From city’s station to station city


 001 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 7 / NUMBER 2 / 2019

Superposition matrix for the 
assessment of performance-
relevant adaptive façade functions

Jens Boeke*1, Ulrich Knaack1, Marco Hemmerling2

* corresponding author
1 TU Delft, Architecture and the Built Environment, J.Boke@tudelft.nl
2 Cologne University of Applied Sciences, Institute for Architectural Design

Abstract
The environmental boundary conditions and the demand for comfort change constantly during the use of a building. By dynamically 
balancing changing conditions and requirements, adaptive façades contribute to the energy efficiency of buildings. The façade fulfils 
a multitude of functions that are interdependent and relate to environmental conditions and requirements. By negotiating mutually 
supportive and competing adaptive functions, intelligent coordination offers the potential for better performance of façades in building 
operation. The strategy is already being applied in other application areas, such as the intelligently cooperating machines in industry 
4.0. There, individual automated production plants are networked to form intelligent technical systems with regard to a common 
production goal. The research presented follows the assumption that this strategy can be applied to automated and adaptive functions 
of the façade to increase the building performance. The study identifies those functions which, due to possible automation and adap-
tivity, as well as effect on performance, can be considered as possible components of an intelligently cooperating system. In addition, 
characteristics are determined which can be used to evaluate the extent of automation and adaptivity of an individual façade function. 
The study shows that the detailed analysis of the automation and adaptivity within identified façade functions is possible. With a super-
imposition matrix, it also provides a tool that enables this assessment of the degree of automation and adaptability.

Keywords
Intelligent building envelope, superposition matrix, adaptive façade, multi-functionality, intelligent technical system



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1 INTRODUCTION

 1.1 BACKGROUND

The façade determines the overall performance of the building. It has an impact on the indoor 

comfort and the buildings´ energy efficiency. In view of current objectives related to energy saving 

and the increased demands on the well-being of users within buildings, there is a demand for 

more efficient façade systems. Researchers see a potential in adaptive façades. (Aelenei et al., 

2015) The climatic conditions of the outdoor environment and the indoor requirements are 

constantly changing. The balancing of both presents a continuous optimisation of the construction 

properties with regard to the performance of the façade. This enables savings in the operation of 

energy-consuming building services, which can be reduced if the building envelope guarantees a 

desired indoor climate. 

The façade fulfils a multitude of additional functions in the role of a mediator between the exterior 

and interior. The façade functions are derived from the influences of the environment and the 

requirements of building use. The façade functions are mutually interdependent. They can conflict 

or positively influence and complement each other. Moloney (2011) and Loonen, Trčka, Cóstola, 

and Hensen (2013) formulate the demand for holistic concepts instead of fragmented solutions 

for adaptive façades. Adaptive façades are being researched and realised, but the development is 

still at an early stage. (Aelenei et al., 2015) The implementation of adaptive façades often includes 

automation technology. Over the past decades, research and development in this field provided the 

technical basis for the realisation of such systems. (Schumacher, Schaeffer, & Vogt, 2009) These 

include the miniaturisation of electronics and computer technologies, as well as the developments in 

sensor and actuator technologies. 

The close interaction of computer-based control and communication with physical technical systems 

forms the concept of Cyber-physical systems. An important aspect is the cooperation of distributed 

system components.  (Monostori, 2014; Rajkumar, Lee, Sha, & Stankovic, 2010; Wang, Torngren, 

& Onori, 2015) The Internet of Things (IOT) describes the comprehensive and internet-based 

networking of physical objects. All devices that have an embedded control system and the ability to 

communicate can be part of it. (Bittencourt et al., 2018) In the current development of an Industry 

4.0, the flexibility and productivity of manufacturing processes is increased by networking individual 

production facilities into so-called intelligent technical systems. Technological developments in 

various research fields, such as IT and neurobiology, are merged to provide mechatronic systems 

with intelligence based on embedded sensors, actuators, and cognitive abilities. The individual 

technical systems within an intelligent technical system work autonomously and are able to 

communicate and cooperate with regard to a common production goal. (Dumitrescu, Jürgenhake, 

& Gausemeier, 2012)  

Böke, Knaack, and Hemmerling (2018) assume that such strategies can be applied to the operation 

of the building envelope. By networking automated adaptive façade functions within an intelligent 

system, the efficiency of the façade in building operation is to be increased in the sense of greater 

flexibility and productivity in industrial production. 

For the networking, a differentiated understanding of the individual façade functions and the 

individual possibilities of automation and adaptivity is required. There are different lists of façade 

functions that do not take adaptivity into account, such as the “façade function tree” by Klein (2013). 



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Loonen et al. (2015), for example, provide characteristics of adaptivity for the overall system of the 

façade without consideration of individual functions.

 1.2 PROBLEM STATEMENT

The possibility of an intelligent cooperation of automated adaptive façade functions according to the 

model of networked production plants in industry has not yet been clarified. The role of an individual 

adaptive façade function as a component of an intelligently networked façade can only be assessed 

by comparing it with the project-specific environmental conditions and performance requirements. 

It is uncertain which façade functions can be considered as a part of an intelligently networked 

system due to an adaptive feasibility and an effect on the performance of the façade. Previous 

listings of façade functions, like the “façade function tree” by Klein (2013) or the “façade as an 

interface” by Hausladen, de Saldanha, Liedl, and Sager (2005) refer to the façade generally, and 

differ in organisation, scope, and detail. The transfer of the networking strategy from industrial 

production plants to the façade depends, according to the technical basis of an industry 4.0, on the 

comprehensive automation and adaptivity of the individual functions. 

