work portfolio
DESCRIPTION
Personal work portfolio Luis Fernando OdiagaTRANSCRIPT
1
Parametric House
The goal of this project was to get a simultaneous transformation of the plot and the house, Both the orientation and the modification are driven by parameters such as: Incidence angle of the sun, wind direction, number of inhabitants, number of sq meters to build. The simultaneous modelling of the topography and the house is driven by 9 chained points, this ensures a soften modelling giving control on the modification without the need of redrawing, being sure that the heights and the minimum dimensions on the same time that are granting comfort, enrich the spacial experience of
the house, the plot and the surroundings of the plot.
parametric design, digital fabrication, laser cut optimiza-tion.
Top solid, Rhino, V-ray, CS3, Laser Cutter 100w
developed in colaboration with Francisca Aroso & Javier Olmeda
South viewNorth view
Entrance view
Structural grid Timber model Correlative modification
2
PLAN <-0.50,3.00>
B
A
CD SECTION CSECTION D
SECTION A
SECTION B
MODELO DE POLVO
Parametric Houseparametric design, digital fabrication, laser cut optimiza-tion.
Top solid, Rhino, V-ray, CS3, Laser Cutter 100w
developed in colaboration with Francisca Aroso & Javier Olmeda
3
Relational Temple
Pilgrimage Sanctuary for Chapi´s Virgin, The design looks after a fusion of the terrain with the proposal defining spaces by the use of foldings on the topography and tectonic interventions rather than constructive ones, the design fosters the needs of a religious place and link them with the ones of the commercial activities, The generated space works as an
accelerator of activities and relations within visitors.
Religious event, path-program, Chapi.
3dsMAX, V-ray, AutoCAD, CS3
Night view Altar view
360º view inside the templeInside view of the temple
Thesis Project
360º view inside the baptistery Baptistery inside view
4
In order to reinforce the protagonic role of the user, which is a walking one, the program was developed trough circulation paths. Instead of giving importance to the functions, the circulation and the activities that may happen on the surroundings are the guidelines for the reshape of the
terrain and for the way the the site wraps the building.
Shopping
Infrastructure
Religious
Relational
Previous temple
New temple
Relational area1
Circulation diagrams
Relational TempleReligious event, path-program, Chapi.
3dsMAX, V-ray, AutoCAD, CS3
Thesis Project
1.- Take the x, y & z coordinates for points A, B & C from the photograms
Frames 1 2 3 4 5 6 7 8 9 10 11 12
Poin
ts
A x 76,03 606,75 854,39 672,82 420,85 154,36 127 679,16 1191,38 1357,48 938,13 432,14y 314,45 0 437,65 1035,33 1615,14 2181,05 2579,94 2217,47 1823,15 1472,84 1148,25 805,04z 1533,63 1447,11 1151,47 917,83 702,16 467,98 87,87 43,01 198,78 637,54 1050,56 1318,85
B x 136,12 117,64 306,11 355,59 277,75 299,09 466,63 586,22 554,58 484,07 395,76 289,98y 688,49 908,78 1029,73 1211,85 1429,98 1638,01 1807,52 1776,66 1568,25 1339,61 1109,21 882,38z 1070,71 1008,45 874,91 720,48 596,75 445,37 386,15 568,51 721,59 829,7 919,75 999,36
C x 235,15 519,64 671,96 660,67 605,99 578,55 499,49 207,01 279,97 307,97 228,5 131,79y 246,42 293,61 571,38 919,89 1255,29 1514,18 1630,32 1531,5 1202,02 889,57 646,57 437,63z 1083,38 889,19 774,16 736,59 651,37 424,39 137,15 278,06 302,9 441,53 681,64 947,28
2.- Arrange the values by coordinate axis (x, y & z) to translate absolute numbers into percentages related to the highest value of each axis from the three points (A,B & C)
Frames 1 2 3 4 5 6 7 8 9 10 11 12
Poin
ts
Coo
rdin
ates
A x 76,03 606,75 854,39 672,82 420,85 154,36 127 679,16 1191,38 1357,48 938,13 432,14B x 136,12 117,64 306,11 355,59 277,75 299,09 466,63 586,22 554,58 484,07 395,76 289,98C x 235,15 519,64 671,96 660,67 605,99 578,55 499,49 207,01 279,97 307,97 228,5 131,79
A y 314,45 0 437,65 1035,33 1615,14 2181,05 2579,94 2217,47 1823,15 1472,84 1148,25 805,04B y 688,49 908,78 1029,73 1211,85 1429,98 1638,01 1807,52 1776,66 1568,25 1339,61 1109,21 882,38C y 246,42 293,61 571,38 919,89 1255,29 1514,18 1630,32 1531,5 1202,02 889,57 646,57 437,63
