2.1. Parameter design task in product development

Laboratory experiments in which human subjects need to solve parametric design tasks only represent a limited period of time in product development. To illustrate that, consider the process model shown in Figure 2 (Ulrich and Eppinger, Reference Ulrich and Eppinger2015).

Figure 2. Generic (sequential) product development process according to Ulrich and Eppinger (Reference Ulrich and Eppinger2015). Parameter design represents the development work during Detail Design and Testing and Refinement.

According to this stage-gate model, product development processes can be divided into six sequential phases: (i) Planning: assessment of market opportunities and new technologies, (ii) Concept Development: identification of customer needs and specification of product concept, (iii) System-Level Design: definition of product architecture and decomposition of requirements, (iv) Detail Design: specification of component geometries and materials, (v) Testing and Refinement: assembly of prototypes and evaluation of performance and (vi) Production and Ramp-Up: product launch and start of manufacturing.

Parametric or ‘parameter’ design, where the goal is to assign proper values to some (predefined) design variables, corresponds to Detail Design and Testing and Refinement. The definition of geometries and materials during Detail Design, for example, refers to the assignment of values to the design variables by the subjects during an experiment. The assembly and testing of prototypes during Testing and Refinement, on the other hand, refers to the evaluation of a specific set of values that the subjects of an experiment have assigned to the design variables.

In earlier phases of product development, the product architecture is unknown or just about to be specified. In terms of parameter design, this would mean that the design variables themselves and the technical dependencies between them are unknown. Thus, parameter design does not represent this phase.

At the final stage of product development, the design is fully specified (fixed) and only has to be manufactured. In terms of parameter design, this would mean that the values of the design variables are ‘frozen’ and subjects cannot manipulate them anymore. Thus, parameter design does not reflect this phase either.

In summary, parameter design only represents a limited (yet important) phase of product development where the physical properties of components (geometry, material, etc.) are to be specified such that the overall design targets are satisfied. The signposting simulation method proposed by Clarkson and Hamilton (Reference Clarkson and Hamilton2000) and Wynn et al. (Reference Wynn, Eckert and Clarkson2006) also focuses on those later phases of product development. Compared to the research approach used in this paper, however, signposting is an agent-based (computational) framework to investigate product design processes.

2.2. Literature on single-actor studies

A large amount of research focuses on the decision-making of individual subjects, that is, how they probe their design variables if the performance function is unknown and has to be explored through trial and error. The study of Borji & Itti (Reference Borji, Itti, Burges, Bottou, Welling, Ghahramani and Weinberger2013), for instance, presents an experiment in which 23 subjects are asked to identify the optimum of an arbitrary 1-D function by using experimentation. They reveal that human search is similar to Bayesian optimisation based on Gaussian processes. The impact of cost and task complexity on the decision-making of single subjects is studied by Chaudhari & Panchal (Reference Chaudhari and Panchal2019). Based on a similar experimental setup, they are able to show that both factors only affect the decision when to stop searching, not the actual search strategy itself. In a context-related study (where specialised domain knowledge is required in order to solve the task), Yu, de Weck, & Yang (Reference Yu, de Weck and Yang2016) analyse the behaviour of 22 subjects who are asked to design a seawater reverse osmosis plant by using 10 key design variables. Compared to previous results, they reveal that the decision-making of top ranked subjects can be compared to a well-tuned simulated annealing algorithm, which is a meta-heuristic optimisation technique that applies exploration and exploitation. An analysis of the task completion time with respect to the task size for parametric, context-free design problems is done by Hirschi & Frey (Reference Hirschi and Frey2002). After introducing a concept called parameter design, the authors conduct an experimental study with 12 subjects that solve a series of coupled and uncoupled parameter design tasks with 2, 3, 4 and 5 design variables. It is shown that both the coupling and the task size have a significant effect on the task completion time. For a context-related design problem, similar results are obtained by Flager, Gerber, & Kallman (Reference Flager, Gerber and Kallman2014). In their study, subjects are asked to design a building by manipulating 2–6 design variables that are inside of a user interface which also shows a graphical representation of the object. It turns out that larger design tasks lead to a lower solution quality if the time available to solve a design task is held constant.

