0001-9006-6510, Teemu Rintala1,3 ORCID 0000-0003-1849-235X.

1 Finnish Institute for Health and Welfare, Kuopio, Finland

2 Kisakallio Sport Institute, Lohja, Finland

3 Institute of Biomedicine, University of Eastern Finland, Kuopio, Finland

* Corresponding author

Email: jouni.tuomisto[]thl.fi


This article describes a decision support method called open policy practice. It has mostly been developed in Finnish Institute for Health and Welfare (THL, Finland) during the last 15 years. Each assessment, case study, and method has been openly described and also typically published in scientific journals. However, this is the first comprehensive summary of open policy practice as a whole (since 2007) and thus gives a valuable overview, rationale, and evaluation for several methodological choices we have made. We have combined methods from several disciplines, including toxicology, exposure sciences, impact assessment, statistical and Bayesian methods, argumentation theory, ontologies, and co-creation to produce a coherent method for scientific decision support.

The article is currently under peer review. You can read about the main topics of the article from Opasnet pages Open policy practice, Shared understanding, Open assessment, and Properties of good assessment.

Abstract

Background

Evidence-informed decision making and better use of scientific information in societal decisions has been an area of development for decades but is still topical. Decision support work can be viewed from the perspective of information collection, synthesis, and flow between decision makers, experts, and stakeholders. Open policy practice is a coherent set of methods for such work. It has been developed and utilised mostly in Finnish and European contexts.

Methods

An overview of open policy practice is given, and theoretical and practical properties are evaluated based on properties of good policy support. The evaluation is based on information from several assessments and research projects developing and applying open policy practice and the authors' practical experiences. The methods are evaluated against their capability of producing quality of content, applicability, and efficiency in policy support, as well as how well they support close interaction among participants and understanding of each other's views.

Results

Many methods within open policy practice are widely used in numerous contexts, such as co-creation, scientific criticism, or open data and models. The evaluation revealed that methods and online tools work as expected, as demonstrated by the numerous assessments and policy support processes conducted. The approach improves the availability of information and especially of relevant details. Experts are ambivalent about the acceptability of openness: it is an important scientific principle, but it goes against many current research and decision making practices. However, co-creation and openness are megatrends that are changing science, decision making and the society at large. Against many experts' fears, open participation has not caused problems in performing high-quality assessments. On the contrary, a key challenge is to motivate more experts, decision makers, and citizens to participate and share their views. ----arg4692: . Check this at the very end if the message could be still strengthened with some findings. --Mikko Pohjola (talk) 20:48, 14 February 2020 (UTC) (type: truth; paradigms: science: comment)

Conclusions

Open policy practice has proved to be a useful and coherent set of methods. It guides policy processes toward more collaborative approach, whose purpose is wider understanding rather than winning a debate. There is potential for merging open policy practice with other open science and open decision process tools. Active facilitation, community building and improving the user-friendliness of the tools were identified as key solutions for improving usability of the method in the future. ----arg4692: . Check this at the very end if the message could be still strengthened with some findings. --Mikko Pohjola (talk) 20:48, 14 February 2020 (UTC) (type: truth; paradigms: science: comment)

Keywords
environmental health, decision support, open assessment, open policy practice, shared understanding, policy making, collaboration, evaluation, knowledge crystal, impact assessment

Background

This article describes and evaluates open policy practice, a set of methods and tools for improving evidence-informed policy making. Evidence-informed decision support has been a hot and evolving topic for a long time, and its importance is not diminishing any time soon. In this article, decision support is defined as knowledge work that is performed during the whole decision process (ideating possible actions, assessing impacts, deciding between options, implementing decisions, and evaluating outcomes) and that aims to produce better decisions and outcomes[1]. Here, "assessment of impacts" means ex ante consideration about what will happen if a particular decision is made, and "evaluation of outcomes" means ex post consideration about what did happen after a decision was implemented.

The area is complex, and all the key players — decision makers, experts, and citizens or other stakeholders — all have different views on the process, their own roles in it, and how information should be used in the process. For example, researchers often think of information as a way to find the truth, while politicians see information as one of the tools to promote political agendas ultimately based on values.[2] Therefore, a successful method should provide functionalities for each of the key groups.

In the late 1970's, the focus was on scientific knowledge and an idea that political ambitions should be separated from objective assessments especially in the US. Since the 1980's, risk assessment has been a key method to assess human risks of environmental and occupational chemicals[3]. National Research Council specifically developed a process that could be used by all federal US agencies. The report emphasised the importance of scientific knowledge in decision making and scientific methods, such as critical use of data, as integral parts of assessments. Criticism based on observations and rationality is a central idea in the scientific method[4]. The report also clarified the use of causality: the purpose of an assessment is to clarify and quantify a causal path where an exposure to a chemical or other agent leads to a health risk via pathological changes described by the dose-response function of that chemical.

The approach was designed for single chemicals rather than for complex societal issues. This shortcoming was approached in another report that acknowledged this complexity and offered deliberation with stakeholders as a solution, in addition to scientific analysis[5]. An idea was to explicate the intentions of the decision maker but also those of the public. Also, mutual learning about the topic was seen important. There are models for describing facts and values in a coherent dual system[6]. However, practical assessments have found it difficult to successfully perform deliberation on a routine basis[7]. Indeed, citizens often complain that even if they have been formally listened to during a process, the processes need more openness, as their concerns have not contributed to the decisions made[8].

Western societies have shown a megatrend of increasing openness in many sectors, including decision-making and research. Openness of scientific publishing is increasing and many research funders also demand publishing of data, and research societies are starting to see the publishing of data as a scientific merit in itself[9]. It has been widely acknowledged that the current mainstream of proprietary (as contrast to open access) scientific publishing is a hindrance to spreading ideas and ultimately science[10]. Also governments have been active in opening data and statistics to wide use (data.gov.uk). Governance practices have been developed towards openness and inclusiveness, promoted by international initiatives such as Open Government Partnership (www.opengovpartnership.org).

As an extreme example, a successful hedge fund Bridgewater Associates implements radical openness and continuous criticism of all ideas presented by its workers rather than letting organisational status determine who is heard[11]. In a sense, they are implementing the scientific method in much more rigorous way than what is typically done in science.

In the early 2000's, several important books and articles were published about mass collaboration[12], wisdom of crowds[13], crowdsourcing in the government[14], and co-creation[15]. A common idea of the authors was that voluntary, self-organised groups had knowledge and capabilities that could be much more effectively harnessed in the society than what was happening at the time. Large collaborative projects have shown that in many cases, they are very effective ways to produce high-quality information, as long as quality control systems are functional. In software development, Linux operating system, Git software, and Github platform are examples of this. Also Wikipedia, the largest and most used encyclopedia in the world, has demonstrated that self-organised groups can indeed produce high-quality content[16].

The five principles of collaboration, openness, criticism, causality, and intentionality (Table 1) were seen as potentially important for environmental health assessment in Finnish Institute for Health and Welfare (THL; at that time National Public Health Institute, KTL), and they were adopted in the methodological decision support work of the Centre of Excellence for Environmental Health Risk Analysis (2002-2007). Open policy practice has been developed during the last twenty years especially to improve environmental health assessmentsa. Developers have come from several countries in projects mostly funded by EU and the Academy of Finland (see Funding and Acknowledgements). ----arg6207: . Should the cooperation in this network be explained here a little bit more in order to emphasize the broader meaning and connectedness of the development process of this method set? --Mikko Pohjola (talk) 21:01, 14 February 2020 (UTC) (type: truth; paradigms: science: comment)

Materials for the development, testing, and analysis of open policy practice were collected from several sources.

Research projects about assessing environmental health risks were an important platform to develop, test, and implement assessment methods and policy practices. Important projects are listed in Funding.

Assessment cases were performed in research projects and in support for national or municipality decision making in Finland. Methods and tools were developed side by side with practical assessment work (Appendix 2).

Literature searches were performed to scientific and policy literature and websites. Concepts and methods similar to those in open policy practice were sought. Data was searched from Pubmed, Web of Knowledge, Google Scholar, and the Internet. In addition, a snowball method was used: found documents were used to screen their references and authors' other publications to identify new publications. Articles that describe large literature searches and their results include[1][7][17][18].

Open risk assessment workshops were organised as spin-offs of several of these projects for international doctoral students in 2007, 2008, and 2009. The workshops offered a place to share, discuss, and criticise ideas.

A master's course Decision Analysis and Risk Management (6 credit points) was organised by the University of Eastern Finland (previously University of Kuopio) in 2011, 2013, 2015, and 2017. The course taught open policy practice and tested its methods in course work.

Finally, general expertise and understanding was developed during practical experiences and long-term follow-up of international and national politics.

The development and selection of methods and tools to open policy practice has roughly followed this iterative pattern, where an idea is improved during each iteration, or sometimes rejected.

  • A need is identified for improving knowledge practices of a decision process or scientific policy support. This need typically arises from scientific literature, project work or news media.
  • A solution idea is developed in aim to tackle the need.
  • It is checked whether the idea fits logically in the current framework of open policy practice.
  • The idea is discussed in a project team to develop it further and gain acceptance.
  • A practical solution (web tool, checklist or similar) is produced.
  • The solution is piloted in an assessment or policy process.
  • The solution is added into open policy practice.

The first methodological focus was on opening the expert work in policy assessments. In 2007, this line of research produced a summary report about the new methods and tools developed to facilitate assessments[19]. Later, a wider question about open policy practiceb emerged: how to organise evidence-informed decision making in a situation where the five principles are used as the starting point? The question was challenging, especially as it was understood that societal decision making is rarely a single event, but often consists of several interlinked decisions at different time points and sometimes by several decision-making bodies. Therefore, it was seen more as a leadership guidance rather than advice about a single decision.

This article gives the first comprehensive, peer-reviewed description about the current methods and tools of open policy practice since the 2007 report[19]. However, case studies have been published along the way, and the key methods have been described in different articles. Also, all methods and tools have been developed online and the full material has been available at Opasnet (http://en.opasnet.org) for interested readers since each piece was first written.

The purpose of this article is to critically evaluate the performance of open policy practice. Does it have the properties of good policy support? And does it enable policy support according to the five principles of open policy practice in Table 1?

Table 1. Principles of open policy practice. (COCCI principles)
Principle Description
Collaboration Knowledge work is performed together in aim to produce shared information.
Openness All work and all information is openly available to anyone interested for reading and contributing all the time. If there are exceptions, these must be publicly justified.
Causality The focus is on understanding and describing the causal relations between the decision options and the intended outcomes. The aim is to predict what impacts will likely occur if a particular decision option is chosen.
Criticism All information presented can be criticised based on relevance and accordance to observations. The aim is to reject ideas, hypotheses — and ultimately decision options — that do not hold against critique.
Intentionality The decision makers explicate their objectives and decision options under consideration. Also values of other participants or stakeholders are documented and considered.

Open policy practice

Figure 1. Information flows in open policy practice. Open assessments and web-workspaces have an important role as information hubs. They collect relevant information for particular decision processes and organise and synthesise it into useful formats especially for decision makers but also for anyone. The information hub works more effectively if all stakeholders contribute to one place, or alternatively facilitators collect their contributions there.

In this section, open policy practice is described in its current state. First, an overview is given, and then each part is described in more detail.

Open policy practice is a set of methods to support and perform societal decision making in an open society, and it is the overarching concept covering all methods, tools, practices, and terms presented in this article[20]. Its theoretical foundation is on the graph theory[21] and systematic information structures. Open policy practice especially focuses on promoting the openness, flow and use of information in decision processes (Figure 1). Its purpose is to give practical guidance for the whole decision process from ideating possible actions to assessing impacts, deciding between options, implementing decisions, and finally to evaluating outcomes. It aims to be applicable to all kinds of societal decision situations in any administrative area or discipline. An ambitious objective of open policy practice is to be so effective that a citizen can observe improvements in decisions and outcomes, and so reliable that a citizen is reluctant to believe claims that are in contradiction with shared understanding produced by open policy practice.

Open policy practice is based on the five principles presented in Table 1. The principles can be met if the purpose of policy support is set to produce shared understanding (a situation where different facts, values, and disagreements related to a decision situation are understood and documented). The description of shared understanding (and consequently improved actions) is thus the main output of open policy practice (see also Figure 2). It is a product that guides the decision and also is basis for evaluation of outcomes.

This guidance is formalised as evaluation and management of the work and knowledge content during a decision process. It defines the criteria against which the knowledge process needs to be evaluated and managed. It contains methods to look at what is being done, whether the work is producing the intended knowledge and outputs, and what needs to be changed. Each task is evaluated before, during, and after the actual execution, and the work is iteratively managed based on this.

The execution of a decision process is about collecting, organising and synthesising scientific knowledge and values in order to achieve objectives by informing the decision maker and stakeholders. A key part is open assessment that typically estimates the impacts of the planned decision options. Assessment and knowledge production is also performed during implementation and evaluation steps. Execution also contains the acts of making and implementing decisions; however, they are so case-specific processes depending on the topic, decision maker, and the societal context that they are not discussed in this article.

Figure 2. The three parts of open policy practice. The timeline goes roughly from left to right, but all work should be seen as iterative processes. Shared understanding as the main output is in the middle, expert-driven information production is a part of execution. Evaluation and management gives guidance to the execution.

Shared understanding

Shared understanding is a situation where all participants' views about a particular topic have been understood, described and documented well enough so that people can know what facts, opinions, reasonings, and values exist; and what agreements and disagreements exist and why. Shared understanding is produced in collaboration by decision makers, experts, and stakeholders. Each group brings in their own knowledge and concerns. Shared understanding aims to reflect all the five principles of open policy practice. This brings requirements to the methods that can be used to produce shared understanding.

Shared understanding is always about a particular topic and produced by a particular group of participants. With another group it could be different, but with increasing number of participants, it putatively approaches shared understanding of the whole society. Ideally, each participant agrees that the written description correctly contains their own thinking about the topic. Participants should even be able to correctly explain what other thoughts there are and how they differ from their own. Ideally any participant can learn, understand, and explain any thought represented in the group. Importantly, there is no need to agree on things, just to agree on what the disagreements are about. Therefore, shared understanding is not the same as consensus or agreement.

Shared understanding has potentially several purposes that all aim to improve the quality of societal decisions. It helps people understand complex policy issues. It helps people see their own thoughts from a wider perspective and thus increase acceptance of decisions. It improves trust in decision makers; but it may also deteriorate trust if the actions of a decision maker are not understandable based on shared understanding. It dissects each difficult detail into separate discussions and then collects statements into an overview; this helps to allocate the time resources of participants efficiently to critical issues. It improves awareness of new ideas. It releases the full potential of the public to prepare, inform, and make decisions. How well these purposes have been fulfilled in practice in assessments are discussed in Results.

Evaluation and management

Evaluation is about following and checking the plans and progress of the decisions and implementation. Management is about adjusting work and updating actions based on evaluation to ensure that objectives are reached. Several criteria were developed in open policy practice to evaluate and describe the decision support work. Their purpose is to help participants focus on the most important parts of open policy practice. ----arg2912: . Viimeisimmän OPP:n uudelleen jäsentelyn myötä tuntuu, että nämä pitäisi kaikki katsoa kertaalleen läpi siltä kantilta, että miten ne ilmentävät periaatteista juontuvaa shared understandingiin pyrkimisen päämäärää. Muuttanee lähinnä sitä miten ne on kuvattu ja selitetty, mutta voisi sinä syntyä samalla muitakin oivalluksia. --Mikko Pohjola (talk) 20:07, 10 February 2020 (UTC) (type: truth; paradigms: science: comment)

Guidance exists about crowdsourced policymaking[22], and similar ideas have been utilised in open assessment.

Properties of good policy support

There is a need to evaluate the assessment work before, during, and after it is done[17]. A key question is, what makes good policy support and what criteria could be used (see Table 2)[23].

Fulfilling all these criteria is of course not a guarantee that the outcomes of the decision will be a success. However, the properties listed are such that have been found to be important determinants of the success of decision processes. In projects utilising open policy practice, poor performance of specific properties could be linked to particular problems observed. Evaluating these properties before or during a decision process could help to analyse what exactly is wrong, as such problems with specific properties are typically visible already then. Thus, using this evaluation scheme proactively makes it possible to manage the decision making process toward higher quality of content, applicability, and efficiency.

Table 2. Properties of good policy support. Here, "assessment" can be viewed as a particular expert work producing a report about a specific question, or as a wider description of shared understanding about a whole policy process. Assessment work is done before, during, and after the actual decision.
Category Description Guiding questions
Quality of content Specificity, exactness and correctness of information. Correspondence between questions and answers. How exact and specific are the ideas in the assessment? How completely does the (expected) answer address the assessment question? Are all important aspects addressed? Is there something unnecessary?
Applicability Relevance: Correspondence between output and its intended use. How well does the assessment address the intended needs of the users? Is the assessment question good in relation to the purpose of the assessment?
Availability: Accessibility of the output to users in terms of e.g. time, location, extent of information, extent of users. Is the information provided by the assessment available when, where and to whom is needed?
Usability: Potential of the information in the output to generate understanding among its user(s) about the topic of assessment. Are the intended users be able to understand what the assessment is about? Is the assessment useful for them?
Acceptability: Potential of the output being accepted by its users. Fundamentally a matter of its making and delivery, not its information content. Is the assessment (both its expected results and the way the assessment is planned to be made) be acceptable to the intended users?
Efficiency Resource expenditure of producing the assessment output either in one assessment or in a series of assessments. How much effort is needed for making the assessment? Is it worth spending the effort, considering the expected results and their applicability for the intended users? Are the assessment results useful also in some other use?

Quality of content refers to the output of an assessment, typically a report, model or summary presentation. Its quality is obviously an important property. If the facts are plain wrong, it is more likely to misguide than lead to good decisions. Specificity, exactness, and correctness describe how large the remaining uncertainties are and how close the answers probably are to the truth (compared with some golden standard). In some statistical texts, similar concepts have been called precision and accuracy, although with decision support they should be understood in a flexible rather than strictly statistical sense.[24] Coherence means that the answers given are those to the questions asked.

