SAQIB AZIZ PORTFOLIO
Dipl.-Ing. Saqib Aziz
Portfolio 2019 s.hashimaziz@gmail.com
+49 178 53 73 150
SAQIB AZIZ Curriculum Vitae
Dipl.-Ing.
My name is Saqib and i have Dipl.-Ing. degree in architecture. Currently i am working as a computational and environmental design specialist for HENN Architects. I am also a visting lecturer for 3D complex modelling for universities and design firms with a true passion for research endeavours.
PERSONAL DATA Name
CONTACT Saqib Hashim Aziz
s.hashimaziz@gmail.com
Date of Birth
04.05.1987
+49 178 5373150
Place of Birth
Rawal-Pindi, Pakistan
Nationality
German
WORK EXPERIENCE Since July 2016 Proof of Concept: Automated 3D Daylight Factor simulation -Klinikum Braunschweig SIKA - Concrete 3D Printing Development of digital tools for evaluation, optimization and G-code export for printing
Pop-Up Factory - Installation: A novel human/machine interface for a prospective design and production pipeline MakeCity Festival 2018
Facade Design - Continental AG
Facade Design - Lab Abu Dhabi Automated Climate Report
designupgrade.thinkific.com Linkedin.com/saqibaziz
Computation Skills HENN Architects Berlin Computation and Environmental Design Specialist
Rhinoceros 3D Grasshopper 3D Kangaroo
Schaeffler & Lufthansa- Case Study Data based Workplace Analytics
Ladybug Honeybee Butterfly HAL Karamba
HENN Workplace Analytics Development of a custom digital toolset to evaluate spatial workplace quality. Case Study: Merck, BMW & OSRAM
Octopus Fologram HumanIUI Firefly
Python C#
Design - C³ Cube TU Dreden Pavillion Worldwide first carbon concrete building Facade Design - Váci Budapest
Communication Landscape Installation : Human/Machine Interface and Robotic fabrication Seoul Biennale 2017
Melanchthonstraße 21, 10557 Berlin
Facade Design - Allianz Open City
Unity 3D
Octane Maxwell / V-ray
XFlow/Ansys (CFD)
SOFTWARE SKILLS
Since July 2015
Adobe Creative Cloud StructAR - Mixed Reality intragation for teaching
Photoshop InDesign Illustrator
SheltAir Pavilion - novel elastic gridshell erection method automization of design and production workflow. Video production of project
Premiere After Effects
SketchUp Autodesk AutoCAD MS-Excel
LANGUAGE German
A Bridge Too Far - CITA Complex modelling and structural analysis. Production Animations Beijing World Horticultural Show 2019 -Design and form finding
gmp-Architects Internship
English Sport - und Freizeitbad Potsdam Design and documentation
Urdu
Oct. 2013 - Feb. 2014 Spanish
Creative
2019/2018 semester course Rhinoceros and Grasshopper
2018 semester course Rhinoceros and Grasshopper
2017/2018 semester course Rhinoceros and Grasshopper Digital form finding seminar BA Modul
Sep. 2014 - Oct. 2015 Al Bayt Stadium - Al Khor City Design and documentation
BILD Architecture Melbourne Internship
Residential Housing Project Design and documentation
Self-Employment
PERSONAL SKILLS Analytic
University of Arts Berlin Visiting scientific researcher and complex modelling lecturer. KET Chair - Prof. Dr. Gengnagel
Dedication
Teamwork
Energy
Positivity
Motivation
Promblem Solving
Design Upgrade - Rhinoceros and Grasshopper 3D Online learning Platform Since Dec. 2018 TESSA StartUp - Development Grasshopper Plug-In May - Oct. 2014
Since Jan. 2019 Falconnier Glasbausteine StartUp - Development Design Application Since May 2018 VIRTĂ™ Private Design, renovation and cost planing condominium
WORK TRAVEL
EDUCATION March 2016
Since July 2015
Diploma Thesis Degree: Dipl.-Ing. Arch Titel: Navigating Parameter Space Semi-automated Stadium Design Grade: 1.0 Tutor - KET Chair
Aug. 2011
Prediploma, Grade: 1.8
Oct. 2009
Enrollment architecture studies University of Arts Berlin