A z 1533,63 1447,11 1151,47 917,83 702,16 467,98 87,87 43,01 198,78 637,54 1050,56 1318,85B z 1070,71 1008,45 874,91 720,48 596,75 445,37 386,15 568,51 721,59 829,7 919,75 999,36C z 1083,38 889,19 774,16 736,59 651,37 424,39 137,15 278,06 302,9 441,53 681,64 947,28
Frames 1 2 3 4 5 6 7 8 9 10 11 12
Poin
ts
Coo
rdin
ates
A x 5,60 44,70 62,94 49,56 31,00 11,37 9,36 50,03 87,76 100,00 69,11 31,83B x 10,03 8,67 22,55 26,19 20,46 22,03 34,37 43,18 40,85 35,66 29,15 21,36C x 17,32 38,28 49,50 48,67 44,64 42,62 36,80 15,25 20,62 22,69 16,83 9,71
A y 12,19 0,00 16,96 40,13 62,60 84,54 100,00 85,95 70,67 57,09 44,51 31,20B y 26,69 35,22 39,91 46,97 55,43 63,49 70,06 68,86 60,79 51,92 42,99 34,20C y 9,55 11,38 22,15 35,66 48,66 58,69 63,19 59,36 46,59 34,48 25,06 16,96
A z 100,00 94,36 75,08 59,85 45,78 30,51 5,73 2,80 12,96 41,57 68,50 86,00B z 69,82 65,76 57,05 46,98 38,91 29,04 25,18 37,07 47,05 54,10 59,97 65,16C z 70,64 57,98 50,48 48,03 42,47 27,67 8,94 18,13 19,75 28,79 44,45 61,77
1.- Take the x, y & z coordinates for points A, B & C from the photograms
Frames 1 2 3 4 5 6 7 8 9 10 11 12
Poin
ts
A x 76,03 606,75 854,39 672,82 420,85 154,36 127 679,16 1191,38 1357,48 938,13 432,14y 314,45 0 437,65 1035,33 1615,14 2181,05 2579,94 2217,47 1823,15 1472,84 1148,25 805,04z 1533,63 1447,11 1151,47 917,83 702,16 467,98 87,87 43,01 198,78 637,54 1050,56 1318,85
B x 136,12 117,64 306,11 355,59 277,75 299,09 466,63 586,22 554,58 484,07 395,76 289,98y 688,49 908,78 1029,73 1211,85 1429,98 1638,01 1807,52 1776,66 1568,25 1339,61 1109,21 882,38z 1070,71 1008,45 874,91 720,48 596,75 445,37 386,15 568,51 721,59 829,7 919,75 999,36
C x 235,15 519,64 671,96 660,67 605,99 578,55 499,49 207,01 279,97 307,97 228,5 131,79y 246,42 293,61 571,38 919,89 1255,29 1514,18 1630,32 1531,5 1202,02 889,57 646,57 437,63z 1083,38 889,19 774,16 736,59 651,37 424,39 137,15 278,06 302,9 441,53 681,64 947,28
2.- Arrange the values by coordinate axis (x, y & z) to translate absolute numbers into percentages related to the highest value of each axis from the three points (A,B & C)
Frames 1 2 3 4 5 6 7 8 9 10 11 12
Poin
ts
Coo
rdin
ates
A x 76,03 606,75 854,39 672,82 420,85 154,36 127 679,16 1191,38 1357,48 938,13 432,14B x 136,12 117,64 306,11 355,59 277,75 299,09 466,63 586,22 554,58 484,07 395,76 289,98C x 235,15 519,64 671,96 660,67 605,99 578,55 499,49 207,01 279,97 307,97 228,5 131,79
A y 314,45 0 437,65 1035,33 1615,14 2181,05 2579,94 2217,47 1823,15 1472,84 1148,25 805,04B y 688,49 908,78 1029,73 1211,85 1429,98 1638,01 1807,52 1776,66 1568,25 1339,61 1109,21 882,38C y 246,42 293,61 571,38 919,89 1255,29 1514,18 1630,32 1531,5 1202,02 889,57 646,57 437,63
A z 1533,63 1447,11 1151,47 917,83 702,16 467,98 87,87 43,01 198,78 637,54 1050,56 1318,85B z 1070,71 1008,45 874,91 720,48 596,75 445,37 386,15 568,51 721,59 829,7 919,75 999,36C z 1083,38 889,19 774,16 736,59 651,37 424,39 137,15 278,06 302,9 441,53 681,64 947,28
Frames 1 2 3 4 5 6 7 8 9 10 11 12
Poin
ts
Coo
rdin
ates
A x 5,60 44,70 62,94 49,56 31,00 11,37 9,36 50,03 87,76 100,00 69,11 31,83B x 10,03 8,67 22,55 26,19 20,46 22,03 34,37 43,18 40,85 35,66 29,15 21,36C x 17,32 38,28 49,50 48,67 44,64 42,62 36,80 15,25 20,62 22,69 16,83 9,71
A y 12,19 0,00 16,96 40,13 62,60 84,54 100,00 85,95 70,67 57,09 44,51 31,20B y 26,69 35,22 39,91 46,97 55,43 63,49 70,06 68,86 60,79 51,92 42,99 34,20C y 9,55 11,38 22,15 35,66 48,66 58,69 63,19 59,36 46,59 34,48 25,06 16,96
A z 100,00 94,36 75,08 59,85 45,78 30,51 5,73 2,80 12,96 41,57 68,50 86,00B z 69,82 65,76 57,05 46,98 38,91 29,04 25,18 37,07 47,05 54,10 59,97 65,16C z 70,64 57,98 50,48 48,03 42,47 27,67 8,94 18,13 19,75 28,79 44,45 61,77
5
Birds
After the flight analysis of a pigeon and considering a complete cycle as the composition of 6 movements, excel sheets were developed with the coordinates of three given points for each wing and for the 6 movements, this was done in order to get an ideal flight cycle. With the use of a parametric software a path with the ability to modify scale and rotation angle of each bird. For the actual project 6 cycles were included and the path was arranged in one loop in the air and 3 support points to the ground. Because of the parametric platform it is possible to modify both, the scale and the location of the birds, getting a aesthetic that merges
the mechanic with the living.
