© 2014 Jonathan Ochshorn. A short version of this paper, constrained by the 20-minute conference time frame, was first presented at the 8th International Conference on Design Principles and Practices held at the University of British Columbia, Vancouver, Canada, Jan. 16- 18, 2014. A somewhat more complete version has been published in The International Journal of Design Education, Volume 7, Issue 4, 2014. What follows is the original, and longer, draft from which both prior versions were abridged, also available in PDF form (1.2 MB).contact | homepage | index of selected writings
Abstract: Architectural design studio pedagogy stands on the twin pillars of abstraction and defamiliarization. Students, immersed in this culture, develop a subjective artistic consciousness aligned with various evolving artistic tendencies within the profession. Technical considerations — those dealing primarily with structure, enclosure, energy/environment, life safety, and, in particular, the continuity of building control layers — are usually introduced within separate courses, and integrated with design at some point in the curriculum through comprehensive design exercises. While architecture remains both an "art" and a "science," the teaching of architecture has not caught up with radical changes in building technology that call into question the strategy of applying "technology" to designs that have been conceived and developed largely on the basis of subjective expressive goals. Architectural pedagogy prior to the twentieth century could "separate" building technology from design largely because building technology was firmly embedded within the various design vocabularies that formed the basis of an architect's education. This is no longer the case. Increasingly abstract building design objectives and increasingly subtle technical requirements have created a perfect storm of building failure in practice — a failure rooted in current architecture design pedagogy.
In some ways, professional practice remains independent of architectural pedagogy: the requirements for contract drawings and specifications bring with them a necessary attention to detail and to aspects of reality (loads and resistance, fire safety and accessibility, zoning constraints, and so on) that are not always critiqued or even addressed within studio instruction. In fact, a case can be made that the separation of technical considerations from more abstract design concerns that typify architectural education has a rational basis that corresponds to the way technical matters are separated from design concerns in practice.1 Nevertheless, and in spite of an ideology that supports an abstract conception of "design" as the underlying basis for architecture — whether in studio instruction or in practice — it has become increasingly clear that this strategy for designing buildings is seriously flawed, and that it leads directly to various types of building failure. This hypothesis, though not immediately self-evident, can nevertheless be tested by examining the following propositions:
That there have been fundamental changes in the nature of abstraction, beginning with the advent of modernism.
That there have been fundamental changes in the nature of architectural technology (from a reliance on "heroic" materials to a reliance on relatively delicate control layers).
That there are important implications for building failure when abstract design is disengaged from technological considerations, the most important of which have to do with the misapplication of — and, in particular, discontinuities in — control layers.
That design pedagogy generally prioritizes abstract formal experimentation over forms of expression based on an understanding of technical opportunities and constraints.
That there is a false symmetry between the application of "design" and "technology" in pedagogy and practice — i.e., it may appear that one can either begin with an abstract and conceptual design and then add in "technology"; or that one can begin with a technologically-sound idea to which "design" is added — and that treating these two potential strategies for creating buildings as equally viable is intellectually flawed.
That there are problems reconciling a pedagogy based on design as an abstract and conceptual formal process with the practice of architecture.
Changes in the nature of abstraction
Architecture cannot be understood without reference to the notion of abstraction. We discuss buildings in terms of form, space, geometry, context, color, meaning, or anything else only to the extent that we abstract from the infinite qualities that are actually present in its material. Tabulating or adding up the infinite objective qualities of building elements does not get you any closer to an understanding of architecture, so abstraction is a fundamental necessity in both critiquing and producing architecture. Understanding architecture as having a conceptual basis is the same as understanding architecture as an abstraction: a concept describes what the architecture is by abstracting from what it is not. As an example: if the concept of the Pantheon in Rome is of a sphere within a cube, such a description simultaneously abstracts from all that is not relevant to this concept — the particular qualities of each brick, stone, and concrete element from which it is constructed, the ornamentation of the exterior and interior surfaces, and so on. If a designer is unable to abstract from these useful and specific material qualities, a design concept will never emerge.2
That architecture has a conceptual basis does not mean that prosaic material properties and material relationships are not important. It only means that, to the extent that architecture is understood conceptually, such information is placed in a different file folder. If it is accepted that abstraction is a requirement for the appreciation, understanding, and creation of architecture, the question remains as to how all the elements abstracted from — those things placed in our metaphorical file folder — become part of the building, as they must: for one cannot build an abstraction.
Up until the end of the nineteenth and the start of the twentieth century, the type of abstraction underlying architectural design was generally built upon — paradoxically — an acceptance of conventional building elements, building materials, and building construction techniques. Windows remained windows, doors remained doors, walls remained walls, and roofs remained roofs. In general, structural forces were resolved in conventional ways, construction proceeded along conventional lines, and environmental constraints on site planning, building orientation, and so forth were respected.
The conceptual basis of such architecture neither challenged, nor threatened, these prosaic elements and conventions, but was rather developed with these elements in mind. Window openings may have been elaborated or framed with Ionic columns and decorated with various ornamental forms, and the geometric organization of the facade may have abstracted from the material or constructional logic of brick, stone, or plaster surfaces from which its expression emerged, but the window was still understood as a window, and the wall was still understood as wall. That architecture took as its point of departure walls, columns, windows, and roofs was rarely questioned; Alberti and other fifteenth- to nineteenth-century architects and writers maintained a conventional and uncontroversial attitude towards such building elements even as they explored issues of architectural design and abstraction.
The origins of a more radically abstract way of understanding architecture were already present, but were not recognized as serious alternative strategies for designing buildings. Rather, examples of conceptually pure forms devoid of references to conventional building elements appear almost exclusively in works of monumental scale, expressing the most unfathomable and sublime concept of all: death. The Great Pyramid of Giza, completed in 2560 BCE, and the Cenotaph for Newton designed — but never built — by Étienne-Louis Boullée in the late eighteenth century, can be cited as precursors to the radically abstract forms characteristic of later works of architecture. However, such precedents were not considered, at the time, to be legitimate role models for non-funerary building types. Whether or not this notion of the sublime ultimately became the defining factor in modern art or architecture, as claimed by Jean-François Lyotard, is not relevant to this argument: all that matters is that the nature of abstraction changed.3
Architectural abstraction as a mere elaboration, or ordering, of conventional building elements began to be challenged in the late nineteenth century, and especially in the early twentieth century. While the canonical houses of twentieth-century modernism were hardly representative of domestic building, then or now, they were extraordinarily influential in creating a kind of beachhead from which radical attitudes towards abstraction could take root and ultimately become major factors in both the pedagogy and practice of architecture. This new form of abstraction differed markedly from traditional forms of abstraction. Le Corbusier's five points of architecture describe the potential of new technologies — in particular, the replacement of loadbearing walls by a structural framework — to overcome what were considered insufferable constraints of traditional construction.4 In many of his buildings, windows are abstracted as rectangular openings, or voids. Other conventional building elements are defamiliarized or eliminated entirely: stucco replaces clapboards as it betrays no material origin, and can be more easily understood as abstract surface; roof shingles, along with sloped roofs of any sort, are simply eliminated, as they contain such strong references to the traditional tectonic geometry of attics and gables; brick chimneys are replaced with painted metal cylindrical pipes; and all traditional ornamental or decorative embellishments are banished. The point here is not to criticize any particular aesthetic outcome, or to propose a return to any particular stylistic tendency. The key change, from the standpoint of building failure and building function, is that — for the first time — architectural abstraction was made independent of building construction and building conventions.
