Contextual Hybridities

CONTEXTUAL HYBRIDITIES

G R E G O R Y W A N G _ 3 0 0 4 1 1 2 0 8 A R C I 3 1 1 _ P R O J E C T 2

PRELUDE:

PROJECT ONE BIOTYPE VIRUS

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C O N TO U R : 01

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CONTOUR: 01

VIRAL SUBSTAN C E ( COAL etc .) S OURCE OF V IRUS D URATION OF GROW TH GROW TH C ONDITIONS

QUAN T IT Y OF SUBSTAN C E SIZE OF SUBSTAN C E M EDIU M F OR DECAY THICK N ESS OF M EDIU M LOCAT ION / PLAC EM EN T OF SUBSTAN C E

PROJECT TWO

PH A S E TW O

DECAY

GROWTH

PROJECT ONE

P H AS E ON E

T he ai m of Pr oj ec t tw o i s to i ntegr ate as pec ts of pr oj ec t one to i nfor m the outc om e of des i gn i n pr oj ec t tw o. T he i m pl em entati on of gr ow th and dec ay as phas es i n the des i gn w i l l deter m i ne the s uc c es s of the outc om e.

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G R E AT E S T A N G L E AT M O A P O I N T

A N A LY S I S O F WAT E R VELOCITY IN Y DIRECTION

MEDIAN ANGLE AT M O A P O I N T

MOA POINT SITE CONSTRAINTS

ONE KILOMETRE GRID

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LOWEST ANGLE AT M O A P O I N T

WATER VELOCITY

A N A LY S I S O F WAT E R VELOCITY IN X DIRECTION

Using G r asshopper, a point gr id is pr oject ed ont o t he M oa Point Cont our. The angle in which t he point on t he cont our sit s in r elat ion t o t he Z axis is r em apped as a ser ies of height s and colour s on a set spect r a. The angles of t he sit e ar e r elat ive t o t he wat er velocit y exper ienced by r ainf all. This inf or m at ion inf or m s us of t he valleys which decay over t housands of year s. Decay at t he specif ic locat ions ar e cor r elat ed t o l ow r oot devel opment of ve getati on and higher quant it ies of soft soi l .

POINTS OF HIGH DECAY

AREAS SUSCEPTIBLE T O D E C AY D U E T O SOFT SOIL AND MINIMAL ROOT DEVELOPMENT

VA L L E Y S A N D R I D G E S DERIVED FROM MODEL

MOA POINT SITE CONSTRAINTS

ONE KILOMETRE GRID

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IMPACT OF GLOBAL WARMING P R O G R E S S I O N

O F

R I S I N G

W A T E R

L E V E L S

The eff ec t s of G l o b a l Wa rm i n g a re b e c o m i ng i ncreasi ngl y evi dent i n the ecol ogi cal and natur al env ir onm e n ts a ro u n d th e w o rl d . C o a stal areas i n parti cul ar are experi enci ng ri si ng wat er lev e l , re s u l ti n g i n re d u c e d c o a stal l and mass. Ri sing s ea lev els a t Mo a P o i n t w i l l re s u l t i n si gni fi cant change to the natural topogr aphic al f ea tu re s p re s e n t o n th e s i te ; the rocky i sl and w i l l one day be no more. The des ign of t hi s p ro j e c t w i l l e n c o mp a s s prehi stori c rai n condi ti ons of Moa P oi nt w hi ch onc e dec ay ed t h e l a n d fo rm to s c u l p t o f th e hi l l s of Moa P oi nt. The desi gn w i l l form an i n ter ac t ion wit h t h e w a te r o v e r ti me a s w a ter l evel s ri se.