There is a lack of assigned characteristics by which the degree of automation and adaptivity of 

an individual façade function can be assessed. Previous studies on a possible characterisation of 

adaptive façades, such as the composition by (Loonen et al., 2015), refer to the façade as an overall 

system. They do not provide a complete result, since they refer to partial aspects such as either 

functionality or the degree of automation.

 1.3 OBJECTIVES

The aim of the study is to develop a holistic view of adaptive façades in the interplay of requirements 

and external boundary conditions. The knowledge about dynamically changing factors of the 

boundary conditions supports a later decision as to which information must be collected via sensors 

for the intelligent operation of a networked façade system. For this purpose, the individual factors to 

which the adaptive façade must react are to be recorded. In addition, the various requirements for 

interior comfort are to be compiled as target values for the intelligently networked façade system.

Façade functions that can be automated and adaptive, and that affect the performance of the façade, 

meet the requirements for a possible cooperation with other façade functions within a networked 

system. One aim of this study is to identify these façade functions and assign characteristics to 

assess the degree of an automated adaptivity. 

As a tool for the subsequent examination of the actual requirements in practice, the identified façade 

functions are to be superimposed with the identified characteristics of automation and adaptivity in 

a superposition matrix.



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 1.4 RESEARCH QUESTION

Main question:

How can the automated adaptivity of façade functions be assessed to systematically identify them as 

a possible part of an intelligently networked façade?

Sub questions: 

 – What are the boundary conditions of an intelligently networked façade and from which 
environmental conditions and comfort requirements derive its adaptive functions? 

 – Which façade functions are possible part of an intelligently networked façade due to a possible 
adaptive implementation and an impact on the building performance?

 – How can the automated adaptivity of a façade function be assessed? 

2 METHODOLOGY 

The investigation is based on a literature review. It is organised into two main parts. In the first 

part, under section 3, the boundary conditions of an intelligently networked façade are recorded 

in response to the first sub question. These include the environmental conditions with dynamic 

parameters, as well as the different requirements for interior comfort. Both fields are extensively 

researched and documented in literature and standards. This first section, as shown in Fig. 

1, provides the context for the subsequent assessment of whether a façade function can be 

implemented automated adaptive and whether it has an effect on building performance.

Literature review

Filtering &
consolidation

Superposition

Indoor comfortEnvironmental 
conditions 

Façade 

Changing 
parameters

Requirements Façade functions Characteristics 
of adaptivity

Superposition matrix of façade functions  
and characteristics for the assessment of 
automation and adaptivity

Context
Filtering &
consolidation

FIG. 1 Graphical abstract



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A focus of the study is on the automated adaptive façade functions examined in the second part in 

Section 4. Previous lists such as the “façade function tree” by Klein (2013) contain an overview of 

all façade functions without restriction as to whether an adaptive implementation is feasible and 

whether it affects the performance of the building envelope. The list “façade as an interface” by 

Hausladen et al. (2005) corresponds to the approach of classifying façade functions in a holistic 

view, taking environmental conditions and comfort requirements into account. It serves as a 

starting point for the identification of relevant façade functions in this study. In order to ensure the 

completeness and accuracy of the functions identified by them, the list is overlaid with alternative 

layouts developed by Klein (2013) and in the research of mppf - The multifunctional plug&play 

approach in facade technology 2015). The overlaid data sets of façade functions is consolidated and 

filtered, as shown in Table 1 of Section 4.1, according to performance relevance as well as a basically 

possible adaptivity. The identification of characteristics that can be used to assess the automated 

adaptivity of a façade function is also based on existing literature. Different references are overlaid 

and consolidated based on the research by Loonen et al. (2015) with the goal of a complete list of 

evaluation characteristics of automation and adaptivity.

Façade function 1

Characteristics of adaptivity

Fu
n

ct
io

n

Characteristic 1 Characteristic  2 Characteristic (...)

Characteristic 1 Characteristic  2 Characteristic (...)Façade function 2

Façade function (...)

FIG. 2 Schematic representation of the superposition matrix

For the assessment of the automated adaptivity, the determined characteristics are assigned to 

the previously identified individual façade functions. This step is done regarding the third sub 

question in a systematically structured superposition matrix according to the representation in 

Fig. 2. The usability of the superposition matrix is tested on the basis of an exemplary application 

to an existing façade project. The necessary project information for the application example is 

derived from literature.  



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3 THE CONTEXT OF ENVIRONMENTAL BOUNDARY 
CONDITIONS AND COMFORT REQUIREMENTS

 3.1 IDENTIFICATION OF ENVIRONMENTAL BOUNDARY 
CONDITIONS AND RELATED DYNAMIC PARAMETERS 

The climate is composed by the variations of different elements. According to Dahl (2010), the 

detached discussion of individual aspects is difficult since they are in a constant and dynamic 

relationship to one another. Bitan (1988) identifies temperature, humidity, wind, precipitation, 

solar radiation, and special features as parameters with a high impact on the building. Hausladen, 

Liedl, and Saldanha (2012) designate the same climate elements as the most important for the 

construction planning, but without the addition of “special features”. In the consideration of the 

“façade as an interface” Hausladen et al. (2005) designate the sound as an influencing element. 

van den Dobbelsteen, van Timmeren, and van Dorst (2009) also supplement this aspect. Dahl (2010) 

focusses on, from his point of view, the most important aspects: heat, humidity, wind, and light.