Changes in the nature of building technology
Many advances in building technology can be cited to explain the motivation, as well as the potential, for changes in architectural form and construction associated with modernism. Perhaps the most obvious were major improvements in the production of ferrous metals used to create structural frameworks, leading to the widespread use of standard I-beams and, later, wide-flange sections made from rolled steel. At about the same time, near the turn of the nineteenth (into the twentieth) century, reinforced concrete also became, for the first time, a viable structural material. It is hardly accidental that the formal inventions of modern architecture drew upon the structural potential of these new materials.
Other materials used in modern buildings were not particularly new, but — at least in some cases — were becoming available as mass-produced commodities. However, unlike structural frameworks that used steel or reinforced concrete to create formal typologies associated with modernism, it is not as easy to make explicit connections between these other building materials and this type of formal abstraction. Even glass, which served as a necessary bridge between the spatial ideals of modernism and the realities of enclosure, was not exactly a new material at the beginning of the twentieth century, although incremental improvements in its manufacture did permit greater experimentation with formal compositions that relied on large "voids."5
If structure were abstract grid (or abstract plane, in the case of load-bearing walls), and if glass were abstract void,6 other constructional elements or materials required to complete the desired abstract compositions of modern design were harder to find. The neutral solid surface had to consist of something, but nothing new was available, except perhaps the mottled grey surface of reinforced concrete. More often, such surfaces were created as they had been for thousands of years — by applying a layer of stucco to an underlying substrate of brick or concrete block.
The important point is this: in spite of an abstract conception of buildings which eschewed conventional building elements and conventional material expression, modern buildings still needed to be actually and physically constructed. Moreover, modern architects had hardly given up, or gone beyond, a traditional understanding of building construction as consisting fundamentally of physical things whose value was measured as it had always been measured: by their strength, by their resistance to movement, and by their durability. Expressing such characteristics of building materials — as heroic elements that were both visible and tangible — may not always have been a formal preoccupation of modern architects, but the heroic quality of constructional elements remained for modern architects an unchallenged model for putting together, for building, their abstract concepts.7
The belief that traditional (heroic) materials constituted the basis of building construction, if not always the conceptual basis of the architecture, became increasingly untenable in the twentieth century because the underlying basis of architectural technology underwent a radical transformation. The reasons for, and results of, this transformation can be summarized as follows:
Steel and reinforced concrete frameworks, together with newly invented elevators, made it possible to develop tall commercial and residential buildings.
The obsolescence of load-bearing masonry walls in this context created both the possibility, and the incentive, for reducing the thickness and weight of cladding systems.
The relatively high costs of mechanical air conditioning provided an incentive to develop and deploy thermal control layers (insulation) at the building perimeter.
Problems with failed sealant joints, condensation, polluted outside air, increasing energy costs, and water intrusion led to the conceptualization and deployment of rigorous control layers for vapor, rainwater, and air, in addition to the thermal control layer.9
It is important to emphasize the fact that what had previously controlled rainwater, vapor, air, and heat loss — the thick and more-or-less monolithic walls of traditional construction — were the same elements that largely defined the "architectural expression" of traditional buildings. That is, architecture grew out of, and supported, this underlying technology, just as the technology supported the architectural expression. However, while the technology of control layers migrated from the "heroic" materials of traditional architecture to the separate, optimized, and non-heroic membranes and insulative materials characteristic of contemporary construction, formal architectural design in the twentieth and early twenty-first centuries remained stuck in the paradigm of traditional and heroic material expression, not only ignoring this profound technological shift, but actually moving in directions that exacerbated problems of vapor, air, and rainwater intrusion, as well as energy efficiency.
Problems when abstraction is disengaged from technological considerations
In the new paradigm for architectural technology, four control layers need to occur consistently at the boundary between inside and outside space in order to control these four environmental factors: rainwater, vapor, air, and heat. Wherever a control layer's integrity is violated along that boundary, the potential for problems increases, in the following ways:
Thermal bridges (i.e., discontinuities in the thermal control layer) not only may lead to unintended heat loss or heat gain, but may also alter the temperature gradient between the outside and inside surfaces of the enclosure system, leading potentially to condensation, whether on interior surfaces, exterior surfaces, or interstitially. Such condensation may lead to structural damage, nonstructural damage, and to the growth of mold.
Holes or gaps in the rainwater control layer obviously increase the potential for water to enter the building in unintended ways. Water is probably the single most damaging element in buildings when not properly controlled: in its presence, wood may rot or decay, ferrous metals may rust, dissimilar metals in contact with each other may undergo galvanic corrosion, gypsum board may be damaged, mold (mildew) may grow, and so on.
Holes or gaps in the air control layer can increase the probability that air will move through the enclosure wall, or within the enclosure wall, in unintended ways. All sorts of negative consequences may result: in particular, energy may be lost in much greater quantities than from discontinuities in the thermal control layer, since pressure differentials between outside and inside areas can drive large amount of unconditioned air into the building (while driving large amounts of conditioned air out of the building). Such unintended patterns of air intrusion can also wreak havoc on HVAC systems, and create unexpected condensation within enclosure walls as conditioned or unconditioned humid air finds its way onto cold surfaces outside or inside the thermal control layer.