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GROWTH S im u l a t i n g t h e g r o w t h o f b a cte r ia o ve r t im e. T h e f o r m i s i n f o r m e d b y Tu r b u le n t W ind p r e s e n t a t M o a Po in t

Me t h o d o l o g y May a - n P a r t i c l e s

Pr o cess - P ar t i c l e e m i t t e r - Del e t e i n f l u e n c e o f g r a vity o n p a r ticle em i s s i o n - Cre a t e a t u r b u l e n c e fie ld - A dj u s t a t t r i b u t e s o f tu r b u le n t fie ld - Con v e r t n P a r t i c l e s to Po lyg o n s - A dj u s t o u t p u t m e s h a ttr ib u te s - Run s i m u l a t i o n a n d p a u se a t se t inc r e m e n t s t o p r o d uce ite r a tio n s s im u l a t i n g g r o w t h

GROWTH 1.1

GROWTH 1.2

GROWTH 1.3

GROWTH 1.4

GROWTH 1.5

GROWTH 1.6

GROWTH 1.7

GROWTH 1.8

GROWTH 1.9

Pr o j ect 01 Vari a b le Dura t i o n o f G r o w t h

Site Vari ab l e W ind ( Tu r b u l e n c e )

1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9

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Pot ent i al Programme of Use W i nd B reak // B i rd S anc tuary

GROWTH S im u l a t i n g t h e g r o w t h o f b a cte r ia o ve r t im e. T h e f o r m i s i n f l u e n ce d b y in cr e a sin g ampl i t u d e s i n t h e o c e a n o ve r tim e .

Me t h o d o l o g y May a - M a s h Tr a i l s / Dyn a m ics

Pr o cess - Cre a t e a p l a n e a n d d e fo r m th e su r fa ce ov e r t i m e u s i n g t e x tu r e m a p p in g to s im u l a t e w a v e s - A dj u s t f r a m e s s o t h a t a m p litu d e o f wa ve s incr e a s e s o v e r t i m e - Cre a t e a m a s h n e t wo r k e m ittin g m o r e c ub e s o v e r t i m e - Lin k t h e u n d u l a t i n g o ce a n su r fa ce to th e c ol l i d i n g s u r f a c e o f th e d yn a m ic - Cre a t e m a s h t r a i l s - Run s i m u l a t i o n a n d p a u se a t se t incr e m e n t s t o p r o d u ce ite r a tio n s s im u l a t i n g g r o w t h

GROWTH 2.1

GROWTH 2.2

GROWTH 2.3

GROWTH 2.4

GROWTH 2.5

GROWTH 2.6

GROWTH 2.7

GROWTH 2.8

GROWTH 2.9

Pr o j ect 01 Vari a b le Dura t i o n o f G r o w t h

Site Vari ab l e Wav e s ( A m p l i t u d e )

2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9

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AMPLITUDE AMPLITUDE AMPLITUDE AMPLITUDE AMPLITUDE AMPLITUDE AMPLITUDE AMPLITUDE AMPLITUDE

0.00M 0.25M 0.50M 0.75M 1.00M 1.25M 1.50M 1.75M 2.00M

Pot ent i al Programme of Use N IWA fl oati ng w ater anal y s i s s tati on

D E C AY Mas h d i s t r i b u t i o n o f s p h e r e s d r o p o n to th e Moa P o i n t S i t e a s a r e su lt o f g r a vity. T h e f orm a l q u a l i t i e s p r o d uce d a r e in flu e n ce d b y t he l a n d f o r m , n a t u r a lly a ttr a cte d to wa r d s t he v a l l e y s .

Me t h o d o l o g y May a - M a s h D y n a m i cs/Co n str a in ts

Pr o cess - I np u t t h e M o a P o i n t la n d fo r m in to M a ya as a m e s h . - Cre a t e a M a s h n e t wo r k. - Cre a t e a M a s h D y n a m ic. - I np u t t h e l a n d f o r m a s a co llid e r fo r th e Ma s h n e t w o r k . - Cre a t e a M a s h g l u e co n str a in t a n d tr a ils c on n e c t i n g t h e M a s h g e o m e tr y to g e th e r. - A ni m a t e a n d f r e e z e a t in te r va ls to ca p tu r e t he c h a n g e o f s h a p e d u e to la n d fo r m .

