4.1. Calculating the area enclosed by a parabola and a secant line

Archimedes dealt extensively with the understanding of bodies in the plane and space. In Archimedes’ Palimpsest (Netz & Noel Reference Netz and Noel2007), we find a treatment for the problem of finding the area enclosed by a parabola and a secant line AB, see Figure 4. The hypothesis is that this area is a third of the area of the triangle $ \Delta $ ABC. This problem was very important for Archimedes as it allowed him to calculate the volume of shapes similar to boats, and together with his buoyancy principle, design ships (Nowacki Reference Nowacki2002): A combination of two theoretical contributions into a single real system design.

Figure 4. Calculating the area enclosed by a parabola and a secant line AB. Credit: CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=642215.

The following reconstruction of the way that Archimedes solved this problem matches that in (Netz & Noel Reference Netz and Noel2007; Assis & Magnaghi Reference Assis and Magnaghi2012) with the addition of his principles; it is as follows, see also Figure 5. First, using his heat ray principle, he decomposed the triangle into many infinitesimal areas represented by line segments with infinitesimal width such as HE that are parallel to the axis of symmetry of the parabola. We further construct a lever JB such that JD=DB and the lever basis is at D. For each of the line segments, HE, we obtain equilibrium via the lever principle by: (a) hanging HE on point G of the lever JB and (b) hanging a small part of it represented by the line segment EF at point J. After repeating this for all infinitesimal areas (i.e., line segments) and recomposing all the intermediate results, we end up with the triangle $ \Delta $ ABC hanging from its centre of gravity I and the parabola hanging perpendicular to the page at point J. Since JD is three times larger than DI, and the lever is in equilibrium, we obtain that the area of the parabola times JD equals the area of $ \Delta $ ABC times JD/3; consequently, the theorem is proven.

Figure 5. The solution process and the elements of Archimedes’ method. Collage of public domain pictures.

We see here perhaps the first example in the history of a reflexive practitioner (in addition to him being reflective). Being reflexive entails using one personally developed method in practice (Reich Reference Reich2017). Archimedes developed the law of the lever as a physical principle and used it now as a conceptual tool in a theoretical inquiry about basic geometry. This also demonstrates Archimedes’ flexibility in assigning object different identities: once a physical law and once a conceptual tool in basic geometry.

Archimedes called this method ‘the method of mechanical theorems’ and it appears in a letter to Eratosthenes. Archimedes’ solution can be considered the beginning of calculus when he used ‘infinitesimal’ rectangular shapes and combined them (Netz & Noel Reference Netz and Noel2007). In the process of proving the theorem, he designed a language (concepts), models of diverse geometric shapes located in different places in space and relationships between these models that sum up to a balanced whole.

Archimedes also used the same method to calculate volumes of bodies and also in other cases. Figure 6 shows on the right the objects and their geometric relationships, and on the left part, the objects are balanced on a lever following the application of Archimedes’ method. The result shows that the volume of the cylinder is twice the sum of the volumes of the other objects.

Figure 6. The volumes of a cylinder, cone and sphere. Reproduced from Assis & Magnaghi (Reference Assis and Magnaghi2012) by permission of the authors.

4.2. Archimedes’ Code

To find the area between the parabola and a secant line, Archimedes decomposed it into smaller problems (following the heat ray decomposition) of finding infinitesimal areas. He calculated these areas using his lever principle and then combined them on the lever to get the whole area. In the process, the subproblem elements were balanced and so is the final result after recomposing all the small areas. Equilibrium plays a critical role. We can generalise this process into a plausible process for addressing complex problems:

Archimedes’ Code: A complex problem can be addressed in the following way:

1. (i) Decompose the problem into simpler problems (i.e., following the heat ray principle).

2. (ii) For each simple problem, study it and apply principles in designing its solution (e.g., using the lever principle), or further, recursively decompose it into simpler problems.

3. (iii) Integrate the solutions into a balanced whole, potentially iterating with step 2 and moving up one level (e.g., the integration resembles the convergence of the different sun rays into a single location to burn it).

The hierarchical decomposition and the recursion mentioned in the code were not foreign to Greek mathematicians or Archimedes (Netz Reference Netz1999; Acerbi Reference Acerbi2003). They used them in their practice of mathematics, both related to expressions and diagrams. Netz (Reference Netz1999, p. 195) showed examples of tree structures of assertions in solving a problem. Hence we may assume that Archimedes used them also in his design practice, and in general, for addressing complex challenges. Archimedes’ Code is a framework for what we practice today when we design systems of any kind, such as a washing machine, a phone, a bridge or a car. The different complexities of these products are reflected in the amount of hierarchical decomposition necessary in steps 1 and 2 of the code; the difficulty to address step 2 for providing a technical solution to each subproblem and the difficulty to integrate the partial solutions into a whole in step 3. Archimedes’ Claw mentioned later (Figure 8), is a complex system that exhibits the code with recursive decomposition. The ability to decompose or represent a problem with multiple decompositions is manifested by Archimedes’ Stomachion discussed in Section 6.2.