Assuming that the various control layers are properly configured with respect to each other — so that, for example, an air barrier isn't positioned within the enclosure wall assembly in such a way that it prevents water or vapor from draining or drying out — the primary task is to make these control layers continuous. This is not particularly easy to do: because control layers are most efficiently deployed outside the building's structural frame (so that they are not constantly interrupted by interior partitions and floor-ceiling assemblies and so that the building's structure is protected from thermal changes and other environmental damage), they must be supported by, or connected to, the building's structure in some way. Unless they are adhered to the building's structure (or to some sort of back-up surface or substrate supported by the building's structure), then their means of support (clip angles, bolts, screws, nails, etc.) invariably penetrate not only the control layer being supported, but also any control layers positioned between the control layer being supported and the structural substrate. And even if all the control layers are light enough so that they may be adhered without the use of penetrating fasteners, the outer "rain screen" cladding material — needed not only to establish some sort of architectural presence for the building, but also to protect relatively delicate control layers from various forms of damage and, in some cases, to create an air cavity or pressure-equalization chamber — still requires some sort of fastening system that invariably must penetrate the control layers it covers and protects.11
Roof systems require the same control layers, but have different problems to reconcile — in particular, problems with penetrations for mechanical equipment or skylights, and transitions between vertical, sloping, or horizontal surfaces.
This illustrates a fundamental contradiction in the theory of control layers, but it is a contradiction that can be largely overcome both by minimizing these inevitable penetrations, and by detailing them explicitly where they occur (e.g., at windows or other openings, penetrations, and at the fasteners themselves) to maintain the continuity of the various control layers that would otherwise be interrupted. This strategy, however, is compromised when the architectural design itself — not just the inevitable encounters with windows, penetrations, and fasteners for cladding support — has a conceptual basis rooted in the expression of discontinuity.
Such discontinuity takes many forms, and it is not the purpose of this paper to document them all, or to suggest that all contemporary architectural expression is aligned with this tendency. The important point is this: where conceptual or schematic design is understood as a process of abstraction in which formal ideas can be developed without any consideration of control layer continuity, where contemporary modes of representation can capture virtually any formal geometry, where structural and energy analysis software can provide numerical validation for the most complex and indeterminate geometric models imaginable, and where architectural culture in general, and generative design methods in particular, encourage a disjunction between formal conceits and constructional logic (Figure 1), the probability of encountering problems with control layer discontinuities dramatically increases.12
Paradoxically, not only the expression of discontinuity, but also the expression of a kind of hyper-continuity can lead to control layer problems — this may occur when walls and roofs become indistinguishable from each other as morphed and flowing building enclosure surfaces turn the conventional understanding of "façade" or "roof" into quaint anachronisms. Potential problems with such hyper-continuity come about because necessary connections at vertical walls are different from those at steep-slope or low-slope roofs. Control layer penetrations that are required for fastening cladding panels may be tolerable in the vertical surface of a metal rain screen wall, for example, but may well become increasingly risky as the enclosure surface bends or curves from a vertical to a more horizontal position. The orientation of enclosure surfaces with respect to the force of gravity matters, and it is dangerous to confuse the abstract formal desire for "continuity" with the practical requirement for control layer continuity derived from building science principles.
There are, of course, other causes of building failure that are not necessarily related to control layer issues — these include problems with interior acoustics, slab cracking, veneer delamination, and indoor air quality, to name just a few. However, in analyzing the relationship between building failure and design pedagogy, control layers have been singled out as deserving special attention for the following reason: whereas the multiplicity of other building failures can be attributed to carelessness in detailing or construction, or to a lack of understanding of basic building science principles, or to incompetence or even greed, such problems do not generally come about because of stylistic or formal manipulations that have been nurtured and encouraged within design studio pedagogy. It is only, or primarily, at the building perimeter that such attitudes and practices lead to a higher risk of building failure, for the reasons outlined above.
Design pedagogy and the prioritizing of abstract formal experimentation
The intention here is not to conduct a systematic survey of design studio methods, intentions, and results, nor to suggest that there is a monolithic strategy evident within all studios. There is, however, a great deal of anecdotal evidence that formal abstraction, independent of serious consideration of technical/functional issues, typifies design studio pedagogy. In an analysis of the "fictions of studio design," Deamer uncovers a consistent hidden agenda at work in the beginning design studio, independent of the apparent or stated objectives: "[T]he role of form and aesthetics cannot be overlooked. No matter how smart a student's concept is, if it isn't visually appealing, no one will pay attention."15
A cursory look through the literature of design studio pedagogy confirms this general proposition, while reinforcing the idea that even technological considerations are subsumed within the formal ideals of modernist/postmodernist abstraction. Where an awareness of materiality, structure, tectonics, light, energy, and sustainability appear as pedagogic objectives, it is almost always within a framework predicated on obsolete building science, more often than not fatally compromised by the formal fetishizing of solid and void within a stylistically "appropriate" composition.
For example, the overwhelming majority of papers presented at the National Conference on the Beginning Design Student (NCBDS) in 2011 show little concern for technical or functional issues, but rather seek to introduce design students to the abstract "culture" of architecture, often also inculcating some skills related to drawing, model making, representation, and so on.16 The formal agenda within these studios, mostly hidden, generally abstracts from all control layer considerations that might otherwise inform the design process. Only one paper of the 80 presented (labeled No. 52 in Table 1) is explicit about the importance of control layers within the design process: "The students are expected to demonstrate understanding that materials and assemblies are not merely subject to whatever form the design supposes, but that the complex layers of building assemblies — structural, thermal, protective, and expressive — are inherent in the final experience and performance of the architectural work."17 More commonly, even where technical issues are included within the studio program, underlying formal biases compromise the outcomes.
Evidence for this lack of attention to building enclosure or control layer requirements can be found by examining the 79 (out of 80) papers within which such issues are not seriously addressed. Two broad categories can be identified: first, those papers where building enclosure and control layer requirements are nowhere evident; and, second, those papers where some concern for "technical" or "environmental" integration is articulated, but where this concern does not seriously consider the importance of control layer interactions and requirements, and therefore still encourages an attitude towards design in which the probability of building failure increases.