MHH Hannover Community Service Psychiatry March 2016
March 2016 IGS Roderbruch, Hannover Degree: Abitur
COMPETITION 1. Price Tudalit 2016 Project: Out Of THe Box
May 2016 Beijing World Hortic. 2019 Bamboo Gridshell
Nov. 2014 Recognition Award AIV Schinkelwettbewerb 2014 SpreebrĂźcke
2012-2014
Oct. 2018 IASS 2016 Tokyo Symposium Paper Title: Alternative Means of Navigating Parameter Space
Sep. 2016
Zurich Seoul Tokio Copenhagen Venice Madrid Paris, Versailles Melbourne Vienna Brussels Washington DC New York
LECTURING Jan. 2019 Sep. 2017
Complex Modelling University Karlsruhe Seoul Biennale Robotic Fabrication
May 2018
IASS 2016 Tokio Digital Crafting
WORKSHOPS May 2016 Recognition Award - Max-Taut-Price Diploma Thesis: Navigating Parameter Space
Aug. 2015 1. Price KPM - ROOM 4 2 Student Competition
Sep. 2018
3D Concrete Printing hosted by SIKA Zurich
July 2018
AEC Hackathon 2018 hosted by TU Berlin
May 2018
Fologram - MR for Rhinoceros 3D. Hosted by UdK Berlin
Feb. 2016
Machine Learning Symposium hosted by CITA Copenhagen
Aug. 2015 4. Price - Solar Decathlon Europe Team Rooftop
RESEARCH PAPER Design Modelling Symposium Abstract Submission 1) Pop-Up Factory Installation 2) HENN Workplace Analytics
2018 2017 2016 2016 2015 2015 2015 2014 2013 2012 2011
LEISURE Jan 2019 RobArch 2018 Paper Title:Communication Landscapes
Sept. 2016 IASS 2016 Tokyo Symposium Paper Title: Immersive Interfacing in Large-Scale Architecture
Pastel, Oil Painting and Digital Art. Brasilian Jiu Jitsu Cross-Fit Electric Guitar Santur, Sitar Diving Reading
Table Of Content
MULTIMEDIA Communication Landscapes P. 8-14
Pop-Up Factory P. 8-14 In this Portfolio multiple QR codes are integrated. Please follow the instructions below to access all multimedia content.
Workplace Analytics P. 26-35 C³ Cube Pavilion P. 36-41 3D Concrete Printing P. 42-47
Created by the Oleksandr Panasovskyi from Noun Project
01. Activate camera
Mash-Lab P. 48-53 SheltAir P. 54-59 A Bridge Too Far P. 60-63
02. Scan QR code
Environmental Design P. 64-77 Self-Employment Samples P. 78-83
03. Open link Beijing Performance Center World Horticultural Show 2019
Diploma Thesis P. 88-99 Selected Student Projects P. 100-125
04. Watch content Ϯϰ
LIST OF COMPUTATIONAL SKILLS WITH INDICATED PROFICIENCY CAD Software: Rhinoceros 6 and the graphical algorithmic editor Grasshopper: Expert level proficiency. Active lecturer teaching complex modelling in Rhinoceros and Grasshopper at the University of Art in Berlin for two years. Publisher of Design Upgrade an online learning platform teaching Rhinoceros and Grasshopper. Detailed list of Plug-In expertise Rhinoceros: Octane (Rendering engine) - Good basic knowledge V-Ray (Rendering engine) - Good basic knowledge Maxwell (Rendering engine) - Good basic knowledge VisualARQ2 (BIM) - Good basic knowledge T-Splines - Good basic knowledge Detailed list of Plug-In expertise Grasshopper: Python Scripting - Expert Level Kangaroo 1/2 - Expert Level Ladybug/ Honeybee (incl. Radiance) - Expert Level Fologram - Expert Level HAL Robotis - Expert Level Human/Human UI - Expert Level Weaverbird - Expert Level Elefront - Expert Level Speckle- Expert Level Skin Designer - Expert Level Lunchbox - Expert Level Pufferfish - Expert Level Impala - Expert Level Hetroptera - Expert Level C# Scripting - Good basic knowledge Hoopsnake / Anemone - Good basic knowledge Firefly (incl. Arduino) - Good basic knowledge Karamba - Good basic knowledge Butterfly (Incl. Open FOAM) - Good basic knowledge Octopus - Good basic knowledge Ped Sim- Good basic knowledge Elk2 - Good basic knowledge Spiderweb- Good basic knowledge BIM Modelling with Autodesk Revit and Dynamo: Good basic knowledge.