As already mentioned, one could observe the application of recursion in Archimedes’ Code. The first sign that this concept was not foreign to Archimedes is that he used the law of the lever as a basic scientific method in calculating the area of the parabola, but there are more explicit examples. We will demonstrate such an example later (e.g., Section 5.1) and note that recursion appears in other works by Archimedes, including his definition of large numbers to solve the problem of counting soil particles on earth (Acerbi Reference Acerbi2003).

The ability to reuse concepts previously developed in different situations, for example, lever, or several similar mirrors, is predicated on the concept of flat space in design (Subrahmanian et al. Reference Subrahmanian, Reich, Konda, Dutoit, Cunningham, Patrick, Thomas and Westerberg1997; Reich et al. Reference Reich, Konda, Subrahmanian, Cunningham, Dutoit, Patrick, Thomas and Westerberg1999). A flat space is a conceptual space where all objects previously created are made available for observation and reused as objects in new models or systems; those systems are then put back onto the flat space. Figure 7 shows object A made out of three objects, which is then used as a component in a new system on the right. Object B in the flat space was used to build A and subsequently C. A flat space affords recursion. It also affords the reuse of parts as in Greek mathematics deduction practice (Netz Reference Netz1999). The hierarchical structure of object C in Figure 7 resembles the hierarchical structures that Netz (Reference Netz1999) presents. If Archimedes practised this in his mathematics, it may not be a surprise that we see traces of this in his engineering practice.

Figure 7. The flat space of objects.

To summarise the formulation of Archimedes’ Code, Netz & Noel (Reference Netz and Noel2007, p. 28) acknowledged that:

The two principles that the authors of modern science learned from Archimedes are:

1. (i) The mathematics of infinity.

2. (ii) The application of mathematical models to the physical world.

We claim that we can also learn from Archimedes the application of the strategies he used in mathematics to the physical world, and specifically to his design of engineering systems.

5.1. Lifting systems

The block and pulley system implements Archimedes’ Code with recursion. On the left of Figure 8, we see two blocks and pulley systems. Each one has a basis and the top pulley acts as a lever. The system is devised such that some pulleys act in parallel and some sequentially to amplify the force afforded by the system; the composition of systems as parallel and serial ordering of components is a powerful strategy. In both, the lever principle is applied recursively to the hierarchical decomposition. The system on the right, Archimedes’ Claw, includes two large levers (the heat ray principle decomposed the problem into two subproblems, each solved by a large lever), each having a block and pulley system on their left side, constituting a complex lever (block and pulley system) inside a large lever. We see Archimedes’ Code applied here flexibly and recursively. We acknowledge that this picture is an artistic expression and not a display of an actual machine built by Archimedes; nevertheless, we assume that the ideas are based on ancient stories.

Figure 8. Lifting systems implementing Archimedes’ code recursively. Credits: left: Themightyquill, CC BY-SA 4.0, https://creativecommons.org/licenses/by-sa/4.0, via Wikimedia Commons; middle: Carhart, Henry; Chute, Horatio, Public domain, via Wikimedia Commons; right: reproduced from Lazos (Reference Lazos1995) by permission of the publisher.

5.2. Archimedes’ heat ray

The following example is the heat ray, see Figure 9. Undoubtedly, the multiplicity or decomposition and recomposition steps in Archimedes’ Code exist here in the multiplicity of mirrors and their focus on a single point, but surprisingly, also the lever appears here. Each mirror acts as a lever where a slight movement of the mirror causes a ray translation near the target. Here the lever is not a way to balance weight, but to amplify a small change in the angle of the mirror into a large movement of the ray path, as well as to amplify the heat transmitted in a single ray by combining several rays. Using the term lever for describing optical phenomena is not new, the term optical lever is quite old as a device that amplifies the measurement of small angles or dimensions (Jones Reference Jones1961). Consequently, the heat ray is a very clear example of a parallel composition of levers applied to the Sun’s rays.

Figure 9. Archimedes’ heat ray. Credit: Finnrind (original); Pbroks13 (talk) (redraw), CC BY-SA 3.0, via Wikimedia Commons.