The effect of varying response times, that is, delays between the moment subjects manipulate an input variable and observe the effect, is investigated by Goodman & Spence (Reference Goodman and Spence1978). Based on their study, in which 30 subjects are allowed to use 5 design variables in order to fit a curve into a predefined area, a response time of 1.49 seconds can already cause an increase in task completion time of 50%. This is further examined by Simpson et al. (Reference Simpson, Iyer, Rothrock, Frecker, Barton, Barron and Meckesheimer2005), who, based on a set of experiments where subjects need to manipulate 2, 4 or 6 design variables to find an appropriate wing design, claim that the response time, which is varied during the study, does not only affect the task completion time but also the design effectiveness (i.e., the error between the submitted design and the optimum). In their case, a 1.5 seconds response time induces a 150% error. Others, like Simpson et al. (Reference Simpson, Barron, Rothrock, Frecker, Barton and Ligetti2007), even note a 280% decrease in design effectiveness for the same response time. A variety of investigations, such as Simpson et al. (Reference Simpson, Barron, Rothrock, Frecker, Barton and Ligetti2007) or Egan et al. (Reference Egan, Schunn, Cagan and LeDuc2015), also examine the graphical representation of parametric design tasks (text-based versus graphical, static versus animated). Their conclusion is that rich GUI’s increase the subjects’ performance.

In summary, research on parametric single-actor studies provides an extensive body of knowledge on how individual designers act in complex design scenarios. Yet, most products are not developed by a single person but by a whole group of people who must collaborate. Studies on this issue are reviewed in the following.

2.3. Literature on multi-actor studies

It appears as if considerably less research revolves around quantitative multi-actor studies than around quantitative single-actor studies. One for our work important contribution, however, is the research undertaken by Grogan & de Weck (Reference Grogan and de Weck2016). They perform a series of experiments in which 10 groups of 3 subjects each solve 42 coupled and uncoupled parameter design tasks which are defined according to the approach suggested by Hirschi & Frey (Reference Hirschi and Frey2002). By varying the technical and social complexity, that is, the number of variables and subjects involved, it is shown that collaboration, which means the team work that is required when design tasks are solved by more than one subject, increases the completion time significantly. If three subjects are involved instead of one, for example, they note a 90% higher task completion time. A further examination of the raw data obtained by Grogan & de Weck (Reference Grogan and de Weck2016) is performed by Alelyani, Yang, & Grogan (Reference Alelyani, Yang and Grogan2017). They suggest multiple regression models for subject-specific performance metrics, like the total number of design iterations or the number of design iterations during which the distance to the target area is reduced, depending on complexity and gender. The research of Austin-Breneman, Honda, & Yang (Reference Austin-Breneman, Honda and Yang2012) deals with game-theoretic experiments in which subjects in groups of 3 have to solve a parametric satellite design task with design variables on multiple hierarchical levels. According to their results, subjects have difficulties to understand the connection between subsystems as they often falsely assume that their design decisions are divisible and independent. The authors also mention that subjects normally focus more on the individual subsystems than the system-level perspective. This, in fact, emphasises the importance of coordinated integration and verification processes which allow to assess product properties on the system level that are influenced by design variables on lower levels, such as the different sub(sub)system levels and the component level.

Instead of investigating the influence of collaboration between subjects, some studies also examine the effect of competition between multiple subjects by using parametric multi-actor design tasks, for example, Sha, Kannan, & Panchal (Reference Sha, Kannan and Panchal2014). In their work, subjects in groups of 2 compete against each other by minimising an unknown, randomly generated function that depends on a single design variable, while each trial, that is, change of the design variable, comes at a specific cost. The authors state that, for example, the cost per trial has a significant effect on how many times each subject probes its function. Similar findings are presented by Panchal, Sha, & Kanna (Reference Panchal, Sha and Kanna2017). They additionally notice that individuals shift their search strategies from exploration to exploitation, which in some sense confirms that human behaviour is similar to a well-tuned simulated annealing algorithm (Yu et al. Reference Yu, Honda, Sharqawy and Yang2016), and that the solution subjects assume their opponent has is at least as good as the real optimum of the function. Finally, McComb, Cagan, & Kotovsky (Reference McComb, Cagan and Kotovsky2015) perform an experimental study in which 48 subjects in groups of 3 solve a truss design problem where some requirements at the system level are modified during the task. Based on their results, successful groups tend to use different problem-solving techniques in a sense that they select more simple designs and search focused areas of the design space.

