algorithmic sketchbook part c final _melissa tokkuzun_638547

A L G O R I T H M I C S K E T C H B O O K

M E L I S S A TO K K U Z U N

A r c h i t e c t u r a l D e s i g n S t u d i o A i r 2 0 1 5

ARCHITECTURAL DESIGN STUDIO AIR SEMESTER 1 2015

TUTORIAL 10 CANHUI CHEN

C o n t e n t s

C O N T E N T S

WEEK 01 4 - 5WEEK 02 6 - 7WEEK 03 8 - 11WEEK 04 12 - 15WEEK 05 16 - 23NON TEACHING 24 - 27WEEK 06 28 - 31WEEK 07 32 - 35WEEK 08 36 - 37WEEK 09 38 - 41WEEK 10-12 42 - 47

WEEK 01

4

LOFTINGReally enjoyed it. The easiest thing possible to do on grasshopper and rhino.

The process of lofting and baking is a very simple and usefull element.

5

TRIANGULATIONAbove computations were really easy to pro-duce.

The computation to the left was difficult to use. The offsetting was not working.

6

WEEK 02

DRIFTWOOD This was really interesting. I struggled to get the fom looking the way it was suppose to be.

7

My failed attempt at the driftwood exercise.I began exploring different forms

This was aan improved version of the driftwood exercise. I didnt quite get it accurate, but the

formal shape is seen. I couldnt manage to shade the object.

WEEK 03

8

GRIDSHELLMy first attempt at the gridshell exercise.

9

My second attempt of the gridshell exercise was more interesting. Instead of haveing the seper-ate curves being selected in a given sequence, I purposely set the curves in different orders.Produced an interesting shape.

10

Shaded version of a gridshell.

11

PATTERNSIntersting way of controling design. Can see that it can be implemented in facade designs of buildings.

PATTERNSThe Voronoi command did not work quite well. The patterns should stop in the referenced box,

but an error occured..

WEEK 04

This was my attmept at mkaing spirals by using the grasshopper containers of range and point to create an effective data flow of information to succesffully produce this form. The point planar element is used and linked with the range container to then use two points, being the start and end, which joins to a nurbs surface.

12

This pattern was created with the use of a sequence of True and False elements in the panel section of grass-hopper.

13

This pattern was created with the use of a sequence of True and False elements in the panel section of grass-hopper.

Here, Field Fundamentals are explored by using a charge to alter the density at a particular point that is de-fined by using grasshopper. This was produced with the use of a negative charge so all elements disperse away from the specified point.

14

Further deeloping the exploration of field fundamen-tals.

15

WEEK 05

16

This image uses the evaluating fields videos in week 5 online tutorials. Graph sections and controllers are used create interesting shapes. The graph mapper is used with the Bezier graph type. Although, this im-age does not clearly show the form that is created.

This uses the image and the colour variations within a selected image which creates a pattern that is more clutered in some area to due the denisty of the colour on the original image.

17

This image displays the use of evaulating fields which incorporates graph sections and controllers to form this unique biothing structure. The graph mapper is set with the Bezier graph type and allows us to control the paramters of line positions that extend from a point.

18

19

Voronoi patterns can be formed by adjusting the number slider of the divide container which forms interesting patterns within the circular form.

20

These two images display my failed at-tempt at adding cones onto a planner surface. While exploring the VoltaDom Script and creating Iterations for B2, I tried to use the same cone form on a more curved surface. However, as ev-ident it has not been too successful.

The surface was easily set in grass-hopper and then connected to the Isotrim container. Although, when the divide surface container came into play, and the cones were attached at these points, the cones were dispered and ex-tended off the defined surface area.

21

Another attempt at placing cones on a curved surface.

Further explorations of the VoltaDom script that was used for B2-Case Study 1.

22

23

Further explorations of the VoltaDom script that was used for B2-Case Study 1. This experiments with the form rather than the whole script that uses the cones on the surface of the form. Both a cone and spherical shape has been tested, which produced fairly similar ooutcomes. Chaning the domain container of the sphere allowed for the form to step away from the standard sphere form.

NON-TEACHING PERIOD

24

Tree statistics and dimensions have been ex-plored to create data structures with a path mapper. The surface is set in grasshopper, in this case a sphere has been used. The surface is then divided, which is then connect-ed to a graft container which create a new branch for each item. The tree statistics contianer is also used which outlines the path of tree structure, length of each branch and the number of paths in the trees.

25

Tree statistics and dimensions have been ex-plored to create data structures with a path mapper. The surface is set in grasshopper, in this case a sphere has been used. The surface is then divided, which is then connect-ed to a graft container which create a new branch for each item. The tree statistics contianer is also used which outlines the path of tree structure, length of each branch and the number of paths in the trees.

26

These are interesting geometries formed with the use of the lunchbox component of the grasshop-per plugin. The varaition of U and V values displays the decomposition pipes that become disconnected.

27

An organic form was used with a larger pipe thickness that forms much smaller cuts on the surface.

WEEK 6

28

Another piping experimentation has failed here. The paneling technique has been used again, although the connections have failed once again. One end of the form is connected with intersecting pipes. Although, the other sides are not structurally viable.

Piping experimentations on differ-ent surfaces. The pipe thickness-es have been varied to test the overall density that is produced.

29

This was a very interesting and aesthetical-ly pleasing piping technique used during the trials of iterations. However, it was not a fea-sible design as the constructability of this form can be questioned. Further connection would be required in order to resolve this issue.

WEEK 07

32

These are explorations of our weav-ing pattern that we decided to use as our final texhnique for Part C. These are basically varying the denisty between each of our curves.

33

These are a few explorations of what the patterns appear by chainigng the map containers that can alter the overall appearance. These are not ide-al patterns that we can use as there would be construction difficulties.

34

35

This repetative pattern is nice and simle, wlthough we could not con-struct this as the lines dont connect.

More complex patterns us-ing the mapping container.

WEEK 08

36

36

Here we attempted to add the weave pattern onto a seperate form. However, alot of errors occured, creating an un-even pattern across the whole surface.

The pattern is somewhat resolved here. We had to rebuild the cruves and adjust the number of points and stips we had to avoid the clutter.

37

Explorations of removing cells on the sur-face to experiment with abstract froms.

WEEK 09

38

Individual cells that can be used as planting pods for our deisgn concept.

Exploring different forms that could potentially work as our passive cooling system and soil stabilizing component.

39

These patterns work nicely, however the edges need work. There are flaws in the script and need to resovle it so that there is a neater finish to the structure,

41

Further explorations of forms with the weave pattern. This is slightly more ef-fective as it can fluently be extended into the ground to achieve our soil stabi-lising component of our design concept.

WEEK 10-12

42

Here we resolved the edges of the weave pattern. it is a much nicer finish around the edges. However, when we thickened the strips, the weave pat-tern along the anrrow sections were all intersecting. We had to adjust this and remove parts of the pattern to en-sure fabraication would be successful.

Playing with input curves that de-fine our overal form. The weave pattern was projected to the addi-tional lines which dictated our form.

43

The final form with the canopy and the soil stabilising component.

The indiviudal cells of the model, that can be used for our planting pods.

44

Final form with the pattern on the surface

45

Extruded strips to cre-ate volume and dimension.

46

Double layering of the cells that was an experimentation of having double sided cells that hang in the canopy area that act as a passive cooling system as the plants go through the transpiration process.

A r c h i t e c t u r a l D e s i g n S t u d i o A i r 2 0 1 5