5.1. H1: Evidence of design heuristic use

In the majority of the cases, the participants did not explicitly articulate their cognitive processes as they worked; however, use of design heuristics was very evident in the protocols. For example, in one protocol, the designer remarked, ‘I’ll use both a magnifying glass and a mirror, since I’m not sure if the energy will be enough to cook the food.’ This was coded as an indication of the design heuristic: Using multiple components to achieve one function. The designers’ sketches also provided evidence of design heuristic use within the specifications of products, the contexts of product use in sketches, and in the relationship of concepts in a sequence. Thus, both verbal and visual (sketched) data were considered for evidence of heuristic use.

The number of design heuristics evident within each concept was coded. This began with a base set of design heuristics from previous studies (Yilmaz & Seifert Reference Yilmaz and Seifert2010, Reference Yilmaz and Seifert2011). The coders, one with a background in industrial design and the other in engineering design, also added new design heuristics to better describe the concepts apparent in the protocols. The coders reviewed the entire dataset independently and then resolved any disagreement through discussion. Initial inter-rater agreement was 80% across the protocols.

Figure 5. The frequency of concepts with a given number of design heuristics observed within each.

Of the 129 separate concepts generated, only 3 (2%) showed no evidence of design heuristic use. This high proportion of concepts where design heuristics are apparent suggests the approach successfully characterizes important aspects of the designers’ concepts. The average number of design heuristics per concept was 5.1, and ranged from 0 to 15. Figure 5 shows that the mode was four heuristics per concept (19 concepts), and 58 of the 129 concepts (45%) exhibited between three and five heuristics. Fifteen concepts (12%) exhibited nine or more heuristics per concept.

The mean number of design heuristics per concept for the engineers was 5.37 and the mean for the industrial designers was 4.82. This difference was not statistically significant either by two-sample $t$ test or a random effects model that took into account multiple concepts per participant. Participants not only used design heuristics in their concept generation, but most frequently, used multiple heuristics within each concept.

For both engineers and industrial designers, one of the most commonly applied design heuristics was Attach independent functional components, where several different parts or systems with distinct functions are combined in a single device. Using this heuristic, some designers in both groups appeared to define each function independently, assign a form to each, and add a connection between the parts to create a concept. For example, as shown in Figure 6 a, an engineering designer attached the handle to the pot and the light-focusing lens, and in Figure 6 b, an industrial designer attached a continuous mirror inside the pot.

Figure 6. Examples using the design heuristic: Attach components that have different functions.

The other most common design heuristics for both groups were as follows: Cover/Form Shell/Wrap surface for another use, Elevate or lower product base, and Repeat a component; all were used more than 50 times. The least frequently observed design heuristics were the following: Design user activities to unite as a community, Include users in customizing the product, Texturize surface, Expose/Uncover internal components, Substitute an existing component with a new design, Use a common base to hold multiple components, and Adjust functions to needs of differing demographics; each was used only once. These differences appear to arise from the applicability of each design heuristic to specific functions within the solar cooker design problem. Thus, the content of the problem seemed to impact heuristic use.

The protocols replicated evidence of most of the design heuristics previously identified (Yilmaz & Seifert Reference Yilmaz and Seifert2010, Reference Yilmaz and Seifert2011). In previous studies, over 70 different heuristics were observed (Daly et al. Reference Daly, Yilmaz, Christian, Seifert and Gonzalez2012c ), but only 53 heuristics were observed in this study. This is likely due to the smaller number of participants and single-problem context in this study. For example, in order to apply the heuristic Use packaging as a functional component within the product, an existing concept is required.

In sum, heuristics were identified 659 times in the 24 individual protocols. The total number of heuristics per concept ranged from 1 to 15 for industrial designers and 0 to 12 for engineers. Both groups of participants used multiple heuristics within a single concept (64 concepts for industrial designers and 61 for engineers). Concepts without any heuristics, or with only one heuristic, were either very simple solutions (i.e. a plate capturing sunlight), were vague and undefined, or were redrawings of existing products. Supporting Hypothesis 1, designers showed evidence of design heuristic use in their concepts.

5.2. H2: Relationship of design heuristic use to creativity and concept diversity

To examine the relationship between design heuristics and the creativity of concepts, we used the consensual assessment technique (CAT) (Amabile Reference Amabile1982). Two coders blind to the heuristic analysis (different from those who coded heuristics) with backgrounds in industrial design and mechanical engineering rated each concept from all participants on a scale from 1 (not creative) to 5 (very creative). The Pearson correlation between the two coders was $r=0.87$ (an acceptable level of reliability), so their creativity ratings were averaged. For each participant, the creativity score across all of their concepts was determined, along with the average number of heuristics used in each concept (Table 2). There was no significant difference between the creativity ratings of concepts by industrial and engineering designers.