In the first broad category, in addition to those specialized studies that make no attempt to foster any particular formal design strategy (for example, "Online / On Target: Reflective Practice through Blogging"18), are familiar odes to expression, feeling, invention, poetics, and abstract formal experimentation. It is not necessary to document all of the variations on this theme; the following five examples give some indication of the range of pedagogic intentions:
Students are asked to "make a 2-D object (area) that exhibits a total figure-ground alternation."20
Students "were charged with a simple task — look at your body and pick an idle position as the basic value to initiate an intensive and precise mass production of drawings."21
"This paper argues that the use of analogy and metaphor offers an optimal pedagogy for introducing beginning design students to integrated thinking."22
"For pure inspiration (concept, theme), students explored the linear notions associated with a piece of instrumental music to translate into architectural space."23
The second broad category is of more importance, since the ideas of technology, environmental systems, sustainability, or technical integration are made explicit within the studio project. Yet even so, the design of building enclosures based on a rigorous examination of control layer issues is absent. Three aspects of this phenomenon can be identified as follows:
The first and most common aspect deals with a kind of materiality, detailing, or even full-scale building that, nonetheless, abstracts from actual building enclosure and control layer issues (see the 16 papers labeled in Table 1 as Nos. 5, 7, 11, 12, 13, 20, 23, 32, 46, 51, 57, 59, 64, 65, 70, and 79). Whether such studios utilize detailing exercises or full-scale building (Figure 2), issues involving control layers are almost always abstracted from, in favor of explorations of formal and material expression.
The second aspect is based on what might be characterized as a LEED-checklist-calculation approach (whether of energy use, carbon footprint, illumination levels, or other parameters). Such an approach also abstracts from building enclosure and control layer issues (see the five papers labeled in Table 1 as Nos. 16, 18, 31, 53, 69). In one project, for example (Figure 3a), numerical calculations demonstrating a "net-zero building" are conjoined with a formal approach to design that maintains the modernist abstractions of surface and void characteristic of control layer failure.
The third aspect focuses on a view of technology that is virtually indistinguishable from that of pure expression (see the five papers labeled in Table 1 as Nos. 38, 44, 55, 62, 71). As an example (Figure 3b), one studio investigated found objects, searching for the poetics embedded in their form and materiality (inspired by Gaston Bachelard's concept of the imagination). This type of approach to design and technology has links to contemporary notions of sustainability and to the reuse of material resources (recommended within LEED guidelines as well as in writings by McDonough and Braungart referenced in Table 1, paper No. 38), but the studio work appears to place greatest value on the expressive qualities of the objects in relation to the students' abstract formal or psychological preferences.
Thus, it seems clear that issues of building science or environmental science are not seriously considered in the typical beginning design studio. Most often, such issues are simply ignored (53 of the 80 design studios represented in the 2011 NCBDS); otherwise, they are typically considered in a manner that abstracts from critical issues of building enclosure and control layer interaction and continuity (26 of the 80 studios). Only one of the 80 design studios represented in the 2011 NCBDS considered building enclosure and control layer issues in an explicit and serious manner.
The false symmetry of building science and formal expression
The notion that architecture is both an "art" and a "science" is widely acknowledged, even if the terms of this disjunction are debated.28 It seems clear, even to those who value the types of abstract thinking encouraged within design studio pedagogy, that somehow — at some point — such abstractions must be reconciled with real conditions encountered when projects are actually constructed and occupied. What is less clear in such formulations are the specific aspects of "reality" which ought to be addressed, if at all, within the academic studio, and the proper means to accomplish this synthesis.
In fact, the types of "building technology" issues that might impinge upon a purely formal or expressive design pedagogy are quite numerous, and include things like structure (strength, stiffness, and efficiency); control of air, rain water, vapor, and heat at the building perimeter; fire (and other life) safety issues; energy use; production of global warming gases (carbon footprint); daylighting and electric lighting; site orientation issues (sun, wind, drainage); acoustic isolation and interior acoustic environments; toxicity of building materials; use of renewable materials and renewable (or on-site) energy; reduction or recycling of potable water and waste water; and so on.
All of these issues need not be addressed in every design studio, and some are almost never critical in terms of influencing or altering the conceptual basis for the design: that is, some "technical" issues can safely be left out of schematic design without compromising the viability of the scheme as it is further developed. For example, the ubiquitous use of electricity within buildings (at least when generated off-site) is never considered within schematic design, in spite of being perhaps the most fundamental of all the "technologies" necessary for the functioning of modern buildings. This is because buildings, no matter how they are formally configured, can accommodate panel boxes, conduit, switches, and outlets in routine ways that have almost no impact on the design concept or on a project's overall cost.
Electrical contractors, in fact, routinely run conduit from panel boxes to switches to lighting fixtures and so on based on nothing more than abstract drawings with curved arrows pointing in general directions, leaving the specific pathways for the field installer to work out; and architects routinely let electrical engineers determine the pattern of outlets, or sometimes even of lighting, well after schematic design decisions have been made. In this case, the "technology" can be "added" to the "design."
Such a model (technology added to design) is often extrapolated to encompass a much greater range of technological decisions. For example, Mohsen Mostafavi, former Dean of the College of Architecture, Art, and Planning at Cornell University, describes a comprehensive design studio project at Cornell as follows: "We asked a group of students whether, as an experiment, they would be prepared to continue working on their old project, the one they had supposedly finished, and to take it to another level of development" (emphasis added).29 By "another level of development," Mostafavi means factoring in issues of building technology not ordinarily considered within the design studio. However, while it may be rational to "add" certain technologies to projects that were conceived without prior consideration of building technology issues, framing this as a general model for pedagogy or practice is both dangerous and counterproductive.
Such a strategy — "adding" technology to design — presumes a kind of symmetry between the process of abstract design and the requirements of building technology. That is, it is presumed that one can begin at either pole of the art-science duality and still end up with a viable building. But this is a false symmetry based on numerous logical errors including "a misplaced confidence in the power of science to compensate for any a priori design decisions."30 In other words, some aspects of building technology are so fundamental, and also so sensitive to unusual or peculiar geometric manipulation, that their underlying logic must inform, if not precede, a schematic design process that prioritizes abstract form and expression.
Problems reconciling abstract design with technology
Of all the many technological systems that fall loosely under the umbrellas of building technology and environmental science, the most important, at least in terms of their relationship to abstract and formal design decisions, are the control layers and cladding systems that together comprise building enclosure systems, constraining in various ways the movement of air, vapor, rainwater, and heat between the outside and inside of buildings.31 There are many specific requirements and attributes that characterize each control layer but the most fundamental — common to all four layers — is continuity. If continuity of all four control layers is maintained, and if control layers are properly configured so that, for example, materials that absorb water are able to dry out, vapor does not condense, rainwater is directed out of cavities, air leakage is limited, and heat loss is minimized, then the overwhelming majority of building failures will be prevented.