Developed in Jordi Roses arquitectos
parametric design, digital fabrication, laser cut optimiza-tion.
Top solid, Rhino, V-ray, CS3, Laser Cutter 400w
6
Personalized Mask
After the study of the relations in the face of 27 people, excel sheets with the relation eyes-nouse-mouth of each one was developed. On a parametric software, a model able to communicate the more relevant characteristics of an ideal face fostering the relations eyes-nouse-mouth of any person was developed. In order to give texture and expression lines, some testing
with Rhino Cam was done.
parametric design, digital fabrication, laser cut optimiza-tion.
Top solid, Rhino, V-ray, CS3, CNC Milling
developed in colaboration with Francisca Aroso & Javier Olmeda
Parametric model development
Texture testingGetting the relations
The 27 people sample
Powder model Fitting the virtual model
7
Infanta Maria Margarita Parametric Design, Digital Fabrication, Rhino CAM, 3d printitng.
The cooperation in Hyperhabitat for the Venice biennale, was about placing the Velazquez´s paint “Las Meninas” inside the exhibition context. In order to do so, the image was vectored with an illustrator script translating it into black spots of different intensity and diameter. The image then was sent to a 400W Laser Cutter to execute the perforations on a Plastic sheet of 20mm, because of the LEDs over its boundaries the image ended being illuminated from the inside, giving an ethereal and electronic aesthetic.
Illustrator, Cortadora Laser 400w
Developed in Hyperhabitat for the Venice biennale 2008
Illustrator script
Actual Paint
Testing the perforations
Testing the LEDs
Final product
CAD/CAM allows serial production of different pieces.
Using the laser cutter to cut a mold, the number of different non-standardized pieces that can be made is limited only by the the amount of recycled materials.
Using themold, thenon-standardizedcan bethe thematerials.
The archs are built-up of 8 pieces, assembled by joints to avoid the use of nails or glue. Due to the use of the arch-shape,v joints work at compression, nevertheless any opossite charge is controlled by the links between joints.
The use of consecutive archs of diferent sizes fosters different configurations acording to multiple needs, with one universal built-up shape.
Extreme natural scenarios helped to render the most suitable shape for a self suffi-cient dwelling with a global aproach.
resistant earthquakefloating aerodynamic
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1 2 3
SPACE RECYCLING recycle of the plot...
...portable dwelling ...interchangable pieces ...folding furniture & cushion-skin with flexible stuff ...indeterminate space
recycle the parts... recycle the void and the envelope... recycle the use...
Self -sufficiencySelf -fab
x6
The archs are built-up of 8 pieces, assembles by joints to avoid the use of nails or glue. Due to the use of the arch-shape, joints work at compression, nvertheless any opossite charge is controlled by the links between joints
Self -Sufficency
energy
materials
supplies
100% indeterminate space
100% eolic microgenerators0.60kW/Day120W/m2
100% stuffed PVC tarpaulin bags
100% hydroponic crops
stuffed tarpaulin bags fill up the structure as an adaptable skin. the stuffing material depends on the climate of the specific environment
waterproof, non toxic, lightweight, UV resistant, flexible
crushed and combined with cement and rubble can make a useful structural material
thermic insulator, lightweight, non toxic, durable
[HOST]Pisco-Peru
pisco city
water pump
eolic micro generator
solar panel
site
PET residues (drink bottles)
PVC tarpaulins recycled from medium advertising, trucks, print errors, etc.
Water from “ollas”(pre-inca technology) near seaside or riverside
hydroponic crops
fog water collectors
rain water
dry toilets
textile waste , straw, sawdust, etc.
can be pumped up with energy supplied by eolic micro-generators
recycled wood
15.5 °C - 22 °CPARACAS WINDS: south east
up to 32km/h
8
3dsMAX, V-ray, AutoCAD, CS3
Self-fab ShelterParametric design, digital fabrication, laser cut optimiza-tion. developed in colaboration with Natalija Boljsakov
A 4x4 proposal, for pre-fab construction on disaster zones, emergence housing, taking in acount the problems of fabrication, transportation, assembly, energy needs, and recycling procedures for a sustainable
behaviour.
Luis Fernando Odiaga portfolio release 2009