Programming:
Good basic knowledge. Detailed list of expertise: Python (Anaconda) - Good basic knowledge C# (Visual Studio) - Good basic knowledge Unity 3D (C# VS) - Basic knowledge
Adobe Create Cloud Suite: Expert level proficiency.
Detailed list of expertise: Photoshop - Expert Level InDesign- Expert Level Illustrator - Expert Level Premiere Pro - Expert Level After Effects - Basic knowledge
CFD Software
Good Basic knowledge Detailed list of expertise: Open FOAM - Good basic knowledge XFlow - Basic knowledge Ansys - Basic knowledge
Microsoft Office
Expert Level proficiency. Detailed list of expertise: Excel - Expert Level Word - Expert Level PowerPoint - Expert Level Outlook - Expert Level
Comm
unicati o Lands n capes
Scan to watch video or Click Me
Live Interaction with Interface
Communication Landscapes Abstract This installation explores robotic fabrication process through real time human machine interaction using natural interfaces. Aiming to contribute to the debate regarding automatization processes described by the industry 4.0, we suggest a future collaborative approach to distributed and participatory design. The installation invites participants to shape a physical object through a robot that interprets the acoustic signal of their voices. The object is then fabricated in near real-time through robotic hotwire cutting. The visitor is gifted with the result of its exploration to take home as a souvenir of a possible future. The negative traces of voices are aggregated through an algorithm in a sculptural wall.
Concept Diagram-Craftsmenship
Form Generation Workflow
Positive and Negative Artifact Distribution
Voice Controlled Interface
or Click Me
On-Demand Robotic Hotwire Cutting
Extracted Voice Parameters for Form Generation
Installation Detail Image
unication Landscapes ent Mapping
0.45
for each voice trace computed to a vector ranging between 0-1
Parameter A
0.45
0.4
0.45
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Placement Concept
0.4 0.45 0.5
Parameter B
Parameter C
earches and places value to the most similar neighbours in a map
nication Landscapes I RobArch 2018 I ETH Zürich Communication Landscapes Seoul Biennale Exhibition 2017
s
Placement Algorithm
Tile with 3 Parameters Lower Range
018 I ETH Zürich
24 Communication Landscapes I RobArch 2018 I ETH Zürich
Tile with 3 Parameters Higher Range
or Click Me
Little Girl Interacting with Installation
or Click Me
Installation Pattern
Robotic Art -Abstract Flow
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POP-U
P FACT Intera O RY ctive M ix ed Rea
lity Ins tallatio
n
Scan to watch video or Click Me
Physical Sculpture
Diagram - Physical Installtion
Holographic Fabrication Station
Diagram-Holographic Installation
Live Vitual Sculpting
Communication Landscapes Abstract This Installtion explores a novel integrated and collaborative approach to design and fabrication enabled by Mixed Reality. To this effect, an interactive workflow has been developed and demonstrated in the creation of a temporary installation. In a bespoke fabrication process, the design is controlled and altered by users in holographic space through a custom holographic interface. The changes in the design are live streamed to the CAD environment. Here a bespoke pipeline translates the aggregation information into robotic machine code. A robot, placed in the same room as the installation, enables on-site/ on-demand fabrication.