Conversely, if control layer continuity is made difficult or impossible because of formal or expressive design decisions that abstract from the underlying logic of such enclosure systems, then the probability of experiencing various types of building failure will increase. Unfortunately, many of the formal design conceits that prevail within schools of architecture (and in practice) — even and especially those that fetishize "materiality," or are based on abstract compositions of figure-ground or solid-void, or are derived from complex geometric or generative manipulations, or are otherwise governed by peculiar manipulations of site, surface, or mass — work against such continuity. Complexity and peculiarity, qualities that characterize many of these compositions, correlate strongly with various types of building failure.32
Objections to the argument
While the idea that architectural design pedagogy is complicit in the epidemic of building failure within the U.S. may be inescapable, it is hardly self-evident. An examination of several potential objections follows:
Objection 1: There really is no epidemic of building failure in the U.S. It is, in fact, difficult to find systematic documentation of building failure within U.S. practice. Owners, developers, manufacturers, contractors, and architects are not required to submit information about roof leaks, curtain wall failures, slab cracking, and so on, to any central database. On the contrary, there are enormous disincentives to provide this information to interested researchers. Manufacturers are not inclined to publicize defective materials or systems; architects are not inclined to publicize defective buildings; and contractors are not inclined to publicize unsatisfactory work. We are left with anecdotal observations, small-scale studies, or evidence revealed through class-action lawsuits (e.g., of EIFS failures in North Carolina33). Nevertheless, the prevailing wisdom is that such nonstructural building failures are extremely common,34 and that the overwhelming majority of such problems — at least those that result in litigation — are related to control layer failure.
Objection 2: Being adventurous with design and detailing actually "pushes the envelope" and ends up improving the technology of building enclosure. There is some truth to this objection. The history of architecture is filled with stories of building failure that led to improvements in the prevailing technology. For example, lacking numerical modeling programs, medieval builders often "pushed the envelope" of Gothic construction to the point where some large structures actually collapsed, most famously the Cathédrale Saint-Pierre de Beauvais in 1284. Lessons learned from these failures led to improvements in the construction of subsequent buildings. A more recent example concerns the curtain wall designed for the Hancock Tower in Boston (1976) by I.M. Pei and Partners; the use of a traditional lead solder with an unexpectedly strong adhesion to reflective coatings on the unusually large glazing panels led to fatigue cracking and, ultimately, to the replacement of more than 10,000 glass lites. William LeMessurier, one of several engineers who examined the building (thinking, at the time, that the glass failure might have been triggered by structural deflection) claimed that this failure "spawned a whole new profession of skin consultants" while also leading to the growth of the "science of wind tunnel investigation and surface forces...[and to] an enormous amount of academic interest in more refined structural analysis..."35
Where resources and expertise are available, this type of investigation and research can precede the construction of a building, and can result in new products, systems, or formal geometries.36 However, such research expertise and monetary resources are hardly typical for ordinary, or even for extraordinary, building projects. To embark on uncertain terrain — to push the envelope — without having the expertise or resources to thoroughly model and test any such unprecedented construction materials, methods, products, systems, or geometries, is simply asking for trouble (i.e., increasing the probability of failure).
Objection 3: There is nothing inherently dangerous about formal manipulation even when it transcends the bounds of conventional, or ordinary, building design. Drawing a line, whether with a pencil or with the most sophisticated modeling software, is a seductive act: like the sculptor Pygmalion, students and practitioners seek to breathe life into their abstract representations. Yet transforming even the simplest lines into real material constructions may pose enormous difficulties. For example, a large number of building products are formed, molded, or extruded into flat or linear elements. Some, like symmetrical steel sections or drywall panels, can be bent into curved forms, at least within certain limits. Yet other products must remain as they were initially formed, and resist efforts to bend them into shapes that are so easily represented on paper (or in digital models). Curving a piece of rigid polystyrene or even a corner bead intended for the edge of a curved gypsum board partition is difficult. Yes, it is possible to find a way, but this often involves a great deal of research and experimentation (while the resulting construction processes may involve greater costs) that are not always factored into the design process. And that is the point: unless a student (or practitioner) has the time and expertise to conduct such research or experimentation, the abstract line will eventually confront an obstinate and unsympathetic reality; and in such confrontations, reality will always prevail.
Complex or peculiar geometries compound such problems and create additional ones, simply by proliferating the number of unique and idiosyncratic intersections with the potential to wreak havoc on control layer continuity (Figure 4). As before, a thorough and exhaustive detailing exercise can overcome some, but not all, of these problems: just the act of multiplying the number of material intersections and joints increases the probability of building failure.
Objection 4: Problems with building enclosure are not the fault of the enclosure design, but rather the fault of sloppy construction practices. It may be true that some instances of building failure are the result of construction practices rather than inherent in the design of the building. Even so, it is clear that faulty design is often the cause of failure: "According to the insurer CNA/Schinnerer, each year between 1994 and 2005 there were between 15 and 21 professional liability claims filed for every 100 [architectural] firms."37 Even if only a fraction of those claims had merit, it points to a serious problem, especially since many additional nonstructural building failures are resolved without recourse to litigation.
It is also true that the culture of competition and the contractual basis for compensation may lead some contractors in the U.S. (at least those operating under standard owner-contractor agreements based on a stipulated sum) to cut corners in order to increase their profits. On the other hand — especially in other countries, operating with different traditions, different project-delivery systems, and different cultural expectations — it may be possible to rely more on contractor expertise and conscientiousness to overcome defects, or complexities, in the design documentation. Yet this just means that the attention paid to detailing and designing, especially as it relates to control layer issues, is split between the architect and other players in the construction process: the need for serious consideration of such issues hasn't mysteriously disappeared. In the U.S., or in any culture where the architect is ultimately responsible for proper consideration of control layer issues, abstracting from such issues within the educational program remains counterproductive and dangerous.
There is a variant on this theme: because some complex designs avoid control layer problems while some ordinary designs experience such problems, then why bother making any special effort to control such apparently random results? Moreover, given this "evidence," isn't it really unfair to blame nonstructural failure on the complexity or peculiarity of the design itself? A similar argument is commonly used to justify all types of risky behavior, and reflects an inability or unwillingness to examine well-defined random events from a probabilistic standpoint. In other words, while any individual building may defy the odds and avoid nonstructural failure in spite of its complexity or peculiarity, the overall incidence, and costs, of building enclosure failure will increase. Encouraging a design process that abstracts from, or increases the difficulty of, control layer continuity contributes to the epidemic of nonstructural building failure.