5.3. Archimedes’ screw

Archimedes’ screw is also built on the lever and heat ray principles, see Figure 10. The lever operation is embedded in the screw handle, the screw radius and the pitch (Ceccarelli Reference Ceccarelli2014, following Del Monte Reference Del Monte1577). The lever basis is the screw bearings. The multiplicity is implemented in the different helical surfaces connected sequentially into a long screw. The use of the code is as follows: to lift water to a certain height, decompose the problem to lift many small heights with a lever, and to recombine the solution such that the water is transferred from one to the next lever. This is an excellent example of a serial composition of helical levers.

Figure 10. Archimedes’ screw. The picture is public domain.

5.4. Buoyancy

The last example of Archimedes’ Code is that of buoyancy, see Figure 11. Here, too, one finds the principle of the lever. First, in the buoyancy of asymmetric bodies, or tilts of ships at sea, there is a moment generated by the gravity and buoyancy forces. The force increases with the tilt angle effectively acting as a lever. To study ship forms, Archimedes had to consider such infinitesimal thick shapes summed together in parallel in the longitudinal dimension with the multiplicity principle, effectively demonstrating the use of his code.

Figure 11. Floating objects as levers.

Floating objects in general act as levers around their centre of floatation. If they are pushed into the fluid, the opposite force is proportional to the push and other objects and fluid properties. Here also, extending to 3D objects requires using the multiplicity principle.

5.5. Summary

The four examples demonstrate that Archimedes’ Code permeates his scientific and engineering work; they validate the code. It is surprising to notice that the same principles work in such diverse cases and multiple levels of complexity. Conceptually, we see again the lever principle. Without the right models of knowledge, looking for such insight is moot. Let us dive more into understanding how Archimedes intentionally used his code to generate new knowledge.

6.1. Calculating the value of a π: method of exhaustion

Archimedes approached the problem of calculating π by approximations. As Bertrand Russell said (Auden & Kronenberger Reference Auden and Kronenberger1981), “All exact science is dominated by the idea of approximation,” but in Archimedes’ time, this was not practised. Figure 12 shows successive placements of polygons with a larger number of edges inside and outside of a circle. The decomposition into a multiplicity of subproblems exists. First, the problem is decomposed into an internal bounded polygon and an external bounding polygon and second, each polygon is subdivided into triangles to calculate its area. The lever here is less apparent but can be interpreted as the need to force the polygons to touch the circle from the inside and outside, causing them to rest in equilibrium on the touchpoints. By increasing the number of edges and calculating the areas of the inside and outside polygons, the value of π could be approximated with any accuracy. As an engineer and designer, Archimedes stopped at some temporary closure (Subrahmanian et al. Reference Subrahmanian, Monarch, Konda, Granger, Milliken and Westerberg2003; Subrahmanian et al. Reference Subrahmanian, Reich and Krishnan2020) with sufficient accuracy; with 96 edged, the value of π was bounded by . Archimedes effectively understood the concept of limit in calculus.

Figure 12. Approximating the value of π. The picture is public domain.

Archimedes could have approached the calculation differently by placing a polygon inside and mounting a triangle on each edge and recursively continuing until desired. But such calculation leads to a more complicated calculation than the elegant bounded approximation. When he calculated the area of a parabola differently than what was presented above, he used this method and solved it by considering the sum of an infinite series of areas (Hahn Reference Hahn1998).

6.2. Stomachion: combinatorics

The last example is interesting as it exposes yet another facet of Archimedes’ ingenuity – the case of the Stomachion. The game has a square box containing 14 shapes, shown on the left of Figure 13. A single page written by Archimedes on the Stomachion was discovered by Heiberg only recently, in 1906, inside Archimedes Palimpsest (Netz & Noel Reference Netz and Noel2007). Initial study and further analyses did not reveal a clear objective that led Archimedes to study the Stomachion. As shown in Figures 14 and 15, scholars thought that the 14 shapes were meant to generate arbitrary interesting and creative shapes. Nevertheless, they were puzzled because according to them, this did not constitute an interesting challenge for Archimedes (Netz, Acerbi & Wilson Reference Netz, Acerbi and Wilson2004; Gow Reference Gow2005).

Figure 13. Two configurations of the Stomachion. The pictures are public domain.

Figure 14. A Stomachion elephant.

Figure 15. Figure construction outside the box. Credit: Meisenstrasse – Own work, CC BY-SA 4.0, https://commons.wikimedia.org/w/index.php?curid=104322269.