In an overarching view, the following climate elements relevant to the building industry are 

identified. With regard to the adaptivity of the façade, the focus is on the dynamic parameters of an 

environmental condition.

Solar radiation 

Solar radiation is electromagnetic radiation emanating from the sun (Givoni, 1976). The energetic 

radiation power determines the intensity of the solar radiation. It changes with respect to the time 

of day or season as well as to the weather. Another important aspect is the duration of irradiation, 

depending on the geographical location and the weather (Ranft & Frohn, 2004). Global radiation 

is composed of direct sunlight and indirect, diffuse radiation. The angle of incidence of the direct 

sunlight is another important aspect. The greatest amount of energy is released at an incidence 

angle of 90 degrees to a surface. The intensity, the duration of irradiation, and the angle of incidence 

of the irradiation can be summarised as the important parameters of the solar radiation.

Temperature

Solar radiation indirectly affects the outside air temperature by heating the earth’s surface. This 

provides heat energy to the air layers above. Also, the exchange with inflowing air affects the 

temperature. Depending on the geographic location, the season, and the time of day, the temperature 

is subject to great variations. Between 1.5 and 3 m depth, the average temperature of the ground 

remains constant throughout the year. (Givoni, 1976; Hausladen et al., 2012) The air temperature 

measured in degrees Celsius is determined as the decisive parameter of this climatic element.

Air quality

The air quality is determined by its oxygen content as well as its pollution. Air pollution occurs 

mainly in dense urban areas as a result of traffic or industrial processes. Plants can also be the 

cause of reduced air quality due to the formation of pollen (Hasselaar, 2013).



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Sound

Developments in both transport and industry are accompanied by noise emissions. Due to the 

density of urban areas noise pollution can often not be avoided. Noise in the environment has an 

impact on human comfort and depends on the distance between the source and the building. Sound 

differs by type, duration, and transmission. Hausladen et al. (2005) distinguish linear and selective 

sound sources. The duration of a noise load can be continuous, interrupted, or recurring. Sound 

transmission can take place via air or via building components and materials. The sound applied to 

the building is measured outside in decibels (Hausladen et al., 2005). 

Wind

Wind is an effect of the earth’s air flow and pressure system. It is based on the distribution of air 

pressure, the rotation of the earth, the alternation of heat and cool over land and over water, and the 

topography of a respective region. Winds vary according to seasons. There are global wind systems 

like the trade-winds, westerlies, and polar winds. Additionally, time-bound winds exist due to high 

temperature differences. Local winds occur between water and land or mountains and valleys 

(Givoni, 1976). The microclimatic conditions such as terrain and building form have a great impact. 

For example, nozzle effects are possible, depending on the building arrangement (Hausladen et al., 

2012). The pressure acting on a building depends on the local wind force. Force and direction of the 

wind are identified as crucial parameters.

Precipitation

Precipitation is a component of the water cycle. Depending on the temperature, the water changes 

its form from gaseous to liquid. The cooling of the air condenses the moisture stored in it and leads 

to precipitation. The dew point is the temperature at which this process takes effect. Along with 

rain, mist and dew are also forms of precipitation (Givoni, 1976). The precipitation quantity and the 

possible precipitation direction are identified as parameters of the climate element. 

Humidity

Humidity is defined as either relative humidity or absolute humidity. Absolute humidity refers to 

the location-related, stored water vapour in the air. It is dependent on precipitation and the distance 

to the sea. Absolute humidity is constant during the day, while relative humidity is subject to 

temperature fluctuations. Cold days have a decreasing effect, warm days have an increasing effect 

(Hausladen et al., 2012). 



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 3.2 IDENTIFICATION OF REQUIREMENTS FOR THE INDOOR COMFORT

The comfort in buildings can be in conflict with energetic performance goals. The quality of an 

interior climate has a significant impact on the well-being, health, and productivity of users. 

The demands on the interior climate of a building are guided by the needs of the comfort of the 

human being. They vary according to subjective perceptions and preferences (Ranft & Frohn, 2004). 

Comfort can be determined by a range of factors, some of which are related to each other in a way 

that is not scientifically understandable (Ranft & Frohn, 2004).   

Essential aspects of comfort are, according to Knaack et al. (2014), perceived temperature, visual 

comfort, hygienic comfort, and acoustic comfort. A clear assignment of the aspects relevant to a 

user’s comfort cannot be determined universally due to varying individual perceptions. In order 

to determine the climatic quality of an interior environment, specialist planners rely on the level 

of satisfaction of users (Hasselaar, 2013). In many cases, there are legal requirements that a 

building must meet. In Germany, minimum requirements for the indoor climate are defined in 

the following guidelines and standards: Important for the evaluation of interior comfort are ANSI/

ASHRAE 55 - Thermal Environmental Conditions for Human Occupancy and DIN EN 15251 - Indoor 

environmental input parameters for design and assessment of energy performance of buildings 

addressing indoor air quality, thermal environment, lighting and acoustics; German version EN 

15251:2007. For indoor environments in general, the ISO 7730 defines requirements with regard to 

thermal comfort and DIN 5035 with regard to daylight.  Requirements for comfort in office buildings 

are defined by the standards DIN1946 and DIN 33403: “Climate at the workplace”. The acoustic 

requirements in office buildings are regulated by DIN 2569: Sound insulation in office buildings. 