Applicability is a large evaluation area. It looks at properties that affect how well the decision support can and will be applied. It is independent of the quality of content, i.e. despite high quality, an assessment may have very poor applicability. The opposite may also be true, as sometimes faulty assessments are actively used to promote policies. However, usability typically decreases rapidly if the target audience evaluates an assessment to be of poor quality.

Relevance asks whether a good question was asked to support decisions. Identification of good questions requires lots of deliberation between different groups, including decision makers and experts, and online forums may potentially help in this.

Availability is more technical property and describes how easily a user can find the information when needed. A typical problem is that a potential user does not know that a piece of information exists even if it could be easily accessed.

Usability may differ from user to user, depending on e.g. background knowledge, interest, or time available to learn the content.

Acceptability is a very complex issue and most easily detectable when it fails. A common situation is that stakeholders feel that they have not been properly heard and therefore any output from decision support is perceived faulty. Also doubts about the credibility of the assessor fall into this category.

Efficiency evaluates resource use when performing an assessment or other decision support. Money and time are two common measures for this. Often it is most useful to evaluate efficiency before an assessment is started. Is it realistic to produce new important information given the resources and schedule available? If more (less) resources were available, what added (lost) value would occur? Another aspect in efficiency is that if assessments are done openly, reuse of information becomes easier and the marginal cost and time of a new assessment decrease.

All properties of decision support, not just efficiency or quality of content, are meant to guide planning, execution, and evaluation of the whole decision support work. If they are kept in mind always, they can improve daily work.

Settings of assessments

A decision process or an assessment may be missing a clear understanding, what should be done and why. An assessment may even be launched in a hope that it will somehow reveal what the objectives or other important things are. Settings of assessments (Table 3) try to help in explicating these things so that useful decision support can be provided[25]. Also the sub-attributes of an assessment question help in this:

  • Research question: the actual question of an open assessment
  • Boundaries: temporal, geographical, and other limits within which the question is considered
  • Decisions and scenarios: decisions and options to assess and scenarios to consider
  • Timing: the schedule of the assessment work
  • Participants: people who will or should contribute to the assessment
  • Users and intended use: users of the final assessment report and purposes of the use
Table 3. Important settings for environmental health and other impact assessments within the context public policy making.
Attribute Guiding questions Example categories
Impacts
  • Which impacts are addressed in assessment?
  • Which impacts are the most significant?
  • Which impacts are the most relevant for decision making?
Environment, health, cost, equity
Causes
  • Which causes of impacts are recognized in assessment?
  • Which causes of impacts are the most significant?
  • Which causes of impacts are the most relevant for decision making?
Production, consumption, transport, heating, power production, everyday life
Problem owner
  • Who has the interest, responsibility and/or means to assess the issue?
  • Who actually conducts the assessment?
  • Who has the interest, responsibility and/or power to make decisions and take actions upon the issue?
  • Who are affected by the impacts?
Policy maker, industry, business, expert, consumer, public
Target users
  • Who are the intended users of assessment results?
  • Who needs the assessment results?
  • Who can make use of the assessment results?
Policy maker, industry, business, expert, consumer, public
Interaction
  • What is the degree of openness in assessment (and management)? (See Table 4.)
  • How does assessment interact with the intended use of its results? (See Table 5.)
  • How does assessment interact with other actors in its context?
Isolated, informing, participatory, joint, shared

Interaction and openness

In open policy practice, the method itself is designed to facilitate openness in all its dimensions. The dimensions of openness help to identify if and how the work deviates from the ideal of openness, so that the work can be improved in this respect (Table 4)[18].

Table 4. Dimensions of openness in decision making-
Dimension Description
Scope of participation Who are allowed to participate in the process?
Access to information What information about the issue is made available to participants?
Timing of openness When are participants invited or allowed to participate?
Scope of contribution To which aspects of the issue are participants invited or allowed to contribute?
Impact of contribution How much are participant contributions allowed to have influence on the outcomes? In other words, how much weight is given to participant contributions?

Openness can also be examined based on how intensive it is and what kind of collaboration is aimed at between decision makers, experts, and stakeholders[7][26]. Different approaches are described in Table 5.

Table 5. Categories of interaction within the knowledge-policy interaction framework.
Category Description
Isolated Assessment and use of assessment results are strictly separated. Results are provided to intended use, but users and stakeholders shall not interfere with making of the assessment.
Informing Assessments are designed and conducted according to specified needs of intended use. Users and limited groups of stakeholders may have a minor role in providing information to assessment, but mainly serve as recipients of assessment results.
Participatory Broader inclusion of participants is emphasized. Participation is, however, treated as an add-on alongside the actual processes of assessment and/or use of assessment results.
Joint Involvement of and exchange of summary-level information among multiple actors in scoping, management, communication and follow-up of assessment. On the level of assessment practice, actions by different actors in different roles (assessor, manager, stakeholder) remain separate.
Shared Different actors involved in assessment retain their roles and responsibilities, but engage in open collaboration upon determining assessment questions to address and finding answers to them as well as implementing them in practice.

Test of shared understanding

Test of shared understanding can be used to evaluate how well shared understanding has been achieved. In a successful case, all participants of a decision process give positive answers to the questions in Table 6. In a way, shared understanding is a metric for evaluating how well decision makers have embraced the knowledge base of the decision situation. ⇤--arg5256: . Should this, in the end, be moved to "Shared understanding" as an explanation and operationalization of the concept (and a prerequisite of the properties of good policy support)? --Mikko Pohjola (talk) 22:44, 14 February 2020 (UTC) (type: truth; paradigms: science: attack)

Table 6. Test of shared understanding.
Question Who is asked?
Is all relevant and important information described? All participants of the decision processes (including knowledge gathering processes)
Are all relevant and important value judgements described? (Those of all participants, not just decision makers.)
Are the decision maker's decision criteria described?
Is the decision maker's rationale from the criteria to the decision described?

All that is done aims to offer better understanding about impacts of the decision related to the objectives of the decision maker. However, conclusions may be sensitive to initial values, and ignoring political opposition's views may cause trouble at a later stage. Therefore, also other values in the society are included in shared understanding.

Shared understanding may have different levels of ambition. On an easy level, shared understanding is taken as general guidance and an attitude towards other people's opinions. Main points and disagreements are summarised in writing, so that an outsider is able to understand the overall picture.

On an ambitious level, the idea of documenting all opinions and their reasonings is taken literally. Participants' views are actively elicited and tested to see whether a facilitator is able to reproduce their thought processes. The objective here is to document the thinking in such a detailed way by using insight networks, knowledge crystals, and shared understanding that a participant's views on the key questions of the policy can be anticipated from the description they have given. Written documentation with an available and usable structure is crucial. It helps participation without being physically present. It also spreads shared understanding to decision makers and to those who were not involved in discussions.

Good descriptions of shared understanding are able to quickly and easily incorporate new information or scenarios from the participants. They can be examined using different premises, i.e., a user should be able to quickly update the knowledge base, change the point of view, or reanalyse how the situation would look like with alternative valuations. Ideally, a user interface would allow the user to select input values with intuitive menus and sliders and would show impacts of changes instantly. Such level of sophistication necessarily requires a few concepts that will be described in the next section.

Execution and open assessment

Execution is the work during a decision process, including ideating possible actions, assessing impacts, deciding between options, implementing decisions, and evaluating outcomes. Execution is guided by information produced in evaluation and management. The focus of this article is on knowledge processes that support decisions. Therefore, methods to reach or implement a decision are not discussed here.

Open assessment is a method for performing impact assessments using insight networks, knowledge crystals, and web-workspaces (see below). Open assessment is an important part of execution and the main knowledge production method in open policy practice.

An assessment aims to quantify important objectives, and especially compare differences in impacts resulting from different decision options. In an assessment, current scientific information is used to answer policy-relevant questions that inform decision makers about the impacts of different options.

Open assessments are typically performed before a decision is made (but e.g. the city of Helsinki has used both ex ante and ex post approaches with its climate strategy[27]). The focus is necessarily on expert knowledge and how to organise that, although prioritisation is only possible if the objectives and valuations of the decision maker and stakeholders are known. For a list of major open assessments, see Appendix S2.

As a research topic, open assessment attempts to answer this question: "How can factual information and value judgements be organised for improving societal decision making in a situation where open participation is allowed?" As can be seen, openness, participation, and values are taken as given premises. This was far from common practice but not completely new, when the first open assessments were performed in the early 2000's[5].

Since the beginning, the main focus has been to think about information and information flows, rather than jurisdictions, political processes, or hierarchies. So, open assessment deliberately focusses on impacts and objectives rather than questions about procedures or mandates of decision support. A premise was that if the information production and dissemination are completely open, the process can be generic, and an assessment can include information from any contributor and inform any kind of decision-making body. Of course, quality control procedures and many other issues must be functional under these conditions.

Co-creation

Co-creation is a method for producing open contents in collaboration, and in this context specifically knowledge production by self-organised groups. It is a discipline in itself[15], and guidance about how to manage and facilitate co-creation can be found from elsewhere. Here, only a few key points are raised about facilitation and structured discussion.

Information has to be collected, organised, and synthesised; and facilitators need to motivate and help people to share their information. This requires dedicated work and skills that are typically available among neither experts nor decision makers. It also contains practices and methods, such as motivating participation, facilitating discussions, clarifying and organising argumentation, moderating contents, using probabilities and expert judgement for describing uncertainties, or developing insight networks (see below) or quantitative models. Sometimes the skills needed are called interactional expertise.

Facilitation is an art of helping people participate in co-creation processes using hearings, workshops, online questionnaires, wikis, and other tools. In addition to practical tools, facilitation implements principles that have been seen to motivate participation[14]. Two are worth mentioning here, because they have been shown to significantly affect the motivation to participate.

  • Grouping: Facilitation methods are used to promote the participants' feeling of being important members of a group that has a meaningful purpose.
  • Respect: Contributions are systematically documented and their merit evaluated so that each participant receives the respect they deserve based on their contributions.

Structured discussions are synthesised and reorganised discussions, where the purpose is to highlight key statements and argumentations that lead to acceptance or rejectance of these statements. Discussions can be organised according to pragma-dialectical argumentation rules[28] or argumentation framework[29], so that arguments form a hierarchical thread pointing to a main statement or statements. Attack arguments are used to invalidate other arguments by showing that they are either untrue or irrelevant in their context; defend arguments are used to protect from attacks; and comments are used to clarify issues. For an example, see Figure S1-5 in Appendix S1 and links thereof.

The discussions can be natural discussions that are reorganised afterwards, or online discussions where the structure of contributions is governed by the tool used. A test environment exists for structured argumentation[30], and Opasnet has R functions for analysing structured discussions written on wiki pages.

Insight networks

Insight networks are graphs as defined by the graph theory[21]. In an insight network, actions, objectives, and other issues are depicted with nodes, and their causal and other relations are depicted with arrows (aka edges). An example is shown on Figure 3, which describes a potential dioxin-related decision to clean up emissions from waste incineration. The logic of such a decision can be described as a chain or network of causally dependent issues: Reduced dioxin emissions to air improve air quality and dioxin deposition into the Baltic Sea; this has a favourable effect on concentrations in the Baltic herring; this reduces human exposures to dioxins via fish; and this helps to achieve an ultimate objective of reduced health risks from dioxin. Insight networks aim to facilitate understanding, analysing, and discussing complex policy issues.

Figure 3. Insight network about dioxins, Baltic fish, and health as described in the BONUS GOHERR project[31]. Decisions are shown as red rectangles, decision makers and stakeholders as yellow hexagons, decision objectives as yellow diamonds, and substantive issues as blue nodes. The relations are written on the diagram as predicates of sentences where the subject is at the tail of the arrow and the object is at the tip of the arrow. For other insight networks, see Appendix S1.

Causal modelling and causal graphs as such are old ideas, and there are various methods developed for them, both qualitative and quantitative. However, the additional ideas with insight networks were that a) also all non-causal issues can and should be linked to the causal core in some way, if they are relevant to the decision, and therefore b) they can effectively be used in clarifying one's ideas, contributing, and then communicating a whole decision situation rather than just the causal core. In other words, a participant in a policy discussion should be able to make a reasonable connection between what they are saying and some node in an insight network developed for that policy issue. If they are not able to make such a link, their point is probably irrelevant.

The first implementations of insight networks were about toxicology of dioxins[32] and restoration of a closed asbestos mine area[33]c. In the early cases, the main purpose was to give structure to discussion about and examination of an issue rather than to be a backbone for quantitative models. In later implementations, such as in the composite traffic assessment[34] or BONUS GOHERR project[31], diagrams have been used for both purposes. Most open assessments discussed later (and listed in Appendix S2) have used insight networks to structure and illustrate their content.

Knowledge crystals

Knowledge crystals are web pages where specific research questions are collaboratively answered by producing rationale with any data, facts, values, reasoning, discussion, models, or other information that is needed to convince a critical rational reader (Table 7).

Knowledge crystals have a few distinct features. The web page of a knowledge crystal has a permanent identifier or URL and an explicit topic, or question, which does not change over time. A user may come to the same page several times and find an up-to-date answer to the same topic. The answer changes as new information becomes available, and anyone is allowed to bring in new relevant information as long as certain rules of co-creation are followed. In a sense, the answer of a knowledge crystal is never final but it is always usable.

Knowledge crystal is a practical information structure that was designed to comply with the principles of open policy practice. Also, open data principles are used when possible[35]. For example, openness and criticism are implemented by allowing anyone to contribute but only after critical examination. Knowledge crystals differ from open data, which contains little or no interpretation, and scientific articles, which are not updated. Rationale is the place for new information and discussions, and resolutions about new information may change the answer.

The purpose of knowledge crystals is to offer a versatile information structure for nodes in an insight network that describes a complex policy issue. They handle research questions of any topic and describe all causal and non-causal relations from other nodes (i.e. the nodes that may affect the answer of the node under scrutiny). They contain information as necessary: text, images, mathematics, or other forms, both quantitative and qualitative. They handle facts or values depending on the questions, and withstand misconceptions and fuzzy thinking as well. And finally, they are targeted also for an interested non-expert to find it online and to understand and use its main message.

Table 7. The attributes of a knowledge crystal.
Attribute Description
Name An identifier for the knowledge crystal. Each page has a permanent, unique name and identifier or URL.
Question A research question that is to be answered. It defines the scope of the knowledge crystal. Assessments have specific sub-attributes for questions (see section Settings of assessments)
Answer An understandable and useful answer to the question. It is the current best synthesis of all available data. Typically it has a descriptive easy-to-read summary and a detailed quantitative result published as open data. An answer may contain several competing hypotheses, if they all hold against scientific critique. This way, it may include an accurate description of the uncertainty of the answer, often in a probabilistic way.
Rationale Any information that is necessary to convince a critical rational reader that the answer is credible and usable. It presents to a reader the information required to derive the answer and explains how it is formed. It may have different sub-attributes depending on the page type, some examples are listed below.
  • Data tell about direct observations (or expert judgements) about the topic.
  • Dependencies tell what is known about how upstream knowledge crystals (i.e. causal parents) affect the answer. Dependencies may describe functional or probabilistic relationships. In an insight network, dependencies are described as arrows pointing toward the knowledge crystal.
  • Calculations are an operationalisation of how to calculate or derive the answer. It uses algebra, computer code, or other explicit methods if possible.
  • Discussions are structured or unstructured discussions about the details of the substance, or about the production of substantive information. On a wiki, discussions are typically located on the talk page of the substance page.
Other In addition to attributes, it is practical to have clarifying subheadings on a knowledge crystal page. These include: See also, Keywords, References, Related files

There are different types of knowledge crystals for different uses. Variables contain substantive topics such as emissions of a pollutant, food consumption or other behaviour of an individual, or disease burden in a population (for examples, see Figure 3 and Appendix S1.) Assessments describe the information needs of particular decision situations and work processes designed to answer those needs. They also may describe whole models (consisting of variables) for simulating impacts of a decision. Methods describe specific procedures to organise or analyse information. The question of a method typically starts with "How to...". For a list of all knowledge crystal types used at Opasnet web-workspace, see Appendix S3.

Openness and collaboration are promoted by design: knowledge crystals are modular, re-usable, and readable for humans and machines. This enables their direct use in several assessment models or internet applications, which is important for the efficiency of the work. Methods are used to standardise and facilitate the work across assessments.

Open web-workspaces

Insight networks, knowledge crystals, and open assessments are information objects that were not directly applicable at any web-workspace available at the time of development. Therefore, web-workspaces have been developed specifically for open policy practice. There are two major web-workspaces for this purpose: Opasnet (designed for expert-driven open assessments) and Climate Watch (designed for evaluation and management of climate mitigation policies).

Opasnet

Opasnet is an open wiki-based web-workspace and prototype for performing open policy practice, launched in 2006. It is designed to offer functionalities and tools for performing open assessments so that most if not all work can be done openly online. Its name is a short version of Open Assessors' Network and also from Finnish word for guide, "opas". The purpose was to test and learn co-creation among environmental health experts and also start opening the assessment process to interested stakeholders.

Opasnet is based on MediaWiki platform because of its open-source code, wide use and abundance of additional packages, long-term prospects, functionalities for good research practices (e.g. talk pages for meta-level discussions), and full and automatic version control. Two language versions of Opasnet exist. English Opasnet (en.opasnet.org) contains all international projects and most scientific information. Finnish Opasnet (fi.opasnet.org) contains mostly project material for Finnish projects and pages targeted for Finnish audiences. A project wiki Heande (short for Health, the Environment, and Everything) requires a password and contains information that can not (yet) be published for a reason or another, but its use is depreciated.

Opasnet facilitates simultaneous development of theoretical framework, assessment practices, assessment work, and supporting tools. This includes e.g. information structures, assessment methods, evaluation criteria, and online software models and libraries.

For modelling functionalities, the statistical software R is used via an R–Mediawiki interface. R code can be written directly to a wiki page and run it by clicking a button. The resulting objects of such codes can be stored to the server and fetched later by another code. Complex models can be run with a web browser without installing anything. It has automatic version control and archival of the model description, data, code, and results.