4.1. Established groundwork in parameter design

Parameter design is a quantitative approach to investigate development processes based on surrogate design tasks that are solved either by individuals or groups of subjects, while the required completion time is captured and evaluated regarding different process performance metrics. Our notation is adopted from Grogan & de Weck (Reference Grogan and de Weck2016). In each surrogate design task, a set of input variables, denoted as $ \mathbf{x} $ , can be altered in order to manipulate a set of output variables, denoted as $ \mathbf{y} $ , for which design goals (requirements) are specified. The mapping between input and output variables, that is, the technical dependencies between them, is defined by the coupling matrix M. Based on this, each system model can be described as:

(1) $$ \mathbf{y}=\mathbf{Mx}. $$

As in previous studies (Hirschi & Frey Reference Hirschi and Frey2002; Grogan & de Weck Reference Grogan and de Weck2016), we assume linear dependencies between the input and output variables (note that this is a strong assumption as real-world systems are often nonlinear). If the number of input variables is $ N $ and the number of output variables is $ K $ , Eq. (1) becomes

(2) $$ \mathbf{y}=\mathbf{Mx}\Rightarrow \left[\begin{array}{c}{y}_1\\ {}\vdots \\ {}{y}_K\end{array}\right]=\left[\begin{array}{ccc}{m}_{11}& \cdots & {m}_{1N}\\ {}\vdots & \ddots & \vdots \\ {}{m}_{K1}& \cdots & {m}_{KN}\end{array}\right]\left[\begin{array}{c}{x}_1\\ {}\vdots \\ {}{x}_N\end{array}\right]. $$

For simplicity, our analysis is restricted to $ N=K $ (i.e., same number of input and output variables), which, as before, is in line with the procedure of former studies. In uncoupled design tasks, only the diagonal elements of M are nonzero numbers. This means that each output variable $ {y}_i $ only depends on the corresponding input variable $ {x}_j $ and the dependency $ {m}_{ij} $ . Fully coupled systems, on the other hand, are characterised by coupling matrices M that include nonzero elements only, which means that $ {m}_{ij}\ne 0\forall i,\hskip0.35em j. $

Tasks in parameter design are usually defined context free, which means that no domain-specific expertise or expert know-how is needed in order to solve them. This is essential for experimental studies in which the effect of special knowledge shall be excluded, like in this paper.

An important measure to characterise the coupling strength of a system is the design matrix trace, which, according to Hirschi (Reference Hirschi2000), compares the magnitude of all diagonal elements to the Euclidean norm of all elements of the coupling matrix if $ N=K $ (in our case, the coupling strength lies between 0.11 and 1.41):

(3) $$ t(\mathbf{M})=\frac{\sum \limits_{i=1}^N\mid {m}_{ii}\mid }{\sqrt{\sum \limits_{i,j=1}^N{m}_{ij}^2}}. $$

Note that this definition is not the same as the established mathematical definition of a trace. In the following, any use of this term refers to Eq. (3).