(Ranft & Frohn, 2004) Al horr et al. (2016) identify the thermal comfort, acoustic comfort, and visual 

comfort as important factors for the well-being and productivity of users. Dahl (2010) complements 

aero-comfort and hydro-comfort in terms of the indoor air quality.

Thermal comfort

The operative temperature, also known as the sensed temperature determines the thermal comfort 

and is composed of the radiation and air temperature of the room (Hasselaar, 2013). It is often 

understood as the most important aspect in terms of interior comfort. The human body maintains 

an operating temperature of about 37 degrees Celsius (Dahl, 2010). Hausladen, Saldanha, and Liedl 

(2008) determine the operative temperature in combination with the air speed as decisive factors 

for the thermal comfort.  Al horr et al. (2016) name air temperature, average radiation temperature, 

relative humidity, air speed, and individual aspects such as clothing as the six influencing factors 

that affect thermal comfort. An uneven distribution of the room temperature leads to discomfort. 

The activity of a person, clothing, age, sex, health and duration of stay in an environment influence, 

according to Hausladen et al. (2005), the sensitivity towards temperature. Too high temperatures can 

weaken the performance of a person while cold temperatures lead to illness. Hausladen et al. (2005) 

formulate the following temperatures as average demand values separated by winter and summer 

season: In winter, the comfortable operating temperature is 22C° at air speeds of approx. 0.16m/s, 

while in summer it is 24C° with an air speed of 0.19m/s.



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Aero- and hydro-comfort 

According to Dahl (2010), comfort also depends on air movement and cooling, both of which occur 

with convection and evaporation. As the temperature increases, larger air movements are perceived 

as positive. (Ranft & Frohn, 2004) The quality of the indoor air is based on the quality of the ventilated 

external air and possible influences by users, technical installations, materials, or indoor plants. 

Air pollution outdoors can have a negative effect on the air supply. High-quality air is based on a high 

oxygen concentration and a low dust and pollution load. The perceived contamination of indoor air 

is measured in Decipol (Dp). The CO2 concentration is also an aspect of air quality. In addition to the 

activity of the user, Hausladen et al. (2008) also name behaviours such as smoking as an influencing 

factor. The perceived quality of the air decreases with increasing humidity and temperature. The olf 

measure corresponds to the air pollution of a user doing light office activities. Hausladen et al. (2008) 

give 0.15vol% as the maximum CO2 concentration. Dahl (2010) describes the hydro-comfort with 

regard to the humidity. Relative humidity can be subject to large fluctuations between about 20% 

and 70%. It has an impact on health and how people feel within interior climates. Large rooms can 

more easily compensate for humidity due to a larger air capacity, whereas small rooms require more 

extensive air exchange. (Dahl, 2010; Ranft & Frohn, 2004)

Visual comfort

Hausladen et al. (2008) establish that natural light has a positive effect on the visual comfort of users. 

According to them, the quantity of the light provided, and its distribution, are crucial. The human 

eye adapts to the prevailing light conditions (Dahl, 2010). Glare can have a negative impact on 

the user. It occurs as a result of direct radiation originating from sun or artificial light sources, as 

well as reflections of light irradiation. Large contrasts in the lighting also lead to possible glare. 

Low contrasts and low shadows reduce it and promote spatial perception. Visual references to the 

outside contribute to the well-being of the users. (Hausladen et al., 2008)

Acoustic comfort

Acoustic comfort is based on the protection from noise and the guarantee of a sound environment 

which corresponds to the use of the building (Al horr et al., 2016). Acoustics is associated with 

well-being and the ability to concentrate within a room. Sources of noise pollution may be outside 

the building or may result from the activities within a room. Sound is measured in Decibel (Db). 

The volume of sound is a decisive factor. The weighted sound level considers people to be more 

sensitive to specific frequencies than to others. The addition (A) indicates the correspondingly filtered 

measured variable. Silence corresponds to the value 0Db(A) and noise above 140Db(A) is perceived to 

be painful (Hasselaar, 2013). The reverberation time describes the duration of a noise and has a great 

effect. The noise should not collide with communication or concentration in a building. Hausladen et 

al. (2005) formulate a noise load of 30-45db (A) as an acceptable maximum.



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 3.3 INTERPRETATION OF THE IDENTIFIED ENVIRONMENTAL 
CONDITIONS AND COMFORT REQUIREMENTS

A total of seven categories of environmental conditions have been identified as illustrated in Fig. 3. 

