Monday, April 21, 2014

Andrew Delle Bovi: Asn11 : FINAL PROJECT












The surface framework that controls the mapping of each component.

The power-copy framework that controls the aperture of each surface in relation to the attractor.










Top View/Elevation View










Surf_Dist Parameter: Controls how long or how short the surface that these components are mapped to is.

Tab_length Paramter: Controls the length of exterior tabs of each power copy, this is to provide for space in order for the modules to overlap successfully. 

Attractor_pos Parameter: This controls the location of the attractor which adjusts the opening aperture of each module in relative distance from the attractor.


Attractor_factor Parameter: This controls how much or how little the attractor takes effect on each module.

Offset_factor Parameter: This controls how large or how small the offset of each module is from its original dimension.










Finally we have a grid showing the unfolded geometry that could be exported and cut for fabrication!



Sunday, April 13, 2014

Andrew Delle Bovi: Asn10 : Knowledge Patterns 2















 Develop-able Flat Surfaces












Knowledge pattern for curve 


 Knowledge Pattern for surface and surface colors












Original surface file controlling curve position and surface curve divisions.

Original curve file control surface position, hole aperture and surface dimension.

Andrew Delle Bovi: Asn8 : Powercopy Knowledgeware


I started with a simple grid, created a multi-sectioned surface and then projected the points 
and created a fill object from connected poly-lines. This created the power copy.


Surface spline: height and length parameters are linked to grid spacing and amount of grid points.

Here the projected point surface is "stretched," we can see how the power-copies adjust to the change in the surface shape.













As the grid spacing is increased, the power-copies grow along with it but at a smaller spacing the extrusions stretch further and the inverse happens when scaling up.

Elevations of 1 inch spacing versus 5 inch spacing respectively. 











Additionally the power-copy extrusions are linked to an excel file which allows access 
to a random number generator. When updated we can see different results. Also,
by applying multiplication factors we can control the "range" of the randomization.










Here is an experimentation with applications of color changing parameters. As we randomize the extrusion heights linked to the excel sheet and stretch the projected point surface, we can see which power-copies exceed the limit of the max-area parameter and which remain below it. 

A quick snip of the color changing script applied for each power copy row created 
digital project.









Some material studies, just for fun......








Thanks for stopping by, come again.  :)-

Sunday, March 30, 2014

Andrew Delle Bovi: Reading 008: Algorithmic Architecture

Kostas Tzerdis discusses the ideas and strengths behind algorithms. He raises the notion that an algorithm may be associated in the use of instructions, commands or rules in architectural practices and have been implemented in past architectural endeavors, tracing back to the age of classical architecture. Interestingly he points out that an algorithm is generated by human ingenuity and the computer only plays the role of actuating upon the algorithm to produce results beyond the capabilities of a human mind. The interplay between human and computer through scripted language is also an intriguing topic. A human to human communication is based upon the prior knowledge that a human has a specific comprehension that the language is built upon. A human to computer language is radically different in that we do not fully comprehend the limitations and functionality of the computer, therefore we can and must be more imaginative of the language and its possible outcomes. This is directly related to the algorithm because we can begin to use this prior knowledge when generating a possible algorithm for a computer to activate. All in all I think the ability to single out each respective role, the algorithm role, verses the computer role, and the human verses the computational processes is an important mindset to have when dealing with algorithmic architecture and design.

Andrew Delle Bovi: Asn9 : Knowledge Patterns 1






Manipulating "curvenumber" parameter to achieve varying amounts of curve resolution.
15/25/35 curves on a plane.




manipulating the sketch plane that has the point on it that is related to the surface passing point attributed to it.

0in/100in/200in/400in/500in are the distances moved away from origin plane. Any distance greater than 500in the surface begins to break. 




Here we can see that by manipulating the original sketch (changing the initial boundary that is tied to the surface) will manipulate the curve contouring.  




Finally, we can begin speculate about a symmetrical relationship to attain a closed volume. This will begin to change according to the original relations.



Saturday, March 29, 2014

Andrew Delle Bovi: Asn7 : Flat Form

Base Framework

Establishing Parameters for future use to manipulate the final form.




Final Form and final unfolded surfaces laid out respectively





manipulating initial framework to produce a varying range of solutions

manipulating the height-field parameter to produce additional solutions.



Monday, March 10, 2014

Andrew Delle Bovi: Asn6 : Powerful Replication



Exploring Powercopies!!!!




The adjustable framework, each limb is limited by a length of 1 unit.

A point located in the center of the framework is projected upwards.
A  three-dimensional curved surface is then derived from the point 
and framework perimeter. The Framework intersecting points are then
projected onto the curved surface.

The initial input parameters are four points on the projected surface
and the center point of the total framework.

Here we see the first geometry created to be "powercopied"
onto the existing quadrants of the grid.

Here the relationship between the top and bottom openings and
the base dimensions of the grid is explained. The result is with closer modules
to the center of the grid, also the peek of the curved surface, there will be 
larger top and bottom openings on the module. The farther away the smaller 
the openings become.





These animations show the results as the center point that controls that peek 
height of the surface is manipulated from -1 unit all the way to +1 unit.