The Concept of Sound Localization

The term sound localization is used to mean the ability of the listener to identify the origin or location of the sound and its direction (Goldstein 9). For instance, if you are standing in the hall and a friend calls from behind, you will automatically know that he/she is behind without even looking. This is because you can detect where the sound is coming from. Sound localization is also important as it helps the hunter to locate the hiding place of the prey or a person can tell the specific location of an animal. Since it is an important aspect of our lives, much research has been done on this area to try and understand the mechanism of sound localization. According to sound localization, the sound is placed in three types of coordinates systems. These include; azimuth, elevation, and distance coordinate. The azimuth is the horizontal coordinate that refers to the sounds that are located to the right or left in comparison to the listener. For the ear to find azimuth sound it uses interaural time differences (ITD) which refer to the disparities between the sounds reaching each ear. In other terms, ITD refers to the amount of time taken for a sound wave to hit one ear compared to the other ear. The work of ITD is to help the ear distinguish whether the sound is originating from the left or right side. The elevation coordinate uses spectral cues to detect the sound when it is coming from above or below the ears. The ear can detect the location of the sound below or above it by measuring the differences in sound frequency caused by bouncing waves around the pinnae. The spectral cues arise when the head and pinnae of the ear affect the sound frequency (Goldstein 40). The difference between the actual sound and the sound that enters the eye after bouncing around the pinnae is referred to as the directional transfer function (DTF). It becomes difficult to locate the sound if the pinnae are smooth. In addition, a recent study has indicated the likelihood of the disparity of auditory perceptions if a person’s pinnae are altered. There has been little research on the distance coordinates which is used to measure the distance between the person receiving the sound and its origin. The distance cues used by the ear include the movement parallax, sound frequency, reflection, and sound level. The distance will affect the sounds since the atmosphere tends to absorb the higher frequencies. In addition, a sound that is closer to the ear will tend to move across our field of view quicker than those that are far away. In the following paragraphs, problems involving the Azimuth and distance coordinates are discussed.

Sometimes in our lives, sound localization may break down as a result of various causes. If a person has ear damage resulting in deafness it becomes impossible for him to locate sounds. The ability to locate sounds will eventually decrease or collapse if the auditory cortex is injured. This is because sound localization processing takes place in the auditory cortex of the brain. A person is able to locate specific sound origins due to the timings of neurons in the auditory cortex. Mostly this affects the azimuth sound localization cues. Such individual with this kind of problem requires hearing aids to help them in sound perception. However, a person has to use a pair of hearing aids as one would not work properly (Klingon and Bontecou 880). In addition, if only one of the ears is functioning clearly the ITD cues become useless. Sound localization is important in music halls, theatres, or opera houses because these buildings require sound non-reflective surfaces. A recent study has been conducted on how sound localization is affected by sound-reflecting surfaces. According to the study, the subjects were placed in an anechoic chamber consisting of twenty-seven speakers that were seated at different locations around the room. The subjects were instructed to locate the correct speaker that produced the sound. In addition, a surface that reflects the sound was placed either on the wall, the floor, or the ceiling. The subjects located the sound effect when the reflecting was placed on the floor as compared to when the reflecting surface was placed on the ceiling (Guski 825). This on the other hand is crucial information to architecture to design halls accordingly in order to get the desired sound reflectance.

References

Goldstein, E. Sensation and Perception. Pacific Grove, CA: Wadsworth-Thomsom Learning, 2002.

Guski R. “Auditory Localization: effects of reflecting surfaces.” Perception 19.6 (1990): 819-30.

Klingon, G.H., and Bontecou, D.C. “Localization inauditory space.” Neurology 16 (1966): 879-886

Sound Design of Pale Man Scene in “Pan’s Labyrinth”

Music is an important tool to convey the story in a movie. Music gives a clue to the viewer and helps to identify a scene or a character. It can dramatize the scene or calm it down. The main character in Pan’s Labyrinth– Ophelia is assigned to enter a lair and open one of the three locked doors to get a dagger. Pale Man is a legendary creature: he lacks a nose, his eyes are on the plate, and his skin is pale and saggy. When Ophelia comes closer to the Pale Man, the sound is rather quiet- it symbolizes his inactiveness. Looking up, she sees pictures of him killing and eating children- here, one can hear distant cries of children. This sound helps to identify him as a cruel, merciless monster.

As Ophelia enters the lair, the echoic sound in the background indicates that it is a dangerous place. While Ophelia is pulling out the key, there is a sharp tinkling sound, which emphasizes its significance. Next, music changes to triumphant and high pitch- it indicates the greatness of the dagger and that the primary mission is accomplished. However, right after that, sound cues that something bad is to happen as it becomes bizarre and intimidating.

Sound motifs represent the Pale man as a danger: loud, creaky, and crunching sound effects accompany the Pale Man’s awakening as his hands start moving, and he takes a deep breath; music gets louder and more intense when he gets up to catch Ophelia. Other sounds, like sand in a glass hour, door closing, chalk dropping, chair shaking, and more, supplement the drama of the scene.

This scene successfully combines a variety of diegetic and non-diegetic sounds, SFX, and music to enhance the visual experience, identify the character of the antagonist, and trigger certain emotions in a viewer.

Sound and Space: Sonic Experience

Importance of sound

Life is made meaningful through the five senses present in human beings. The experiences that people go through are facilitated through the senses that enable people to decipher the messages contained in the sounds that they hear. Seeing and hearing are touted as the most fundamental and can only be compared to food and water, the most basic human need.

The sonic impressions created by hearing do to a greater extent help in determining visual impressions that are created by sight. Sounds, together with images have been developed and they form the basis of the creative arts sector in many countries1.

Just as hearing comes top among the senses, music is ranked above all other arts. Art uses both visual and sound impressions. However, sound has proven to be more powerful over visual images in the world of art.

From birth, human beings use sound qualities and later on during gradual maturity use the expressive qualities found in speech and music to familiarize themselves with the qualities of life. The invaluable experiences offered by music and other sound qualities help in human development and self-discovery through communication2.