DECAY 1.1

DECAY 1.2

DECAY 1.3

DECAY 1.4

DECAY 1.5

DECAY 1.6

DECAY 1.7

DECAY 1.8

DECAY 1.9

Pr o j ect 01 Vari a b le Thic k n e s s o f M a t e r i a l ( Du r a tio n )

Site Vari ab l e Nat u r a l f e a t u r e s o f L an d fo r m ( Va lle ys)

Poten t i al P ro g ra m m e o f U s e P ubl i c Wa l k w a y N e t w or ks

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D E C AY S im u l a t i n g t h e d e c a y o ve r tim e se e n in plan . T h e f o r m i s i n f l ue n ce d b y th e lo ca tio n of po i n t s r e p r e s e n t i n g th e p la ce m e n t loc ati o n o f t h e v i r a l s ub sta n ce .

Me t h o d o l o g y G rass h o p p e r - A n e m o n e

Pr o cess - Cre a t e a g r i d o n G r a ssh o p p e r to sp e cifie d len g t h s a n d s u b d i v i sio n s - Us i n g a r a n d o m s e ed ite r a te p o in t loca t i o n s w i t h i n t h e g r id ; a lso sp e cifyin g t he q u a n t i t y o f p o i n ts. - A re a a r o u n d s p e c i f i ed co n tr o l p o in ts dec r e a s e s o v e r t i m e. Gr id d ivisio n p o in ts t ha t f a l l o u t s i d e o f t h e a r e a , sn a p to a n d c lu s t e r a r o u n d c l o s est p o in ts o n a r e a bou n d a r y. - Da t a s t r u c t u r e o f p o in ts a r e r e ta in e d af t e r c l u s t e r i n g , a n d cu r ve is in te r p o la te d t hr o u g h n e w i t e r a t i on s o f th e g r id . - A ne m o n e l o o p i s u s ed to sim u la te tim e and a r e a d e c a y.

DECAY 2.1

DECAY 2.2

DECAY 2.3

DECAY 2.4

DECAY 2.5

DECAY 2.6

DECAY 2.7

DECAY 2.8

DECAY 2.9

Pr o j ect 01 Vari a b le P lace m e n t L o c a t i o n o f Vir a l Su b sta n ce Q uan t i t y o f Vi r a l S u b sta n ce

Site Vari ab l e -

2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9

POINTS: POINTS: POINTS: POINTS: POINTS: POINTS: POINTS: POINTS: POINTS:

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DECAY 2.1

D E C AY PLAN

Us in g t h e D e c a y e d f o r m cr e a te d o n G rass h o p p e r f r o m t h e p r e vio u s p a g e , c urve s e x t r a c t e d f r o m a fr e e ze fr a m e a r e t hen r e i n t r o d u c e d i n t o M a ya . A M a s h n e t w o r k i s d i s tr ib u te d a lo n g th e c urve e x t r a c t e d f r o m Gr a ssh o p p e r. T h is Mas h n e t w o r k e m u l a t e s th e h o t co a ls fr o m P roje c t 1 . A n a n i m a t i o n o v e r a pe r io d o f 2 5 0 fr a m e s is c re a t e d w i t h a t r a n sla tio n d o wn wa r d s. A s t h e a n i m a t i o n i s p l a ye d . th e cu r ve is rot ate d o n a l l a x i s a n d th e sca le d e cr e a se s ov er t i m e .

Pr o j ect 01 E mu la tio n

The d e c r e a s e i n s c a l e is in tr o d u ce d to emul a t e t h e l o s s o f t he r m a l e n e r g y o f th e hot c o a l s a s i t p a s s e s th r o u g h th e fo a m medi u m . T h i s r e s u l t s in th e e xit p o in t o f th e c oals t o b e m o r e s l e nd e r with le ss o f th e f oam ‘ d e c a y i n g ’ a w a y.

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TRANSLATION ROTATION SCALE

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TRANSLATION ROTATION SCALE

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TRANSLATION ROTATION SCALE

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ELEVATION

The r o t a t i o n i s i n t r o d u ce d to e m u la te d th e rand o m n e s s o f t h e c oa ls p a th in Pr o je ct 1 .

DECAY 2.2

ELEVATION

PLAN

DECAY 2.3

DECAY 2.4

DECAY 2.5

DECAY 2.6

ELEVATION

PLAN

DECAY 2.7

DECAY 2.8

DECAY 2.9

D E C AY

TESTING MODEL CONSTRAINTS Varia b l e s f r o m P r o j e ct On e a r e reint r o d u c e d a s v a r i a b le s with in M a ya . T h e f ollow i n g s e r i e s o f m o d e l will b e ite r a tio n s of De c a y m o d e l 2 . 9 .