Objection 5: It's no big deal if a few buildings leak — better to live in a world with formal design freedom (even if accompanied by various forms of building failure) then in a dull, repetitive world where everything functions properly. This attitude, at its most extreme, can be found in the "client's response" to Peter Eisenman's House VI, a building constructed in Cornwall, Connecticut in the mid 1970s. By 1980, the homeowner writes, "...physical problems with the house caused a hiatus. As I mentioned, from the beginning we had problems with leakage, and by 1980 they had become serious. We had often asked Eisenman to help us in this regard, but he backed away from our pleas... I think he also mistakenly considered such problems to be beneath his interests. [My husband] called in a local builder to put a sloping roof over the back door at the south and the living room at the west, where leakage was worst... Eisenman spread the word to the architectural community about how his clients had spoiled the lines of his design. Probably as a result of this, Martin Filler, who was then architectural editor of House and Garden, in his article on Eisenman's polemical houses... questioned whether this was an act of cultural vandalism."38
There is some truth, and a number of fallacies, in the argument that accepting and applying principles of building science within the design process prevents a designer from heroically pursuing an avant-garde agenda — what for Eisenman in the context of his House VI involved "inverting the accepted canon" of spatial strategies.39 The truth is that such considerations do constrain design freedom. A "paper" architecture conceived without gravity, for example, will surely be frustrated when confronted with the reality of, and requirements for, vertical equilibrium.
Yet it is equally true that the constraints brought about by what might be termed "reality" — not only gravity, but also the necessary control of air, vapor, rainwater, and heat at the building's perimeter — can be reconciled with a desire to create new architectural forms of expression. Yes, freedom is constrained, but it is not entirely destroyed. The problem is that in a world of architectural production driven by competition,40 any logical constraint on a designer's freedom of expression leads the designer — perversely but inevitably — to explore precisely those forbidden places outlawed by prevailing conventions. In defying such logic, the designer seeks to "defamiliarize" what has become so commonplace that it is no longer capable of eliciting an aesthetic response and, therefore, serving as a useful mode of competition.41 This is the heroic conceit of the contemporary avant-garde: to confront "danger" in whichever of its manifestations appears as an appropriate target at any given point in time.
Joseph Campbell abstracts from the culture of competition that motivates artists to embark on such counterproductive heroic journeys, seeing only the mythical and idealized shell of heroism in such attempts: "Artists are magical helpers. Evoking symbols and motifs that connect us to our deeper selves, they can help us along the heroic journey of our own lives... Over and over again, you are called to the realm of adventure, you are called to new horizons. Each time, there is the same problem: do I dare? And then if you do dare, the dangers are there, and the help also, and the fulfillment or the fiasco. There's always the possibility of a fiasco. But there's also the possibility of bliss."42
Ironically, an inattention to building science is — precisely — what this version of heroism entails. The architect (qua artist) is not so much "help[ing] us along the heroic journey of our own lives" but rather creating, out of thin air, a heroic journey for herself: leaving the world of safe, predictable constructions; proposing buildings that have both the appearance and the reality of danger (where danger comes from challenging conventional notions of aesthetic, and sometimes literal, comfort; challenging class-based conventions regarding economy of means; and especially, challenging forces of nature such as gravity, or rain, or snow); and returning in glory after having confronted the agents of conformity (whether owners, users, public officials, etc.). For such a hero, having proposed, or built, such a brave thing with all the attendant risks of failure is a badge of honor.43
The argument propounded here — that changes in the nature of both abstraction and building technology have contributed to a virtual epidemic of nonstructural building failure in which design studio pedagogy is complicit — is not entirely convincing, in part because it relies on probabilistic reasoning rather than on some definitively causal smoking gun.
Moreover, the alleged problem and its causes remain largely invisible. Even well publicized instances of nonstructural building failure can be easily dismissed as exceptional cases, pointing not to a general crisis but only to the hubris of a few architectural superstars. The bulk of evidence that might otherwise point to a bigger problem is largely unavailable, and so cannot be systematically compiled and analyzed.
In addition, architectural critics, educated primarily in the history and connoisseurship of culture and form, can be counted on neither to understand architecture from the standpoint of building science, nor to challenge it on that basis. They tend, therefore, to lend support to a mode of education and practice that reinforces their own educated prejudices. Control layers are fundamental to the functionality of buildings. Because the probability of control layer failure is directly correlated with the proliferation of discontinuities in both geometry and material that are characteristic of complex and peculiar designs; and because the education of architects (reflecting and enabling the intense competition among practicing architects for recognition based upon increasingly complex and peculiar formal manipulation) often abstracts from the underlying logic of control layer design, one can conclude that architectural design pedagogy is complicit in the epidemic of building failure within the U.S.44
Hannes Meyer famously attempted to devalue the role of the artist while emphasizing functional and technological issues within the curriculum of the Bauhaus. Such an extreme formulation of the art-science duality is only marginally relevant to the argument advanced in this paper, since there is no reason to "abolish" or even to denigrate the role of artistic expression within the design process. Even if "the idea of the 'composition of a dock' is enough to make a cat laugh,"45 such a finding (and I'm purposely taking this quotation literally) should not be extrapolated into the realm of human cognition. We construct — and in doing so, compose — our world irrespective of any desire, however rational, to prioritize function and technology. The question isn't whether art should be eliminated from architecture — art is unavoidable; the only question considered herein is whether and how the art of architecture can adjust its trajectory so that it aligns itself with the most fundamental requirements of building science.
Table 1: Papers from NCBDS 27 (2011)46
1 Many of the underlying ideas in this paper derive from my previous investigations into the relationships between technology and design.
2 I'm not denying the possibility of creating an abstract or conceptual architecture on the basis of intuition, or any other unselfconscious mode of creation. The point is that, in the final analysis, all architecture has a conceptual basis — that is, some abstract qualities — no matter how its designers understand or articulate their own design process.
3 Jean-François Lyotard, "Answering the Question: What is Postmodernism?" Thomas Docherty, ed., Postmodernism: A Reader, Columbia University Press, New York, 1993: "...modern aesthetics is an aesthetic of the sublime, though a nostalgic one. It allows the unpresentable to be put forward only as the missing contents; but the form, because of its recognizable consistency, continues to offer to the reader or viewer matter for solace and pleasure. Yet these sentiments do not constitute the real sublime sentiment, which is an intrinsic combination of pleasure and pain: the pleasure that reason should exceed all presentation, the pain that imagination or sensibility should not be equal to the concept." He continues: "The postmodern would be that which, in the modern, puts forward the unpresentable in presentation itself; that which denies itself the solace of good forms, the consensus of a taste which would make it possible to share collectively the nostalgia for the unattainable; that which searches for new presentations, not in order to enjoy them but in order to impart a stronger sense of the unpresentable." (p.46)
4 For a discussion of Le Corbusier's five points, see: Alan Colquhoun, Modern Architecture (Oxford: Oxford University Press, 2002), 146-149.
