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Channelbeta - Canale d'Informazione sull'Architettura
Contemporanea |
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This study wants to investigate methodologies of
spatial organization alternative to the orthogonal grid. In order to do so I've
decided to work on Chandigarh, a clear example of the role of the orthogonal grid
in urban and architectural design in the 20th
century. From a recent demographic studies done on Chandigarh, it merged that
there's a trend that could, if persisting, bring to a 33% population growth
in the turn of 15 year: this constituted my operational pretext. Today's
urban and economic structures of Chandigarh would not be able to deal with such
an expansion, thus it is necessary to formulate a strategy for change. The first
problem to be tackled then is to choose were to intervene. This
project, moving from these issues, focuses on the individuation of active areas,
those areas, that is, that have the potential for change. These areas could then
inform strategic decisions and characterize the early stages of the design
process. The
paradigm adopted by this research has been as close as possible to a non deterministic
and acausal model. The approach has been characterized by a mix of top-down/arbitrary
(push) and bottom-up/data-driven (pull). Software tools have been used unconventionally
through rigorous operational methodologies, defining operation-tools whose application
was consistent through out the work. The
project developed three phases: Information, Activation, Individuation.
In the first phase systems of data have been chosen in order to inform the three
basic elements in particle animation: the emitter, the attractors and the rejectors. The
use of 3D animation software allowed, in the second phase, the objectification
of the complex systems of relations that was set up during phase one. In
the last part area of potential intervention have been identified, they've been
characterized based on boolean operations (unite and intersect), whose operational
meaning is substantiated by the process that generated them. Image
captions. 01.0.0
Information Definition
of the elements within the particle animation: emitter, attractors, rejectors. 01.1.0
Emitter. 01.1.1
Pre-existing villages: the area that Chandigarh occupies
today as it was before the city was built, with the indication of the location
and size of villages and the grid of the modern city. The influence of previous
systems of spatial organization can effectively undermine the rigidity imposed
by the orthogonal grid to the evolution of the city. 01.1.2
Information on pre-existing villages is extracted from
the initial plan. Starting from this data a new spatial organization will be generated
which will inform the movement of the emitter and the quantity of particles in
the animation. Villages included within the boundaries of Chandigarh are shown
in black, external ones are shown in gray. 01.1.3
Through the use of the gaussian blur in Photoshop, interaction
among the elements of the previous diagram is shown Different shades of color
indicate higher or lower degrees of interaction among the parts. The gray fill
indicates the shared area of interaction (continuos isochromatic area). 01.1.4
By tracing the contours of the isochromatic areas an interaction
levels map is obtained. The gaussian blur is now applied to the shared interaction
area in order to show the areas of higher or lower intensity. The edge of the
area in color is what generates the emitter's trajectory in the particle animation. 01.1.5
In this last diagram the definition of the emitter is
finally complete. The colored area represents the emitter: it's axis corresponds
to the path followed during the animation, changes in width, instead, represent
different intensities in the emission of particles. These values were obtained
using the isochromatic curves (intensity index) to increase the width of the colored
strip by a factor multiplied by the isochromatic level in that point. 01.2.0
Attractors. 01.2.1
Informal markets (rehris). The area that Chandigarh occupies
today as it was before the city was built is shown, with the indication of the
location and size of informal markets. Markets are at the base of daily life:
areas around markets would attract incoming population. 01.2.2
Information on informal markets is extracted from the
initial plan. Starting from this data a new spatial organization will be generated
which will inform the location and strength of the attractors in the particle
animation 01.2.3
Through the use of the gaussian blur in Photoshop, interaction
among the elements of the previous diagram is shown Different shades of color
indicate higher or lower degrees of interaction among the parts. The gray fill
indicates the shared area of interaction (continuos isochromatic area). 01.2.4
By tracing the contours of the isochromatic areas an interaction
levels map is obtained. The gaussian blur is now applied to the shared interaction
area in order to show the areas of higher or lower intensity. The color fill generate
the organization of the attractors in the field. 01.2.5
In this last diagram the definition of the attractors
is finally complete. The small crosses indicate the position of the attractors,
while changes in the width of the colored strip represent different intensities.