The target values assigned to all output variables are denoted as $ {\mathbf{y}}^{\star } $ . A design task is considered to be solved if the error function E, which we assume to be the distance between each output variable and the corresponding target value, which means

(4) $$ {\mathrm{E}}_i=\left\{|{y}_i-{y}_i^{\star }|\right\}, $$

is less than or equal to the given error tolerance $ {\mathbf{E}}^{\star } $ , meaning that:

(5) $$ \mathbf{E}\left(\mathbf{y},{\mathbf{y}}^{\star}\right)\le {\mathbf{E}}^{\star }. $$

By assigning an identical error tolerance to all output variables, that is, $ {\mathrm{E}}_i^{\star }=\varepsilon $ , the problem statement for each surrogate design task can be formulated as:

(6) $$ \mathrm{find}\;\mathbf{x},\hskip0.5em s.t.|\sum \limits_j{m}_{ij}{x}_j-{y}_i^{\star }|\le \varepsilon,\;\forall i. $$

In single-actor design scenarios, all input and output variables are assigned to the same subject. This means one actor controls all $ {x}_j $ and, at the same time, monitors the influence on all $ {y}_i $ . In case of multi-actor design scenarios, however, input and output variables are distributed among multiple subjects. Thus, one actor might observe a change in its output variable $ {y}_i $ , which is caused by a change of an input variable $ {x}_j $ that is controlled by a different actor. To formalise the assignment of input and output variables, two binary matrices, $ \mathbf{I} $ and $ \mathbf{O} $ , can be used. The matrix $ \mathbf{I} $ , with the dimension $ n\hskip1em \times \hskip1em N $ , where $ n $ represents the number of subjects, describes the mapping of subjects to input variables. Each entry $ {I}_{sj} $ is defined as:

(7) $$ {I}_{sj}=\left\{\begin{array}{ll}1,& \mathrm{if}\ \mathrm{output}\hskip0.3em j\hskip0.3em \mathrm{is}\ \mathrm{assigned}\ \mathrm{to}\ \mathrm{subject}\hskip0.3em s,\\ {}0,& \mathrm{else}.\end{array}\right. $$

In a similar way, the matrix $ \mathbf{O} $ , with the dimension $ n\times K $ , represents the mapping of subjects to output variables. Each entry $ {O}_{si} $ is defined as:

(8) $$ {O}_{si}=\left\{\begin{array}{ll}1,& \mathrm{if}\ \mathrm{input}\hskip0.3em i\hskip0.3em \mathrm{is}\ \mathrm{assigned}\ \mathrm{to}\ \mathrm{subject}\hskip0.3em s,\\ {}0,& \mathrm{else}.\end{array}\right. $$

4.2. Modelling integration and verification phases

In previous studies with a focus on multi-actor parameter design, such as the one from Grogan & de Weck (Reference Grogan and de Weck2016), the flow of information between subjects was assumed to be instantaneous. This means that any change in an input variable was directly mapped onto all output variables. Real-world product design processes, however, are usually characterised by phases in which stakeholders work isolated from each other, without constant feedback on design changes until an integration and verification takes place. This means that the information flow across domain interfaces is blocked for some time during which stakeholders potentially rely on obsolete design information.

In the automotive industry, for example, subsystems, like the engine, gear-box or body, are developed by distributed design teams, who eventually do not receive any design update from others for several weeks or even months. At some point, these subsystems are then geometrically assembled and used as input for different system simulations based on the finite element method (FEM), computational fluid dynamics (CFD) or multibody simulation (MBS), see Wöhr et al. (Reference Wöhr, Königs, Ring and Zimmermann2020). This is an integration. Once the simulations are completed, the results are compared to the given requirements (e.g., some crash performance). This is a verification.

In order to incorporate these three phases, we extend the existing framework by dividing each parameter design experiment into three phases that are repeated periodically: (i) isolated design, (ii) integration and (iii) verification.