DECAY 2.90

THICKNESS OF TRAILS: 0.1 NUMBER OF “COALS” : 75 TRAILS SCALE: 1.0

DECAY 2.91

THICKNESS OF TRAILS: 0.5 NUMBER OF “COALS” : 75 TRAILS SCALE: 1.0

DECAY 2.92

THICKNESS OF TRAILS: 1.0 NUMBER OF “COALS” : 75 TRAILS SCALE: 1.0

DECAY 2.93

THICKNESS OF TRAILS: 1.0 NUMBER OF “COALS” : 35 TRAILS SCALE: 1.0

DECAY 2.94

THICKNESS OF TRAILS: 1.0 NUMBER OF “COALS” : 35 TRAILS SCALE: 5.0

DECAY 2.95

THICKNESS OF TRAILS: 1.0 NUMBER OF “COALS” : 35 TRAILS SCALE: 10

DECAY 2.96

THICKNESS OF TRAILS: 1.0 NUMBER OF “COALS” : 35 TRAILS SCALE: 20

DECAY 2.97

THICKNESS OF TRAILS: 1.0 NUMBER OF “COALS” : 15 TRAILS SCALE: 20

DECAY 2.98

THICKNESS OF TRAILS: 0.1 NUMBER OF “COALS” : 500 TRAILS SCALE: 1.0

DECAY 2.90

DECAY 2.91

DECAY 2.92

DECAY 2.93

DECAY 2.94

Poten t i al P ro g ra m m e o f U s e Ligh t H o u s e / / Vi e w i n g To we r

DECAY 2.95

DECAY 2.96

DECAY 2.97

DECAY 2.98

VA L L E Y RECIPROCATING PREHISTORIC PATH OF RAINFALL TO MORPH MOA POINT

Releasing Mash particles at specified location to reciprocate historic path of rain fall to emulate the decay Moa Point; forming t h e s i t e i t i s t o d a y.

PLAN VIEW

VA L L E Y RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

VA L L E Y RECIPROCATING PREHISTORIC PATH OF RAINFALL TO MORPH MOA POINT

Releasing another set of Mash particles to interacting with the site contours.

PLAN VIEW

VA L L E Y RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

VA L L E Y RECIPROCATING PREHISTORIC PATH OF RAINFALL TO MORPH MOA POINT

Mash particles join to fully reciprocate the prehistoric rainfall of Moa Point, sculpting valleys. Speed of particles are hard to control, resulting in estrayed particles flowing down the contour at differing speeds.

PLAN VIEW

VA L L E Y RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

VA L L E Y RECIPROCATING PREHISTORIC PATH OF RAINFALL TO MORPH MOA POINT

By using Mash constraints the interaction between the Mash particles and the contour become more controlled with even distribution. The particles emulating rain, reconnect with the Ocean.

PLAN VIEW

VA L L E Y RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

VA L L E Y RECIPROCATING PREHISTORIC PATH OF RAINFALL TO MORPH MOA POINT

Mash particles interact with t h e O c e a n w a t e r. O v e r a period of years, the rising water levels influence the growth of a tower-like structure to emerge from the ocean This is achieved by using successful elements from the series: Decay 2

Poten t i al P ro g ra m m e o f U s e Light H o u s e / / Vi e w i n g To we r // Wa l k w a y

PLAN VIEW

VA L L E Y RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

PLAN VIEW

VA L L E Y RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

VA L L E Y RECIPROCATING PREHISTORIC PATH OF RAINFALL TO MORPH MOA POINT

Ideas from Decay series 1, are re-implemented to create networks between Mash particles. This create a structure situated in the valleys of Moa Point.

RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

PLAN VIEW

VA L L E Y

VA L L E Y PLAN VIEW

RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

P o t e n tia l P r o g r a m m e o f U s e

C a n t i l e ve r e d Str u ctu r e // F u tu r istic DOC H utt

VA L L E Y PLAN VIEW

RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

RECIPROCATING HISTORIC PATH OF RAINFALL TO MORPH MOA POINT

PLAN VIEW

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