5 For a concise history of innovations in glass manufacturing, see "Chronology of Advances" in the "History of Glass," Wikipedia, (accessed 9/25/13).
6 Glass as "void" was not the only abstract category in which glass appeared within modernism: aside from its transparency, its reflectivity was also valued at times, as was its potential to let in sunlight or — when tinted — various colored lights.
7 Modernism, especially in its "brutalist" phase, exploited the "heroic" quality of materials like concrete, steel, or brick.
8 It is interesting to note, in this regard, that the funerary building types (pyramids, and so forth) or unbuilt Cenotaphs that can be seen as precursors of abstract modernism had little or no need for natural ventilation.
9 An informal and Canadian-centric "history" of the development of these control layers into pressure-equalized rain screen systems can be found in Joseph Lstiburek's "But I Was So Much Younger Then (I'm So Much Older Than That Now)," BSI-065, Building Science Insights (accessed Oct. 24, 2013).
10 Joseph Lstiburek, "Vapor Barriers and Wall Design," Research Report 0410, November, 2004 (pdf accessed Oct. 25, 2013).
11 Most cladding systems must be fastened through those control layers that are placed between the cladding itself and the structural substrate that supports it, but there is at least one exception: certain polymer-based exterior insulation and finish systems (EIFS) are light enough so that the lamina constituting the "cladding" of such systems is adhered directly to rigid insulation boards without mechanical fasteners.
12 Control layer problems emerged at Peter Eisenman's Wexner Center: "...it would seem embarrassing for any architect, let alone one as prominent as Peter Eisenman. You design a museum — your first large-scale work, a breakout project whose exterior scaffolding design, a virtual celebration of impermanence, sets the architecture world buzzing. Within just a few years, however, cracks start to show. Quite literally: the skylight leaks. The glass curtain wall lets in too much light, threatening to damage delicate artwork. The interior temperature swings by as much 40 degrees some days." (Robin Pogrebin, "Extreme Makeover: Museum Edition," New York Times, Sept. 18, 2005.
Different control layer problems plagued Frank Gehry's Stata Center: "MIT has settled its 2007 lawsuit against the architects and builders of the Ray and Maria Stata Center... MIT's lawsuit cited design and construction failures in the building. These included masonry cracking and poor drainage in the amphitheater; 'mold growth at various locations on the brick exterior vertical elevations'; 'persistent leaks' throughout the building; and sliding ice and snow." John A. Hawkinson, "MIT settles with Gehry over Stata Ctr. defects," The Tech, online edition, March 19, 2010.
Joseph Lstiburek also examined control layer problems at the Stata Center: "Lstiburek speculates that the Stata Center's leaks are caused by 'fishmouthing' of the waterproof membranes, discontinuities between the roof and walls, and poor design of the window-to-wall connections. But he claims something else is wrong — something even more basic. During a 45-minute, PowerPoint-aided lecture, he shows me MIT's own photos of the center being built. 'You see the yellow stuff, gypsum board. And you'll see the membrane going over this and then the brick. The insulation that is put on the inside should have been put on the outside. They just have them in the wrong order.' In the winter, when a building like this is heated, explains Lstiburek, who wrote the U.S. Department of Energy's handbook on moisture control, water vapor 'sweats' through the wall into the insulation and is trapped there by the waterproof membrane, just like your T-shirt gets sopping under a leather jacket. This erodes the wall, causes mold, and even makes the insulation smell like dirty socks." Anna Kamenetz, "Lost in the Funhouse: The Battle Between Starchitect Frank Gehry and MIT Reveals the Widening Chasm Between Design and Down-to-Earth Craft," Fast Company, first published February, 2008, later updated (accessed Nov. 10, 2013).
13 Photo credit: Ibagli, 2009, public domain (accessed Oct.25, 2013).
14 Photo credit: Tafyrn, 2006, public domain (accessed Oct.25, 2013).
15 Peggy Deamer, "First Year: The Fictions of Studio Design," Perspecta 36 (2005), p.2.
16 Proceedings of the 27th NCBDS (National Conference on the Beginning Design Student), University of Nebraska, Chairs: Lindsay Bahe, Peter Hind, Brian Kelly (2011) accessed 7/18/14.
17 Leslie Johnson, "Matter Matters," Proceedings of the 27th NCBDS, ibid., p. 337.
18 Claire Alyea and Nancy Yen-wen Cheng, "Online / On Target: Reflective Practice through Blogging," Proceedings of the 27th NCBDS, ibid., p. 154.
19 Brian T. Rex and Marti Lea Gottsch, "From a Sandbox of Objects to One of Things," Proceedings of the 27th NCBDS, ibid., p. 26.
20 Richard L Hoag, " Cumulative Learning in the Act of Design," Proceedings of the 27th NCBDS, ibid., p. 47.
21 Maria Vera, Jonathon Anderson, Ming Tang, and Shai Yeshayahu, "Re-Tooling the Logic of Design," Proceedings of the 27th NCBDS, ibid., p. 100.
22 Rima Al Ajlouni, "Biomimcry Studio: Nature-Inspired Sustainable Design Thinking Approach," Proceedings of the 27th NCBDS, ibid., p. 118.
23 Lohren Ray Deeg, "Introducing Multidisciplinary and Multi-scale Thinking Into a Beginning Design Project," Proceedings of the 27th NCBDS, ibid., p. 138.
24 Lohren Ray Deeg, "Introducing Multidisciplinary and Multi-scale Thinking Into a Beginning Design Project," Proceedings of the 27th NCBDS, ibid., p. 142.
25 Christopher Romano, Nicholas Bruscia, and Shadi Nazarian, The Living Wall: A Project of Many," Proceedings of the 27th NCBDS, ibid., p. 93.
26 Troy Nolan Peters, " Starting with Integration. Using Hybrid Techniques for Zero Energy Design," Proceedings of the 27th NCBDS, ibid., p. 126.