Different dynamic parameters are possible within the respective category.  The influencing factors 

are not always subject to a natural origin but can also be the result of human intervention in the 

environment. Examples of such artificial influencing factors are the noise environment within urban 

areas or traffic-related air pollution. Depending on the project’s geographical and temporal context, 

different patterns of influencing factors are possible. On the other hand, there are a total of four 

identified categories for interior comfort. Different requirements can be assigned to the individual 

categories. Hausladen et al. (2008) distinguish detailed requirements of the interior comfort in 

the “façade as an interface”. The “room temperature”, the “inside surface temperature”, and the 

“supply air temperature” named by them can be assigned to the thermal comfort. Illuminance, glare 

protection, and visual relationships affect the visual comfort. The aero- & hydro-comfort can be 

detailed into air changes, air quality, and air speed, while the sound load named by Hausladen et 

al. (2008) can be assigned to the acoustic comfort. It is not claimed that the listed requirements are 

complete. They are the basic requirements that can be supplemented depending on the conditions 

of different building uses. Fig. 3 illustrates the context of the environmental conditions and comfort 

requirements from which the adaptive functions of the façade derive:

Environmental 
Conditions

Solar radiation
Temperature
Air quality
Sound
Wind
Precipitation
Humidity

Indoor requirements

Thermal comfort
Aero- & hydro-comfort 
Visual comfort
Acoustic comfortFaçade

FIG. 3 Context of environmental conditions and comfort requirements 

The context provides a holistic view of the façade in terms of its dependence on environmental 

conditions and comfort requirements. It contributes to the understanding of individual reactions of 

an adaptive façade function. Possible intersections between the individual reactions can be identified 

with regard to the differentiated environmental conditions and indoor comfort requirements. 

The context is intended to serve as a decision aid in the selection of façade functions for networking 

and existing dependencies and interferences in cooperation.



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4 IDENTIFICATION OF FAÇADE FUNCTIONS AND 
CHARACTERISTICS OF ADAPTIVITY

 4.1 PERFORMANCE RELEVANT AND POSSIBLY 
ADAPTIVE FUNCTIONS OF THE FAÇADE

The façade has a great impact on the energy and comfort-related quality of a building. As shown in 

Fig. 4, it balances the dynamic climatic conditions of the exterior environment with regard to the 

requirements of the interior (Hausladen et al., 2008). It determines the appearance and contributes to 

the design assessment of a building (Fassaden, 2015; Knaack et al., 2014). Features of the façade can 

be distinguished according to whether they have an effect on the building’s performance or solely on 

the aesthetic design of the façade. In this respect, Loonen et al. (2013) exclude, for example, media 

façades, which exclusively present visual adaptive features without contributing to the performance, 

from the definition of climate-adaptive building envelope. 

The expectations and demands on the functional spectrum of façades continuously increased 

throughout the development history. (mppf - The multifunctional plug&play approach in facade 

technology, 2015) At the same time, technical possibilities available for the façade construction have 

multiplied. Klein (2013) notes an extensive mechanisation of the façade, which, in his view, in the 

latest development also fulfils additional comprehensive tasks of building services. Klein (2013) 

describes the functions as an elementary aspect for the investigation and development of façade 

constructions. According to Herzog et al. (2004) the building envelope separates and filters between 

the outdoor environment and interior of the building. From a historical point of view, it is the job of 

the façade to provide protection against the dangers and the weather of the exterior. Herzog et al. 

(2004) state that additional requirements for the building envelope result from the local external 

environment and the requirements of the interior. In this context they specify further control and 

regulatory functions in addition to the protection function of the façade. According to Knaack et al. 

(2014), the façade is a dividing element between the exterior and interior, that satisfies multiple 

functions with the simplest structure possible. They argue that these functions include the provision 

of visual openings, balancing of wind loads, and load-bearing properties. Herzog, Krippner, and Lang 

(2004) see the façade as an interface, which ensures a comfortable interior climate. Depending on the 

different requirements of different seasons, they are also confronted with a target conflict of different 

façade functions. Herzog et al. (2004) also identify conflicts of interest in the different requirements 

of different seasons. They differentiate between different requirements in summer and in winter. 

According to Herzog et al. (2004), it is not only crucial which functions the building envelope fulfils, 

but also how the functions are organised with regard to one another. The interplay of individual 

façade functions can allow for synergy effects. There are different, differentiated representations 

of the functions of a façade. They differ in scope, detailing, and organisational structure. In an 

overlapping composition of façade functions “The façade as an interface”, Hausladen et al. (2005) 

contrast the functions with corresponding influencing factors and requirements. In this way, they 

also manifest superimpositions, for example when façade functions are derived from several external 

conditions or when they affect various interior requirements. They identify a total of thirteen climate-

related functions. Participating researchers of the project “multifunctional plug & play facade” 

formulate functions of the façade in three categories. The first category refers to the basic, mainly 

protective and climate-related functions of the façade. Solar thermal energy and photovoltaics are 

listed in a separate section on energy production. In the third category, supporting functions of the 

façade are named. This category includes tasks such as heating, cooling, or mechanical ventilation 

(mppf - The multifunctional plug&play approach in facade technology, 2015), Klein (2013) differentiates 



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the functions of the façade in an objective tree, based on strategies from product design. It organises 

the functions stepwise into primary, secondary, and support functions. The “Façade function tree” 

represents a comprehensive and detailed breakdown of the façade functions in five categories. 

These include the durability of the construction, an appropriate manufacturing process, ensuring 

sustainability, support for building use, and the shape of the façade. It is assumed that the functions 

of the categories: “Create a durable construction”, “Allow reasonable building methods” and “Spatial 

formation of façade” can in principle not be implemented in an adaptive manner. It is also assumed 

that not all functions affect the performance of the building in operation. Against this background 

and due to the size of the composition, a pre-selection is made regarding the categories “provide 

comfortable interior climate” and “responsible handling in terms of sustainability”.