During isolated design, subjects manipulate their input variables to meet the design targets (requirements + error tolerances) of their output variables, without exchanging design information with other subjects. This means that, first, design changes related to the own input variables do not affect output variables assigned to others, even if they depend on it. And, second, design changes related to input variables that are assigned to other subjects do not affect the own output variables, even if they depend on it. In essence, information flow across domain interfaces is blocked during that time. To formalise this, we suggest a mathematical extension of the parameter design framework: for each subject there is a local representation of the entire system model, consisting of $ {\mathbf{x}}^s=\left[{x}_1^s,\dots, {x}_N^s\right] $ and $ {\mathbf{y}}^s=\left[{y}_1^s,\dots, {y}_K^s\right] $ . Just as before, $ {\mathbf{x}}^s $ and $ {\mathbf{y}}^s $ are related by:

(9) $$ {\mathbf{y}}^s={\mathbf{Mx}}^s. $$

Within $ {\mathbf{x}}^s $ and $ {\mathbf{y}}^s $ , a subject still only controls the input variables and monitors the output variables that he or she is assigned to according to $ \mathbf{I} $ and $ \mathbf{O} $ . The remaining entries are interim values that originate from the last integration and verification.

During integration, the latest status of all input variables is assembled based on each local representation of $ \mathbf{x} $ and the assignment of subjects to input variables stored in $ \mathbf{I} $ . First, each local representation is preconditioned (i.e., turned into $ {\tilde{\mathbf{x}}}^s $ ), such that only the entries a subject is responsible for remain:

(10) $$ {\tilde{x}}_j^s=\left\{\begin{array}{ll}{x}_j^s& \mathrm{if}\hskip0.24em {I}_{sj}=1,\\ {}0& \mathrm{if}\hskip0.24em {I}_{sj}=0.\end{array}\right. $$

The most recent design, denoted as $ {\mathbf{x}}^{\prime } $ , is identified based on all $ {\tilde{\mathbf{x}}}^s $ :

(11) $$ {\mathbf{x}}^{\prime }=\sum \limits_{s=1}^n{\tilde{\mathbf{x}}}^s. $$

The result $ {\mathbf{x}}^{\prime } $ is then used to compute the most recent system performance $ {\mathbf{y}}^{\prime } $ , that is, the current status of all output variables, based on Eq. (1).

During verification, the most recent system performance is then compared to the design targets, see Eqs. (4) and (5), in order to evaluate whether the design task is solved. If this is the case, the experiment is terminated. If it is not the case, each local representation of $ \mathbf{x} $ and $ \mathbf{y} $ is updated based on the most recent design ( $ {\mathbf{x}}^{\prime } $ ) and the most recent system performance ( $ {\mathbf{y}}^{\prime } $ ), which means that:

(12) $$ \left\{{\mathbf{x}}^s={\mathbf{x}}^{\prime}\right\}\forall s, $$

and:

(13) $$ \left\{{\mathbf{y}}^s={\mathbf{y}}^{\prime}\right\}\forall s. $$

After this, the next isolated design phase begins.

Note that subjects are not actively involved during integration and verification, that is, the computations during both phases are performed automatically without any interference or intervention. In reality, this might be quite different, as integration and verification phases usually require intense human effort and additional labour in order to process all of the design information (see description of detailed design work during each integration and verification step in introduction of this paper). For simplicity, we neglect the specific activities performed during both phases.

Each phase, that is, isolated design, integration and verification, has a predefined duration: $ {t}_{iso},{t}_{int}\hskip0.22em \mathrm{and}\hskip0.22em {t}_{ver} $ . In our case, both the integration and verification occur instantaneously (i.e., $ {t}_{int}={t}_{ver}=0s $ ). The duration of isolated design, on the other hand, is varied between 0, 3, 6, 9 and 12 seconds. Note that in case of 0 seconds, each design change, that is, update of $ {\mathbf{x}}^s $ and $ {\mathbf{y}}^s $ , performed by any of the subjects is automatically followed by an integration and verification phase. This means each local design modification triggers a system assembly and requirement evaluation. The setup $ \hskip0.1em {t}_{iso}={t}_{int}={t}_{ver}=0\hskip0.1em s $ corresponds exactly to the information exchange conditions used by Grogan & de Weck (Reference Grogan and de Weck2016). We associate lower values of $ {t}_{iso} $ with higher integration and verification frequencies (and vice versa).