An R package OpasnetUtils is available (CRAN repository cran.r-project.org) to support knowledge crystals and impact assessment models. It contains the necessary functions and information structures. Specific functionalities facilitate reuse and explicit quantitation of uncertainties: Scenarios can be defined at a wiki page or via a model user interface, and these scenarios can then be run without changing the model code. If input values are uncertain, uncertainties are automatically propagated through the model using Monte Carlo simulation.

For data storage, Opasnet Base, a MongoDB no-sql database, is used. Each dataset must be linked to a single wiki page, which contains all the necessary descriptions and metadata about the data. Data can be uploaded to the database via a wiki page or a file uploader. The database has an open application programming interface for data retrieval.

For more details, see Appendix S4.

Climate Watch

Figure 4. System architecture of the Climate Watch web-workspace.

Climate Watch is a web-workspace primarily for evaluating and managing climate mitigation actions (Figure 4). It was originally developed in 2018-2019 by the city of Helsinki for its climate strategy. Already from the beginning, scalability was a key priority: the web-workspace was made generic enough so that it could be easily used by other municipalities in Finland and globally, and also used for evaluation and management of other topics than climate mitigation.

Climate Watch is described in more detail by Ignatius and coworkers[36]. In brief, Climate Watch consists of actions that aim to reduce climate emissions, and indicators that are supposedly affected by the actions and give insights about progress. Actions and indicators are knowledge crystals, and they are causally connected, thus forming an insight network. Each action and indicator has one or more contact people who are responsible for reporting of progress (and sometimes for actually implementing the action).

The requirements for choosing the technologies were wide availability, ease of development, and an architecture based on open application programming interfaces or APIs. On the public-facing user interface the NextJS framework (https://nextjs.org/) is used. It provides support for server-side rendering and search engine optimisation which is based on the React user interface framework (https://reactjs.org/). The backend is built using the Django web framework (https://www.djangoproject.com/) which provides the contact people with an administrator user interface. The data flows to the Climate Watch interface over a GraphQL API (https://graphql.org/). GraphQL is a standard that has the most traction in the web development community because of its flexibility and performance.

Opasnet and Climate Watch have functional similarities but different technical solutions. The user interfaces for end-users and administrators in Climate Watch have similar purposes as MediaWiki in Opasnet; and while impact assessment and model development are performed by using R at Opasnet, Climate Watch uses Python, Dash, and Jupyter.

Open policy ontology

There is a need to describe all the information structures and policy content in a systematic, coherent, and unambiguous way. So, there was a need for an open policy ontology.

World Wide Web Consortium has developed the concepts of open linked data and resource description framework (RDF)[37]. These were used as the foundations for ontology development.

Ontologies are based on vocabularies with specified terms and meanings. Also the relations of terms are explicit. Resource description framework is based on the idea of triples, which have three parts: subject, predicate (or relation), and object. These can be thought as sentences: an item (subject) is related to (predicate) another item or value (object), thus forming a claim. Claims can further be specified using qualifiers and backed up by references. Insight networks can be documented as triples, and a set of triples using this ontology can be visualised as diagrams of insight network. Triple databases enable wide, decentralised linking of various sources and information.

Open policy ontology (see Appendix S3) focusses on describing all information objects and terms described above, and making sure that there is a relevant item type or relation to every critical piece of information that is described in an insight network, open assessment, or shared understanding. "Critical piece of information" means something that is worth describing as a separate node, so that it can be more easily found, understood, and used. A node itself may contain large amounts of information and data, but for the purpose of producing shared understanding about a particular decision, there is no need to highlight the node's internal data on an insight network.

The ontology was used with indicator production in the climate strategy of Helsinki[27] and a visualisation project of insight networks[38].

For a full description of the current vocabulary in the ontology, see Appendix S3 and Figures S1-3 and S1-4 in Appendix S1.

Novel concepts

This section presents novel concepts that have been identified as useful for a particular need and conceptually coherent with open policy practice. However, they have not been thoroughly tested in practical assessments of policy support.

Value profile is a documented list of values, preferences, and choices of a participant. Voting advice applications are online tools that ask electoral candidates about their values, worldviews, or decisions they would make if elected, and then voters can compare own answers with those of a candidate or a party. The public can then answer the same questions and analyse which candidates share their values. Nowadays, such applications are routinely developed by all major media houses for every national election in Finland. Thus, voting advice applications produce a kind of value profiles. However, these tools are not used to collect value profiles from the public for actual decision making or between elections although such information could be used in decision support. Value profiles are mydata, i.e. data about which an individual themself may decide who is allowed to see and use it. This requires trusted and secure information systems.

Archetype is an internally coherent value profile of an anonymised group of people. Coherence means that when two values are in conflict, the value profile describes which one to prefer. Archetypes are published as open data describing the number of supporters but not their identities. People may support an archetype in full or by declaring partial support to some specific values, with a degree ranging from zero to one. Archetypes aim to save effort in gathering value data from the public, as not everyone needs to answer all possible questions, when archetypes are used. It also increases security when there is no need to handle individual people's potentially sensitive value profiles, but instead open aggregated data about archetypes.

Political strategy papers typically contain explicit values of that organisation, aggregated in some way from their members' individual values. The strategic values are then used in the organisation in a normative way, implying that the members should support these values in their membership roles. An archetype differs from this, because it is descriptive rather than normative and a "membership" in an archetype does not imply any rights or responsibilities of an organisation membership. Yet, political parties could use also archetypes to describe the values of their members.

The use of archetypes is based on an assumption that although their potential number is very large, most of people's thinking can be covered with a manageable amount of archetypes. As a comparison, there are usually from two to a dozen significant political parties in a democratic country rather than hundreds. There is also research on human values showing that they can be systematically evaluated using a fairly small amount (e.g., 4, 10, or 19) of different dimensions[39].

Paradigms are collections of rules to describe inferences that participants would make from data in the system. For example, scientific paradigm has rules about criticism and a requirement that statements must be backed up by data or references. Participants are free to develop paradigms with any rules of their choosing, as long as they can be documented and operationalised within the system. For example, a paradigm may state that when in conflict, priority is given to the opinion presented by a particular authority. Hybrid paradigms are also allowed. For example, a political party may follow the scientific paradigm in most cases but when economic assessments are ambiguous, the party chooses an interpretation that emphasises the importance of an economically active state (or alternatively market approach with a passive state).

Destructive policy is a policy that a) is actually being implemented or planned, making it politically relevant, b) causes significant harm to most or all stakeholder groups, as measured using their own interests and objectives, and c) has a feasible, less harmful alternative. Societal benefits are likely to be greater if a destructive policy is identified and abandoned, compared with a situation where an assessment only focusses on showing that one good policy option is slightly better than another one.

There are a few mechanisms that may explain why destructive policies exist. First, a powerful group can dominate the policymaking to their own benefit, causing harm to others. Second, the "prisoner's dilemma" or "tragedy of commons" makes a globally optimal solution to be unoptimal for each stakeholder group, thus draining support from it. Third, the issue is so complex that the stability of the whole system is threatened by changes[40]. Advice about destructive policies may produce support for paths out of these frozen situations.

An analysis of destructive policies attempts to systematically analyse policy options and identify, describe, and motivate rejection of those that appear destructive. The tentative questions for such an analysis include the following.

  • Are there relevant policy options or practices that are not being assessed?
  • Do the policy options have externalities that are not being assessed?
  • Are there relevant priorities among stakeholders that are not being assessed?
  • Is there strong opposition against some options among the experts or stakeholders? What is the reasoning for and science behind the opposition?
  • Is there scientific evidence that an option is unable to reach the objectives or is significantly worse than another option?

The current political actions to mitigate the climate crisis are so far from the global sustainability goals that there must be some destructive policies in place. Identification of destructive policies often requires that an assessor looks out of the box and is not restricted to default research questions. In this example, such questions could be like: "What is such a policy B that fulfils the objectives of the current policy A but with less climate emissions?", and "Can we reject the null hypothesis that A is better than B in the light of data and all major archetypes?" This approach has a premise that rejection is more effective than confirmation; an idea that was already presented by Karl Popper[4].

Parts of open policy practice have been used in several assessments. In this article, we will evaluate how these methods have performed.

Methods

The methods of open policy practice were critically evaluated. The open assessments performed (Appendix S2) were used as the material for evaluation. The properties of good policy support (Table 2) were used as evaluation criteria in a similar way as in a previous evaluation[23]. In addition, open policy practice as a whole was evaluated using the categories of interaction and the test of shared understanding as criteria[25]. Key questions in the evaluations were the following. Does open policy practice have the properties of good policy support? And does it enable policy support according to the five principles of open policy practice in Table 1? For each method within open policy practice, these questions were asked: In what way could the method materialise improvements in the property considered? Are there evidence or experiences showing that improvement has actually happened in practice? Has the method shown disadvantages or side effects when implemented?

What has been the acceptance and usage of the method? Are same or similar methods being used elsewhere? What can be learned from the other uses?

⇤--arg1050: . Do we actually handle these issues? --Jouni (talk) 11:05, 14 February 2020 (UTC) (type: truth; paradigms: science: attack)

----arg9077: . E.g. refs 7 and 21 review different other approaches with some connecting points to the method set. --Mikko Pohjola (talk) 17:30, 14 February 2020 (UTC) (type: truth; paradigms: science: comment)
----arg9077: . referring to the related projects in declarations could help in communicating the broader context within which the method set has evolved - influencing and being influenced by its environment. --Mikko Pohjola (talk) 17:30, 14 February 2020 (UTC) (type: truth; paradigms: science: comment)
----arg9077: . these questions should probably be addressed in discussion, while considering the broader implications of our analysis. --Mikko Pohjola (talk) 17:30, 14 February 2020 (UTC) (type: truth; paradigms: science: comment)
----arg6234: . article "Pragmatic knowledge services" made comparisons and considerations of similarity between Opasnet, Innovillage and KPE --Mikko Pohjola (talk) 17:40, 14 February 2020 (UTC) (type: truth; paradigms: science: comment)

Results

Different methods of open policy practice were evaluated for their potential or observed advantages and disadvantages according to the properties of good policy practices. Major advantages are listed on Table 8. Some advantages, as well as disadvantages and problems, are discussed in more detail in the text. The text is organised along the properties of good policy support (Table 2), categories of interaction (Table 5), and test of shared understanding (Table 6).

Table 8. Methods evaluated based on properties of good policy practices. Background colours: white: no anticipated benefit, yellow: potential benefit, green: actual benefit observed in open policy practice materials. Numbers in parentheses refer to the assessments in Appendix S2, Table S2-1. The last row contains general suggestions to improve the properties (with references to relevant principles).
Method Quality of content Relevance Availability Usability Acceptability Efficiency
Co-creation Participants bring new info (2, 3, 25, 26) Y New questions are identified during open work (6, 11) Y Draft results raise awareness during work (2, 8, 27) P Readers ask clarifying questions P Participants are committed to conclusions (2, 8, 27) Y Readers bring links to new data P
Open assessment MISSING P End-user discussions improve assessment (16, 26, 27) Y It is available as draft since the beginning P Standard structure facilitates use P Openness was praised (3, 8, 9, 21) Y Scope can be widened incrementally (12-16) P
Insight network It brings structure to assessment (8, 9, 11, 16, 17) P It helps and clarifies discussions between decision makers and experts (8, 9) P N Readers see what is excluded P MISSING P N
Knowledge crystal They streamline work (e.g. 3, 23, 24) Y They clarify questions (1, 6) Y It is mostly easy to see where information should be found P Summaries help to understand P N Answers can be reused across assessments (12–16, 23-24) Y
Web-workspace Its structure supports content production (8, 9) P It combines user needs and open policy practice (8, 9) P It offers an easy approach to and archive of materials (16, 21, 23, 26) Y User needs guided the functions developed (8) P N It offers a place to document shared understanding P'
Structured discussion It helps to moderate discussion (2, 30) Y It guides focus on important topics (16, 30) Y N Threads help to focus reading P User feedback has been positive (8, 30) Y Structure discourages redundancy P
Open policy ontology ? It gives structure to insight networks and structured discussions (8, 16, 30) ? ? Ontology clarifies issues and relations ? ? ?
Destructive policies N Approach widens the scope (3, 8) Y N Approach emphasises mistakes to be avoided P Focus is on everyone's problems P Lessons learned can be reused in other decisions. P
Value profile and archetype N Value profiles helps to prioritise (8) Y N Voting advice applications may offer an exampleP Stakeholders' values are better heard P Archetypes are effective summaries (8) Y
Paradigm It motivates clear reasoning ? It systematically describes confslicting reasonings ? ? ? Stakeholders' reasonings are better heard ? MISSING ?
Suggestions by open policy practice Work openly, invite criticism (see Table 1.) (causality, criticism) Characterize the setting (see Table 3.) (collaboration, openness, criticism, intentionality) Use web-workspaces. For evaluation, see Table 4. (openness) Invite participation from the problem owner and user groups early on (see Table 5.) (collaboration, openness, causality, intentionality) Use the test of shared understanding (see Table 6.) (collaboration, openness, criticism, intentionality) Use shared information objects with open license, e.g. knowledge crystals. (collaboration, openness)

Quality of content

Open policy practice does not restrict the use of common quality control methods and therefore it has at least the same potential to produce high-quality assessments as those using the common methods. The quality of open assessments has been acceptable for publishing in peer-reviewed scientific journals. However, limited external criticism in the open assessments demonstrates, that quality control must be taken care of by usual means: additional participation does not solve this issue on behalf of the assessors.

Knowledge crystals are designed to be updated based on continuous discussion about the scientific issues (or valuations, depending on the topic) aiming to back up conclusions. In contrast, scientific articles are expected to stay permanently unchanged after publication. Articles offer little room for deliberation about the interpretation or meaning of the results after a manuscript is submitted: reviewer comments are often not published, and further discussion about an article is rare and mainly occurs only if serious problems are found. Indeed, the current scientific publishing system is poor in correcting errors via deliberation[41].

Relevance

Destructive policies can be used as a method to focus on critical aspects of an assessment. For example, Climate Watch has an impact assessment tool[42] that dynamically simulates the total greenhouse gas emissions of Helsinki based on scenarios provided by the user. The tool is able to demonstrate destructive policies: for example, if the emission factor of district heating production does not significantly decrease in ten years, it will be impossible to reach the emission targets of Helsinki. Thus, there are sets of solutions, which could be chosen because of their appealing details but which would not reduce the emission factor. The tool excplicitly demonstrates that these solutions fail to reach the objectives and that the emission factor is a critical variable that must be evaluated and managed carefully to avoid destructive outcomes.

Other examples include the Helsinki energy decision assessment (assessment 3 in Table S2-1). It showed that residential wood combustion is a devastating way to heat houses in urban areas and health risks are much larger than in any other method. Yet, this is a popular practice in Finland. Also, a health benefit–risk assessment showed that whatever policy is chosen with dioxins and young women, it should not reduce Baltic fish consumption in other population subgroups (assessment 16 in Table S2-1).

Availability

Participation among decision makers, stakeholders, and experts outside an assessment team is a constant challenge and requires special attention. The participation has been remarkable in projects where special emphasis and effort has been put to dissemination and facilitation, such as the Climate Watch and the Transport and communications strategy (assessments 8 and 26 in Table S2-1). Participation is a challenge also in Wikipedia, where only a few percent of readers ever contribute, and the fraction of active contributors is even smaller[43].

Timing is critical, and assessment results are preferably available early on in a decision process. This is a major challenge, because political processes may proceed rapidly and change focus, and quantitative assessments take time. A positive example of agility was a dioxin assessment model that had been developed in several projects during a few years (assessment 16 in Table S2-1)[31]. When European Food Safety Authority released their new estimates about dioxin impacts on sperm concentration[44], the assessment model was updated and new sperm concentration results were produced within days. This was possible because the existing dioxin model was modular and using knowledge crystals, so it was rerun after updates in just one part about sperm effects.

Feedback suggested that finding pages at Opasnet was difficult. This was helped by using navigation boxes and categories in the same way as in Wikipedia; and cleaning and updating pages. But typical policy assessments are performed by consultants that keep critical parts to themselves as proprietary information.

The version control and archival process is inherently supported by Opasnet workspace. Many experts are reluctant to make their text available if other people can edit it, but this fear was often alleviated by the fact that the original version can always be restored if needed. Availability is also improved as information is produced in a proper format for archiving, backups are produced automatically, and it is easy to produce a snapshot of a final assessment. It is not necessary to copy information from one repository to another, but it is also easy to store final assessments in external open data repositories.

In structured discussion, hierarchical threads increase availability, because a reader does not need to read further if they agree with the topmost arguments. On the other hand, any thread can be individually scrutinised to the last detail if needed.

There are established open source tools for managing triple data and RDF (such as SPARQL) and thus open policy ontology. At Opasnet, this has been implemented by using R. This increases availability.

Usability

Insight network provides a method to illustrate and analyse a complex decision situation, while knowledge crystals offer help in describing quantitative nuances within the nodes or arrows, such as functional or probabilistic relations or estimates. There are tools with both graphical and modelling functionalities, e.g. Hugin (Hugin Expert A/S, Aalborg, Denmark) for Bayesian belief networks and Analytica® (Lumina Decision Systems Inc, Los Gatos, CA, USA) for Monte Carlo simulation. However, these tools are designed for a single desktop user rather than for open co-creation. In addition, they have limited possibilities for adding non-causal nodes and links or free-format discussions about the topics.

Insight networks are often complex and therefore better suited for detailed expert or policy work rather than for general dissemination. Other dissemination methods are needed as well. This is true also for knowledge crystals, although page summaries facilitate dissemination.

A knowledge crystal is typically structured so that it starts with a summary, then describes a research question and gives a more detailed answer, and finally provides a user with relevant and increasingly detailed information in a rationale. This has increased the usability of a page among different user groups. On the other hand, some people have found this structure confusing as they don't expect to see all the details of an assessment. Users were unsure about the status of a knowledge crystal page and whether some information is up to date or still missing. This is because many pages are work in progress rather than finalised products. This was clarified by adding status declarations on the tops of pages. Declaring drafts as drafts has also helped experts who are uncomfortable in showing their own work before it is fully complete.