27 Jodi La Coe, " [re]Constructing the Sustainable Imagination," Proceedings of the 27th NCBDS, ibid., no page number.
28 The "art" and "science" of architecture produce a tension between the "freedom" of abstract thinking and the "pragmatics" of actual construction: "It is widely perceived today that there is an intrinsic tension between freedom of ideas in architectural education and the pragmatics of negotiation in the building process. Architecture remains one of the few professions that still allow dreams, but all designs, banal or avant-garde, must endure constraints of reality and seemingly unbearable compromises when put to realization. To their credit, architecture schools largely privilege abstract thinking in the design studio. This discrepancy between the education of architects and the practice of architecture produces an obscure yet revealing dynamic between the two realms, and it is this disjunction that enables the distance necessary to stretch and expand the boundaries of the architectural vocation." Angela Pang, "Implementing Architecture: Cornell and the Education of Architects," Architecture and Urbanism (A+U), May 2005 Special Issue, p.9.
29 Seng Kuan and Angela Pang (interviewers), "Education in Process: New Directions at Cornell," ibid, p.18.
30 Jonathan Ochshorn, "Designing Building Failures," op. cit.
31 Not considered in this paper are the types of "passive" technologies related to the orientation and position of a building on a site: in particular, the influence of sun and wind. While the damage done by abstracting from such issues is real, it is of a different sort from the literal damage caused by control layer failure. Poor decisions about orientation, functionality, and so on create added costs and inconveniences for building users, building owners, and for the larger society, but the building itself may remain intact.
32 "Perhaps the most important conclusion derives from the fact that, for unusual (peculiar or complex) architectural designs, the interaction of materials, systems, geometries, environmental conditions, installation methods, and so on, is rarely systematically tested or theoretically grasped. Conventional construction details and methods, on the other hand, have at least a track record of generally successful (or unsuccessful) application. While the lack of a consistent measure of reliability applies to such conventional systems as well, there is at least an informal understanding of how such systems perform over time. For this reason alone, one can state that nonstructural failure will generally increase as the peculiarity or complexity of the architecture (i.e., the deviation of its design from well-established norms) increases." Jonathan Ochshorn, "A Probabilistic Approach to Nonstructural Failure," op. cit.
33 Tony Tufariello, "Synthetic Stucco Failures," Gen Re Connect, undated (accessed Nov. 7, 2013)
34 Marshall, Robert R. "2001 Building Failures Study." CMHC Technical Series 01-140 (2001): 1-4. Conceptual Reference Database for Building Envelope Research, cited in Ochshorn, "Designing Building Failures," op. cit.
35 Robert Campbell, "Learning from the Hancock," Architecture, March 1988, p.68, cited in Ochshorn, "Dis-integrating technology and design," op. cit.
36 An example of such "pre-building" research can be seen in the glass enclosure system developed for La Cité des Sciences et de l'Industrie in Paris as described in: Rice, P. and Dutton, H. (1995) Structural Glass, E & FN Spon, London, New York, cited in Ochshorn, "A Probabilistic Approach to Nonstructural Failure," op. cit.
37 Casius Pealer, "Professional liability insurance: When to get serious," Architectural Record, Dec. 2007 (originally accessed Nov. 7, 2013; new link provided Nov. 24, 2015).
38 Suzanne Frank, Peter Eisenman's House VI: The Client's Response, New York: Whitney Library of Design, 1994, p. 64.
39 Peter Eisenman, "House VI," originally published in Progressive Architecture 58, no. 6 (June 1977) and reprinted in Frank, ibid., p.21.
40 I discuss the role of competition in driving and defining fashionable architecture in an unpublished essay written in 1983: "Fashionable Building: The Purpose of Architectural Education" (accessed Nov. 8, 2013).
41 The origin and meaning of "defamiliarization" is explained in countless texts, all of which credit the term to a 1917 essay by Viktor Shklovsky translated as "Art as Device" or "Art as Technique": see, for example, Svetlana Boym, "The Poetics and Politics of Estrangement: Viktor Shklovsky and Hannah Arendt," Alastair Renfrew and Galin Tihanov, eds., Critical Theory in Russia and the West, Routledge, New York, 2010, p.101.
42 Joseph Campbell, Pathways to Bliss: Mythology and Personal Transformation, Edited by David Kudler. Novato, California: New World Library, 2004, pp. 132-133.
43 Much of this material on the "heroic journey" is taken from my online essay, "Critique of Milstein Hall: Nonstructural Failure" (accessed Nov. 7, 2013), including the following evidence that some architects really do proudly wear this "badge of honor":
"'There's not an architect I know that doesn't have problems with important buildings,' Mr. Eisenman said in a recent interview in his New York office. He cited a comment that Frank Lloyd Wright is said to have made when a client called to complain that a house was leaking: You mean you left my building out in the rain? 'Do you know any architect that's been free of that? I don't know any,' Mr. Eisenman said. 'Frank, Rem — they all do,' he said, referring to Frank Gehry and Rem Koolhaas. 'Wright, Corbu, Mies. Look at Mies and the Farnsworth House — enormous problems.'" Peter Eisenman quoted in Robin Pogrebin, "Extreme Makeover: Museum Edition," op. cit.
Frank O. Gehry, referring to suit brought by M.I.T. over leaks, cracks and drainage problems at the Stata Center, said: "These things are complicated and they involved a lot of people, and you never quite know where they went wrong. A building goes together with seven billion pieces of connective tissue. The chances of it getting done ever without something colliding or some misstep are small." Robin Pogrebin and Katie Zezima, "M.I.T. Sues Frank Gehry, Citing Flaws in Center He Designed," New York Times, November 7, 2007 (accessed June 9, 2010).
The heroic attitude was articulated brilliantly by Piet Mondrian in 1925: "If one takes technique, utilitarian requirements, etc., as the point of departure, there is a risk of losing every chance of success, for intuition is then troubled by intelligence." L'Architecture Vivante (Autumn, 1925), p.11; referenced in Collins, Peter. Concrete: The Vision of a New Architecture, 2nd edition. Montreal: McGill-Queen's University Press, 2004, p.281.
44 Chen, S., et. al, eds. (2010) Forensic Engineering 2009: Pathology of the Built Environment, American Society of Civil Engineers, Reston, VA., cited in Ochshorn, A Probabilistic Approach to Nonstructural Failure, op. cit.
45 Hannes Meyer in the essay, "Bauen," quoted in K. Michael Hays, Modernism and the Posthumanist Subject: the Architecture of Hannes Meyer and Ludwig Hilberseimer, MIT Press, Cambridge, MA, 1992, pp.158-159.
46 The images and quotes in Table 1 are taken from the 80 papers in the Proceedings of the 27th NCBDS, op. cit., numbered in the order of their appearance, as follows:
First posted 18 July 2014. Last updated: 9 July 2019