Surrogate design tasks and the assignment of variables can be visualised with attribute dependency graphs (or ADGs), see (Zimmermann et al. Reference Zimmermann, Königs, Niemeyer, Fender, Zeherbauer, Vitale and Wahle2017; Rötzer et al. Reference Rötzer, Schweigert-Recksiek, Thoma and Zimmermann2022). According to this concept, physical properties of a technical system, such as the input and output variables in parameter design, are shown as vertices and the dependencies between them, such as the linear functions that we assume, are shown as edges. The colours reveal who controls and monitors which variable. Figure 3a, for example, shows a simple single-actor design task with two input and two output variables which are controlled and monitored by the same subject. This is representative for the research of Hirschi & Frey (Reference Hirschi and Frey2002). A multi-actor design task with two input variables and two output variables that are split among multiple subjects is depicted in Figure 3b. This is representative for the research of Grogan & de Weck (Reference Grogan and de Weck2016). By contrast, the setting of this work is visualised in Figure 3c. In this case, it is not possible to represent a design task by using a single ADG because the current state of design is controlled by various subjects who (partially) work isolated from each other.

Figure 3. Attribute dependency graphs (ADGs) representing different design tasks which are used in: (a) Hirschi & Frey (Reference Hirschi and Frey2002), (b) Grogan & de Weck (Reference Grogan and de Weck2016) and (c) this work.

4.3. Software implementation and user interface

Our new approach (for the investigation of integration and verification processes) is integrated into an existing open-source software devised by Grogan (Reference Grogan2019). In its original state, the software, which contains a front-end and back-end, supports parameter design experiments that are focused on single- and multi-actor settings with varying degrees of technical and social complexity. For this study, we added an algorithm to the back-end which organises the three recurring phases: isolated design, integration and verification. It is set up in a way that allows the duration of isolated design to be varied independently.

The unmodified front-end, or GUI, of the software architecture for a subject who controls one input variable and monitors one output variable is depicted in Figure 4. It contains two sliders: a vertical one for the input variable and a horizontal one for the output variable. The relative position of both equals the status of $ {\mathbf{x}}^s $ and $ {\mathbf{y}}^s $ . Adjusting the output slider (during isolated design) is only possible by manipulating the input slider which, in turn, can be controlled by drag-and-drop or by clicking the buttons on the top or bottom. As in previous studies, changes made to the input slider (during isolated design) are instantly mapped onto the output slider (of the own GUI) without a delay. Two small lines below the output slider show the target area. If a subject reaches that area during a multi-actor experiment, however, it does not automatically mean that the overall design task is solved, as others may still try to reach their design goals. Yet, those might be unachievable due to the latest input variables they received. Whether or not the local design goals of a subject are currently satisfied is shown by a green tick or a red cross on the right-hand side of the interface. A maximum duration is specified for each design task after which an experiment is terminated. The time remaining to solve a design task is displayed in the upper right corner. Note that each subject is only permitted to observe his or her own GUI. The aim of this is to simulate the communication barriers and limited information exchange inherent to distributed design processes.

Figure 4. Graphical user interface of the open-source software from Grogan (Reference Grogan2019).

During isolated design, only the subjects themselves can cause a movement of their output slider by manipulating their input slider. This allows them to probe different designs in order to anticipate the dependency between $ {\mathbf{x}}^s $ and $ {\mathbf{y}}^s $ without receiving constant feedback (possible disturbance) resulting from design changes made by others. During each integration phase, the output sliders of all subjects are then updated based on the latest $ {\mathbf{y}}^{\prime } $ . The new positions of all output sliders are then compared to the target intervals during each verification phase. Again, note that both of these phases occur instantaneously and the subjects are not involved. It can be assumed that time delays caused by network latencies are small and so have no impact on the results.

In an attempt to establish the same boundary conditions as in previous studies (see Hirschi & Frey (Reference Hirschi and Frey2002) as well as Grogan & de Weck (Reference Grogan and de Weck2016)) subjects are not informed about the dependencies between the input and output variables ( $ \mathbf{M} $ ), the assignment of subjects to input and output variables ( $ \hskip0.1em \mathbf{I} $ , $ \mathbf{O}\hskip0.1em $ ) and the numeric values of the own input and output variables during an experiment. The GUI includes all the information that subjects are aware of in the course of an experiment. The aim of this is to prevent any reverse engineering that might allow subjects to solve design tasks analytically.