Holographic Design Mode
Holographic Voice Modulation Station
Holographic Interface
Holographic Fabrication Station
Robotic Hotwire Cutting
Holographic Assembly Station
Current Practise Linear
Future Practise Realtime
Holographic Assembly Station
Holographic Construction Mode
Holographic Construction Mode
Mixed Reality -Visual Sound
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s c ti y l a n A e c a
l tion p a u k l a r v E o W l and Social Space
atia p S r o o Ind
First Case Study-HENN Office
atial Sociometry stom Applikation - Team Location
73
...
... Visualization
Design
Performing
Programming
Model Shop
Speakers Corner - Workplace Environments
75
Speakers Corner - Workplace Environments
First Case Study-Reach and visibility factor
atial Sociometry stom Applikation - Distance Routes
76
Spatial Sociometry Custom Applikation - Indoor Tracking
Spatial Sociometry Custom Applikation - Personal Interaction and Sight Field
Field of View
Speakers Corner - Workplace Environments
First Case Study-Employee Profil
78
Speakers Corner - Workplace Environments
Visibility-Animation
or Click Me
Connectivity Animation
or Click Me
3-Dimensional Workplace Analytics Comparison
Worplace Analytics Abstract In this work i present a methodology for a comprehensive simulation and visualization process of indoor workplace qualities of large-scale office buildings. The aim is to generate a workflow to investigate social dynamics enabled by spatial qualities and patterns in indoor environments. I investigate how factors such as the overall spatial connectivity of an office space, its visibility and daylight availability interact to create unique characteristics of an office space. I then visualize these findings through various interactive graphical maps. In order to accomplish this i have generated a custom set of digital tools within the CAD software Rhinoceros and its graphical algorithm editor Grasshopper. First the methodology and simulation principles are highlighted and then tested on three case studies. Then i will compare each case study to derive at overriding principles of spatial and social workplace qualities for the assessed office spaces. Further i will generate an architectural usage profile, that i refer to as the Multi-Variable Map of the evaluated office buildings based on the previously illustrated findings.
3D Spatial Connectivity
3D Spatial Daylight Factor
3D Spatial Visibility
3 Category Multi Variable Map
7 Category Multi Variable Map
Experiential Analysis
or Click Me
Scharffler-Case Study-Escape potential
Main gates utilization
or Click Me
Distance heat map
Accessibility
or Click Me
Logistic routes
Collision Potential
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3D Concrete Printing Sika has developed a large scale 3D concrete printing process over the last years and reached out to HENN to think of possible collaboration opportunities. After visiting the 3D printing site and further discussions with the Sika-team we realized that they where having some troubles with the generation of the respective G-Code for any digital geometry. We agreed to first develope a application in Rhinoceros and Grasshopper that enbales the evaluation, optimization and translation of any geometry into the required G-Code format. Here i present the non confidential initial steps of the Plug-In developement aswell as some initial form studies. In the second phase we are moveing on to large scale architectural forms and also investigate mass-customizable prefabrication and assembly on site.