FIG. 4 Facade functions by Knaack, Klein, Bilow, and Auer (2014)

The assembly of façade functions in Table 2 is derived from the consolidation of the previously 

identified lists by Hausladen et al. (2005),  Herzog et al. (2004), Klein (2013), and (mppf - The 

multifunctional plug&play approach in facade technology, 2015). The layout by Hausladen et al. 

(2005) is already tailored to the climate related functions of the façade. It serves as the starting 

point for the merging with the alternative constellations. In the superposition of the compositions 

it becomes clear that many of the functions, which are designated identically or slightly modified, 

overlap. Duplicates are removed as part of the consolidation. 



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CONSOLIDATED LIST FILTER ACTION CONSOLIDATED LIST FILTERED

General function Specification

Sun

1 Glazing fraction Irrelevant to an adaptive imple-
mentation

Skipped 1 Solar shading

2 Shading Specified to „Solar“ Modified

3 Solar control glass Specification

4 Light deflection 2 Light deflection

5 Glare protection 3 Glare protection

6 Control daylight radiation 4 Control daylight radiation Provide a comfortable 
daylight level

8 Allow natural lighting of interior Allow to control Modified Allow natural lighting of 
interior

Temperature 

9 Thermal insulation 5 Thermal insulation Heat protection

10 Heat insulation glass Specification (of Thermal insulation) Modified   maintain indoor tem-
perature

11 Thermal storage mass Irrelevant to an adaptive imple-
mentation

Skipped

12 Decentralised equipment Is more of a property than a function Skipped

13 Maintain air tightness Irrelevant to an adaptive imple-
mentation

Skipped

Air

14 Window ventilation Specification (Change to Ventilation) Modified 6 Ventilation Control air exchange rate

15 Control air exchange rate Specification Ventilate excessive heat

16 Ventilate excessive heat Specification

User

17 Allow visual contact Allow to control Modified 7 Control visual contact Visual contact to outside

  Visual protection for inside

Acoustic

18 Sound insulation Sound insulation = reduction? 
Level of success

8 Sound insulation

19 Sound reduction

20 Insulation of connection to divid-
ing walls

Irrelevant to an adaptive imple-
mentation

Skipped

21 Insulation of floor connection Irrelevant to an adaptive imple-
mentation

Skipped

Energy

22 Collect solar thermal energy 9 Generate energy Collect solar thermal 
energy

23 Collect solar energy   Collect solar energy

10 Store energy

Supply (not dependent on outdoor climate but relevant to indoor comfort) 

24 heating combination with cooling Modified 11 heating and cooling

25 cooling Modified

26 humidification combination with dehumidification Modified

27 dehumidification Modified 12 de- / humidification

28 electricity 13 electricity

29 artificial light 14 artificial light

30 communication 15 communication

TABLE 1 Development of the consolidated and filtered list of façade functions



 014 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 7 / NUMBER 2 / 2019

In addition, the functions are filtered as shown in Table 1 in consideration of the environmental 

factors and requirements identified in Section 3 according to two decisive aspects: first, an adaptive 

implementation must be possible in principle. This precondition is not given for example in the 

case of “glazing fraction” listed by Hausladen et al. (2005). The function is definitively determined 

within the planning and manufacturing process and not dynamically changeable in the operating 

phase of the building. It is therefore not taken into account for the present assembly. On the other 

hand, the function must have an impact on the performance of the building. Within the scope of the 

consolidation, further decisions are made that have an impact on the result. In some cases, Klein 

(2013) provides the detailing of individual, opposite states of a front function. With regard to an 

adaptive implementation, these functions can be summarised. An example of such a merge are the 

functions “block radiation” and “let radiation pass”. Correspondingly, the reduction and the insulation 

of sound can be combined as different degrees of fulfilment of the function. Klein formulates 

several of the identified façade functions with the addition “Allow”. With respect to an adaptive 

implementation of the respective function, an opposite state is assumed to be possible and the term 

is converted to “Control”. In the category “Responsible handling in terms of sustainability”, Klein 

(2013) identifies functions which do not directly affect the performance of the building. The collection 

of solar and solar-thermal energy can contribute to the functioning of the façade depending on the 

climatic conditions of the exterior. The corresponding functions are also named in the list by mppf - 

The multifunctional plug&play approach in facade technology 2015) and are taken into account in the 

consolidated summary. In the “Supply” category, they also name functions of building technology, 

which have an effect on the interior climate, regardless of external boundary conditions. They are 

also added to the list of functions.

GENERAL FUNCTION SPECIFICATION GENERAL FUNCTION SPECIFICATION

Sun Acoustic

1 Solar shading   8 Sound insulation  

2 Light deflection   Energy

3 Glare protection   9 Generate energy Collect solar thermal energy

4 Control daylight radiation Provide a comfortable daylight level   Collect solar energy

Control natural lighting Allow natural lighting of interior 10 Store energy  

Temperature Supply

5 Thermal insulation Heat protection 11 Heating and cooling  

  maintain indoor temperature 12 De- / humidification  

Air 13 Electricity  

6 Ventilation Control air exchange rate 14 Artificial light  

  Ventilate excessive heat 15 Communication  

User

7 Control visual contact Visual contact to outside

  Visual protection for inside

TABLE 2 Consolidated and filtered assembly of performance-related façade functions 



 015 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 7 / NUMBER 2 / 2019

 4.2 CHARACTERISTICS OF ADAPTIVITY

Loonen et al. (2015) require uniform aspects which can be used to determine the adaptiveness of 

a building envelope. They identify eight characteristics of adaptivity which they also assemble in 

a matrix. The starting point of the investigation by Loonen et al. (2015) is the adaptivity. In the first 

aspect, they question the goal and purpose which should be achieved with it. Loonen et al. (2015) 

name a total of six objectives, which are derived from the requirements of interior comfort, user 

control and energy generation. For each objective, they identify appropriate, responsive functions. 