A simple count of the number of different concepts generated by each individual is a measure of fluency commonly used in tests of creativity (e.g., Torrance Reference Torrance1972). However, more concepts did not appear to be an indicator of more creative concepts in this study. An individual’s total number of concepts and their creativity ratings (averaged over their set of concepts) were not statistically related, $r=0.10$ , n.s. This may be due to the relatively small number of concepts generated (averaging less than 6) in this task paradigm; other paradigms with longer work time may result in generating tens of concepts, as in the Torrance (Reference Torrance1972) tests.

Industrial designers generated more concepts on average than engineers, but the difference was not significant ( $t<1$ ). Similarly, the industrial designers used more heuristics per concept than the engineers, but this difference was also not significant ( $t=1.1$ , n.s.).

However, the Pearson correlation between the average creativity scores and the number of design heuristics coded for each concept was $r(127)=0.51$ , $p<0.001$ . (The Spearman correlation was also 0.51, so we report Pearson correlations throughout.) We also conducted a multilevel regression to address non-independence due to subjects contributing multiple concepts to the analysis. Using the number of heuristics as a predictor of creativity rating, the relationship remains highly significant, $p<0.0001$ . Correlations of similar magnitude are observed within each of the two fields (industrial designers: $r=0.51$ ; engineers: $r=0.54$ ). This indicates a substantial, positive relationship between the use of heuristics within a concept and the separately rated creativity of concepts. It was the presence of heuristics, and not simply the number of concepts generated, that was found to relate to higher creativity ratings.

The diversity of the concepts generated by each designer was analyzed as a set for each participant. The coders again used a five-point Likert scale ( $1=\text{not diverse}$ , $5=\text{very diverse}$ ) to rate the set generated by each participant. The Pearson correlation between the two raters on diversity was $r=0.66$ , which is a relatively low reliability; to improve consistency, we averaged the coder’s diversity ratings. We also applied relevant structural equation models to take into account the relatively low reliability of the diversity ratings. These models led to the same decisions with respect to statistical significance, so we report the analyses using the simpler averaged diversity rating scores. No statistically significant differences were observed between the diversity ratings of industrial designers compared to the engineering designers (see Table 2).

Considering designers’ concept sets, neither diversity nor creativity measures were strongly related to the number of concepts in the set ( $r=-0.10$ and 0.16, respectively, n.s.). Perhaps surprisingly, generating more concepts was not related to the higher creativity or diversity of ideas. However, creativity and diversity (when entered into a multiple regression as two additive predictors) were both significantly associated with the number of design heuristics used in the concept set (creativity: $beta=2.75$ , $t(21)=4.41$ , $p=0.0002$ and diversity: $beta=-1.15$ , $t(21)=-3.48$ , $p=0.002$ ).

Comparing these scores across participants demonstrated the same positive relationship between creativity ratings and the use of design heuristics seen for the concept level analysis, $r=0.55$ , $p<0.005$ . The opposite trend occurred between concept set diversity and the use of design heuristics ( $r=-0.38$ , $p<0.063$ , marginally significant). Using design heuristics was negatively related to concept set diversity ratings. This pattern may have occurred because individuals who used multiple heuristics in generating concepts may have developed an idea through subsequent concepts, resulting in a set that shared common features and so received lower diversity scores.

The correlation between average creativity scores and average diversity scores for each participant was 0.20, $p=0.35$ . This suggests diversity of concepts and their creativity reflect different qualities of the designs, as shown by the differences in their relationships to the use of design heuristics.

In sum, ratings of the diversity within a concept set were marginally related to fewer heuristics used (on average) within the set. Considering the concepts as a set and independently, perceived creativity was related to more frequent use of design heuristics in concept generation. When a concept included more heuristics, the subjective creativity rating tended to be higher. Thus, Hypothesis 2 is supported for creativity of concepts, but not for diversity of concept sets.