In the long history of human development, one of the most important factors that have characterized that development is the concept of sound. Is has been one of the crucial deciding factors in the development and advancement of society as well as its sustenance in the dynamic world. Many cultures including Indian and Vedic have myths that seek to explain the mysterious nature of sound.

These myths explore the existence of the soul before the existence of the earth and how sound developed after the universe came to exists. In Indian culture, for instance sound was regarded highly that it is classified as one of the characteristics of ether, one of the elements of nature. They ancient Indians believed that sound pervaded everything3.

The existence of sound in the world is crucial to the creation of perception and presence that determine the shape of the world. Sound according to Thompson creates perception, emotional, spiritual, and psychological spaces (50). Through the above elements, understanding within ourselves, the environment and between human beings is enhanced. Communication too is enhanced through sound and space.

On the same note, the importance of sonic space and the experience that it creates in everyday human life comes to the fore. In the middle of the sonic experience is the space and human beings. This presents a complicated relationship that intensely involves the audible domain and the visceral involvement with architects of sonics that work on structures to transform space to a sonic experience4.

There is a unique articulation of space and place in the interactive sound environment that are helpful to human brings in their efforts in engaging with the immediate environment.

In the experiment for instance, a subtly performative medium done in an immersive environment will help transform the space to a sonic experience effectively casting the listener as a creator and performative agent5.

An important point to note is the characterization of interactive environments like walled rooms by an interface that aids in triggering sonic material from the axial coordinate location of an interactive agent within an architectural space. The triggering may be done by direct triggers like objects including wall boxes, floor pads and light beams.

The sound is generated and recorded and plays itself out regardless of the morphology of the person interacting with them6. This is possible because the sonic content of objects installed with fixed morphological structures that are acquired when samples of the sound are generated and recorded.

There is a variance on interactive input because of the collage of objects that are used in the experiment and they provide a direct relationship between the qualities of the interactive gestures and the sonic outcomes.

Perhaps the most important role that sound plays in the development of human beings as well as the day-to-day lives is the nurturing of emotion. Through sound, human beings are able to learn and feel emotions while attaching meaning to them.

Emotions help transform human beings to social beings capable of feeling. After learning emotions, human beings use the sonic arts to communicate the emotions to fellow human beings in their quest to have corresponding real life experiences7.

An emotional being through socialization is transformed to a social being. The preservation of quality sounds reinforces sound integrity to ensure human beings get the best of the sounds that we use and those that we get through music and other sonic arts. The social being is developed through the sounds he/ she hears.

It’s important to note that there exists a wide variety of sounds that help human beings to develop full social beings. It’s also important to add that it helps when human beings are exposed to various sounds because it helps the above said development.

To ensure that quality sound is made and is available for human social development, recording was introduced. Recording was a big step in the development and storage of music and quality sounds that help human beings develop. Through recording relationship between sound and space and there are numerous sonic transformations that can be achieved8.

There is more to the projection of sound into space than meets the eye. Space is more than a container for sound. Sound has the ability to define space through the creation of metaphorical walls. When sound happens in space, there is a regular process that helps waves traverse the distance between the source and the ear.

An important element in this relationship between sound and space is the existence of a common structural design that can be referred to as architectonics9. This experiment will address the behavior of sonic qualities of space as well as the spatial characteristics of sound. It’s helped that through the experiment, the important role that sound and/ or silence plays in giving space its sonic qualities will be brought out.

Throughout time, there have been sonic and spatial constructions that have been useful in defining places in time. They will also be looked at albeit briefly to underscore the importance they played in the transformation of space to a sonic experience. The literature and experiment will be dedicated to the explanation of sound and space applications that include architectural creation of sonic spaces, landscapes and sculptures.

Sonic space

The acoustic coloration can be described as the sonic space. The sonic space is crucial in how people hear and perceive interact with sound in their environment. Particularly important especially in the experiment is the human interaction aspect with sonic space.

Human interaction with space can be primitive or cultural and emotional. Human beings primitively gather raw sonic data for instance reverberation and echo. Additionally, cultural and emotional sonic interaction with space evokes higher cognitive processes in human beings10.

It’s important to recognize the importance of sonic space in the virtual worlds. In games, for instance there is realistic sound simulation that brings the foley effects, atmospheric sound and sound effects. Additionally, sonic space enhances the emotional aspects of a scene through narration and music.

Sonic space in games brings out the realistic sound simulation that includes dialogue. The experiment’s main objective of transforming space to a sonic experience can be used to enhance information communication and education.

According to Wade, the interaction between human beings and sonic space is more than just a primitive reaction to the environment.

The process involves the use of raw data gathering abilities which are largely primitive, perception which are also primitive characteristics of higher cognition and high impact listening that are also part of higher cognition. The illustrations that follow will demonstrate this in a room environment that will form the wider context of the experiment (46).

Source: Landy, Leigh. What’s the Matter with Today’s Experimental Music?: Organized Sound too Rarely Heard. Chur, Reading: Harwood Academic Press, 1991. Print.

This is primitive raw data gathering in a room environment.

There is also perception which is primitive raw data gathering and higher cognition in a room environment as illustrated below.

Source: Landy, Leigh. What’s the Matter with Today’s Experimental Music?: Organized Sound too Rarely Heard. Chur, Reading: Harwood Academic Press, 1991. Print.

Finally, there is high-impact listening that involves higher cognition in a room environment.

Sonification mainly deals with the use of non-speech sound. It’s important to look at some of the difficulties that are experienced in the use of non-speech sound to convey information. Interference between different dimensions of sonic space and the cognitive overload are some of them.

Some of these problems can be alleviated incorporating some of the background functions into sonic space11. For instance, the problem may be solved through association of data size with sonic space instead of dimensions like pitch or loudness12. A particular importance of the experiment will be a demonstration of the potential that exists in using sonic space to help in the learning processes in visually impaired learners13.

Sound and space

According to LaBelle and Roden sound cannot exist on its own without space (34). Additionally for sound to exist, it needs architecture and sight. The examination of the relationship between sound and space was first mooted by the ancient Greeks. The experiments conducted by the Greeks sought to investigate the behaviors of sound in different space settings.