Receive and slice geometry
Check and optimize curvature domain
Check and optimize overhang domain
Generate continuous print path
Generate G-Code
Branching structure
or Click Me
Case Study-Layer width
Case Study - Full Branching
Modul 02 - Seminar Assignment Modul 02 - Seminar Assignment Case Study Generative Structural Optimization
Generative Structural Optimization
ilipede
Iteration 10 Modul 02 - Seminar Assignment
Iteration 20
Iteration 30
Generative Structural Optimization
Iteration 50
- Print path efficiency Currently on going project
Modul 02 - Seminar Assignment Postprocessing Optimization Output
Iteration 80
Iteration 0
Milipede
Milipede
Ameba
Iteration 0
Iteration 10
Iteration 20
Modul 02 - Seminar Assignment Generative Structural Optimization Iteration 20
Iteration 10
Iteration 30
Iteration 50
Iteration 80
Milipede Iteration 50
Iteration 80
twerfen splanung - Universität der Künste Berlin
KET
13
Ameba
Ameba ragwerksplanung - Modul 02 - Konstruktives Entwerfen achgebiet für Konstruktives Entwerfen und Tragwerksplanung - Universität der Künste Berlin
Tragwerksplanung - Modul 02 - Konstruktives Entwerfen Fachgebiet für Konstruktives Entwerfen und Tragwerksplanung - Universität der Künste Berlin
Milipede
14
Case Study -Prefab
2 - Seminar Assignment
Modul 02 - Seminar Assignment
Modul 02 -Modul Seminar Assignment 02 - Seminar Assignment
ing for 3D Printing
3D Printed Geometry Modul 02 - Seminar Assignment
of additional structural and MEP elements + + Pour Integration ofIntegration additional structural and MEP elements PourConcrete Concrete
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3D Printed Geometry
Iteration 30
Iteration 50
Iteration 80
KET
Tragwerksplanung - Modul 02 - Konstruktives EntwerfenTragwerksplanung - Modul 02 - Konstruktives Entwerfen Ameba Fachgebiet für Konstruktives Entwerfen und TragwerksplanungFachgebiet - Universität Künste Berlin 12der Künste Berlin für der Konstruktives Entwerfen und Tragwerksplanung - Universität
Tragwerksplanung - Modul 02 - Konstruktives Entwerfen Fachgebiet für Konstruktives Entwerfen und Tragwerksplanung - Universität der Künste Berlin
Tragwerksplanung - Modul 02 - Konstruktives Entwerfen achgebiet für Konstruktives Entwerfen und Tragwerksplanung - Universität der Künste Berlin
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- Seminar Assignment
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KET 13
Tragwerksplanung - Modul 02 - Konstruktives Entwerfen Fachgebiet für Konstruktives Entwerfen und Tragwerksplanung - Universität der Künste Berlin
Tragwerksplanung - Modul 02 - Konstruktives Entwerfen Fachgebiet für Konstruktives 16 Entwerfen und Tragwerksplanung - Universität der Künste Berlin
Tragwerksplanung - Modul 02 - Konstruktives Entwerfen Fachgebiet für Konstruktives Entwerfen und Tragwerksplanung - Universität der Künste Berlin
17
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Tragwerksplanung - Modul 02 - Konstruktives Entwerfen Fachgebiet für Konstruktives 17 Entwerfen und Tragwerksplanung - Universität der Künste Berlin
Case Study - Prefab Large-Scale
b a L h Mas Abu Dhabi
tory in a r o b a L ign of s e D t p Conce
Exterior Rendering
Concept Diagram Facade
+ pattern
Perspective Section
+ solar management
sustainable operation
Environmental facade studies ANNUAL RADIATION Avarage 442 KW/m²
ANNUAL RADIATION Avarage 442 KW/m² ANNUAL RADIATION Avarage 442 KW/m²
North Facade
North Facade
North Facade
South Facade
South Facade
0 20
100
200
300
400
500
600
700
800
KW/m²
0 200
900 100
100
South Facade
200
300
400
500
600
700
800
900 0 1000
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Facade Concept
3
I Changchun High-Tech City I Climate Analysis | 06.09.16
Conceptual references Architectural Design Facade Concept
Mathematical Pattern - Girih Tiles Inspired by the rich heritage of geometric patterns in the Islamic culture, the core of the facade design utilizes the Girih Tiles to generate a parametric designed methodology. The Girih tiles are a set of five tiles that can generate a infinite number of diverse and intricate patterns. The five different tiles consist of basic geometric shapes. The actual Girih lines or strapwork are additional and unique decorations for each of the shapes and can be executed Traditional Privacy Screen Contemporary Adaptation in a variety of methods.
Traditional Sunshading
Contemporary Adaptation
Core Pattern used for the facade design. Iterative expansion then polar arrayed The Mashrabiya was traditionally used to The apparently intricate pattern is comsecure undesired views into the living area. posed of a small numbers of repeating In order to achieve this, intricate geometric elements a rational and ecopatterned screensfacilitating were crafted and nomical production. mounted upon the facade openings. These principles are here adopted to secure the high demand for privacy in the laboratories.