These values were obtained using the isochromatic curves (intensity index) to
increase the width of the colored strip by a factor multiplied by the isochromatic
level in that point.
01.3.0 Rejectors. 01.3.1
Rents. This diagram shows rent costs for each sector:
the higher the rent the less people would be likely to move to that area. 01.3.2
Information on rents is extracted from the initial plan.
Starting from this data a new spatial organization will be generated which will
inform the location and strength of the rejectors in the particle animation 01.3.3
Through the use of the gaussian blur in Photoshop, interaction
among the elements of the previous diagram is shown Different shades of color
indicate higher or lower degrees of interaction among the parts. The gray fill
indicates the shared area of interaction (continuos isochromatic area). 01.3.4
By tracing the contours of the isochromatic areas an interaction
levels map is obtained. The gaussian blur is now applied to the shared interaction
area in order to show the areas of higher or lower intensity. The color fill generate
the organization of the rejectors in the field. 01.3.5
In this last diagram the definition of the rejectors is
finally complete. The small crosses indicate the position of the rejectors, while
changes in the width of the colored strip represent different intensities. These
values were obtained using the isochromatic curves (intensity index) to increase
the width of the colored strip by a factor multiplied by the isochromatic level
in that point. 02.0.0
activation. The
particle animation is run The particles' movement in the field objectifies the
complex system of relationships that was set up in section 1.
02.1.0 First
frame. 02.1.1
Particle distribution in the chosen frame. 02.1.2
Gaussian blur shows areas of higher or lower particle
density. 02.1.3
different levels of density are identified through the
tracing of isochromatic areas. 02.1.4
The area shown in color identifies the largest area in
which particles can be found (area of diffusion). 02.1.5
The area shown in color identifies the area of highest
density (area of concentration). 02.2.0
Second frame.
02.2.1 Particle
distribution in the chosen frame. 02.2.2
Gaussian blur shows areas of higher or lower particle
density. 02.2.3
different levels of density are identified through the
tracing of isochromatic areas. 02.2.4
The area shown in color identifies the largest area in
which particles can be found (area of diffusion). 02.2.5
The area shown in color identifies the area of highest
density (area of concentration). 02.3.0
Third frame.
02.3.1 Particle distribution in
the chosen frame. 02.3.2
Gaussian blur shows areas of higher or lower particle
density. 02.3.3
different levels of density are identified through the
tracing of isochromatic areas. 02.3.4
The area shown in color identifies the largest area in
which particles can be found (area of diffusion). The
area shown in color identifies the area of highest density (area of concentration). 03.0.0
Individuation. Framing
of the areas in which changes in Chandigarh's urban and economical structures
could occur. 03.1.0
Active Areas 03.1.1
Superimposition of largest areas in which particles can
be found from the selected frames (areas of diffusion). 03.1.2
Areas are colored and made translucid to show where they
overlap. The intersection of all the areas of diffusion identifies a specific
zone (area of permanence) relevant to develop a strategy for intervention, the
area, that is, in which, in any given moment in the animation, particles can be
found. They're concentration can vary, but we have absolute certainty of particle
activity in this area. Superimposition
of areas of highest density from the selected frames (areas of concentration). 03.1.4
The union of all the areas of concentration identifies
a specific zone (area of variation) relevant to develop a strategy for intervention,
the area, that is, in which, in any given moment in the animation, the highest
particle density can be found, thus we have absolute certainty of highest concentrations
of particles will float within these boundaries. 03.1.5
The area of permanence and the area of variation allow
to develop a substantiated strategy. The architect is now able to interact with
the physical site through an abstract construct distant from the orthogonal
grid. QuArch
2001 |
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[10-2002] |
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Pictures provided by
the author |
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