The climate strategy of Helsinki (assessment 8, Table S2-1) has taken the usability challenge seriously and developed Climate Watch from scratch based on open source code modules and intensive user testing and service design. Insight networks and knowledge crystals are basic building blocks of the system architecture. So far, it has received almost exclusively positive feedback from both users and experts. Also, a lot of emphasis has been put on building a user community, and city authorities, other municipalities, and research institutes have shown interest in collaboration. In contrast, Opasnet was designed as generic tool for all kinds of assessments but without an existing end-user demand. As a result, the penetration of Climate Watch has been much quicker.

Voting advice applications share properties with value profiles and archetypes, and offer material for concept development. The popularity of these applications implies that there is a societal need for value analysis and aggregation. Current demonstrations have also shown that the data can be used to understand differences between individuals and political groups. With more nuanced data, a set of archetypes describing common and important values in the population can probably be developed. Some of them may have potential to increase in popularity and form kind of virtual parties that represent population's key values.

Value profiles and paradigms have been tested on structured discussions and shared understanding descriptions. Also Helsinki has tested value profiles in prioritising the development of Climate Watch. They have been found to be promising and conceptually sound ideas in this context. Data that resembles value profiles are being collected by social media companies, but the data is used to inform marketing actions, often without the individual's awareness so it is not mydata. In contrast, the purpose of value profile data is to inform societal decisions with consent from its owner rather than nudge the voter to act according to the company's wishes. The recent microtargeting activities by Cambridge Analytica and AggregateIQ to use value-profile-like data to influence voting decisions have proved to be very effective[45]. Value profiles are clearly severely underutilised as a tool to inform decisions. We are not aware of systems that would collect value profile data for actual democratic policy support between elections.

Acceptability

The most significant problem with open policy practice has been that the intensity of participation has typically been lower than what was hoped for. Especially experts have been reluctant to participate openly due to numerous reasons. Experts were concerned that expertise is not given proper weight, if open participation is allowed. They feared that strong lobbying groups hijack the process. They feared that self-organised groups produce low-quality information or even malevolent dis-information. They often demanded the final say as the ultimate quality criteria, rather than trust that data, reasoning, and critical discussion would do a better job. In brief, experts commonly think that it is simply easier and more efficient to produce high-quality information in closed expert groups.

In a vaccine-related assessment (Tendering process for pneumococcal conjugate vaccine, Table S2-1), comments and critique were received from both drug industry and vaccine citizen organisations by using active facilitation, and they were all very matter-of-fact. This was interesting, as the same topics cause outrage in social media, but this was not seen on structured assessments. This is possibly because the questions asked were specific and typically required some background knowledge of the topic. Interestingly, one of the most common objections and fears against open assessment is that citizen contributions will be ill-informed and malevolent. The experience with open assessments shows that they are not.

Efficiency

A common solution to co-operation needs seems to be a strict division of tasks. Detailed understanding of and contributions to other groups' work and models remain low or non-existent. This has been typical in large assessment projects such as Urgenche, Bioher, and Claih (see Table S2-1 and Funding). On the other hand, most researchers are happy in their own niche and don't expect that other experts could or should learn the details of their work. Consequently, the perceived need for shared tools or open data is often low, which hinders mutual sharing, learning, and reuse.

The implementation phase of Climate Watch, which started in December 2018, is involving also citizens, decision-makers, and other municipalities. It is the largest case study so far using open policy practice. It combines existing and produces new climate emission models for municipalities. An objective is to collect detailed input data for the whole country and offer all models to all municipalities, thus maximising reuse.

The art of open policy practice is to learn to identify important pieces of relevant information (such as scientific facts, publications, discussions etc.) and to add that information into a proper place in an insight network by using open policy ontology and a reasonable amount of work. A key to success is to identify the right level of detail to describe in the system for the purpose of informing decision makers, stakeholders, and others. An ontology helps to do this in a way that is understandable for both humans and computers.

Accumulation of scientific merit is a key motivator for researchers. Policy support work typically does not result in scientific articles. When researchers evaluate the efficiency of their own work, they are likely to prefer tasks that produce articles in addition to societal benefit. The same reasoning has been seen with open assessments and knowledge crystals, resulting in reluctance to participate. Win-win situations could be found, if policy processes were actively developed into containing experimental aspects, so that new information would not only be synthesised but also produced and published in scientific journals.

Categories of interaction

Assessment methods have changed remarkably in forty years. During the last decades, the trend has been from isolated to more open approaches, but all categories of interaction (Table 6) are still in use[7]. The open assessments performed so far have enabled more collaboration and interaction. However, enabling is not enough, as interaction requires special attention with active invitation of stakeholderes and facilitation. Recent examples, especially the Helsinki climate strategy, have shown that the potential of shared assessments can be reached when aspiration and resources meet.

Test of shared understanding

Shared understanding has been a well accepted idea among decision makers in Finland. This was observed in collaboration with Prime Minister's Office of Finland (Yhtäköyttä project, Table S2-1) Many civil servants in ministries liked the idea that sometimes it is better to aim to understanding rather than consensus. They soon adopted the light version of the term and started to use it in their own discussions and publications[46][47].

Shared understanding has clarified complex issues and elicited implicit valuations and reasonings. It has facilitated rational discussion about a decision. It can also be used for creating political pressure against options that are not well substantiated. Shared understanding can be reached even if a stakeholder is ignorant of or even hostile to scientific knowledge, or not interested in participating. Then, there is an attempt to describe their views anyway, based on what other people know about their values. Their views are seen as important policy-relevant information that may inform policy making.

Discussion

For many interest groups, non-public lobbying, demonstrations and even spreading faulty information are attractive ways of influencing the outcome of a decision. These are problematic methods from the perspective of open policy practice, because they reduce the availability of important information in decision processes. Further studies are needed on how open, information-based processes could be developed to be more tempting to groups that now prefer other methods. A key question is whether shared understanding is able to offer acceptable solutions to disagreeing parties and alleviate political conflict. Another question is whether currently underrepresented groups would have better visibility in such open processes.

A major challenge in open policy practice is to build an assessor community for decision support. Lack of contributions limits the amount of new views and ideas that potentially could be identified with co-creation. However, the current practices of open criticism in research are often worse, as criticism rarely happens. Pre-publishing peer review is almost the only time when scientific work is criticised by people outside the research group, and those are typically not open. A minute fraction of published works are criticised openly in journals; a poor work is simply not cited and subsequently forgotten. Interestingly, some administrative processes follow scientific principles better than many research processes do: for example, environmental impact assessment has a compulsory process for open criticism at both design and result phases[48][11].

All claims are critically evaluated in open policy practice, especially claims about an action being able to reach objectives. Some of the claims are found unsubstantiated, and views of some individuals are found internally inconsistent. On the societal level, shared understanding aims to increase political pressure against decisions based on poor ideas by informing the public about them. A decision maker is more likely to reject them if the problems are identified and explicated.

However, shared understanding does not contain an idea that individual proponents of unsubstantiated thoughts should be pressured to reject them. It does not threat personal beliefs, it attempts to understand them. This is hopefully a feature that builds acceptance and facilitates contributions, but the open assessments performed so far do not contain sensitive personal matters to demonstrate this.

Although openness is a guiding principle in science, the working environment has changed much faster than the practices in research, and openness is actually in conflict with many current practices. For example, it is common to hide expert work until it has been finalised and published. Also, a demand to produce assessments openly and describe all reasoning and data already from the beginning is often seen as an unreasonable requirement and makes experts reluctant to participate. This observation has raised two opposite conclusions: either that openness should be incentivised and promoted actively in all research and expert work[9], including decision support; or that openness as an objective hinders expert work and should be rejected.

The principles behind open policy practice are not unique; on the contrary, they have been borrowed from good practices of various disciplines. The aim has been to use solid principles to build a coherent set of methods that gives practical guidance to decision support. It is reassuring that many principles from the original collection[19] have increased in popularity in the society. Openness in science is a current megatrend, and its importance has been accepted much more widely than in 2006 when Opasnet was launched.

Although open policy practice seems to work in theory, it must also work in practice. The experience about open policy practice demonstrates that it works as expected when the participants are committed to the methods, practices, and tools. However, there have been less participants in most open assessments than what had been hoped for. This is partly due to insufficient marketing, as reader and contributor numbers have gone clearly up with assessments that have gained large media coverage and public interest. Other major reasons include non-optimal user experience and inertia to change established practices and tools. Also, more information is needed about how hostile contributions get handled, when they occur; fortunately, they have been very rare despite fears.

Criticism has a central role in the scientific method. It is applied in practical situations, because rejecting poor statements is much easier and more efficient than trying to prove statements true[4]. Most critique is verbal or written discussion between participants, focussing on particular, often detailed topics. Useful information structures have been found for criticism, notably structured discussions that can target any part of an assessment (scope, data, premises, analyses, structure, results etc).

None of the websites and tools described in this article offer a complete environment for open topic-wise scientific information production and discussion that would also support decision making. Opasnet works well for online assessments, but it is not optimised for documenting policy discussions or scientific work in real time. Climate Watch was designed to implement open policy practice in a narrow field of evaluation and management of municipality action plans. There are plans to generalise the functionalities for wider use base. This could be achieved by merging the functionalities of e.g. Opasnet, Open Science Framework, open data repositories, and discussion forums. Even if different tasks would happen at separate websites, they could form an integrated system (by using e.g. standard interfaces and permanent resource locations) to be used by decision makers, experts, stakeholders, and machines. Resource description framework and ontologies could be helpful in organising such a complex system.

To keep expert and decision making practices up to the recent progress, there is a need for tools and also training designed to facilitate a change. New practices could also be promoted by developing ways to give scientific — or political — merit and recognition more directly based on online co-creation contributions. The current publication counts and impact factors — or public votes — are very indirect measures of scientific or societal importance of the information or policies produced.

This article presents methods and practices designed for decision support. Many of them have already been successfully used, while there are many parts that have been thought as important in open policy practice but that have not yet been extensively tested. There is still a lot to learn about using co-created information in decision making. However, experiences so far have demonstrated that decision making can be more evidence-informed than what it is today, and several tools promoting this change are available.

Political practices in western democracies are based on a premise that ultimately the citizens decide about things by voting. Therefore, in a sense, people can not vote "wrong". In contrast, open policy practice is based on a premise that the objectives of the citizens are the ultimate guiding principle, and it is a matter of discussion, assessment, and other information work to suggest which paths should or should not be taken to reach these objectives. This thinking is close to James Madison's ideas about democracy in Federalist 63 from 1788.[49]. In this context, people vote wrong if they vote for an option that is objectively speaking incapable of delivering the outcomes that they want.

If people are well-informed and have time and capability of considering different alternatives, the two premises lead to similar outcomes. However, recent policy research has shown that this prerequisite is often not met, and people can be and increasingly are being mislead, especially with modern microtargeting tools[45]. The need for protecting people and decision making from misleading information has been recognised, but new effective tools are still lacking[50].

Public institutions such as independent justice system, free press, and honest civil servants provide protection against misleading activities and disruptive policies. However, these democratic institutions have deteriorated globally and in some countries especially, even in places with previously good situations[51].

It seems that one key indicator for the performance of open policy practice and other decision support methodologies is, whether they are capable of effectively producing understanding among decision makers and citizens. Understanding is especially needed about priorities and impacts or destructiveness of policy options. The performance is critical if the decision maker, or media environment, or some political groups are indifferent about or even hostile against scientific knowledge or public values.

There is no data about open policy practice usage in such a hostile environment. Yet, open policy practice can be collaboratively used even without support from a decision maker. Although decision maker's objectives are important for an assessment, these may be either deduced indirectly from their actions, or even directly replaced by the objectives of the citizens or the society at large. Thus, open policy practice is arguably a robust set of methods that can be used to bypass non-democratic power structures and focus on the needs of the public even in a non-optimal collaboration environment.

Destructive policies may be an effective way to inform stakeholders in a grim societal environment. Open policy practice may not be able to choose the best alternative among good ones, but it may be more effective in identifying and rejecting poor alternatives, i.e. destructive policies, which is often more important. This is expected to reduce the influence of a single leader or decision maker, resulting in more stable and predictable policies. It is possible to focus on disseminating information about what actions especially should not be taken, why, and how it is known. In such discourse, the message can be practical, short, clear, and rationale is available for anyone interested. Practical experiments are needed to tell, whether this could reduce the support of destructive policies among the public.

Further research is also needed to study other aspects of destructive policies: Can such policies be unambiguously recognised? Is shared understanding about them convincing enough among decision makers to change policies? Does it cause objections about science being biased and partisan? Does open policy practice prevent destructive policies from gaining political support?

Conclusions

In conclusion, open policy practice works technically as expected. Open assessments can be performed openly online. They do not fail due to reasons many people think they will, namely low quality contributions, malevolent attacks or chaos caused by too many uninformed participants; these phenomena are very rare. Shared understanding has proved to be a useful concept that guides policy processes toward more collaborative approach, whose purpose is wider understanding rather than winning.

However, open policy practice has not been adopted in expert work or decision support as expected. A key hindrance has been that the initial cost of learning and adopting new tools and practices has been higher than what an expert is willing to pay for participation in a single assessment, even if its impacts on the overall process are positive. The increased availability, acceptability, and inter-assessment efficiency have not yet been fully recognised by the scientific or policy community.

Active facilitation, community building and improving the user-friendliness of the tools were identified as key solutions in improving usability of the method in the future.

List of abbreviations

  • THL: Finnish Institute for Health and Welfare (government research institute in Finland)
  • IEHIAS: Integrated Environmental Health Impact Assessment System (a website)
  • RDF: resource description framework

Declarations

  • Ethics approval and consent to participate: Not applicable
  • Consent for publication: Not applicable
  • Availability of data and materials: The datasets generated and/or analysed during the current study are available at the Opasnet repository, http://en.opasnet.org/w/Open_policy_practice
  • Competing interests: The authors declare that they have no competing interests.
  • Funding: This work resulted from the BONUS GOHERR project (Integrated governance of Baltic herring and salmon stocks involving stakeholders, 2015-2018) that was supported by BONUS (Art 185), funded jointly by the EU, the Academy of Finland and and the Swedish Research Council for Environment, Agricultural Sciences and Spatial Planning. Previous funders of the work: Centre of Excellence for Environmental Health Risk Analysis 2002-2007 (Academy of Finland), Beneris 2006-2009 (EU FP6 Food-CT-2006-022936), Intarese 2005-2011 (EU FP6 Integrated project in Global Change and Ecosystems, project number 018385), Heimtsa 2007-2011 EU FP6 (Global Change and Ecosystems project number GOCE-CT-2006-036913-2), Plantlibra 2010-2014 (EU FP7-KBBE-2009-3 project 245199), Urgenche 2011-2014 (EU FP7 Call FP7-ENV-2010 Project ID 265114), Finmerac 2006-2008 (Finnish Funding Agency for Innovation TEKES), Minera 2010-2013 (European Regional Development Fund), Scud 2005-2010 (Academy of Finland, grant 108571), Bioher 2008-2011 (Academy of Finland, grant 124306), Claih 2009-2012 (Academy of Finland, grant 129341), Yhtäköyttä 2015-2016 (Prime Minister's Office, Finland), Ympäristöterveysindikaattori 2018 (Ministry of Social Affairs and Health, Finland). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
  • Authors' contributions: JT and MP jointly developed the open assessment method and open policy practice. JT launched Opasnet web-workspace and supervised its development. TR developed OpasnetUtils software package from an original idea by JT and implemented several assessment models. All authors participated in several assessments and discussions about methods. JT wrote the first manuscript draft based on materials from MP and TR. All authors read and approved the final manuscript.
  • Acknowledgements: We thank Einari Happonen and Juha Villman for their work on developing Opasnet, and Juha Yrjölä and Tero Tikkanen for developing Climate Watch; and Arja Asikainen, John S. Evans, Alexanda Gens, Patrycja Gradowska, Päivi Haapasaari, Sonja-Maria Ignatius, Suvi Ignatius, Matti Jantunen, Anne Knol, Sami Majaniemi, Päivi Meriläinen, Kaisa Mäkelä, Raimo Muurinen, Jussi Nissilä, Juha Pekkanen, Mia Pihlajamäki, Teemu Ropponen, Kalle Ruokolainen, Simo Sarkki, Marko Tainio, Peter Tattersall, Hanna Tuomisto, Jouko Tuomisto, Matleena Tuomisto, and Pieta Tuomisto for crucial and inspiring discussions about methods and their implementation, and promoting these ideas on several forums.

Endnotes

a This paper has its foundations on environmental health, but the idea of decision support necessarily looks at aspects seen relevant from the point of view of the decision maker, not from that of an expert in a particular field. Therefore, this article and also the method described are deliberately taking a wide view and covering all areas of expertise. However, all practical case studies have their main expertise needs in public health, and often specifically in environmental health. b Whenever this article presents a term in italic (e.g. open assessment), it indicates that there is a page at the Opasnet web-workspace describing that term and that it can be accessed using a respective link (e.g. http://en.opasnet.org/w/Open_assessment). c Insight network was originally called pyrkilo (and at some point also extended causal diagram). The word and concept pyrkilo was coined in 1997. In Finnish, pyrkilö means "an object or process that tends to produce or aims at producing certain kinds of products." The reasoning for using the word was that pyrkilo diagrams and related structured information such as models tend to improve understanding and thus decisions. The first wiki website was also called Pyrkilo, but the name was soon changed to Opasnet.