The unique behaviours that sound exhibited in these different space settings was the main content of the investigations they carried. These early researchers came up with the premise that the relationship between sound and space was utterly dependent on architecture.

This relationship was vividly captured in the ideas and works of Vitruvius when he sought to control sound in theatres. A concrete conclusion that was reached by these researchers was that sound and music had an explicit linkage to architecture underlain through the harmony of the universe.

Of special importance however was the relationship that exists between sound space and place and their linkage to transforming space to a sonic experience. Presence of bodies and movement aids in the realization of the existence of space14. In the experiment, one will discover that sound is a temporary medium that needs careful analysis to uncover its properties.

Through the use of psychoacoustics, reverberation is analyzed to bring out the information on size of the sonic environment15. The presence and active participation of the human mind in this experiment brings to the fore the ability to envision and discover the source of excitation while determining the fine qualities of the materials used in case boxes.

The above is possible when one considers reverberation together with timbre and attack. The concept of morphology is brought back through its entrenchment in the sonic recording of the audio sample.

It’s important to note that the recording that will be involved in the sonic transformation of a space is interactive in nature and does little to condition the response hence the exact nature of the interaction is produced at the external reference16.

It therefore does not reflect the participants’ experience and cognition rather that of natural rules of sonics. The need to mould the environment therefore through the use of architecture in order to condition the interactive experience arises17.

Sound and space could not be understood without the use of architecture that was crucial in developing harmonic properties of sound as well as the mathematical impressions of sound and music.

The ancient researchers also did conclude that site and sound existed simultaneously and that the relationship could be examined through the listening experience. Their joint existence can fall within the social presence context or private experience context.

In terms of acoustics and resonance, site and sound do determine their development where one of them is characterized as a receiver while the other is characterized as a transmitter18. The above explanation by the Greek researchers of sound and space concluded that space is crucial in the controlling, deadening, reflection, and destruction of sound.

There is a lot of architecture that goes to designing and developing areas where people live for instance in cities and quiet parks. That therefore means there can be a deliberate generation of sound to alter space. Similarly, one can shape space to manipulate sound to a negative or positive effect instead of reducing or deadening or eliminating it19.

Besides the perception capabilities that human beings display toward sound, they can also create and destroy both sound and space. When designing space, architects are mostly concerned about the acoustic factors that will affect the spaces they design.

Acoustics

One of the concepts that come out prominently in the relationship between sound and space and sonic is acoustics. According to Ripley et al, every room has a sound. In any room, sound waves experience reflection, absorption, and dispersion (45).

This is done by the boundaries the physical contents like furniture and the people present. It’s important to note that different rooms have different sounding formats. The sounding is determined by the size, geometry and the materials that are used. More importantly, their acoustic behaviour is more critical to the sounding of the room.

A connection between acoustics and sonic transformation will be necessary in the experiment in its quest to transform space to a sonic experience. No doubt there is a lot of architecture and other fine details that go into transforming space to fit acoustics. While this experiment has little to do with acoustics, the sonic gestalt that is involved considers sound as a unique media that is an internal artifact.

According to Thompson sound penetrates the body and it’s very difficult for anyone to use it in a concrete way to come up with anything far from appeasing emotional experiences20. According to Smalley, this “slippery” nature of sound is referred to as surrogacy.

The sonic transformation of space in this experiment is will operate on the principle of remote surrogacy with the assumption that when the listeners will be hearing the sound from the materials on the wall, they will involve their cultural and environmental experiences to find meaning. In other words, the experiment will mainly concentrate on the production of sound in a room space with different materials.

The materials in a room or space will be crucial in the transformation of space to a sonic experience and a good understanding of the dynamics involved in acoustics will help shed some light on the concept and help in explaining the effect of space and sound21.

Size, geometry, diffusion, and absorption describe acoustics in the most basic terms. Acoustics is all about eliminating resonances by ensuring reflections of sound disappear through absorption and diffusion.

In their quest to improve sound quality, acousticians try to modify rooms through architectural designs that greatly alter sound in rooms especially theatres to fit the purpose. However, it is imperative to highlight that the sound source is also a factor in determining the quality of the sound experiences in a room22.

More often than not, acoustic engineers and architects try to dampen the rooms in order to improve the sound of the reflection. Sometimes it is successful while at times it flops badly. Sound quality in a room is mainly determined by the material used. Every material possesses a vibration character. This is more critical in the reflection of sound waves, perhaps more critical than the absorption and dispersion coefficients.

To achieve the best reflection, engineers struggle to match the mother of tone to the character of the reflecting material. The mother of tone is ideal because it is the same benchmark that is used by the human body in its regulation of vibration of ears and generally, bodies. It’s against these that all sounds that are meant for any human being are evaluated.

Size

Resonant frequencies are mainly affected by the size of the room. These cavity models of the room signify that a few of frequencies will be higher or louder than all other frequencies available. For instance, a sub hoofer that normally has low frequencies is designed to activate and excite the cavity modes present in rooms.

The cavity modes or frequencies of a room can only be changed through alteration of the size or its volume that is more or less the size23. The objects that will be used in the experiment will be of different sizes to fulfil the intentional purpose of producing several sounds.

Geometry

Direction of sound reflections in a room is determined by the geometry of the room. On the other hand, the geometry of the room is determined by the angles and the positioning of the walls as well as the floor, ceiling, furniture and any other physical object in the room.

Any new entry into a room changes the acoustics of that particular room. It is important to note that the commonest reflection happens between parallel rather than perpendicular walls24.

Materials

The materials that make up the walls, ceiling, and floor of the room as well as the materials of the furniture and any other physical objects greatly determine the acoustics. Understanding into these individual material properties will need a macro understanding of the individual materials on the physical features of a room.

Concisely, the acoustic properties of a material in a room are determined through the amount of sound that is reflected by that particular object. The amount of sound is determined by the absorption coefficient. Also determining the acoustic properties of a material is the direction the reflection takes which is determined by the dispersion or diffusion coefficient25.