A newer interpretation (Netz et al. Reference Netz, Acerbi and Wilson2004; Netz & Noel Reference Netz and Noel2007) suggests that Archimedes was interested in counting how many times a square can be formed from these 14 pieces; effectively studying combinatorics. It is, therefore, the first evidence of such work in history. Arriving at this interpretation required forming hypotheses from the written text, reading other available sources on the Stomachion, and understanding the historical context. The researchers reporting it wrote:

The story of finding the Palimpsest and interpreting it is an example of a complex challenge. It was read in different ways by different people, depending on the context and their expectations, and the team mobilised to decipher it and its available resources. This initial state was the lever from which they started. The readers had to integrate diverse sources and interact with the text to form an acceptable interpretation, out of several they tried; we can only appreciate these interpretations without knowing which is correct. Readings of his work resemble Archimedes’ work with external models: drawing, forming hypotheses and redrawing until insight emerges. Similarly, the interpretation of Archimedes’ work in this article follows the research plan presented in Section 2: studying Archimedes’ work, generating hypotheses about his work, refining the readings, and evolving the definition of Archimedes’ Code. The three stages of the research mentioned in Section 2 embed this evolution, as well as the review of this article which led to additional evolution. Is not this providing evidence that the study of different complex challenges goes through similar steps?

Finding different arrangements of the Stomachion pieces that fit into the square is a difficult task if we spread them out. It requires effort and concentration to succeed. Figure 13 depicts two possibilities to arrange the objects. It transpires that there are 17,152 possibilities according to a study in 2003 – a recent result for such an old game (Netz & Noel Reference Netz and Noel2007). By considering various symmetries, this number can be reduced to 536 options. It is much easier to use such considerations to generate new configurations than to spread all pieces and solve them. It is a case that one configuration acts as a lever for generating others by simple manipulations.

The Stomachion has continued to attract the imaginations of people. Further studies found all the configurations of pieces that fit into convex shapes (Rennhak Reference Rennhak2004) or attempted to create several shapes from the 14 pieces with some relations between their areas (e.g., 1:2:3) (Pitici Reference Pitici2008). The variety of surprising shapes that could be done with the Stomachion pieces is a testimony to its underlying richness. What then is the most interesting question related to the Stomachion and how does it represent Archimedes’ Code? The most interesting problem is designing the game itself: Dissecting the square in different ways into several (e.g., 14) pieces that give rise to interesting, as well as unanticipated shapes. Readers may find it interesting to take a square piece of paper and cut it, not perpendicular to the edges, into 14 pieces and try to assemble them into a different square shape. If it is difficult to perform with the original game, it is much more difficult to design the game. What would we call a successful game and can we tell that the present Stomachion is the optimal one? We do not have answers to these questions suggesting that designing the Stomachion is an example of an extremely difficult problem, which is quite surprising for a puzzle. Designing it followed careful studies of shapes and their relations (Netz et al. Reference Netz, Acerbi and Wilson2004) and potentially evolved following numerous attempts. We do not know whether Archimedes designed the Stomachion or not, but its design embeds the ideas of the newly formulated Archimedes’ Code.

7.1. Design theory: knowledge generation

Interpreting the foregoing discussion in the language of C-K (Hatchuel & Weil Reference Hatchuel and Weil2009) suggests that the creative part of generating new shapes would be engaging in manipulating concepts in C, while the generation of new squares or other well-defined shapes (e.g., convex) would be considered perhaps as K orderings. For Archimedes, it was much more challenging to work on the K than on the C, although based on his inventions, he mastered the C. The best testament for this in the context of the Stomachion is asking the most interesting question: how could we design the shapes of the Stomachion in the first place, making it an interesting game? How do we make sure it is possible to generate even just one additional square shape? Designing the basic knowledge structure is a fascinating problem.

In the language of C-K, creating good structures of K endangers generativity (Hatchuel et al. Reference Hatchuel, Le Masson, Reich and Weil2011). Hence, to be able to design solutions to challenges, we need to construct our knowledge structures beforehand. Only in this way, do we have a good and stable basis and a lever to rely on. Within the 14 pieces of the Stomachion, lies the future capacity that can be obtained from the forms. It sets the framework for the future and that is why it is so important. Reviewing the C-K theory, this resonates with the challenge of developing future technologies to allow for developing new products without encountering gaps or missing knowledge in the future (Kokshagina et al. Reference Kokshagina, Gillier, Cogez, Le Masson and Weil2017).