References and notes

  1. 1.0 1.1 Pohjola M. Assessments are to change the world. Prerequisites for effective environmental health assessment. Helsinki: National Institute for Health and Welfare Research 105; 2013. http://urn.fi/URN:ISBN:978-952-245-883-4
  2. Jussila H. Päätöksenteon tukena vai hyllyssä pölyttymässä? Sosiaalipoliittisen tutkimustiedon käyttö eduskuntatyössä. [Supporting decision making or sitting on a shelf? The use of sociopolitical research information in the Finnish Parliament.] Helsinki: Sosiaali- ja terveysturvan tutkimuksia 121; 2012. http://hdl.handle.net/10138/35919. Accessed 1 Feb 2020. (in Finnish)
  3. National Research Council. Risk Assessment in the Federal Government: Managing the Process. Washington DC: National Academy Press; 1983.
  4. 4.0 4.1 4.2 Popper K. Conjectures and Refutations: The Growth of Scientific Knowledge, 1963, ISBN 0-415-04318-2
  5. 5.0 5.1 National Research Council. Understanding risk. Informing decisions in a democratic society. Washington DC: National Academy Press; 1996.
  6. von Winterfeldt D. Bridging the gap between science and decision making. PNAS 2013;110:3:14055-14061. http://www.pnas.org/content/110/Supplement_3/14055.full
  7. 7.0 7.1 7.2 7.3 Pohjola MV, Leino O, Kollanus V, Tuomisto JT, Gunnlaugsdóttir H, Holm F, Kalogeras N, Luteijn JM, Magnússon SH, Odekerken G, Tijhuis MJ, Ueland O, White BC, Verhagen H. State of the art in benefit-risk analysis: Environmental health. Food Chem Toxicol. 2012;50:40-55.
  8. Doelle M, Sinclair JA. (2006) Time for a new approach to public participation in EA: Promoting cooperation and consensus for sustainability. Environmental Impact Assessment Review 26: 2: 185-205 https://doi.org/10.1016/j.eiar.2005.07.013.
  9. 9.0 9.1 Federation of Finnish Learned Societies. (2020) Declaration for Open Science and Research (Finland) 2020-2025. https://avointiede.fi/fi/julistus. Accessed 1 Feb 2020
  10. Eysenbach G. Citation Advantage of Open Access Articles. PLoS Biol 2006: 4; e157. doi: 10.1371/journal.pbio.0040157
  11. 11.0 11.1 Dalio R. Principles: Life and work. New York: Simon & Shuster; 2017. ISBN 9781501124020
  12. Tapscott D, Williams AD. Wikinomics. How mass collaboration changes everything. USA: Portfolio; 2006. ISBN 1591841380
  13. Surowiecki J. The Wisdom of Crowds: Why the Many Are Smarter Than the Few and How Collective Wisdom Shapes Business, Economies, Societies and Nations. USA: Doubleday; Anchor; 2004. ISBN 9780385503860
  14. 14.0 14.1 Noveck, BS. Wiki Government - How Technology Can Make Government Better, Democracy Stronger, and Citizens More Powerful. Brookings Institution Press; 2010. ISBN 9780815702757
  15. 15.0 15.1 Mauser W, Klepper G, Rice M, Schmalzbauer BS, Hackmann H, Leemans R, Current HM. Transdisciplinary global change research: the co-creation of knowledge for sustainability. Opinion in Environmental Sustainability 2013;5:420–431; doi:10.1016/j.cosust.2013.07.001
  16. Giles J. Internet encyclopaedias go head to head. Nature 2005;438:900–901 doi:10.1038/438900a
  17. 17.0 17.1 Pohjola MV, Pohjola P, Tainio M, Tuomisto JT. Perspectives to Performance of Environment and Health Assessments and Models—From Outputs to Outcomes? (Review). Int. J. Environ. Res. Public Health 2013;10:2621-2642 doi:10.3390/ijerph10072621
  18. 18.0 18.1 Pohjola MV, Tuomisto JT. Openness in participation, assessment, and policy making upon issues of environment and environmental health: a review of literature and recent project results. Environmental Health 2011;10:58 http://www.ehjournal.net/content/10/1/58.
  19. 19.0 19.1 19.2 Tuomisto JT, Pohjola M, editors. Open Risk Assessment. A new way of providing scientific information for decision-making. Helsinki: Publications of the National Public Health Institute B18; 2007. http://urn.fi/URN:ISBN:978-951-740-736-6.
  20. Tuomisto JT, Pohjola M, Pohjola P. Avoin päätöksentekokäytäntö voisi parantaa tiedon hyödyntämistä. [Open policy practice could improve knowledge use.] Yhteiskuntapolitiikka 2014;1:66-75. http://urn.fi/URN:NBN:fi-fe2014031821621 (in Finnish)
  21. 21.0 21.1 Bondy, J. A.; Murty, U. S. R. (2008). Graph Theory. Springer. ISBN 978-1-84628-969-9.
  22. Aitamurto T, Landemore H. Five design principles for crowdsourced policymaking: Assessing the case of crowdsourced off-road traffic law in Finland. Journal of Social Media for Organizations. 2015;2:1:1-19.
  23. 23.0 23.1 Sandström V, Tuomisto JT, Majaniemi S, Rintala T, Pohjola MV. Evaluating effectiveness of open assessments on alternative biofuel sources. Sustainability: Science, Practice & Policy 2014;10;1. doi:10.1080/15487733.2014.11908132 Assessment: http://en.opasnet.org/w/Biofuel_assessments. Accessed 1 Feb 2020.
  24. Cooke RM. Experts in Uncertainty: Opinion and Subjective Probability in Science. New York: Oxford University Press; 1991.
  25. 25.0 25.1 Pohjola MV. Assessment of impacts to health, safety, and environment in the context of materials processing and related public policy. In: Bassim N, editor. Comprehensive Materials Processing Vol. 8. Elsevier Ltd; 2014. pp 151–162. doi:10.1016/B978-0-08-096532-1.00814-1
  26. van Kerkhoff L, Lebel L. Linking knowledge and action for sustainable development. Annu. Rev. Environ. Resour. 2006. 31:445-477. doi:10.1146/annurev.energy.31.102405.170850
  27. 27.0 27.1 City of Helsinki. The Carbon-neutral Helsinki 2035 Action Plan. Publications of the Central Administration of the City of Helsinki 2018:4. http://carbonneutralcities.org/wp-content/uploads/2019/06/Carbon_neutral_Helsinki_Action_Plan_1503019_EN.pdf Assessment: https://ilmastovahti.hel.fi. Accessed 1 Feb 2020.
  28. Eemeren FH van, Grootendorst R. A systematic theory of argumentation: The pragma-dialectical approach. Cambridge: Cambridge University Press; 2004.
  29. Dung PM. (1995) On the acceptability of arguments and its fundamental role in nonmonotonic reasoning, logic programming, and n–person games. Artificial Intelligence. 77 (2): 321–357. doi:10.1016/0004-3702(94)00041-X.
  30. Hastrup T. Knowledge crystal argumentation tree. https://dev.tietokide.fi/?Q10. Web tool. Accessed 1 Feb 2020.
  31. 31.0 31.1 31.2 Tuomisto JT, Asikainen A, Meriläinen P et Haapasaari P. Health effects of nutrients and environmental pollutants in Baltic herring and salmon: a quantitative benefit-risk assessment. BMC Public Health 20, 64 (2020). https://doi.org/10.1186/s12889-019-8094-1 Assessment: http://en.opasnet.org/w/Goherr_assessment, data archive: https://osf.io/brxpt/. Accessed 1 Feb 2020.
  32. Tuomisto JT. TCDD: a challenge to mechanistic toxicology [Dissertation]. Kuopio: National Public Health Institute A7; 1999.
  33. Tuomisto JT, Pekkanen J, Alm S, Kurttio P, Venäläinen R, Juuti S et al. Deliberation process by an explicit factor-effect-value network (Pyrkilo): Paakkila asbestos mine case, Finland. Epidemiol 1999;10(4):S114.
  34. Tuomisto JT; Tainio M. An economic way of reducing health, environmental, and other pressures of urban traffic: a decision analysis on trip aggregation. BMC PUBLIC HEALTH 2005;5:123. http://biomedcentral.com/1471-2458/5/123/abstract Assessment: http://en.opasnet.org/w/Cost-benefit_assessment_on_composite_traffic_in_Helsinki. Accessed 1 Feb 2020.
  35. Open Knowledge International. The Open Definition. http://opendefinition.org/. Accessed 1 Feb 2020.
  36. Ignatius S-M, Tuomisto JT, Yrjölä J, Muurinen R. (2020) From monitoring into collective problem solving: City Climate Tool. EIT Climate-KIC project: 190996 (Partner Accelerator).
  37. W3C. Resource Description Framework (RDF). https://www.w3.org/RDF/. Accessed 1 Feb 2020.
  38. Tuomisto JT. Näkemysverkot ympäristöpäätöksenteon tukena [Insight networks supporting the environmental policy making](in Finnish) Kokeilunpaikka. Website. https://www.kokeilunpaikka.fi/fi/kokeilu/nakemysverkot-ymparistopaatoksenteon-tukena. Accessed 1 Feb 2020.
  39. Schwartz SH, Cieciuch J, Vecchione M, Davidov E, Fischer R, Beierlein C, Ramos A, Verkasalo M, Lönnqvist J-E. Refining the theory of basic individual values. Journal of Personality and Social Psychology. 2012: 103; 663–688. doi: 10.1037/a0029393.
  40. Bostrom N. (2019) The Vulnerable World Hypothesis. Global Policy 10: 4: 455-476. https://doi.org/10.1111/1758-5899.12718.
  41. Allison DB, Brown AW, George BJ, Kaiser KA. Reproducibility: A tragedy of errors. Nature 2016;530:27–29. doi:10.1038/530027a
  42. Climate Watch. Impact and scenario tool. https://skenaario.hnh.fi/. Website. Accessed 1 Feb 2020.
  43. Wikipedia: Wikipedians. https://en.wikipedia.org/wiki/Wikipedia:Wikipedians. Accessed 1 Feb 2020
  44. EFSA. Risk for animal and human health related to the presence of dioxins and dioxin‐like PCBs in feed and food. EFSA Journal 2018;16:5333. https://doi.org/10.2903/j.efsa.2018.5333
  45. 45.0 45.1 UK Parliament. (2019) Disinformation and 'fake news': Final report. https://publications.parliament.uk/pa/cm201719/cmselect/cmcumeds/1791/179102.htm. Accessed 1 Feb 2020
  46. Dufva M, Halonen M, Kari M, Koivisto T, Koivisto R, Myllyoja J. Kohti jaettua ymmärrystä työn tulevaisuudesta [Toward a shared understanding of the future of work]. Helsinki: Prime Minister's Office: Publications of the Govenrment's analysis, assessment and research activities 33; 2017. (in Finnish) http://tietokayttoon.fi/julkaisu?pubid=18301. Accessed 1 Feb 2020.
  47. Oksanen K. Valtioneuvoston tulevaisuusselonteon 1. osa. Jaettu ymmärrys työn murroksesta [Government Report on the Future Part 1. A shared understanding of the transformation of work] Prime Minister’s Office Publications 13a; 2017. (in Finnish) http://urn.fi/URN:ISBN:978-952-287-432-0. Accessed 1 Feb 2020.
  48. European Parliament. Directive 2014/52/EU of the European Parliament and of the Council of 16 April 2014 amending Directive 2011/92/EU on the assessment of the effects of certain public and private projects on the environment Text with EEA relevance. https://eur-lex.europa.eu/eli/dir/2014/52/oj Accessed 1 Feb 2020.
  49. James Fishkin. (2011) When the people speak. Democratic deliberation and public consultancy. Publisher: Oxford University Press. ISBN 978-0199604432
  50. REF ABOUT FIGHT AGAINST FAKE NEWS AND HOW IT IS SUCCEEDING##
  51. Freedom House. (2019) Freedom in the World 2019 https://freedomhouse.org/report/freedom-world/freedom-world-2019. Accessed 1 Feb 2020.

Figures and tables

Move them here for submission.

Appendix S1: Examples of insight networks

Appendix S2: Open assessments performed

A number of open assessments have been performed in several research projects (see the funding declaration) and health assessments since 2004. Some assessments have also been done on international Kuopio Risk Assessment Workshops for doctoral students in 2007, 2008, and 2009 and on a Master's course Decision Analysis and Risk Management (6 credit points), organised by the University of Eastern Finland (previously University of Kuopio) in 2011, 2013, 2015, and 2017.

More assessments can be found at Opasnet page Category:Assessments.

Table S2-1. Some environmental health assessments performed using open assessment. References give links to both an assessment page and a scientific publication as applicable.
Topic # Assessment Year Project
Vaccine effectiveness and safety 1 Assessment of the health impacts of H1N1 vaccination[1] 2011 In-house, collaboration with Decision Analysis and Risk Management course
2 Tendering process for pneumococcal conjugate vaccine[2] 2014 In-house, collaboration with the National Vaccination Expert Group
Energy production, air pollution and climate change 3 Helsinki energy decision[3] 2015 In-house, collaboration with city of Helsinki
4 Climate change policies and health in Kuopio[4] 2014 Urgenche, collaboration with city of Kuopio
5 Climate change policies in Basel[5] 2015 Urgenche, collaboration with city of Basel
6 Availability of raw material for biodiesel production[6] 2012 Jatropha, collaboration with Neste Oil
7 Health impacts of small scale wood burning[7] 2011 Bioher, Claih
8 Climate strategy of Helsinki: Carbon neutral Helsinki 2035 action plan[8] 2018 In-house, collaboration with city of Helsinki
9 Climate mitigation of the social affairs and health sector in Finland[9] 2019 In-house, commissioned by the Prime Minister
Health, climate, and economic effects of traffic 10 Gasbus - health impacts of Helsinki bus traffic[10] 2004 Collaboration with Helsinki Metropolitan Area
11 Cost-benefit assessment on composite traffic in Helsinki[11] 2005 In-house
Risks and benefits of fish consumption 12 Benefit-risk assessment of Baltic herring in Finland[12] 2015 Collaboration with Finnish Food Safety Authority
13 Benefit-risk assessment of methyl mercury and omega-3 fatty acids in fish[13] 2009 Beneris
14 Benefit-risk assessment of fish consumption for Beneris[14] 2008 Beneris
15 Benefit-risk assessment on farmed salmon[15] 2004 In-house
16 Benefit-risk assessment of Baltic herring and salmon intake[16] 2018 BONUS GOHERR
Dioxins, fine particles 17 TCDD: A challenge to mechanistic toxicology[17] 1999 EC ENV4-CT96-0336
18 Comparative risk assessment of dioxin and fine particles[18] 2007 Beneris
Plant-based food supplements 19 Compound intake estimator[19] 2014 Plantlibra
Health and ecological risks of mining 20 Paakkila asbestos mine[20] 1999 In-house
21 Model for site-specific health and ecological assessments in mines[21] 2013 Minera
22 Risks of water from mine areas [22] 2018 Kaveri
Water safety 23 Water Guide for assessing health risks of drinking water contamination[23] 2013 Conpat
24 Bathing Water Guide for assessing health risks of bathing water contamination[24] 2019 Water Guide update
Organisational assessments 25 Analysis and discussion about research strategies or organisational changes within THL 2017 In-house
26 Transport and communication strategy in digital Finland[25] 2014 Collaboration with the Ministry of Transport and Communications of Finland
Information use in government or municipality decision support 27 Case studies: Assessment of immigrants' added value; Real-time co-editing, Fact-checking, Information design[26] 2016 Yhtäköyttä, collaboration with Prime Minister's Office
28 Evaluation of forest strategy process for Puijo, Kuopio[27] 2012 In-house
Indicator development 29 Environmental health indicators in Finland[28] 2018 Ympäristöterveysindikaattori
Structuring discussions 30 Developing and testing tools and practices for structured argumentation[29] 2019 Knowledge Crystal