5.3. H3: Comparing design heuristic use across design disciplines

On the main measures of the study, there were many similarities between the outcomes of the design processes for engineering and industrial designers. They generated a similar number of concepts as a group, and on average, shared similar ratings of the creativity and diversity of their concepts. They also rated their own performance similarly (ID: $\text{M}=5.0,~\text{SD}=1.48$ ; ENG: $\text{M}=5.1,~\text{SD}=0.996$ ) along with their creativity in the study (ID: $\text{M}=5.0,~\text{SD}=1.54$ ; ENG: $\text{M}=4.5,~\text{SD}=1.2$ ); $t<1.0$ , n.s. However, industrial designers used 24% more design heuristics within their concepts. This suggests design heuristics may be somewhat more familiar to, or at least somewhat more likely to be used by, industrial designers.

Of the 53 design heuristics observed in this study, 8 showed significant differences in their frequency of use between the two groups of designers. Table 3 presents the 53 design heuristics observed in the concepts separately for engineering and industrial designers, and a statistical comparison of frequency between the two groups of designers. Fisher’s exact test (two-tailed) is used throughout, with a significance level of $p<0.05$ . Of course, if the null hypothesis is true and each of these 53 tests is independent, we would expect about two or three significant results; we observe eight. If we apply a stricter criterion to address the multiple comparison problem by raising the bar with a Type I error rate of 0.01, we observe four significant results (approximately one result is expected by chance under independence); if we apply an even stricter criterion of 0.001, which roughly corresponds to Bonferroni’s correction under independence, we observe two significant results. We point out that the results indicate mostly similarity between the two groups, with a few potentially important differences between engineers and industrial designers. These potential differences should be explored in future research.

Some interesting differences in design heuristic use are evident in these findings. Industrial designers used more design heuristics than did engineering designers (365 vs. 294). This difference seems to be due to the number of criteria brought into the problem. For example, one industrial designer said: ‘What else…. I will have to think about kids maybe. When you are a child, you play with your friends and you know, mimic your mom’s cooking…’, and she continued by adding more criteria: ‘it’s like making it more portable and then very flexible, so you can roll it like a pad, and then you just spread it on the ground and then you can just use it’.

The engineering designers focused more on technical feasibility during ideation. For example, 10 of the engineers used insulation as a heating method, while the 12 industrial designers mostly used closure to maintain the heat without insulation. The engineers used a diverse range of cooking methods, such as the greenhouse effect, liquid, and pressure, while the industrial designers were more likely to use direct sunlight and a heated surface. Another engineering solution was to use multiple mirrors to collect sunlight, demonstrating concern about functional heat, while only one of the industrial designers included this feature. In other concepts, engineers generated solutions incorporating fluids like water or oil for cooking, while none of the industrial designers did. Also, industrial designers utilized existing products (microwave oven, grill) as part of their concepts more often than the engineers.

Engineers more often used the heuristic, Use multiple components to achieve one function (8 vs. 1), adding different components contributing to the same function to enhance capturing sunlight. These components were sometimes identical to each other with minor changes (size, color) to facilitate adjustability in use, or they were different but served similar functions. The reason for the difference may be that engineers were concerned about function, which may have led them to use multiple components. For example, in Figure 7 a, Engineer 10 attached an umbrella with solar panels and mirrors to a conventional outdoor grill to ensure that the required energy would be generated. In Figure 7 b, Industrial Designer 4 also attached solar panels and magnifying lenses; however, the goal was not only to capture more sunlight, but also to use these functional surfaces as the lid and food preparation surfaces. Instead of attaching multiple components to achieve one function as in the engineer’s concept, the industrial designer assigned additional functions to those components.

Figure 7. Examples using the design heuristic: Use multiple components to achieve one function.

Industrial designers used the design heuristic, Use the same component for multiple functions, more frequently than engineers (23 vs. 3), perhaps because they considered portability and compactness, which would lead them to select components that perform two or more discrete functions using a single part. As seen in Figure 8 a, the concept generated by Engineering Designer 5 incorporates the use of a reflective curved surface, which also functions as a stand, and the concept formed by Industrial Designer 1 (Figure 8 b) shows the reflective surface angled for gathering sunlight as well as doubling the cooking surface, collapsing the entire product into two surfaces that share the same dimensions. Industrial designers also used Use inner space for added component placement more frequently (12 vs. 3), again suggesting a portability concern where the inner part of the product or an existing volume is used to allow for the placement of another component.

Figure 8. Examples using the design heuristic: Use the same component for multiple functions.