The Stomachion teaches us that anything even as perfect as a square can be dissected, disassembled and reassembled in ways other than it was conceived. Similar ideas have been taught 100 years ago at the Bauhaus (Le Masson, Hatchuel & Weil Reference Le Masson, Hatchuel and Weil2016). Similarly, morphological thinking or charts (Zwicky Reference Zwicky1957) could be considered as a way to dissect a complex problem in different ways (e.g., functions, requirements and technologies) and to use available building blocks, new and inspirational inputs from nature, or other sources to address challenges. For example, a chart could have material, texture, smell and reflection parameters, and each parameter can have all the values available independent of its source. Such independence breaks objects’ identities, creating the ability to generate objects that no one has ever seen (Hatchuel et al. Reference Hatchuel, Le Masson, Reich and Subrahmanian2018). Consequently, one can map the Bauhaus teaching techniques to morphological thinking.

Archimedes demonstrated the expansion of knowledge not only within specific projects but across his work. When he developed the lever law, he abstracted it and made it generic knowledge to be used in science and practice. Similarly, his heat ray invention embeds the decomposition and recomposition strategy that became part of his code, again serving as a generic knowledge source. In using the methods he developed in his work, he demonstrated being a reflexive practitioner (Reich Reference Reich2017).

7.2. Patterns: pros and cons

The concept of a pattern is fundamental to human thinking. We learn patterns and similarly today, machine learning software learns patterns, so they could be identified quickly and efficiently in the future. The efficiency of processing patterns in real-time is critical (Eysenck & Keane Reference Eysenck and Keane2020); patterns can encode knowledge for sharing among people (Alexander Reference Alexander1977) and they are associated with superior human capabilities (Mattson Reference Mattson2014). But patterns are also fixating. As they emerge, they can attract attention. I, for example, can identify a Star of David or Swastika in places that others would not notice. In such situations, I may ignore other stimulations (Chabris & Simons Reference Chabris and Simons2010).

The Stomachion explains to us how we could be fixated by the constraint to operate in the square but also how to unfix us, allowing infinite options if we move out of the box. The Stomachion further informs us that if we dissect a square – a familiar object – into seemingly odd shapes in a particular manner, we can be enormously generative and otherwise get stuck in one shape. The way we chose to take an object and break it down, including the constraints between its constituents, the properties we use, and their common meanings, allow us to be generative.

The concept of flat space allows unlimited decomposition and recompositions to occur. If the space remains static then fixation will ensue. To be generative, the space of objects in the flat space will have to include patterns arising out of new perspectives and knowledge and their dissection in potentially unconventional ways. Depending on our objectives, we can design such patterns and objects – we can design the knowledge structures in the flat space so that we can design the context of the design problem. Considering these properties of the flat space, Archimedes’ design of the Stomachion, if indeed it was him, could be considered one of his significant theoretical accomplishments related to design.

7.3. Transdisciplinary theory and practice

By and large, previous analyses of Archimedes’ work focused on one invention or contribution at a time. There may be some that covered several topics related to a single subject, such as buoyancy, the law of the lever, the method of exhaustion, and the method of mechanical systems, since they are all related to ship design (Nowacki Reference Nowacki2002). But otherwise, the analyses were siloed. In contrast, Archimedes was a transdisciplinary scholar working on diverse topics, and only a transdisciplinary analysis, such as the one conducted in this article, can uncover the true richness of his work and ideas. Transdisciplinarity avoids disciplinary fixations leading to new opportunities.

Archimedes not only crossed disciplinary boundaries but also was a pragmatic scholar seamlessly combining theory and practice. While he advanced theory, a significant part of his theoretical work was driven by practice and his practical results were used as conceptual tools in his theoretical investigations. For example, much of his work on areas enclosed by curves, the volume of bodies and buoyancy, was driven by his interest in ship design (Nowacki Reference Nowacki2002; Di Pasquale Reference Di Pasquale2010). Archimedes also wanted to demonstrate the importance of practical knowledge. As Di Pasquale (Reference Di Pasquale2010) writes, quoting Plutarch, King Hieron II asked Archimedes to publicly demonstrate his mechanical knowledge. The opportunity came when it was time to launch the ship Syrakousia that Archimedes built for Hieron II, a ship that was the largest of his time. Archimedes sat and used a device potentially including a block and pulley system and an endless screw to move the ship himself.

Archimedes selected this simple device to counter Aristotle who considered every combination of the five basic machines (i.e., winch, pulley, lever, screw and wedge) to be limited for addressing complex challenges, such as moving a boat. Archimedes with his code knew better. It was the triumph of his practical knowledge over the theoretical abstract reasoning of Aristotle and he wanted to demonstrate this to the public. Perhaps this occasion was when he expressed his immortal statement: “Give me a place to stand on, and I will move the earth.”