References for assessments

  1. Assessment: http://en.opasnet.org/w/Assessment_of_the_health_impacts_of_H1N1_vaccination. Accessed 1 Feb 2020.
  2. Assessment: http://en.opasnet.org/w/Tendering_process_for_pneumococcal_conjugate_vaccine. Accessed 1 Feb 2020.
  3. Tuomisto JT, Rintala J, Ordén P, Tuomisto HM, Rintala T. Helsingin energiapäätös 2015. Avoin arviointi terveys-, ilmasto- ja muista vaikutuksista. [Helsinki energy decision 2015. An open assessment on health, climate, and other impacts]. Helsinki: National Institute for Health and Welfare. Discussionpaper 24; 2015. http://urn.fi/URN:ISBN:978-952-302-544-8 Assessment: http://en.opasnet.org/w/Helsinki_energy_decision_2015. Accessed 1 Feb 2020.
  4. Asikainen A, Pärjälä E, Jantunen M, Tuomisto JT, Sabel CE. Effects of Local Greenhouse Gas Abatement Strategies on Air Pollutant Emissions and on Health in Kuopio, Finland. Climate 2017;5(2):43; doi:10.3390/cli5020043 Assessment: http://en.opasnet.org/w/Climate_change_policies_and_health_in_Kuopio. Accessed 1 Feb 2020.
  5. Tuomisto JT, Niittynen M, Pärjälä E, Asikainen A, Perez L, Trüeb S, Jantunen M, Künzli N, Sabel CE. Building-related health impacts in European and Chinese cities: a scalable assessment method. Environmental Health 2015;14:93. doi:10.1186/s12940-015-0082-z Assessment: http://en.opasnet.org/w/Climate_change_policies_in_Basel. Accessed 1 Feb 2020.
  6. Sandström V, Tuomisto JT, Majaniemi S, Rintala T, Pohjola MV. Evaluating effectiveness of open assessments on alternative biofuel sources. Sustainability: Science, Practice & Policy 2014;10;1. doi:10.1080/15487733.2014.11908132 Assessment: http://en.opasnet.org/w/Biofuel_assessments. Accessed 1 Feb 2020.
  7. Taimisto P, Tainio M, Karvosenoja N, Kupiainen K, Porvari P, Karppinen A, Kangas L, Kukkonen J, Tuomisto JT. Evaluation of intake fractions for different subpopulations due to primary fine particulate matter (PM2.5) emitted from domestic wood combustion and traffic in Finland. Air Quality Atmosphere and Health 2011;4:3-4:199-209. doi:10.1007/s11869-011-0138-3 Assessment: http://en.opasnet.org/w/BIOHER_assessment. Accessed 1 Feb 2020.
  8. City of Helsinki. The Carbon-neutral Helsinki 2035 Action Plan. Publications of the Central Administration of the City of Helsinki 2018:4. http://carbonneutralcities.org/wp-content/uploads/2019/06/Carbon_neutral_Helsinki_Action_Plan_1503019_EN.pdf Assessment: https://ilmastovahti.hel.fi. Accessed 1 Feb 2020.
  9. Assessment: https://hnpolut.hnh.fi. Accessed 1 Feb 2020
  10. Tainio M, Tuomisto JT, Hanninen O, Aarnio P, Koistinen, KJ, Jantunen MJ, Pekkanen J. Health effects caused by primary fine particulate matter (PM2.5) emitted from buses in the Helsinki metropolitan area, Finland. RISK ANALYSIS 2005;25:1:151-160. Assessment: http://en.opasnet.org/w/Gasbus_-_health_impacts_of_Helsinki_bus_traffic. Accessed 1 Feb 2020.
  11. Tuomisto JT; Tainio M. An economic way of reducing health, environmental, and other pressures of urban traffic: a decision analysis on trip aggregation. BMC PUBLIC HEALTH 2005;5:123. http://biomedcentral.com/1471-2458/5/123/abstract Assessment: http://en.opasnet.org/w/Cost-benefit_assessment_on_composite_traffic_in_Helsinki. Accessed 1 Feb 2020.
  12. Tuomisto JT, Niittynen M, Turunen A, Ung-Lanki S, Kiviranta H, Harjunpää H, Vuorinen PJ, Rokka M, Ritvanen T, Hallikainen A. Itämeren silakka ravintona – Hyöty-haitta-analyysi. [Baltic herring as food - a benefit-risk analysis] ISBN 978-952-225-141-1. Helsinki: Eviran tutkimuksia 1; 2015 (in Finnish). Assessment: http://fi.opasnet.org/fi/Silakan_hy%C3%B6ty-riskiarvio. Accessed 1 Feb 2020.
  13. Leino O, Karjalainen AK, Tuomisto JT. Effects of docosahexaenoic acid and methylmercury on child's brain development due to consumption of fish by Finnish mother during pregnancy: A probabilistic modeling approach. Food Chem Toxicol. 2013;54:50-8. doi:10.1016/j.fct.2011.06.052. Assessment: http://en.opasnet.org/w/Benefit-risk_assessment_of_methyl_mercury_and_omega-3_fatty_acids_in_fish. Accessed 1 Feb 2020.
  14. Gradowska PL. Food Benefit-Risk Assessment with Bayesian Belief Networks and Multivariable Exposure-Response. Delft: Delft University of Technology (doctoral dissertation); 2013. https://repository.tudelft.nl/islandora/object/uuid:9ced4cb2-9809-4b58-af25-34e458e8ea23/datastream/OBJ Assessment: http://en.opasnet.org/w/Benefit-risk_assessment_of_fish_consumption_for_Beneris. Accessed 1 Feb 2020.
  15. Tuomisto JT, Tuomisto J, Tainio M, Niittynen M, Verkasalo P, Vartiainen T et al. Risk-benefit analysis of eating farmed salmon. Science 2004;305(5683):476. Assessment: http://en.opasnet.org/w/Benefit-risk_assessment_on_farmed_salmon. Accessed 1 Feb 2020.
  16. Tuomisto JT, Asikainen A, Meriläinen P et Haapasaari P. Health effects of nutrients and environmental pollutants in Baltic herring and salmon: a quantitative benefit-risk assessment. BMC Public Health 20, 64 (2020). https://doi.org/10.1186/s12889-019-8094-1 Assessment: http://en.opasnet.org/w/Goherr_assessment, data archive: https://osf.io/brxpt/. Accessed 1 Feb 2020.
  17. Tuomisto JT. TCDD: a challenge to mechanistic toxicology [Dissertation]. Kuopio: National Public Health Institute A7; 1999.
  18. Leino O, Tainio M, Tuomisto JT. Comparative risk analysis of dioxins in fish and fine particles from heavy-duty vehicles. Risk Anal. 2008;28(1):127-40. Assessment: http://en.opasnet.org/w/Comparative_risk_assessment_of_dioxin_and_fine_particles. Accessed 1 Feb 2020.
  19. Assessment: http://en.opasnet.org/w/Compound_intake_estimator. Accessed 1 Feb 2020.
  20. Tuomisto JT, Pekkanen J, Alm S, Kurttio P, Venäläinen R, Juuti S et al. Deliberation process by an explicit factor-effect-value network (Pyrkilo): Paakkila asbestos mine case, Finland. Epidemiol 1999;10(4):S114.
  21. Kauppila T, Komulainen H, Makkonen S, Tuomisto JT, editors. Metallikaivosalueiden ympäristöriskinarviointiosaamisen kehittäminen: MINERA-hankkeen loppuraportti. [Summary: Improving Environmental Risk Assessments for Metal Mines: Final Report of the MINERA Project.] Helsinki: Geology Survey Finland, Research Report 199; 2013. 223 p. ISBN 978-952-217-231-0. Assessment: http://fi.opasnet.org/fi/Minera-malli. Accessed 1 Feb 2020.
  22. Assessment: http://fi.opasnet.org/fi/Kaivosvesien_riskit_(KAVERI-malli). Accessed 1 Feb 2020.
  23. Assessment: http://en.opasnet.org/w/Water_guide. Accessed 1 Feb 2020.
  24. Assessment: http://en.opasnet.org/w/Bathing_water_guide. Accessed 1 Feb 2020.
  25. Liikenne ja viestintä digitaalisessa Suomessa. Liikenne- ja viestintäministeriön tulevaisuuskatsaus 2014 [Transport and and communication in digital Finland] Helsinki: Ministry of Transport and Communication; 2014. http://urn.fi/URN:ISBN:978-952-243-420-3 Assessment: http://fi.opasnet.org/fi/Liikenne_ja_viestint%C3%A4_digitaalisessa_Suomessa_2020. Accessed 1 Feb 2020.
  26. Tuomisto JT, Muurinen R, Paavola J-M, Asikainen A, Ropponen T, Nissilä J. Tiedon sitominen päätöksentekoon. [Binding knowledge to decision making] Helsinki: Publications of the Government's analysis, assessment and research activities 39; 2017. ISBN 978-952-287-386-6 http://tietokayttoon.fi/julkaisu?pubid=19001. Assessment: http://fi.opasnet.org/fi/Maahanmuuttoarviointi. Accessed 1 Feb 2020.
  27. Kajanus M, Ollikainen T, Partanen J, Vänskä I. Kävijätutkimukseen perustuva Puijon virkistysmetsien hoito- ja käyttösuunnitelma. [Forest strategy for recreational forests at Puijo, Kuopio, based on visitor study.] (in Finnish) Kuopion kaupunki, Metsätoimisto; 2010. http://fi.opasnet.org/fi-opwiki/images/8/8a/Puijo-loppuraportti.pdf. Assessment: http://fi.opasnet.org/fi/Puijon_metsien_k%C3%A4ytt%C3%B6suunnitelman_p%C3%A4%C3%A4t%C3%B6ksenteko Accessed 1 Feb 2020.
  28. Tuomisto JT, Asikainen A, Korhonen A, Lehtomäki H. Teemasivu ympäristöterveys [Portal: Environmental health]. A website, THL, 2018. [1]
  29. Hastrup T. Knowledge crystal argumentation tree. https://dev.tietokide.fi/?Q10. Web tool. Accessed 1 Feb 2020.

Appendix S3: Open policy ontology

Shared understanding aims at producing a description of different views, opinions, and facts related to a specific topic such as a decision process. The open policy ontology describes the information structures that are needed to document shared understanding of a complex decision situation. The purpose of the structure is to help people identify hidden premises, beliefs, and values and explicate possible discrepancies. This is expected to produce better understanding among participants.

The basic structure of a shared understanding is a network of items and relations between them. This network uses Resource description framework, which is an ontology standard used to describe many Internet contents. Items and relations (aka properties) are collectively called resources. Each item is typically of one of the types mentioned below. This information is documented using property instance of (e.g. Goherr assessment is instance of assessment).

Items are written descriptions of the actual things (people, tasks, publications, or phenomena), and on this page these descriptions rather than the actual things are discussed. Different item types have different levels of standardisation and internal structure. For example, knowledge crystals are web pages that always have headings question, answer and rationale, and the information is organised under those headings. Some other items describe e.g. statements that are free-text descriptions about how a particular thing is or should be (according to a participant), and yet some others are metadata about publications. A common feature is that all items contain information that is relevant for a decision.

In the open policy ontology, each item may have lengthy texts, graphs, analyses or even models inside them. However, the focus here is on how the items are related to each other. The actual content is often referred to as one key sentence only (description). Each item also has a unique identifier URI that is used for automatic handling of data.

The most important items are knowledge crystals and they are described here.

  • Assessment describes a particular decision situation and focuses on estimating impacts of different options. Its purpose is to support the making of that decision. Unlike other knowledge crystals, assessments typically have a defined start and end dates and they are closed after the decision is made. They also have contextually and situationally defined goals`to be able to better serve the needs of the decision makers of the decision.
  • Variable answers a particular factual or ethical question that is typically needed in one or more assessments. The answer of a variable is continually updated as new information arises, but its question remains constant in time. Variable is the basic building block of assessments. In R, variables are typically implemented using ovariable objects from OpasnetUtils package.
  • Method tells how to systematically implement a particular information task. Method is the basic building block for describing the assessment work (not reality, like variables). In practice, methods are "how-to-do" descriptions about how information should be produced, collected, analysed, or synthesised in an assessment. Typically, methods contain a software code or another algorithm to actually perform the method easily. In R, methods are typically ovariables that require some context-specific upstream information about dependencies before it can be calculated.

There are also other important classes of items:

  • Publication is any documentation that contains useful information related to a decision. Publications that are commonly used at Opasnet include encyclopedia article, lecture, nugget, and study. Other publications at Opasnet are typically uploaded as files.
    • Encyclopedia article is an object that describes a topic like in Wikipedia rather than answers a specific research question. They do not have a predefined attribute structure.
    • Lecture: Lecture contains a piece of information that is to be mediated to a defined audience and with a defined learning objective. It can also be description of a process during which the audience learns, instead of being a passive recipient of information.
    • Nugget is an object that is not editable by other people than a dedicated author (group) and is not expected to be updated once finalised. They do not have a predefined attribute structure.
    • Study describes a research study and its answers, i.e. observational or other data obtained in the study. The research questions are described as the question of the information object, and the study methods are described as the rationale of the object. Unlike in an article, introduction or discussion may be missing, and unlike in a variable, the answer and rationale of the study are more or less fixed after the work is done; this is because the interpretations of the results typically happen elsewhere, e.g. in variables for which a study contains useful information.
  • Discussion is a hierarchically structured documentation of a discussion about a defined statement or statements.
  • Stakeholder page is used to describe a person or group that is relevant for a decision or decision process; they may be an actor that has an active role in decision making or is a target of impacts. Contributors of Opasnet are described on their own user pages; other stakeholders may have their page on the main namespace.
  • Process describes elements of a decision process.
  • Action describes what, who and when should act to e.g. perform an assessment, make a decision, or implement policies.

Relations show different kinds of connections between items.

  • Causal link tells that the subject may change the object (e.g. affects, increases, decreases, prevents).
  • Participatory link describes a stakeholder's particular role related to the object (participates, negotiates, decides).
  • Operational link tells that the subject has some kind of practical relation to the object (executes, offers, tells).
  • Evaluative link tells that the subject shows preference or relevance about the object (has truthlikeness, value, popularity, finds important).
  • Referential link tells that the object is used as a reference of a kind for the subject (makes relevant; associates to; has reference, has tag, has category).
  • Argumentative link occurs between statements that defend or attack each other (attack, defend, comment).
  • Property link connects an evaluative (acceptability, usability), a logical (opposite, inverse) or set theory (has subclass, has part) property to the subject.

Item types

This ontology is specifically about decision making, and therefore actions (and decisions to act) are handled explicitly. However, any natural, social, ethical or other phenomena may relate to a decision and therefore the vocabulary has to be very generic.

Table S3-1. Item types used in open policy ontology.
Class English name Finnish name Description
resource resurssi All items and relations are resources
resource item asia Relevant pieces of information related policy making. Sometimes also refers to the real-life things that the information is about. Items are shown as nodes in insight networks.
resource relation relaatio Information about how items are connected to each other. Relations are shown as edges in insight networks.
item substance ilmiö Items about a substantive topic or phenomenon itself: What issues relate to a decision? What causal connections exist between issues? What scientific knowledge exist about the issues? What actions can be chosen? What are the impacts of these actions? What are the objectives and how can they be reached? What values and preferences exist?
item stakeholder sidosryhmä Items about people or organisations who have a particular role in a policy process, either as actors or targets of impacts: Who participates in a policy process? Who should participate? Who has necessary skills for contributing? Who has the authority to decide? Who is affected by a decision?
item process prosessi Items about doing or happening in relation with a topic, especially information about how a decision will be made): What will be decided? When will it be decided? How is the decision prepared? What political realities and restrictions exist?
item action toiminta Items about organising decision support (impact assessment, decision making, implementation, and evaluation): What tasks are needed to collect and organise necessary information? How is information work organised? How and when are decisions implemented? Actions are also important afterwards to distribute merit and evaluate the process: Who did what? How did information evolve and by whom?
item information object tieto-olio A specified structure containing information about substance, stakeholders, processes, methods, or actions.
information object knowledge crystal tietokide information object with a standardised structure and contribution rules
knowledge crystal assessment arviointi Describes a decision situation and typically provides relevant information to decision makers before the decision is made (or sometimes after the decision about its implementation or success). It is mostly about the knowledge work, i.e. tasks for decision support.
knowledge crystal variable muuttuja Describes a real-world topic that is relevant for the decision situation. It is about the substance of the topic.
knowledge crystal method metodi Describes how information should be managed or analysed so that it answers the policy-relevant questions asked. How to perform information work? What methods are available for a task? How to participate in a decision process? How to use statistical and other methods and tools? How to motivate participation? How to measure merit of contributions?
information object discussion part keskustelun osa Information object that is used to organise discussions into a specified structure. The purpose of the structure is to help validation of statements and facilitate machine learning.
information object discussion keskustelu Discussion, or structured argumentation, describes arguments about a particular statement and a synthesis about an acceptable statement. In a way, discussion is (a documentation of) a process of analysing the validity of a statement.
discussion fact discussion faktakeskustelu Discussion that can be resolved based on scientific knowledge.
discussion value discussion arvokeskustelu Discussion that can be resolved based on ethical knowledge.
discussion part statement väite Proposition claiming that something is true or ethically good. A statement may be developed in a discussion by adding and organising related argumentation (according to pragma-dialectics), or by organising premises and inference rules (according to Perelman).
statement value statement arvoväite Proposition claiming that something is ethically good, better than something else, prioritised over something, or how things should be.
statement fact statement faktaväite Proposition claiming how things are or that something is true.
value statement true value statement tosi arvoväite A statement that has not been successfully invalidated.
value statement false value statement epätosi arvoväite A statement that has been successfully invalidated.
fact statement true fact statement tosi faktaväite
fact statement false fact statement epätosi faktaväite
statement true statement tosi väite
statement false statement epätosi väite
statement opening statement avausväite A statement that is the basis for a structured discussion, a priori statement.
statement closing statement lopetusväite A statement that is the resolution of a structured discussion, a posteriori statement. Closing statement becomes an opening statement when the discussion is opened again.
opening statement fact opening statement avausfaktaväite
closing statement fact closing statement lopetusfaktaväite
opening statement value opening statement avausarvoväite
closing statement value closing stetement lopetusarvoväite
discussion part argument argumentti A statement that has also contains a relation to its target as an integral part. Due to this relation, arguments appear inside discussions and target directly or indirectly the opening statement.
discussion part argumentation väittely Hierarchical list of arguments related to a particular statement.
information object knowledge crystal part tietokideosa This is shown separately to illustrate that the objects are actually linked by has part rather than has subclass relation.
knowledge crystal part question kysymys A research question asked in a knowledge crystal. The purpose of a knowledge crystal is to answer the question.
knowledge crystal part answer vastaus An answer or set of answers to the question of a knowledge crystal, based on any relevant information and inference rules.
knowledge crystal part rationale perustelut Any data, discussions, calculations or other information needed to convince a critical rational reader that the answer of a knowledge crystal is good.
knowledge crystal part answer part vastausosa This is shown separately to illustrate that the objects are actually linked by has part rather than has subclass relation.
answer part result tulos The actual, often numerical result to the question, conditional on relevant indices.
answer part index indeksi A list of possible values for a descriptor. Typically used in describing the result of an ovariable.
answer part conclusion päätelmä In an assessment, a textual interpretation of the result. Typically a conclusion is about what decision options should or should not be rejected and why based on the result.
knowledge crystal part ovariable ovariable A practical implementation of a knowledge crystal in modelling code. Ovariable takes in relevant information about data and dependencies and calculates the result. Typically implemented in R using OpasnetUtils package and ovariable object type.
ovariable key ovariable avainovariable An ovariable that is shown on an insight network even if some parts are hidden due to practical reasons.
information object publication julkaisu Any published report, book, web page or similar permanent piece of information that can be unambiguously referenced.
publication nugget tiedomuru An object that is not editable by other people than a dedicated author (group).
substance topic aihe A description of an area of interest. It defines boundaries of a content rather than defines the content itself, which is done by statements. When the information structure is improved, a topic often develops into a question of a knowledge crystal, while a statement develops into an answer of a variable.
priority objective tavoite A desired outcome of a decision. In shared understanding description, it is a topic (or variable) that has value statements attached to it.
substance risk factor riskitekijä
substance indicator indikaattori Piece of information that describes a particular substantive item in a practical and often standard way.
indicator risk indicator riski-indikaattori Indicator about (health) risk or outcome
information object data tietoaineisto
information object graph kuvaaja Graphical representation of a piece of information. Typically is related to an information object with describes relation.
work data work tietotyö
work data use tiedon käyttö
substance priority prioriteetti
substance expense kustannus
substance health impact terveysvaikutus
stakeholder decision maker päättäjä
stakeholder public officer virkamies
stakeholder assessor arvioija
stakeholder expert asiantuntija
stakeholder citizen kansalainen
stakeholder agent toimija
action task toimenpide action to be taken when the option has been selected
action decision päätös action to be taken when the option is yet to be selected. Describes a particular event where a decision maker chooses among defined alternatives. This may also be a part of an assessment under heading Decisions and scenarios.
action work työ continuous actions of the same kind and typically independent of the decision at hand. If the decision changes work routines, the action to make this change happen is called task.
work prevention ennaltaehkäisy trying to prevent something
work treatment hoito trying to fix something when something has already happened
work support tuki work that aids in the completion of the selected option, in whatever way
method open policy practice avoin päätöksentekokäytäntö framework for planning, making, and implementing decisions
method open assessment avoin arviointi method answering this question: How can factual and value information be organised for supporting societal decision making when open participation is allowed?
method analysis analyysi
method reporting raportointi
method measurement mittaus
publication study tutkimus
publication encyclopedia article ensyklopedia-artikkeli An object that describes a topic rather than answers a specific research question.
publication lecture luento Contains a piece of information that is to be mediated to a defined audience and with a defined learning objective.
method procedure toimintamalli
method principle periaate a short generic guidance for information work to ensure that the work is done properly. They especially apply to the execution phase.
principle intentionality tavoitteellisuus See Table 2 for explanations.
principle causality syysuhteiden kuvaus
principle criticism kritiikki
principle permanent resource locations kohteellisuus
principle openness avoimuus
principle reuse uusiokäyttö
principle use of knowledge crystals tietokiteiden käyttö
principle grouping ryhmäytyminen Facilitation methods are used to promote the participants' feeling of being an important member of a group that has a meaningful purpose.
principle respect arvostus Contributions are systematically documented and their merit evaluated so that each participant receives the respect they deserve based on their contributions.
objective expense objective kustannustavoite
process step jakso one of sequential time intervals when a particular kind of work is done in decision support. In the next step, the nature of the work changes.
step impact assessment vaikutusarviointi the first step in a decision process. Helps in collecting necessary information for making a decision.
step decision making päätöksenteko the second step in a decision process. When the decision maker actually chooses between options.
step implementation toimeenpano the third step in a decision process. When the chosen option is put in action.
step evaluation evaluointi the fourth step in a decision process. When the outcomes of the implementation are evaluated.
process phase vaihe one part of a decision work process where focus is on particular issues or methods. Typically phases overlap temporally.
phase shared understanding jaettu ymmärrys documenting of all relevant views, facts, values, and opinions about a decision situation in such a way that agreements and disagreements can be understood
phase execution toteutus production of necessary information for a decision at hand
phase evaluation and management seuranta ja ohjaus ensuring that all work related to a decision will be, is, and has been done properly
phase co-creation yhteiskehittäminen helping people to participate, contribute, and become motivated about the decision work