The physical objects that are capable of creating and sometimes destroying sound and the acoustic energy that fills the air are some of the major aspects of sound. Both scientific and aesthetic ways, the relationship with the environment and the circumstances that surround someone determine who gets to hear what.

Perhaps the relationship between space and sound is better captured through the demonstration of an empty house and that is already furnished26. An empty house demonstrates acoustic harshness that is not pleasant to the ear at all. Sound in occupied houses is more soft and accommodating than the former.

The different surfaces from different objects that are present in the house help in the refraction and softening of the sound giving a soothing acoustic. According to Pallasmaa, different spaces and buildings display varied characteristics of attractiveness, feelings, intimacy, monumentality, harshness, invitation, or rejection (58). The above characteristics signify either hospitality

The features described above come in hand in the achievement of acoustics of a room. They are also important in the transformation of space to a sonic experience. The different objects that will be used in the experiment will spot various measurements of the features that will directly impact on the sound they will produce.

Of importance is the morphology and timbre of the objects that will be placed to act as the sources of the sounds that will aid in the transformation of the space to a sonic experience.

Acoustic engineers

Given the importance of space in this transformation, it’s only important to understand how the human element through architecture influences electro-acoustics that are directly linked to the space-sonic transformation experience.

The human effect on sound and space is mainly captured through the architectural element that is directly related to sound and space. People have come up with designs that manipulate sound to achieve the sound qualities that they want. The creation of Symphony Hall marked the beginning of an acoustic era dominated by technology.

This technology enabled architects and acousticians to have greater control of over sound. The Symphony hall is still regarded as the first ever, modern science inspired creation that clearly captured the effect of human beings and space on sound. It’s important to note that there are many symphony halls and their workings are basically the same.

One critical factor that comes up in the human effect on sound on space and the incorporation of architecture into the study and understanding of sound is the materiality of the objects used.

Reverberation is determined by the frequency dependency of the powers of sound absorbing by the materials used in architecture. Within the materiality concept, the barriers that aid in minimizing noise pollution in buildings and construction came up27.

According to Wade, human beings have largely been responsible for the manipulation of architecture and space in the cities to introduce a completely new concept of soundscape (56). The use of space has ensured the resonation of the cities, echoing, muffling, and the isolation of all the urban sounds creating a new dimension of soundscape.

Urban designers and planners have responded by planning every building in the cities in specialized and differentiated ways. Determination of the openness of the streets, planting of trees and the specification of materials for different surfaces has been carefully considered in the use of space to control sound.

Due to the relative easiness through which architects can make predictions on the reverberations, the acoustics of the inside of buildings have been easily controlled and their spaces only reflect the acoustic qualities that their owners prefer28.

Wade says that human beings are perceptive creatures as well as active creators of sound and space. The acoustic space that is designed by architects is the primary concern when designing structures. Human beings are increasingly capable of manipulating the soundscapes of buildings through advanced architectural designs.

In this advanced manipulation of sound contexts, architects have sought to understand the effect of spatial sound. With the advancement in technology brought about by the industrial revolution, people started modifying and measuring sound.

Scientific study of sound enabled acoustic engineers and acousticians to manipulate microphones and amplifiers and loudspeakers together with the electrical signals that sound devices used. The discovery of sound production through electronics redefined acoustical phenomena using electronics rather than architecture. Acousticians could easily study and understand the behaviours of sound thanks to the advanced technology29.

According to Labelle and Roden, the sounds that are present today are because of technological mediation that is as a direct result of the manipulation by engineers and architects. Control of the behaviors of sound is no longer the mystery it used to be (132).

Many more materials used in the generation of sound have been developed together with numerous electro-acoustic devices that have helped greatly in the understanding of acoustics.

The development of the electro-acoustic and other techniques of manipulating sound have led to the production of both intended and unintended consequences. These noises include radio broadcasts, music concerts, and motion pictures with soundtracks that have become popular with people30.

It’s important to note that it is the need to control sound behavior and a culture for listening that have driven both the architectural and technological developments in acoustics.

New worries about noise that is as a direct result of human being manipulation of the sound space led to the desire by acousticians to control the sound in specific rooms where performances were held and that were important in producing acoustically correct music. Furthermore, the desire to eliminate all unnecessary sound was informed by the need to achieve efficiency in acoustics.

According to Ripley et al control of acoustics by architects and engineers was seen as a way of enabling these musicians exercise choice in a world filled with all kind of aural commodities (89). This developments helped producers and other acoustically interested people to determine what constitutes good and acceptable sound and to determine how and what it took to achieve it.

The gradual development of the relationship between sound and space led to the reformation of the principles that define it. There was gradual dissociation of sound from space to an extent that the relationship became non-existent31. The development of sound absorbing structures and the instruments that produced their own authentic acoustic sounds diminished the relationship between sound and space.

It is safe to conclude that the architectural bit has became a little differentiated and now concentrated on the development of either good structures or instruments that produce acoustic sounds according to the preference of the listeners. Reverberation was a direct creation of architecture that necessitated its creation. It was always a function of the room size, geometry and the materials of the surfaces of the objects in the room.

These factors together controlled the production of acoustic sound for long periods. It is therefore with relief that products that can produce acoustic sounds can be made and reverberation is just a form of noise that does not need to be controlled to produce acoustic sound32.

Directly related to architecture and human effect is the phenomenon of the sound transformation. The experiment on the transformation of space to a sonic experience can be said to be a miniature of electroacoustics that has been necessitated through architecture. Through the objects in a room is the creation of timbre development from basic one basic sound texture to another.

The fundamental concept here is the timbral metamorphosis which is more or less the transformation that space goes through to become a sonic experience. Though there may be numerous transformations that take place to form one sonorous gesture, an analysis of one is enough to illustrate the point since the process is repetitive.

It’s important to note that there is considerable manipulation of the sound source which in this case will be the objects placed in the room to generate the morphology of the source to create a sound transformation to a sonic experience33.