Seljuk Mama Hatun Mausoleaum,
DECAGON
HEXAGON
Turkey (about AD 1200)
118
PENTAGON
BOW-TIE
The Mashrabiya also acts as a sunshading device that reduces the exposure to solar radiation. The overall porosity of the facade is determined by a parametric approach, which takes in to account environmental factors and privacy requirements given by the program distribution resulting in a smooth modification of the facade geometry.
RHOMBUS 117
20
KW/m²
3 I Changchun High-Tech City I Climate Analysis | 06.09.16
Architectural Design 3 I Changchun High-Tech City I Climate Analysis | 06.09.16
100
HAAD Health Authority Abu Dhabi | BSL 4 Laboratory Abu Dhabi, UAE | Feasibility Study March 2017
HAAD Health Authority Abu Dhabi | BSL 4 Laboratory Abu Dhabi, UAE | Feasibility Study March 2017
Conceptual Facade Diagram Dissolved Pattern
Organic Pattern
Mathematical Pattern
Interior Rendering
Climatic Facade
R I A t l She avilion
F
hell P s d i r g c elasti d e t a m o ully aut
Scan to watch video or Click Me
Concept Rendering-SheltAir for troubled Regions Fully automated design and fabrication workflow for pneumatic inflated gridshell structures.
Concept Rendering-SheltAir Interior Option
3D Scan + Inflation Animation
or Click Me
Inflation
or Click Me
Erection Analysis-Bending moments
Erection Analysis-Reactions
Automated Fabrication Data-Fiberglass rods
or Click Me
Automated Fabrication Data-Ring beam
Automated Fabrication Data-Membrane
Assembly Detail-Flassfiber rods
Production Detail - Edge beam
Erection Detail-Membrane inflation
A Brid
ge Too R obotic
Far
Fabric ation o
f Steel
Plated
bridge
Scan to watch video or Click Me
Automated Fabrication Data-Membrane
Automated Fabrication Data-Membrane
Geometry Optimization
or Click Me
Structural Analysis
or Click Me
t s e p a d u B i c
Vaonmental Analysis ir
Env d n a n g i Des
Microclimate HOW - ENVIRONMENTAL STRATEGY Urban microclimates
or Click Me
Winter - Low potential
Air temperature
Humidity
Sun radiation
Wind
Let the sun shine in
protect from cold winds
CFD Analysis 56
BUDAPEST CENTRAL BUSSINESS DISTRICT | 18.10.2017 | Budapest 2020
or Click Me
Q H t r a w g r Bo nmental Analysis iro
D Facade
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and
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R2B Europacity
Smart Facades, Munich, 17.06.2016
Facade Ventilation Analysis
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Des Facade
ig
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CFD Analysis for Facade Desing Length of Blades
Length of Blades
Length of Blades
130 mm
90 mm
50 mm
Other Variations
Number of Blades 1 x 50 cm
A1
A2
A3
B1.3cm
B1
B2
B3
Z1
C1
C2
C3
Z2
Number of Blades 2 x 50 cm
Number of Blades 3 x 50 cm
or Click Me
D B C n u h c g n nalysis
Csighn aand Environmental A
De Facade
Solar Envelope
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Useful Daylight Illuminance (UDI)
UDI Based Facade Optimzation
Solar Radiation on Facade
LIDL C
ampu
Autom
ated D e
s
sign an
d Anal
ysis W o
rkflow
Automated Design Inputs
Automated Design Process
Automated Design Process
Automated Design Process
Automated Design Analysis
Environmental Design
Automated DIN 5034-1 Simulation For a commissioned building we had to prove that the office spaces are getting enough natural daylight according to the DIN 5034-1. Usually the simulation is generated for a worst case scenario. We defined a alogorithmic workflow allowing to evalute the entire building and even allow for interactive optimization processes.