Relation types

Relations are edges between items (or nodes). A relation I is said to be an inverse of relation R, iff, for all items subject and object, claim "subject R object" is always equal to claim "object I subject".

Table S3-2. Relation types used in open policy ontology.
Class English name Finnish name English inverse Finnish inverse Description
relation participatory link osallisuuslinkki The subject is a stakeholder that has a particular role related to an object
relation operational link toimintolinkki The subject has some kind of practical relation to the object (a fairly wide class)
relation evaluative link arvostuslinkki The subject shows preference or relevance about the object
relation referential link viitelinkki The subject is used as a reference of a kind for the object
relation argumentative link argumentaatiolinkki The subject is used as an argument to criticise the object.
relation causal link syylinkki The subject has causal effect on the object (or vice versa in the case of an inverse relation)
relation property link ominaisuuslinkki The object describes a defined property of the subject.
causal link negative causal link negatiivinen syylinkki The subject reduces or diminishes the object.
causal link positive causal link positiivinen syylinkki The subject increases or enhances the object.
negative causal link decreases vähentää is decreased by vähentyy
positive causal link increases lisää is increased by lisääntyy
negative causal link worsens huonontaa is worsened by huonontuu
positive causal link improves parantaa is improved by parantuu
negative causal link prevents estää is prevented by estyy
positive causal link enhances edistää is enhanced by edistyy
negative causal link impairs heikentää is impaired by heikentyy
positive causal link sustains ylläpitää is sustained by ylläpitäytyy
causal link affects vaikuttaa is affected by vaikuttuu
causal link indirectly affects vaikuttaa epäsuorasti indirectly affected by vaikuttuu epäsuorasti
causal link cause of syy caused by johtuu Wikidata property P1542
causal link immediate cause of välitön syy immediately caused by johtuu välittömästi Wikidata property P1536
causal link contributing factor of vaikuttava tekijä Wikidata property P1537
participatory link performs toteuttaa performer toteuttajana who does a task?
participatory link decides päättää decider päätäjänä
participatory link asks kysyy asker kysyjänä
participatory link participates osallistuu participant osallistujana
participatory link accepts hyväksyy accepted by hyväksyjänä
participatory link develops kehittää developed by kehittäjänä
participatory link proposes ehdottaa proposed by ehdottajana
participatory link answers vastaa answered by vastaajana
participatory link responsible for vastuussa responsibility of vastuullisena
participatory link negotiates neuvottelee negotiated by neuvottelijana
participatory link recommends suosittelee recommended by suosittelijana
participatory link controls kontrolloi controlled by kontrolloijana
participatory link claims väittää claimed by väittäjänä
participatory link owns omistaa owned by omistajana
participatory link does tekee done by tekijänä
participatory link maintains ylläpitää maintained by ylläpitäjänä
participatory link oversees valvoo overseen by valvojana
operational link has option omistaa vaihtoehdon option for vaihtoehtona
operational link has index omistaa indeksin index for indeksinä
operational link tells kertoo told by kertojana
operational link describes kuvaa described by kuvaajana
operational link maps kartoittaa mapped by kartjoittajana
operational link contains data sisältää dataa data contained in data sisältyy
operational link data for on datana gets data from saa datansa
operational link uses käyttää is used by on käytettävänä an input (object) for a process (subject)
operational link produces tuottaa is produced by tuottajana Object is an output of a process produced by a stakeholder (subject)
operational link provides varustaa is provided by varustajana
operational link about aiheesta a task is about a topic. This overlaps with has topic; merge them?
property link logical link looginen linkki Relations based on logic
property link set theory link joukko-oppilinkki Relations based on set theory
set theory link part of osana has part sisältää osan is a part of a bigger entity, e.g. Venus is part of Solar System. Wikidata property P361 (part of) & P527 (has part). Previously there were relations about a decision: substance of, decision process of, stakeholder of, method of, task of, irrelevant to. But these are depreciated and replaced by has part, because the class of the object makes specific relations redundant.
set theory link context for kontekstina has context omistaa kontekstin
set theory link has subclass omistaa alajoukon subclass of alajoukkona Wikidata property P279
set theory link has instance omistaa instanssin instance of instanssina Object belongs to a set defined by the subject and inherits the properties of the set. Sysnonym for has item, which is depreciated. Wikidata property P31
logical link opposite vastakohta subject is opposite of object, e.g. black is opposite of white. Wikidata property P461; it is its own inverse
logical link inverse toisinpäin a sentence is equal to another sentence where subject and object switch places and has the inverse relation. This is typically needed in preprocessing of insight networks, and it rarely is explicitly shown of graphs. Wikidata property P1696; it is its own inverse
logical link if - then jos - niin if not - then not jos ei - niin ei If subject is true, then object is true. Also the negation is possible: if - then not. This links to logical operators and, or, not, equal, exists, for all; but it is not clear how they should be used in an insight network.
operational link prepares valmistelee prepared by valmistelijana
operational link pays kustantaa paid by kustantajana
operational link rationale for perustelee has rationale perusteltuu
operational link offers tarjoaa offered by tarjoajana
operational link executes suorittaa executed by suorittajana
operational link irrelevant to epärelevantti asiassa If there is no identified relation (or chain of relations) between a subject and an object, it implies that the subject is irrelevant to the object. However, sometimes people may (falsely) think that it is relevant, and this relation is used to explicate the irrelevance.
evaluative link finds important kokee tärkeäksi is found important tärkeäksi kokijana
evaluative link makes relevant tekee relevantiksi is made relevant relevantiksi tekijänä if the subject is valid in the given context, then the object is relevant. This typically goes between arguments, from a variable to value statement or from a value statement to a fact statement. This is a synonym of 'valid defend of type relevance'.
evaluative link makes irrelevant tekee epärelevantiksi is made irrelevant epärelevantiksi tekijänä Opposite of 'makes relevant'. Synonym of 'valid attack of type relevance'.
evaluative link makes redundant tekee turhaksi is made redundant turhaksi tekijänä Everything that is said in the object is already said in the subject. This depreciates the object because it brings no added value. However, it is kept for archival reasons and to demonstrate that the statement was heard.
evaluative link has opinion on mieltä Subject (typically a stakeholder) supports the object (typically a value or fact statement). This is preferred over 'values' and 'finds important' because it is more generic without loss of meaning.
evaluative link values arvostaa valued by arvostajana A stakeholder (subject) gives value or finds an object important. Object may be a topic or statement. Depreciated, use 'has opinion' instead.
evaluative link has truthlikeness on totuudellinen A subjective probability that subject is true. Object is a numeric value between 0 and 1. Typically this has a qualifier 'according to X' where X is the person or archetype who has assigned the probability.
evaluative link has preference mieltymys preference of mieltymyksenä Subject is better than object in a moral sense.
evaluative link has popularity on suosiossa A measure based on likes given by users.
evaluative link has objective omaa tavoitteen objective of tavoitteena
argumentative link agrees samaa mieltä
argumentative link disagrees eri mieltä
argumentative link comments kommentoi commented by kommentoijana
argumentative link defends puolustaa defended by puolustajana
argumentative link attacks hyökkää attacked by hyökkääjänä
argumentative link relevant argument relevantti argumentti Argument is relevant in its context.
argumentative link irrelevant argument epärelevantti argumentti Argument is irrelevant in its context.
argumentative link joke about vitsi aiheesta provokes joke kirvoittaa vitsin This relation is used to describe that the subject should not be taken as information, even though it may be relevant. Jokes are allowed because they may help in creating new ideas and perspectives to an issue.
referential link topic of aiheena has topic aiheesta This is used when the object is a publication and the subject is a (broad) topic rather than a statement. In such situations, it is not meaningful to back up the subject with references. Useful in describing the contents of a publication, or identifying relevant literature for a topic.
referential link discussed in kerrotaan discusses kertoo
referential link reference for viitteenä has reference viite Subject is a reference that backs up statements presented in the object. Used in the same way as references in scientific literature are used.
referential link states väittää stated in väitetään kohteessa Describes the source of a statement; may also refer to a person.
referential link tag for täginä has tag omistaa tägin Subject is a keyword, type, or class for object. Used in classifications.
referential link category for kategoriana has category kuuluu kategoriaan
referential link associates with liittyy Subject is associated with object in some undefined way. This is a weak relation and does not affect the outcomes of inferences, but it may be useful to remind users that an association exists and it should be clarified more precisely. This is its own inverse.
referential link answers question vastaa kysymykseen has answer vastaus Used between a statement (answer) and a topic (question). In knowledge crystals, the relation is embedded in the object structure.
irrelevant argument irrelevant comment epärelevantti kommentti Inverses are not needed, because the relation is always tied with an argument (the subject).
irrelevant argument irrelevant attack epärelevantti hyökkäys
irrelevant argument irrelevant defense epärelevantti puolustus
relevant argument relevant comment relevantti kommentti
relevant argument relevant attack relevantti hyökkäys
relevant argument relevant defense relevantti puolustus
property link evaluative property arviointiominaisuus characteristic of a product or work that tells whether it is fit for its purpose. Especially used for assessments and assessment work.
evaluative property property of decision support päätöstuen ominaisuus What makes an assessment or decision support process fit for its purpose?
evaluative property setting of assessment arvioinnin kattavuus See Table 4.
setting of assessment impacts vaikutukset
setting of assessment causes syyt
setting of assessment problem owner asianomistaja
setting of assessment target users kohderyhmä
setting of assessment interaction vuorovaikutus
interaction dimension of openness avoimuuden ulottuvuus See Table 5.
dimension of openness scope of participation osallistumisen avoimuus
dimension of openness access to information tiedon avoimuus
dimension of openness timing of openness osallistumisen ajoitus
dimension of openness scope of contribution osallistumisen kattavuus
dimension of openness impact of contribution osallistumisen vaikutus
interaction category of interaction vuorovaikutuksen luokka See Table 6. How does assessment interact with the intended use of its results? Possible values: isolated (eristetty), informing (tiedottava), participatory (osallistava), joint (yhteistyöhakuinen), shared (jaettu).
property of decision support quality of content sisällön laatu See Table 3.
quality of content informativeness tarkkuus
quality of content calibration harhattomuus
quality of content coherence sisäinen yhdenmukaisuus
property of decision support applicability sovellettavuus
applicability relevance merkityksellisyys
applicability availability saatavuus
applicability usability käytettävyys
applicability acceptability hyväksyttävyys
property of decision support efficiency tehokkuus
efficiency intra-assessment efficiency sisäinen tehokkuus
efficiency inter-assessment efficiency ulkoinen tehokkuus

Appendix S4: Workspace tools: OpasnetUtils package and Opasnet Base

Ovariable

Ovariable is an object class that is used in R to operationalise knowledge crystals. In essence, impact assessment models are built using ovariables as the main tool to organise, analyse, and synthesise data and causal relations between items. The purpose of ovariables is to offer a standardised, generalised, and modular solution to modelling. Standardised means that all ovariables have the same overall structure, and this makes it possible to develop generalised functions and processes to manipulate them. Modular structure of a model makes it possible to change pieces within the model without braking the overall structure of functionality. For example, it is possible to take an existing health impact model, replace the ovariable that estimates the exposure of the target population with a new one, and produce results that are otherwise comparable to the previous results but differ based on exposure.

What is the structure of an ovariable such that

  • it complies with the requirements of variable and
  • it is able to implement probabilistic descriptions of multidimensional variables and
  • it is able to implement different scenarios?

An ovariable contains the current best answer in a machine-readable format (including uncertainties when relevant) to the question asked by the respective knowledge crystal. In addition, it contains the information needed to derive the current best answer. The respective knowledge crystal typically has an own page at Opasnet, and the code to produce the ovariable is located on that page under subheading Calculations.

It is useful to clarify terms here. Answer is the overall answer to the question asked (including an evaluated ovariable), and it is the reason for producing the knowledge crystal page in the first place. Answer is typically located near the top of the page to emphasise its importance. An answer may contain text, tables, or graphs on the web page. It typically also contains an R code for evaluating the respective ovariable. Output is the key part (technically a slot) of the answer within an ovariable and contains the details of what the reader wants to know about the answer. All other parts of the ovariable are needed to produce the output or understand its meaning. Finally, Result is the key column of the Output table (technically a data frame) and contains the actual numerical values for the answer.

Slots

The ovariable is a class S4 object defined by OpasnetUtils in R software system. An ovariable has the following separate slots that can be accessed using X@slot (where X is the name of the ovariable):

@name
  • Name of <self> (the ovariable object) is useful since R's S4 classes doesn't support self reference. It is used to identify relevant data structures as well as to set up hooks for modifiers such as scenario adjustments.
@output
  • The current best answer to the question asked.
  • A single data frame (a 2D table type in R)
  • Not defined until <self> is evaluated.
  • Possible types of columns:
    • Result is the column that contains the actual values of the answer to the question of the respective knowledge crystal. There is always a result column, but its name may vary; it is of type <self>Result.
    • Indices are columns that define or restrict the Result in some way. For example, the Result can be given separately for males and females, and this is expressed by an index column Sex, which contains locations Male and Female. So, the Result contains (at least) one row for males and one for females. If there are several indices, the number of rows is typically the product of numbers of locations in each index. Consequently, the output may become very large with several indices.
    • Iter is a special kind of index used in Monte Carlo simulations. Iter contains the number of the iteration. In Monte Carlo, the model is typically run 1000 or 10000 times.
    • Unit contains the unit of the Result. It may be the same for all rows, but it may also vary from one row to another. Unit is not an index.
    • Other, non-index columns can exist. Typically, they are information that were used for some purpose during the evolution of the ovariable, but they may be unimportant in the current ovariable if they have been inherited from parent ovariables. Due to these other columns, the output may sometimes be rather wide.
@data
  • A single data frame that defines <self> as such.
  • data slot contains data about direct measurements or estimates of the output. Typically, when data is used, the output can be directly derived from the information given, with possibly some manipulations such as dropping out unnecessary rows or interpreting given ranges or textual expressions as probability distributions.
  • Probability distributions are interpreted by OpasnetUtils/Interpret.
@marginal
  • A logical vector that indicates full marginal indices (and not parts of joint distributions, result columns, or units or other row-specific descriptions) of output.
@formula
  • A function that defines <self> using objects from dependencies as inputs.
  • Returns either a data frame or an ovariable, which is then used as the output of the ovariable.
  • Formula and dependencies slots are always used together. They estimate the answer indirectly in cases when there is knowledge about how this variable depends on the results of other variables (called parents). The slot dependencies is a table of parent variables and their identifiers, and formula is a function that takes the outputs of those parents, applies the defined code to them, and in this way produces the output for this variable.
@dependencies
  • A data frame that contains names and tokens or identifiers for model runs of variables required for <self> evaluation (list of causal parents). The following columns may be used:
    • Name: name of an ovariable or a constant found in the global environment (.GlobalEnv).
    • Key: the run key (typically a 16-character alphanumeric string) of a model run that is stored to Opasnet server. Key to be used in objects.get() function to fetch the dependent object.
    • Ident: Page identifier and rcode name to be used in objects.latest() function where the newest run contains the dependent object. Syntax: "Op_en6007/answer".
    • Also other columns are allowed (e.g. Description), and they may contain additional information about parents.
  • Dependencies is a way of enabling references in ovariables by using function OpasnetUtils/ComputeDependencies. It creates variables in .GlobalEnv environment so that they are available to expressions in formula.
  • Dependent ovariables are fetched and evaluated (only once by default) upon <self> evaluation.
@ddata
  • A string containing an Opasnet identifier e.g. "Op_en1000". May also contain a subset specification e.g. "Op_en1000/dataset".
  • This identifier is used to download data from the Opasnet database for the data slot (by default, only if empty) upon <self> evaluation.
  • By default, the data defined by ddata is downloaded when an ovariable is created. However, it is also possible to create and save an ovariable in such a way that the data is downloaded only when the ovariable is evaluated.
@meta
  • A list of descriptive information of the object. Typical information include date created, username of the creator, page identifier for the Opasnet page with the ovariable code, and identifier of the model run where the object was created.
  • Other meta information can be added manually.