Conclusion

Throughout the paper both direct and indirect literature and details of transforming space to a sonic experience have been dealt with. The explanations have sought to explain the settings that this particular experiment will use to transform space to a sonic experience and how concepts like acoustics relate to the sonic concept.

In so doing the paper has in significant proportions concentrated on architecture and the role it plays in acoustics and sonic transformation. Additionally, there is substantial information relating to the projection of sound into a space and the cognitive characteristics of human beings that are necessary for a sonic transformation to be complete.

In so doing, a number of scholars and their works on sonic transformation and the metamorphic process involved in the process have been used and cited. The process and the finer aspects involving transformation of space to a sonic experience have been explicitly examined. It’s therefore hoped that the information presented in the paper adequately explains the experiment that seeks to transform space to a sonic experience.

Works Cited

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Thompson, Emily. The Soundscape of Modernity. Massachusetts: MIT Press, 2004. Print.

Taylor, Charles. Reflections, Reverberations, and Recitals”. Exploring Music: The Science and Technology of Tones and Tunes. CRC Press, 1999. pp. 232–4

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Wishart. Audible Design. A Plain and Easy Introduction to Practical Sound Composition. York, UK: Orpheus the Pantomime Ltd, 1994.

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Footnotes

1 LaBelle, Brandon and Roden, Steve. Site of sound: of architecture and the ear, Volume 1. London: Errant Bodies Press, 1999. Print. P.67

2 Hayles, Katherine. 1996. Embodied Virtuality: Or How To Put Bodies Back Into The Picture. In

Immersed In Technology: Art and Virtual Environments, Massachusetts: The MIT Press, 1996, Print. P.88

3 Paine, Garth. Gesture and Musical Interaction: Interactive Engagement Through Dynamic Morphology. Paper presented at NIME, at Hamamatsu, Japan, 2004. Print. Pp 23-30.

4 Moravec, Hans. Mind Children: The Future of Robot and Human Intelligence. Cambridge: Harvard University Press. 1988. Print. pp 90

5 Schiphorst, Thecla. Body, Interface, Navigation Sense and the State Space. Paper presented at The Art of programming: Sonic Acts, at Amsterdam, 2001. Print. Pp 21-26

6 Smalley. Spectro-morphology and Structuring Processes. In The Language of Electroacoustic Music. New York: Macmillan, 1986. Print. P.78

7 Pallasmaa, Juhani. The eyes of the skin: architecture and the senses. New York: Wiley-Academy, 2005. Print. p.65

8 Thompson, Emily. The Soundscape of Modernity. Massachusetts: MIT Press, 2004. Print. P.54

9 Wade, Bonnie. Imaging sound: an ethno musicological study of music, art. Chicago: University of Chicago Press, 2006. Print. P. 45-46

10 Pallasmaa, Juhani. The eyes of the skin: architecture and the senses. New York: Wiley-Academy, 2005. Print. P. 66

11 Taylor, Charles. Reflections, Reverberations, and Recitals”. Exploring Music: The Science and Technology of Tones and Tunes. CRC Press, 1999. pp. 232–4

12 Scott, Jill. The Body as Interface. In Reframing Consciousness, UK: Intellect, 1999. Print. P. 23.

13 Smalley, Dennis. Spectromorphology: Explaining sound-shapes. Organised Sound 2 (2):107-26. Wiener, N. 1948. Cybernetics: MIT Press, 1997. Pp107-126

14 Sallie, Westwood; John, Williams. Imagining Cities: Scripts, Signs, Memory. Routledge, 1997. Print.

15 Paynter, John,et al. A Companion to Contemporary Musical Thought. London: Routledge Publishers, 1992. Print. Pp.89

16 Kahn, Douglas. Noise Water Meat — A History Of Sound In The Arts. Massachusetts: MIT Press, 1999.pp.78

17 Alec, Nisbett. The Sound Studio: Audio Techniques for Radio, Television, Film and Recording. Focal Press, 2003. pp. 50

18 Thompson, Emily. The Soundscape of Modernity. Massachusetts: MIT Press, 2004. Print.pp.48

19 Yost, William. Fundamentals Of Hearing. NY: Academic Press, Inc., USA, 1994.pp. 190

20 Thompson, Emily. The Soundscape of Modernity. Massachusetts: MIT Press, 2004. Print. Pp 58-60

21 Smalley, Dennis. Spectromorphology: Explaining sound-shapes. Organised Sound 2 (2):107-26.

Wiener, N. 1948. Cybernetics: MIT Press, 1997. Pp107-126

22 Campbell, Murray. The Musicians Guide to Acoustics. London: Sage Publications, 1987. Print. pp. 123-125.

23 Emmerson, Simon. The Language of Electroacoustic Music. London: Macmillan Press, 1986. Print. pp.98-105

24 Cox and D’Antonio. Acoustic Absorbers and Diffusors – Theory, Design and Application. London: Spon press.Print. pp. 48-54.

25 Ripley et al. In the place of sound: architecture, music, and acoustics. Cambridge: Cambridge University Press, 2007. Print. Pp108-110.

26 Erickson, Robert. Sound Structure in Music. Berkeley: University of California Press 1975. Print. pp. 154

27 Bregman. Auditory Scene Analysis. The perceptual organisation of sound. London: MIT Press, 1994.pp. 78-79.

28 Wade, Bonnie. Imaging sound: an ethno musicological study of music, art. Chicago: University of Chicago Press, 2006. Print.p.56

29 Wishart. Audible Design. A Plain and Easy Introduction to Practical Sound Composition. York, UK: Orpheus the Pantomime Ltd, 1994.

30 LaBelle, Brandon and Roden, Steve. Site of sound: of architecture and the ear, Volume 1. London: Errant Bodies Press, 1999. Print. Pp132-134.