4.4. Design of experiments and procedural setup

Selection of design tasks

Based on the theoretical foundation, we conduct two series of experiments: first, a single-actor study with the goal to replicate previous results obtained by Hirschi & Frey (Reference Hirschi and Frey2002) and Grogan & de Weck (Reference Grogan and de Weck2016). This step allows us to confirm earlier findings and, thus, approve the reliability of our setup. As in both of those studies, we use design tasks with 2, 3 and 4 input and output variables that are all assigned to the same subject. This can be expressed as $ n=1 $ (number of subjects) and $ 2\leqslant N,\hskip0.4em K\leqslant 4 $ (number of input and output variables). All of the three design scenarios in the first experimental series, for which the original parameter design framework and initial open-source software is used, are shown in Figure 5a–c. In a second multi-actor study, we then analyse the effect of varying time intervals between each integration and verification by using design tasks with two input variables, two output variables ( $ N,\hskip0.2em K=2 $ ) and two subjects ( $ n=2 $ ). Each subject is responsible for one of the input and output variables. This scenario is illustrated in Figure 5d. At this point, we apply the extended parameter design framework and the adjusted open-source software outlined above to vary the time span between each integration and verification between 0, 3, 6, 9 and 12 seconds.

Figure 5. Attribute dependency graphs (ADGs) representing different design tasks in our experimental study: (a), (b), (c) single-actor study and (d) multi-actor study.

Subjects and procedure

A total of 34 subjects from an automotive manufacturing company participated in the experiments, which were conducted virtually via an online communication platform. All subjects, whose demographic data are shown in Table 1, received an email containing basic information about the study together with an invitation to take part on a voluntary basis. None of them received compensation. All subjects were divided into groups of 2 and then assigned to a 90 minute time slot (session), arranged based on their availability. At the beginning of each session, each group was introduced to the user interface (GUI), familiarised with the objective of the study and informed about the rules. Rules contained two major requests: first, not to use any external tool, such as pen and paper, or a calculator (even if numeric values were not displayed) to further reduce the risk of reverse engineering and, second, not to engage in any form of communication, for example, talking or messaging, since we observed in a preliminary study that conversations among subjects can affect the dynamics of experiments considerably, especially if individual subjects dominate others and attempt to coordinate the decision process. Finally, multiple training rounds were performed to enable the subjects to become accustomed to the experimental setup and the given rules.

Table 1. Demographic data of the subjects who took part in the single- and multi-actor study. Data was reported by the subjects themselves. Note that only 32 of the 34 subjects participated in the multi-actor study

Then, the main part of each session began. This included a set of single-actor experiments done individually and simultaneously, along with a set of multi-actor experiments, done in pairs. A list of all design tasks presented to the subjects is given in Table 2. In both studies, the order of tasks was randomised to prevent any learning or adaptation of behaviour during the experiments. There were, however, two exceptions: the 4 × 4 design tasks were not presented at the beginning of the single-actor study, and the design tasks with 12 seconds between each integration and verification were not presented at the beginning of the multi-actor study. This was done in order not to overstress, confuse or demotivate the subjects by giving them a challenging task right away. It can be assumed that these exceptions had a negligible effect and that the randomisation negated any influences that might have been caused by the order of the design tasks. Each set of repetitions (three per task size and three per interval) was performed together.

Table 2. Experimental procedure of the single- and multi-actor study. 2 × 2 design tasks have 2 input variables and 2 output variables, 3 × 3 design tasks have 3 input variables and 3 output variables and 4 × 4 design tasks have 4 input variables and 4 output variables

Before each experiment in the multi-actor study, the subjects were informed about the current time interval between each integration and verification to enable them to anticipate when design information is to be shared (like in reality). After each session, a qualitative evaluation sheet was sent to the subjects, in which they could give feedback and explain their decision-making.