OpasnetUtils and operations with ovariables

OpasnetUtils is an R package found in CRAN repository (cran.r-project.org). It contains tools for open assessment and modelling at Opasnet, especially for utilising ovariables as modelled representations of knowledge crystals. Typically, ovariables are defined at Opasnet pages, and their data and evaluated output are stored to Opasnet server. There are also special user interface tools to enable user inputs before an R code is run on an Opasnet page; for further instructions, see http://en.opasnet.org/w/R-tools. However, ovariables can be used independently for building modular assessment models without any connection to Opasnet.

The example code shows some of the most important functionalities. Each operation is followed by an explanatory comment after # character.

install.packages("OpasnetUtils") # Install the package OpasnetUtils. This is done only once per computer.

library(OpasnetUtils) # Open the package. This is done once per R session.

objects.latest("Op_en4004", code_name="conc_mehg") # Fetch ovariables stored by code conc_mehg at Opasnet page Mercury concentrations in fish in Finland (with identifier 4004)

conc_mehg <- EvalOutput(conc_mehg) # Evaluate the output of ovariable conc_mehg (methyl mercury concentrations in fish) that was just fetched.

dat <- opbase.data("Op_en4004", subset="Kerty database") # Download data from Kerty database on the same page and put that to data.frame dat

a <- Ovariable("a", data=data.frame(Fish=c("Herring","Salmon"), Result=c(1,3))) # Define ovariable for scaling salmon results with factor 3.

mehg_scaled <- conc_mehg * a # Multiply methyl mercury concentrations by the scaling factor.

An ovariable is well defined when there is enough data, code or links to evaluate the output. Ovariables often have upstream dependencies whose output affect the output of the ovariable at hand. Therefore, ovariables are usually stored in a well defined but unevaluated format (i.e. without output). This makes it possible to use the same ovariable in different contexts, and the output varies depending on the upstream dependencies. On the other hand, it is possible to store all evaluated ovariables of a whole assessment model. This makes it possible to archive all details of a certain model version for future scrutiny.

Ovariables have an efficient index handling, which makes it possible to do arithmetic operations such as sums and products in a very simple way with ovariables. The basic idea is that if the outputs of two ovariables have two columns by the same name, they are automatically merged (or joined, using the SQL vocabulary) so that rows are merged iff they have the same location values in those two columns. The same principle applies to all pairs of columns by the same name. After the merge, the arithmetic operation is performed, row by row, to the Result columns of each ovariable. This results in an intuitive handling of outputs using a short and straightforward code.

Recursion is another important property of ovariables. When an ovariable is evaluated, a code checks whether it has upstream dependencies. If it does, those ovariables are fetched and evaluated first, and recursively the dependencies of those ovariables are fetched also, until all dependencies have been evaluated. Case-specific adjustments can be done to this recursion by fetching some upstream ovariables before the first ovariable is evaluated; if an upstream ovariable exists already in the global environment, the existing object is used and the respective stored object is not fetched (dependencies are only fetched if they do not already exist; this is to avoid unnecessary computation).

Decisions and other upstream commands

The general idea of ovariables is such that their code should not be modified to match a specific model but rather define the knowledge crystal in question as extensively as possible under it's scope. In other words, it should answer its question in a reusable way so that the question and answer would be useful in many different situations. (Of course, this should be kept in mind already when the question is defined.) To match the scope of specific models, ovariables can be modified without changing the ovariable code by supplying commands upstream. A typical decision command is to make a new decision index with two scenarios, "business as usual" and "policy" and use the original ovariable result for business as usual and adjust the result for the policy e.g. by adding or multiplying it by a constant reflecting the impact of the policy on the ovariable. Such adjustments can be done on the assessment level without a need to change the ovariable definition in any way.

Evaluating a latent ovariable triggers first the evaluation of its unevaluated parent ovariables (listed in dependencies) since their results are needed to evaluate the child. This chain of evaluation calls forms a recursion tree in which each upstream variable is evaluated exactly once (cyclical dependencies are not allowed). Decision commands about upstream variables are checked and applied upon their evaluation and then propagated downstream to the first variable being evaluated. For example, decisions in decision analysis can be supplied this way:

  1. pick an endpoint ovariable
  2. make decision variables for any upstream ovariables (this means that you create new scenarios with particular deviations from the actual or business-as-usual answer of that ovariable)
  3. evaluate endpoint ovariable
  4. optimize between options defined in decisions.

Other commands include: collapse of marginal columns by sums, means or sampling to reduce data size; and passing input from model level without redefining a whole ovariable.

Opasnet Base

Opasnet Base is a storage database for all kinds of data needed in open assessments. It may contain parameter values for models, which are typically shown as small tables on knowledge crystal pages, from which they are automatically stored to the database. It may also contain large dataset such as research datasets or population datasets of thousands or even millions of rows, and they are uploaded to the database using an importer interface. Each table has its own structure and may or may not share column names with other tables; however, if a table is directly used as data slot for an ovariable, it must have a Result column.

Technically, Opasnet Base is a noSQL database using MongoDB software. Metadata of the tables is stored in a MySQL database. This structure offers the speed, searchability, and structural flexibility that a large amount of non-standard data requires. The database also offers version control, as old versions of a data table are kept in the database when new data is uploaded.

The database also contains data about model runs that have been performed at Opasnet, if objects were stored during that model run. This makes it possible to fetch objects produced by a particular code on a particular knowledge crystal page. Typically the newest version is fetched, but information about the old versions are kept as well. The objects stored are not located in MongoDB but on server files that can be accessed with a key. It is also possible to save objects in a non-public way so that the key is not stored in the database and is only given to the person who ran the code. Due to disc storage reasons, Opasnet does not guarantee that stored objects will be kept permanently; therefore, it is a good practice to store final assessment runs with all objects to another location for permanent archival.

There are several ways to access database content.

For further instructions, see http://en.opasnet.org/w/Opasnet_Base_UI for user interface and http://en.opasnet.org/w/Table2Base for the wiki interface of small tables.

Appendix S5: Tools to help in shared understanding

There are lots of software and platforms to support decision making. Some of them have been listed here. The focus is on open source software solutions when available. Many examples come from Finland, as we have practical experience about them. The list aims to cover different functionalities and show examples rather than give an exhaustive list of all possibilities; such lists may be found from Wikipedia, e.g. https://en.wikipedia.org/wiki/Comparison_of_project_management_software. All links were accessed 1 Feb 2020.

Table S5-1. Useful functionalities and software in open policy practice.
Item Functionality or process phase Tool or software
Decision process Information-based decision support There is no single tool covering the whole decision process. Development work is needed. An interesting pilot software is being developed by the city of Helsinki for comprehensively managing and evaluating their ambitious Climate Watch and its impacts.
Initiative Several websites for launching, editing, and signing citizen initiatives at municipality or national level: Kansalaisaloite (Citizen Initiative), Nuortenideat (Ideas of the Young), Kuntalaisaloite (Municipality Initiatives). Similar tools could be used also for initiatives launched by Members of Parliament or the Government.
Substance Content management Diary systems, file and content management systems. Lots of individual solutions, mostly proprietary. VAHVA project by the Finnish Government will provide knowledge and tools for content management.
Research data and analyses AVAA, IDA, Fairdata and other data management tools help in managing research data from an original study to archival. Avoin data (open data in Finland), platform for publishing open data. Findicator: indicators from all sectors of the society. Datahub for open data sharing. Tools for separate analysis tasks are numerous, e.g. QGIS for geographical data. Several research fields have their own research and article databases, such as ArXiv.org (articles about physics, mathematics and other fields). Several biological databases.
Public discussion, argumentation, statements Otakantaa, Facebook, Twitter, blogs, and other social media forums for discussion. Websites for fact checking: Factbar, Fullfact, Need to know project for fact checking. Agoravoting is an open voting system. Lausuntopalvelu collects statements from the public and organisations related to planned legislation and Government programs in Finland. Swarm AI for collective intelligence
News News feeds (open source) CommaFeed, Tiny Tiny RSS. Semantic, automated information searches, e.g. Leiki.
Description and assessment of decision situations and relevant causal connections Opasnet for performing Open assessments and impact assessments. Knowledge crystals as integral parts of models and assessments. Simantics System Dynamics in semantic models. Jupyter notebooks for collaborative model development. Wikidata, Wikipedia as storages of structured data and information.
Laws and regulations Semantic Finlex contains the whole Finnish legislation and e.g. the decisions by the Supreme Court in a semantic structure.
Methods Preparation of documents, co-creation, real-time co-editing Several co-editing tools, e.g. Hackpad, MS Office365, Google Docs, Etherpad, Dropbox Paper, MediaWiki and Git. These tools enable the opening of the planning and writing phase of a decision. E.g. the climate strategy of Helsinki was co-created online with Google Docs and Sheets in 2018.
Development and spreading good practices InnoVillage helps to develop practices faster, when everyone's guidance is available online and can be commented.
Organising systems for information and discussions Decentralised social networking protocol Activitypub

Tools: Full Fact automated fact checking Compendium. Vocabularies and semantic tools: Resourse Description Framework (RDF), Finto (Finnish Thesaurus and Ontology Service), AIF-RDF Ontology using Conceptual Graphics User Interface COGUI. These act as a basis for organising, condensing and spreading knowledge.

Information design, visualisations Interactive and static visualisations from complex data. Shiny, Diagrammer, Gapminder, Lucify Plotly Cytoscape
Work Work processes in decision making, research etc: follow-up, documentation Ahjo decision repository and Openahjo interface document and retrieve decisions that have been done in the city of Helsinki. Git enables reporting of both research and decision processes. There are several new platforms for improving science, such as Open Science Framework for facilitating open collaboration in research. Omidyar Network is a philantropic investment firm supporting e.g. governance and citizen engagement. Tsampo is a platform for matching questions, funding, and experts.
Co-creation, experiments, crowdsourcing Kokeilun paikka promotes experiments when applicable information is needed but not available. Sociocracy 3.0 provides learning material and principles for open collaboration in organisations of any size.
Project management There are lots of project management software, mainly targeted for enterprise use but somewhat applicable in decision making or research. Some examples: OpenProject, Project Management Body of Knowledge, Comparison of project management software, Fingertip.
Stakeholders Expert services Network of innovators, ResearchGate Solved and other expert networks.

See also

Parts not used

Boundary object is a concept for managing information work within a heterogeneous group of participants[1]. As people come from different disciplines, they see things differently and use different words to describe things. Boundary objects are common words or concepts that are similar enough across disciplines so that they help understanding but allow specific interpretations within disciplines or by individuals. Several dioxin-related knowledge crystals were successfully used as boundary objects in BONUS GOHERR project (Table S2-1) to produce shared understanding among authorities, fishers, and researchers from public health, marine biology, and social sciences.[2]

Shared understanding aims to bring different views together. This is something that is needed especially during this time of polarisation[3]. The open assessments performed have identified more agreements even about heated topics that what seems to be case based on social media. The pneumococcus case is an example of this.

Presenting also controversial and unpopular ideas is a prerequisite for a complete shared understanding. Thus, a community producing shared understanding should cherish and respect such activity and promote contributions even if they are incompatible with scientific or another paradigms. This is challenging to both someone presenting such claims and someone else personally against the presented idea. It helps if all parties have faith in the process and its capability to produce fair conclusions[4]. Therefore, the society should promote the acceptability of open decision processes, open participation, and diverse contributions. Such attitude prevails in the climate strategy of Helsinki, but it was present already five years earlier in Transport and communication strategy in digital Finland (Table S2-1).

Openness does not mean that any kind of organisation or individual is equally prone or capable of using assessment information. Such equity issues are considered as a separate question and are not dealt with in this generic examination.

Openness is crucial because a priori it is impossible to know who may have important factual information or value judgements about the topic.

Open platforms for deliberation of decisions are available (otakantaa.fi, kansalaisaloite.fi), and sharing of code is routinely done via large platforms (ubuntu.com, cran.r-project.org). Also generic online tools such as Google Drive (drive.google.com), Slack (slack.com), and others have familiarised people with online collaboration and idea that information is accessible from anywhere.

ArXiv.org is a famous example of preprint servers offering a place for publishing and discussing manuscripts before peer review[5]. Such websites, as well as open access journals, have increased during recent years as the importance of availability of scientific information has been understood. Using open data storages (ida.fairdata.fi) for research results are often required by research funders.

Aumann's agreement theorem shows that rational Bayesians demonstrates that rational agents with common knowledge of each other's beliefs cannot agree to disagree, because they necessarily end up updating their posterior with that of the other[6]. In this thinking, shared understanding can be seen as an intermediate phase where the disagreements have been identified but the posteriors have not yet been updated to reflect the data that is possessed by the other person.

Acquiescence, i.e. situations where people know that their choice is irrational but they choose it anyway[7]

There is a new political movement (Liike Nyt https://liikenyt.fi/) in Finland that claims that their member of parliament will vote whatever a public online discussion concludes. This approach is potentially close to co-created policy recommendations based on shared understanding. However, they are - at least so far - not using novel information tools or concepts to synthesise public discussions. Instead, they use social media groups and online polls. VIIDEN TÄHDEN LIIKE?

Also, we hypothesise that only a few major paradigms will emerge, and those are ones whose applicability is wide and independent of the discipline. Scientific paradigm is expected to be one of them, and it will be interesting to see what else emerges. People commonly reason against some unintuitive rules of the scientific method (e.g. they try to prove a hypothesis right rather than wrong) but it is not clear whether this will cause a need to develop a paradigm for an alternative approach. It is even not clear whether people are willing to accept the idea that there could be different, competing rules for reasoning in a single assessment or decision process.

Indeed, only 7 % of people contributing to Wikipedia do it for professional reasons[8].

Omidyar Network is an organisation that gives grants to non-profit organisations and also invest in startups that promote e.g. governance and citizen engagement[9]. As an example, they support tools to improve discussion online with annotations[10], an objective similar to with structured discussions.

Additional references to pragma-dialectics[11].

Some experts and politicians seem to see criticism as a threat that should be pre-emptively avoided by only publishing finalised products. In contrast, agile processes publish their draft products as soon as possible and use criticism as a source of useful and relevant information.

Open Science Framework is a project that aims to increase reproducibility in science by developing structured protocols for reproducing research studies, documenting study designs and results online, and producing open source software and preprint services to support this[12]. The Framework maintains a web-workspace for documenting research as it unfolds rather than only afterwards in articles.

Our own experience is the same, and we have not seen hijacking, malevolent behaviour or low-quality junk contributions. However, some robots produce unrelated advertisement material at Opasnet pages, but that is easy to identify and remove, and it has not become a problem.

TO DO

  • A specific link should be available to mean the object itself rather than its description. http://en.opasnet.org/entity/...?
  • All terms and principles should be described at Opasnet at their own pages. Use italics to refer to these pages.
  • Upload Tuomisto 1999 thesis to Julkari. And Paakkila 1999

Suggested editors: Daniel Angus, Özlem Uzuner, Sergio Villamayor Tomás, Frédéric Mertens

  1. Star SL, Griesemer JR. Institutional Ecology, 'Translations' and Boundary Objects: Amateurs and Professionals in Berkeley's Museum of Vertebrate Zoology, 1907-39. Social Studies of Science, 1989; 19 387-420.
  2. GOHERR VIITE työpajapaperi##
  3. Pew Research Center. (2020). U.S. Media Polarization and the 2020 Election: A Nation Divided. https://www.journalism.org/2020/01/24/u-s-media-polarization-and-the-2020-election-a-nation-divided/
  4. Rodriguez‐Sanchez C, Schuitema G, Claudy M, Sancho‐Esper F. (2018) How trust and emotions influence policy acceptance: The case of the Irish water charges. British Journal of Social Psychology 57: 3: 610-629. https://doi.org/10.1111/bjso.12242
  5. Cornell University Library. arXiv.org. https://arxiv.org/. Accessed 1 Feb 2020.
  6. Aumann RJ. (1976) Agreeing to Disagree. The Annals of Statistics. 4 (6): 1236–1239. doi:10.1214/aos/1176343654.
  7. Walco DK, Risen, JL. The Empirical Case for Acquiescing to Intuition. PSYCHOLOGICAL SCIENCE 2017;28:12:1807-1820. doi:10.1177/0956797617723377
  8. Pande M. Wikipedia editors do it for fun: First results of our 2011 editor survey. 2011. https://blog.wikimedia.org/2011/06/10/wikipedia-editors-do-it-for-fun-first-results-of-our-2011-editor-survey/. Accessed 1 Feb 2020.
  9. Omidyar Network. A world of positive returns. http://www.omidyar.com. Accessed 1 Feb 2020.
  10. Hypothesis. Annotate the web, with anyone, anywhere. https://web.hypothes.is/. Accessed 1 Feb 2020.
  11. Eemeren FH van. Reasonableness and effectiveness in argumentative discourse. Fifty contributions to the development of pragma-dialectics. Springer International Publishing Switzerland, 2015. ISBN 978-3-319-20954-8. doi:10.1007/978-3-319-20955-5
  12. Open Science Framework. https://osf.io/. Accessed 1 Feb 2020.