31 Wishart. On Sonic Art. Ed. Simon Emmerson. UK: Harwood Academic Publishers, 1996. Print. pp 90-101.

32 Ripley et al. In the place of sound: architecture, music, and acoustics. Cambridge: Cambridge University Press, 2007. Print.p.89

33 Thompson, Emily. The Soundscape of Modernity. Massachusetts: MIT Press, 2004. Print.p.79.

Importance of Sound

Life and Sound

Hearing

Life is made meaningful through the five senses present in human beings. The experiences that people go through are facilitated through the senses that enable people to decipher the messages contained in the sounds that they hear.

Seeing and hearing are touted as the most fundamental and can only be compared to food and water, the most basic human need. Of the two hearing is touted as bearing the biggest responsibility in determining the character of human beings.

Scholars have argued over the supremacy of the two higher senses. Often, hearing comes over sight. That is not to say that sight is important. However, the sonic impressions created by hearing do to a greater extent help in determining visual impressions that are created by sight.

According to Pallasmaa, sound incorporates while sight isolates. This is a tribute to the unifying nature that sound has among human beings. The interpretations that sound is subjected to are less likely to be subjective compared to the interpretations sight impressions are subjected to (20).

Pallasmaa adds that sight represents exteriority while on the other hand, sound and hearing display omni-directional qualities as well as interiority. Sound approaches and receives while eyes reach on to something (21).

Some scholars even argue that it’s possible to lead an almost normal life even after losing the sense of sight. Through encholation, blind people easily find their way through many places, be it in a forest or a large town. Sounds, together with images have been developed and they form the basis of the creative arts sector in many countries.

Music

Just as hearing comes top among the senses, music is ranked above all other arts. Art uses both visual and sound impressions. However, sound has proven to be more powerful over visual images in the world of art. From birth, human beings use sound qualities and later on during gradual maturity use the expressive qualities found in speech and music to familiarize themselves with the qualities of life. The invaluable experiences offered by music and other sound qualities help in human development and self-discovery through communication.

Concept of Sound

In the long history of human development, one of the most important factors that has characterized that development is the concept of sound. Is has been one of the crucial deciding factors in the development and advancement of society as well as its sustenance in the dynamic world.

Myths

Many cultures including Indian and Vedic have myths that seek to explain the mysterious nature of sound. These myths explore the existence of the soul before the existence of the earth and how sound developed after the universe came to exists. In Indian culture, for instance, sound was regarded highly that it is classified as one of the characteristics of ether, one of the elements of nature. They ancient Indians believed that sound pervaded everything.

Emotions

The existence of sound in the world is crucial to the creation of perception and presence that determine the shape of the world. Sound according to Thompson creates perception, emotional, spiritual, and psychological spaces (50). Through the above elements, understanding within ourselves, the environment and between human beings is enhanced. Communication too is enhanced through sound and

Perhaps the most important role that sound plays in the development of human beings as well as the day-to-day lives is the nurturing of emotion. Through sound, human beings are able to learn and feel emotions while attaching meaning to them. Emotions help transform human beings to social beings capable of feeling.

After learning emotions, human beings use the sonic arts to communicate the emotions to fellow human beings in their quest to have corresponding real-life experiences. On this point alone, hearing underscores its importance and perhaps serves to prove its superiority over sight.

Socialization

An emotional being through socialization is transformed to a social being. The preservation of quality sounds reinforces sound integrity to ensure human beings get the best of the sounds that we use and those that we get through music and other sonic arts. The social being is developed through the sounds he/ she hears.

It’s important to note that there exists a wide variety of sounds that help human beings to develop full social beings. It’s also important to add that it helps when human beings are exposed to various sounds because it helps the above-said development.

Recording

To ensure that quality sound is made and is available for human social development, recording was introduced. Recording was a big step in the development and storage of music and quality sounds that help human beings develop. However, they have been subjected to various limitations that somehow diminish the importance of sound in human life.

Sound and Space

According to LaBelle and Roden, sound cannot exist on its own without space (34). Additionally for sound to exist, it needs architecture and sight. The examination of the relationship between sound and space was first mooted by the ancient Greeks. The experiments conducted by the Greeks sought to investigate the behaviours of sound in different space settings.

The unique behaviours that sound exhibited in these different space settings was the main content of the investigations they carried. These early researchers came up with the premise that the relationship between sound and space was utterly dependent on architecture.

This relationship was vividly captured in the ideas and works of Vitruvius when he sought to control sound in theatres. A concrete conclusion that was reached by these researchers was that sound and music had an explicit linkage to architecture underlain through the harmony of the universe.

Sound and space could not be understood without the use of architecture that was crucial in developing harmonic properties of sound as well as the mathematical impressions of sound and music. All the above was necessary because it necessitated the consideration of acoustic perspectives in designing ancient theatres.

The ancient researchers also did conclude that site and sound existed simultaneously and that the relationship could be examined through the listening experience. Their joint existence can fall within the social presence context or private experience context.

In terms of acoustics and resonance, site and sound do determine their development where one of them is characterized as a receiver while the other is characterized as a transmitter. The above explanation by the Greek researchers of sound and space concluded that space is crucial in the controlling, deadening, reflection, and destruction of sound.

There is a lot of architecture that goes to designing and developing areas where people live for instance in cities and quiet parks. That therefore means there can be a deliberate generation of sound to alter space. Similarly, one can shape space to manipulate sound to a negative or positive effect instead of reducing or deadening or eliminating it.

Besides the perception capabilities that human beings display toward sound, they can also create and destroy both sound and space. When designing space, architects are mostly concerned about the acoustic factors that will affect the spaces they design.

Acoustics

One of the concepts that come out prominently in the relationship between sound and space is acoustics. According to Ripley et al, every room has a sound. In any room, sound waves experience reflection, absorption, and dispersion (45). This is done by the boundaries the physical contents like furniture and the people present.

It’s important to note that different rooms have different sounding formats. The sounding is determined by the size, geometry and the materials that are used. More importantly, their acoustic behaviour is more critical to the sounding of the room.

A good understanding of the dynamics involved in acoustics will help shed some light on the concept and help in explaining the effect of human beings on space and sound.

Size, geometry, diffusion, and absorption describe acoustics in the most basic terms. Acoustics is all about eliminating resonances by ensuring reflections of sound disappear through absorption and diffusion.