In contrast to the listing by Loonen et al. (2015), this study is organised according to the façade 

functions themselves. According to the identified façade functions in context of environmental 

conditions and indoor comfort requirements in Chapter 3 of this research, the objectives of a façade 

function are not questioned again. A relevant characteristic is whether a façade function can be 

adaptive at all. A distinction is made between the flexibility of the building envelope, i.e. the adaptivity 

which has to be initiated by the user, and the adaptiveness which requires independent, self-

regulated adjustments (Ross, Rhodes, & Hastings, 2008). In addition, the technology, which can be 

a construction component or a material that carries out the function, is questioned as an aspect by 

Loonen et al. (2015). The accordingly named “spatial scale” is understood to be directly coupled to 

it. Under “Degree of adaptivity” they summarise the possible states of an adaptive process. These 

can, according to them, map the direct change between extreme states (on-off) or smooth transitions 

(gradients). With regard to the application to a façade function or a component, this characterisation 

appears to be insufficient. The question arises as to whether an open window is ON or OFF. As a 

supplement to this characteristic, a generalisation of the state description is proposed in “active” and 

“inactive”. Additionally, one should define when a corresponding state is reached for each function. 

The response time is adopted as a criterion of adaptivity. It is assumed that it provides information 

on whether the adaptation processes meet the dynamic requirements of a façade function. Loonen 

et al. (2015) identify visibility as a characteristic of an adaptive façade. As this aspect has no effect 

on the performance of the façade it is not taken into account in the present study. Loonen et al. 

(2015) distinguish between intrinsic adaptations, the construction or material inherent adaptations 

in response to ambient stimuli, and extrinsic adaptations, which are based on additional automation 

technology. From a technical point of view, therefore, the scope of introduced automation technology 

can also be a criterion for the capabilities of an adaptive façade function. In this context, Moloney 

(2011) and Ochoa and Capeluto (2008) refer to the components of a mechatronic system, an existing 

input system, a processing system, and an output system. An existing sensor system, which 

continuously collects data on the relevant environmental conditions, can be identified as a criterion 

for adaptive façades. Additionally, an existing control, which processes the determined data, as well 

as actuators, which initiate adjustments within the façade construction, are further criteria. Table 

3 is a revised list of characteristics for the adaptivity of façades. 



 016 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 7 / NUMBER 2 / 2019

GENERAL CRITERIA DESCRIPTION POSSIBLE PARAMETERS

General

1 Technology The construction-related element, which ensures the 
fulfilment of the function.

Building component / System / Material

2 Flexible Possible Flexibility of the construction regarding the 
function

Yes / No

3 Adaptive Self-initiated adaptations (applied Automation 
 technologies) 

Yes / No

Behaviour

4 Operation Component or material-integrated self-adaptation or 
on the basis of information processing

Intrinsic / Extrinsic

5 Response time Time intervals of adaptation processes Seconds, Minutes, Hours, Day-night, Seasons, Years, 
Decades

6 Degree of adaptability The number and type of possible states that the 
 adaptive system can map.

Active / Inactive / Gradual 

Automation

7 Input system Existing information gathering (sensors) Yes / No

8 Processing system Existing processing of the gathered information 
(controller)

Yes / No

9 Output system Existing actuators, which implement adaptations of the 
design with regard to the function 

Yes / No

TABLE 3 Revised list of characteristics of adaptivity

Using the overlapping of façade functions and characteristics of an adaptive system, a database is 

created in which the identified functions are organised vertically, the corresponding characteristics 

of adaptivity horizontally. The additionally identified specifications support the understanding 

of general functions and can be used for a detailing in subsequent investigations. In the present 

database, only the general functions are taken into account. The present breakdown of functions 

is made based on the assumption that they are confronted with individual dynamic factors and 

requirements within the façade as a holistic system. 

5 SUPERPOSITION OF FAÇADE FUNCTIONS AND 
CHARACTERISTICS OF ADAPTIVITY

In the superposition matrix shown in Table 4, the identified façade functions are overlaid with the 

determined characteristics of adaptivity. The façade functions are listed vertically in the table. 

The respective characteristics of adaptivity contrast them in horizontal organisation. 