Perspective
Radiance Simualtion Set-Up
Worst Location Evaluation
Automated Spatial Evaluation
Interactive Design Optimization
Automated EPW File based Climate Report Given the limited time during a competition phase we wanted to automate the process of harvesting Energy Plus Weather (EPW) files to generate a customized climate report for any needed location. We scripted a process in Rhinoceros and Grasshopper in such a way that a colleague just needs to provide a EPW file and will receive a fully automated climate report. Next you will see some sample pages of one of those reports.
Temperature-Sky Cover-Precipitation
Radiation-Sun Path
Solar Gain
Wind
Microclimate
TESSA - Grasshopper Plug-In Extension TESSA is a Rhino and Grashhopper Plug-In that tesselates any geometry into identical panels. The extension features a larger set of tesselation pattern and also allows to generate block instances for further modelling and detailing.
n I g u l P A S TES hino Grasshopper
are for w f o s n o Tesselati
R
Tesselated Grid Examples
Customized Mapped Block Geometry
Falcon nier Authe
ntique
Start-Up Falconnier-CT -Scan
Start-Up Falconnier- Concept Application
3D-CT-Labormuster
Die technische Untersuchung mit der an der TU verfßgbaren Mikro-Computertomografie dient nicht nur der Erfassung der Form der seltenen, sensibelen Originale, deren Makel wir im zu generierenden 3D-Modell ausbessern und standardisieren kÜnnen, sondern auch der Messung der Wandstärken, die op-
Design Upgrade Design Upgrade is online learning platform i lunched January 2019 and is dedicated towards Rhinoceros and Grashopper 3D online courses. Based on my teaching at the university it offers in-depth training in 3D modelling.
Designupgrade.thinkific.com
Youtube Channel- Design Upgrade
Navigating Parameter Spaces
Digital Strategies for the Discipline of Stadium Design Diploma Thesis
Architectural workflows are continuously evolving. New technologies are affecting construction, while novel digital design methods are becoming part of the architect‘s everyday work. Our contribution to the ongoing controversial discussion on computational design is a workflow proposal for the discipline of stadium design, based on a series of studies on digital methods. The proposed strategies all follow the same goal of supporting architects in their most central task: decision-making. This work was presented in the form of an interactive installation. Stadium design as a case study gave us the opportunity to develop methods for two vastly different building parts: the so-called „bowl“ refers to the viewer stands and is largely the result of a functional, numeric optimization process, while the „hull“, i.e. the roof and facade, requires a different approach due to its varying function and construction as well as a higher creative freedom in the design process.
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Navigating Parameter Spaces Software Design Digital Tools
The functional and numeric design criteria for the Bowl given by the FIFA, enabled the design of a comprehensive programmed digital Tool called BowlBuilder., which can be used in Grasshopper.
The HullBuilder is a extension to the Bowlbuilder and constructs a adjusted Hull geometry, with various other features, in respect to the constructed Bowl.
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Navigating Parameter Spaces Software Design Parameter Space
Generating digital models of various stadiums for further comparison of typological resemblance and further the comparison of the digital definitions generating the models.
Alternative digital workflow, called Modifier. One definition is generated to preduce a variety of output geometries.
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Navigating Parameter Spaces Software Design Parameter Space
Generative design processes are characterized by modifications of a design model‘s parameters with the aim of improving its characteristics. The entirety of possible parameter combinations in a given design scenario is referred to as parameter space, in which each parameter represents a dimension. The efficacy of a design process could be measured by the quality of the final design found in the vastness of a multidimensional parameter space, as well as by the time needed to arrive at this solution.
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David Raups investigation of the evolutionary modification Generating digital models of various stadiums for further of shell geometries., visualised comparison of typological resemblance and further the comparison in a Parameter of Space. the digital definitions generating the models. Implementation of the Parameter Space for the digital programmed Modifier.
Alternative digital workflow, called Modifier. One definition is generated to preduce a variety of output geometries.
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Navigating Parameter Spaces Software Design Numeric and Subjective Evaluation
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Programmed digital Evaluationtools
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Navigating Parameter Spaces Software Design Numeric and Subjective Evaluation
Subjective verification of numeric evaluation through Virtual Reality interface.