Another factor that appeared to be considered more often by the industrial designers than engineers was the interaction between the user and the product. For implementing a better interaction, they applied heuristics such as Change the surface material at points of human contact (6 vs. 1), and Create the hierarchy of features (8 vs. 0) more often. Some designs used a different material on the product where the user touched the product for safety or comfort purposes, or applied a different color or pattern to communicate where to touch the product. For creating a hierarchy of features, they presented the user with functions in a set order to assist them while using the product. In this manner, the users were not allowed to access the second function without using the first one. In fact, industrial designers depicted users in multiple concepts, while no engineers did so. The other heuristics significantly more commonly used by industrial designers were as follows: Integrate or attach the product to an existing item (19 vs. 11), Add gradations or transitions to use (6 vs. 0), and Mirror shapes (7 vs. 1).

Another interesting difference was that industrial designers more often used environmental contexts, such as bringing outdoor or indoor features into the concept. This difference might relate to educational differences, as industrial designer education focuses on the context of use, including examining personas and storyboards. Industrial designers also considered more diverse forms (e.g., pipes, racks, and ropes) more often.

Industrial Designer 7 demonstrated an additive approach in heuristic use, showing how heuristics can be used to add increasing elaborations to a design concept to produce variations. Seven similar concepts were generated, but multiple heuristics appear in each, and multiple heuristics to transition between them (see Figure 9). This designer began by attaching two existing components to each other – a magnifying glass and a griddle – to create a surface with focused sunlight. In her second concept, she transformed the magnifying glass to a square magnifying glass attached to the griddle. In the following concept, she made the lens height adjustable, and, in the fourth concept, she added sides to it to maintain the heat more effectively. She then considered portability by adding a rigid handle, which was changed to a flexible handle in Concept 6. In addition to all of the features included in the previous versions of the concept, the final concept included an attachment that held utensils and a spout for draining fluids from the cooking surface.

Figure 9. Seven sequential concepts generated by Industrial Designer 7.

Table 4 displays the design heuristics within each concept from Industrial Designer 7. The total number of heuristics increased in each sequential concept while the changes already introduced were maintained. This suggests later concepts were more complex and included more features.

In contrast to this systematic building on earlier concepts, the protocol from Engineering Designer 1 offered nine concepts that differed more, shown in Figure 10. For his first concept, he created a container that could be transported by users to a larger community gathering. The second concept was a large Fresnel lens, adjustable to the angle of the sun as well as to the best angle for cooking. For his next concept, he extended the previous one by segmenting his original lens into four separate lenses. The fourth concept was a spit cooker, which utilized a lens to focus on a line of heat rather than a point. The fifth concept was a double boiler, consisting of a system pumping hot water from a boiler into an outer pot. Concept 6 was a synthesis of previous concepts combining a double boiler with a Fresnel lens. The seventh concept was a lightweight reflective blanket with a drying rack. The eighth concept proposed a smoking chamber. The final concept was a three-stage boiler, which included a solar heater to warm up water to be utilized for steaming or boiling food.

Figure 10. Nine sequential concepts generated by Engineer 1.

To generate these diverse concepts, Engineer 1 spoke about a specific type of food, and then generated a concept for cooking that food. For example, he said ‘Other things to eat. We’ve got shish-kabobs, jerked meat, the dried herbs, the soups and thing; um, let’s see’. He also emphasized different constraints from the problem as he worked; in Concept 3, he focused on ‘maximizing the intensity of the sunlight’, while in Concept 7, he emphasized the constraints of being ‘inexpensive and portable’. A number of design heuristics were evident in the concepts, such as Adjust functions by moving the product’s parts in Concept 3 (where the lens angles could be altered) and Repeat as he added multiple lenses. However, his concept series had more differences between concepts than did Industrial Designer 7’s series. Considering types of food that might be cooked led to a more diverse concept set, with few commonalities across them.

In sum, the design heuristics evident in the protocols were largely similar across design disciplines. Despite presumed differences in training and experiences, both sets of designers used similar approaches to concept generation, and both made heavy use of design heuristics in creating their concepts. Of the 53 different design heuristics evident in the concepts, there were no differences in frequency of use for 85%. This suggests the utility of different design heuristics may depend more on the content of the design problem, the context of the designer’s work, or the instructions to generate multiple ideas. Even so, some interesting differences in the application of design heuristics occurred between groups. In particular, industrial designers focused less on technical questions, while as might be expected, this was emphasized by engineering designers. Industrial designers emphasized user experience, environmental contexts, and added features, resulting in concepts that utilized more design heuristics, but not more concepts. Hypothesis 3 was partially supported; while design heuristic use was similar in the two disciplines, important differences in their use were observed among designers in engineering compared to industrial design.