In their quest to improve sound quality, acousticians try to modify rooms through architectural designs that greatly alter sound in rooms especially theatres to fit the purpose. However, it is imperative to highlight that the sound source is also a factor in determining the quality of the sound experiences in a room.

More often than not, acoustic engineers and architects try to dampen the rooms in order to improve the sound of the reflection. Sometimes it is successful while at times it flops badly. Sound quality in a room is mainly determined by the material used. Every material possesses a vibration character. This is more critical in the reflection of sound waves, perhaps more critical than the absorption and dispersion coefficients.

To achieve the best reflection, engineers struggle to match the mother of tone to the character of the reflecting material. The mother of tone is ideal because it is the same benchmark that is used by the human body in its regulation of vibration of ears and generally, bodies. It’s against these that all sounds that are meant for any human being are evaluated.

Size

Resonant frequencies are mainly affected by the size of the room. These cavity models of the room signify that a few of frequencies will be higher or louder than all other frequencies available. For instance, a sub hoofer that normally has low frequencies is designed to activate and excite the cavity modes present in rooms. The cavity modes or frequencies of a room can only be changed through alteration of the size or its volume that is more or less the size.

Geometry

Direction of sound reflections in a room is determined by the geometry of the room. On the other hand, the geometry of the room is determined by the angles and the positioning of the walls as well as the floor, ceiling, furniture and any other physical object in the room. Any new entry into a room changes the acoustics of that particular room. It is important to note that the commonest reflection happens between parallel rather than perpendicular walls.

Materials

The materials that make up the walls, ceiling, and floor of the room as well as the materials of the furniture and any other physical objects greatly determine the acoustics. Understanding into these individual material properties will need a macro understanding of the individual materials on the physical features of a room.

Concisely, the acoustic properties of a material in a room are determined through the amount of sound that is reflected by that particular object. The amount of sound is determined by the absorption coefficient. Also determining the acoustic properties of a material is the direction the reflection takes which is determined by the dispersion or diffusion coefficient.

The physical objects that are capable of creating and sometimes destroying sound and the acoustic energy that fills the air are some of the major aspects of sound. Both scientific and aesthetic ways, the relationship with the environment and the circumstances that surround someone determine who gets to hear what.

Example with Empty House

Perhaps the relationship between space and sound is better captured through the demonstration of an empty house and that is already furnished.

An empty house demonstrates acoustic harshness that is not pleasant to the ear at all. Sound in occupied houses is more soft and accommodating than the former. The different surfaces from different objects that are present in the house help in the refraction and softening of the sound giving a soothing acoustic.

According to Pallasmaa, different spaces and buildings display varied characteristics of attractiveness, feelings, intimacy, monumentality, harshness, invitation, or rejection (58). The above characteristics signify either hospitality or rejection.

Human Effect on Sound in a Space

The human effect on sound and space is mainly captured through the architectural element that is directly related to sound and space. People have come up with designs that manipulate sound to achieve the sound qualities that they want.

Streets

For instance, different city echoes are determined by the shape of the streets as dictated by the architectural styles and materials. Thompson notes that many cities nowadays have lost the echo touch that ancient cities used to have (78).

Contemporary streets cannot return the echo because the interiors have been designed to censure and absorb sound. The acoustic volume of space has been eliminated over time through the programmed recorded designs that dominate the sound industry. Heavy urban traffic characteristic of the cities nowadays and the varying open spaces wildly affect sound quality.

Symphony Hall

The creation of Symphony Hall marked the beginning of an acoustic era dominated by technology. This technology enabled architects and acousticians to have greater control of over sound. The Symphony Hall is still regarded as the first-ever, modern science-inspired creation that clearly captured the effect of human beings and space on sound.

Urban Architecture

One critical factor that comes up in the human effect on sound on space and the incorporation of architecture into the study and understanding of sound is the materiality of the objects use. Reverberation is determined by the frequency dependency of the powers of sound absorption by the materials used in architecture. Within the materiality concept, the barriers that aid in minimizing noise pollution in buildings and construction came up.

According to Wade, human beings have largely been responsible for the manipulation of architecture and space in the cities to introduce a completely new concept of soundscape (56). The use of space has ensured the resonation of the cities, echoing, muffling, and the isolation of all the urban sounds creating a new dimension of soundscape.

Urban designers and planners have responded by planning every building in the cities in specialized and differentiated ways. Determination of the openness of the streets, planting of trees and the specification of materials for different surfaces has been carefully considered in the use of space to control sound.

Due to the relative easiness through which architects can make predictions on the reverberations, the acoustics of the inside of buildings have been easily controlled and their spaces only reflect the acoustic qualities that their owners prefer.

Wade says that human beings are perceptive creatures as well as active creators of sound and space. The acoustic space that is designed by architects is the primary concern when designing structures. Human beings are increasingly capable of manipulating the soundscapes of buildings through advanced architectural designs.

In this advanced manipulation of sound contexts, architects have sought to understand the effect of spatial sound. With the advancement in technology brought about by the Industrial Revolution, people started modifying and measuring sound.

Electro-Acoustics

Scientific study of sound enabled acoustic engineers and acousticians to manipulate microphones and amplifiers and loudspeakers together with the electrical signals that sound devices used. The discovery of sound production through electronics redefined acoustical phenomena using electronics rather than architecture. Acousticians could easily study and understand the behaviours of sound thanks to the advanced technology.

According to Labelle and Roden, the sounds that are present today are because of technological mediation that is as a direct result of the manipulation by engineers and architects.

Control of the behaviours of sound is no longer the mystery it used to be. Many more materials used in the generation of sound have been developed together with numerous electro-acoustics devices that have helped greatly in the understanding of acoustics.

The development of electro-acoustics and other techniques of manipulating sound have led to the production of both intended and unintended consequences. These noises include radio broadcasts, music concerts, and motion pictures with soundtracks that have become popular with people.

Sound Pollution

It’s important to note that it is the need to control sound behaviour and a culture for listening that have driven both the architectural and technological developments in acoustics.