 017 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 7 / NUMBER 2 / 2019

GENERAL BEHAVIOUR AUTOMATION

Technol-
ogy

Flexible Adaptive Operation Response 
time

Degree of 
adaptivity

Input 
system

Pro-
cessing 
system

Output 
system

Sun

1 Solar shading

2 Light deflection

3 Glare protection

4 Control daylight radiation

Temperature 

6 Thermal insulation

Air

7 Ventilation

User

8 Control visual contact

Acoustic

9 Sound insulation

Energy

10 Generate energy

11 Store energy

Supply

12 Heating and cooling

13 De- / humidification

14 Electricity

15 Artificial light

16 Communication

TABLE 4 Superposition matrix 

6 EXAMPLE FOR THE APPLICATION OF 
THE SUPERPOSITION MATRIX

Table 5 shows the application of the superposition matrix to the façade of the KFW Westarkade 

in Frankfurt, Germany. The project, designed by Sauerbruch Hutton and completed in 2010, was 

selected because the building and the façade are extensively documented in the literature (Fortmeyer 

& Linn, 2014).  The double façade of the building is characterised by vertical coloured blinds. It has 

automated ventilation flaps. A glare shield is installed in the space between the façade. Based on 

the literature sources, the façade functions can be assigned the characteristics of adaptivity and 

automation shown in Table 5. Characteristics which cannot be determined due to missing data are 

marked with N.A. (González, Holl, Fuhrhop, & Dale, 2010; Winterstetter & Sobek, 2013)



 018 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 7 / NUMBER 2 / 2019

GENERAL BEHAVIOUR AUTOMATION

Technol-
ogy

Flexible Adaptive Operation Response 
time

Degree of 
adaptivity

Input 
system

Pro-
cessing 
system

Output 
system

Sun

1 Solar shading Lamella 
screen

Yes Yes Extrinsic N.A gradual Yes Yes Yes

2 Light deflection No No No No No No No No No

3 Glare protection Lamella 
screen

Yes Yes Extrinsic N.A gradual Yes Yes Yes

4 Control daylight radiation Lamella 
screen

Yes Yes Extrinsic N.A gradual Yes Yes Yes

Temperature 

6 Thermal insulation Inter-
mediate 
space

Yes Yes Extrinsic N.A gradual Yes Yes Yes

Air

7 Ventilation Ventila-
tion flaps

Yes Yes Extrinsic N.A Active- In-
active

Yes Yes Yes

User

8 Control visual contact Lamella 
screen

Yes Yes Extrinsic N.A gradual Yes Yes Yes

Acoustic

9 Sound insulation Absorber No No No No No No No No

Energy

10 Generate energy No No No No No No No No No

11 Store energy No No No No No No No No No

Supply

12 Heating and cooling No No No No No No No No No

13 De- / humidification No No No No No No No No No

14 Electricity No No No No No No No No No

15 Artificial light No No No No No No No No No

16 Communication No No No No No No No No No

TABLE 5 Superposition matrix applied to the façade of the KFW Westerkade

The case study shows that the characteristics determined can principally be applied to buildings. 

An absolute assignment of a function to a particular component of the façade is not always possible, 

since there are undefinable overlaps between them. In the investigated project, for example, the 

function of sound insulation is fulfilled by the intermediate space of the double façade. In this 

context, the opening of the ventilation flaps has an effect on the noise protection. Absorbent surfaces 

also contribute to the fulfilment of acoustic requirements, which, however, are not able to adapt. 

Such complex contexts can only be mapped abstractly, and interpretations are necessary in the 

assignment. This also applies to the determination of individual characteristics. Thus, the opening 

state of a ventilation flap can be evaluated as an active or inactive state; however, in the case of a 

plurality of ventilation flaps that are capable of opening, it is also possible to estimate that a gradual 

adaptation is present. It is necessary to clarify whether the respective evaluation refers to a single 

element or to the overall system.



 019 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 7 / NUMBER 2 / 2019

7 CONCLUSION

The study compiles the external boundary conditions and interior comfort requirements of adaptive 

façades. Based on existing literature, the following seven external influencing factors were identified: 

“solar radiation, temperature, air quality, sound, wind, precipitation, and humidity”. As stated above in 

Section 2.3, apart from natural factors, human intervention in the environment also has an impact 

on the functions of the façade. In terms of interior comfort, the four requirement categories “thermal 

comfort, aero- & hydro-comfort, visual comfort, and acoustic comfort” were identified. The listing 

provides an initial basis and is not understood to be complete. Depending on the field of application 

and in further research, more aspects may be added. Taking the identified framework conditions into 

account, the study provides a detailed breakdown of performance-relevant and possibly automated 

adaptive façade functions as potential parts of an intelligently networked, adaptive façade system. 

While some of the identified functions have a direct impact on the façade performance by balancing 

of environmental conditions and comfort requirements, others are cited because of an existing 

reference to environmental conditions and an indirect impact on the system, for example, through 

the provision of energy. The “Supply” functions category lists such functions that are not necessarily 

linked to external influences but do affect the interior comfort. As an extension of previously 

existing research results, the found characteristics of an adaptive façade as an overall system 

are summarised, supplemented with automation aspects, and applied to the individual functions. 

This detailing enables a differentiated consideration of dependencies and shared requirements 

between individual performance-relevant and automated adaptive façade functions within an 

intelligently networked façade system. The superposition matrix developed in this study can 

contribute to the design of intelligent-networked and multifunctional-adaptive building envelopes. 

As a theoretical assembly based on existing literature, it does not provide information about the 

actual realised automated adaptive functions in building practice. The superposition matrix can 

be used as organisational tool for the systematic assessment of automated and adaptive façade 

functions in realised building envelopes to examine the technical basis for intelligent networking. 

A corresponding practical investigation is identified as a future research task for the clarification of 

a possible intelligent cooperation of automated adaptive façade functions according to networked 

production plants in industry.

Acknowledgements

The study is part of a PhD research project and is not subject to any specific funding. 

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