New worries about noise that is as a direct result of human being manipulation of the sound space led to the desire by acousticians to control the sound in specific rooms where performances were held and that were important in producing acoustically correct music. Furthermore, the desire to eliminate all unnecessary sound was informed by the need to achieve efficiency in acoustics.

According to Ripley et al control of acoustics by architects and engineers was seen as a way of enabling these musicians exercise choice in a world filled with all kinds of aural commodities (89). This development helped producers and other acoustically interested people to determine what constitutes good and acceptable sound and to determine how and what it took to achieve it.

Sound Absorbing Structures

The gradual development of the relationship between sound and space led to the reformation of the principles that define it. There was gradual dissociation of sound from space to an extent the relationship became non-existent. The development of sound-absorbing structures and the instruments that produced their own authentic acoustic sounds diminished the relationship between sound and space.

Outcome

It is safe to conclude that the architectural bit has become a little differentiated and now concentrated on the development of either good structures or instruments that produce acoustic sounds according to the preference of the listeners. Reverberation was a direct creation of architecture that necessitated its creation. It was always a function of the room size, geometry and the materials of the surfaces of the objects in the room.

These factors together controlled the production of acoustic sound for long periods. It is therefore with relief that products that can produce acoustic sounds can be made and reverberation is just a form of noise that does not need to be controlled to produce acoustic sound.

Conclusion

Though significantly diminished, sound and space still have a long relationship. Modern science has helped acousticians to achieve a distinct sound without much input from architecture. Architecture now is concerned more with reality than abstraction. It is now an important factor in the development of other fields like politics and social development.

Distraction will always exist in the world given the different preferences and natures of the sound-producing objects that inhabit the earth. However, it is safe to conclude that harmony has been achieved through the development of electro-acoustic instruments and the reduction of the dependence of acoustics on architecture.

The dissociation of sound and space has been achieved only to some extent. Many musicians and artists’ sounds still are dictated by the architecture of the places where they perform. The influence that an artist puts on space determines to a great extent the type of sound that is produced. Artists nowadays have focused on the manipulation of sound through architecture only for recording purposes.

On the same note, it’s will be absurd to generally say that other sounds that are produced on Earth are not worth listening to. Besides acoustic sound, other sounds can be harnessed to produce aesthetic plays that are pleasant to the ear.

Works Cited

LaBelle, Brandon and Roden, Steve. Site of sound: of architecture and the ear, Volume 1. London: Errant Bodies Press, 1999. Print.

Pallasmaa, Juhani. The eyes of the skin: architecture and the senses. New York: Wiley-Academy, 2005. Print.

Ripley et al. In the place of sound: architecture, music, and acoustics. Cambridge: Cambridge University Press, 2007. Print

Thompson, Emily. The Soundscape of Modernity. Massachusetts: MIT Press, 2004. Print.

Wade, Bonnie. Imaging sound: an ethno musicological study of music, art. Chicago: University of Chicago Press, 2006. Print.

Sound Techniques in the Truman

The movie The Truman Show directed by Peter Weir is an illustration of the manipulation of the lead character’s life. Truman Burbank is the main star of the reality show watched by many. However, he is not aware of that, and to him, everything he is experiencing is real. The director is using a variety of techniques such as lighting, camera work, and sound to convey the story and shape the meaning of the film. These effects, in different scenes, support the interactions of the characters and their actions. They create the mood of the scenes and support the visuals seen on the screen. One of these means, the sound effects in particular, help develop the narrative and form a better understanding of the story for the viewer.

The sound effects are essential components of the modern movie making process. They appear throughout Peter Weir’s film and help shape the plot. Gocsic et al. describe the importance of this element in this way – “the sound we hear in a film— its music, dialogue, and sound effects — creates meaning just as much as what we see” (49). These effects in this movie are marching sounds, the thunderstorm and music. According to Gocsic et al., a sound effect is “a sound artificially created for the soundtrack that has a definite function in telling the story” (255). Therefore, sound effects are crucial factors in communicating the plot to the viewer. In The Truman Show, the effects of the military marching, thunderstorm and piano music are significant because they reinforce the course of the narrative by supporting the visuals.

The sound of marching sets the scene and emphasizes the unsettling mood of searching for Truman Burbank. In the search scene, after Truman has realized he is being filmed and the life that he has known is not real, the director uses the sounds of military marching to set the atmosphere of worry. Together with lighting and camera angles, the episode conveys the seriousness of the director’s decision to catch the main character.

The thunder noise helps portray the disturbing atmosphere when Truman Burbank is caught in a storm on the boat. In this scene, the director used thunder sounds, together with lighting effects. In this scene, Christof, the director of the show, is trying to force the main character to return. As in the previous episode, the sounds help the viewer understand the danger that Truman is in. Therefore, the viewer can understand the feelings of Truman Burbank more clearly.

The music in the final scene of the movie intensifies the atmosphere of Christof’s monologue. Piano sounds are heard during the speech, in which the character expresses his feeling of being the “God” in the show. The melody is long and melancholic, fitting the main idea of Christof’s speech. The character is expressing his believes while trying to convince Truman to stay on the show. The tone of voice and an echo create the mood for the divine atmosphere. The contrast of this scene with the previous escape and search episode is evident. While the earlier one sets the mood for worry, the final scene creates an illusion of the director being a positive character, a creator of everything around him. The scene gives a peaceful feeling as Christof talks about hope and inspiration.

Overall, the sound effects in Peter Weir’s The Truman Show together with lighting and camera angles help build the atmosphere of the film. The sound effects the viewer hears throughout a movie are important as they shape the mood of the scenes. The sounds of military marching and the storm effects create the unsettling feeling for Truman’s escape. The tone of voice and the piano melody help the scene of Christof’s final speech to have a divine and peaceful atmosphere.

Works Cited

Gocsic, Karen M. et al. Writing About Movies. 4th ed., Norton & Company Inc., 2016.

The Truman Show. Directed by Peter Weir, performance by Jim Carrey, Paramount Pictures, 1998.