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Navigating Parameter Spaces Software Design Interaktive Selection
in order to harness the full potential of the parameterized modeling paradigm, the workflow advocates the need to efficiently visualize parameter spaces for better comparability of design variations. The design of the „hull“ allows for great diversity during the design process. Rather than trying to create a hard-coded tool to accomodate these endless possibilities, we suggested a more top-level approach in which an initial geometry is successively modified by new algorithms generated as needed by the architect. At each step of the design process, the existing geometry is modified by three parameters and the possible outcomes respresented as a 3-dimensional matrix of variations to choose from.
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Navigating Parameter Spaces Interaktive Selection Applikation
Design is characterized by testing various paths of inquiry and upon hitting dead ends, back-pedaling in one’s decision chain to pursue new paths. Hence, the workflow promotes documenting the iterative design cycle in family tree logic, giving the designers an overview of multiple decision chains and enabling them to retrogress from dead-ends in the design process or make upstream modifications that automatically propagate downstream.
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Navigating Parameter Spaces Interaktive Selection Applikation
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Navigating Parameter Spaces Family Tree Design Archive
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Navigating Parameter Spaces SELF-ORGANIZED FITNESS LANDSCAPES
The SOM is a machine learning algorithm used to reduce n-dimensionality to two-dimensionality. Since bowl design is constituted by a collection of interdependent parameters, we used the SOM to generate planar fields of multi-dimensional design instances. This makes it easy to identify areas of the parameter space that best fulfill aesthetic criteria. In order to overlay this representation with numeric performance feedback, we combined the SOM concept with that of the so-called fitness landscape.
Using our analytical tools from „BowlBuilder“, each design variation in the map is evaluated for specific numeric criteria and assigned a height in the map accordingly. If the designer considers a variation that seems architecturally valuable but inefficient numerically, the designer can simply „climb“ the nearest hill to achieve better performance through small alterations.
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Out Of The Box Leben unter einer Betonschale
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Arbeitsraum
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Wohnbereich
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WC
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Kinderzimmer
Arbeitsraum Schlafzimmer
Freizeit Sitzlandschaft
Arbeitsraum
6,00 6.05
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Schlafzimmer WC
Begehbarer Kleiderschrank WC
Grundriss EG M 1/200 12,00
UmlaufendeTerrasse
Grundriss OG M 1/200
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Herstellung Die Herstellung der doppelt gekrümmten Dachschale erfolgt mit Hilfe eines neuartigen Schalungskonzepts: Die Betonage (3) erfolgt auf einem zweischichtigem Kunststoffkern (2), welcher sich aus einer wärmedämmenden Schicht und einem Gegenstück zusammensetzt. Die Dämmung ist aus einem druckfesten Material (z.B. Polystyrol) gefräst und wird durch die Betonage dauerhaft mit der Schale verbunden. Das Gegenstück leitet die Lasten aus dem Bauzustand auf ein konventionelles Schalungssystem (1) weiter. Es sind aufgrund geringer Anforderungen verschiedene Materialien möglich.
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Textilbetonschale aus hochfesten Beton und Carbonbewehrung, Dicke d = 5 - 20 cm, C 40/50 Glasfassade als umlaufernde PfostenRiegel - Konstruktion, sowie begehbares Deck mit Außen- und Innenfläche; Erschließung über zwei Treppen Fassadenplatten aus Textilbeton mit doppelt gekrümmter Regelflächengeometrie, Dicke d = 2,5 cm Erdgeschoss mit Raumboxen in HolzLeichtbauweise mit einem zusätzlichen StahlGlaszylinder als Schalenlager
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18 Saqib Aziz, Jakob Grave - 8. Architekturwettbewerb TUDALIT 2016
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BER16 Die doppelt gekrümmte Textilbetonschale umhüllt einen offenen Wohnraum, der sich aus geradkantigen Volumina (‚Boxen‘) und Freiflächen zusammensetzt. Es entsteht eine neuartige Wohnform mit zahlreichen Vorteilen.
Architektur
Die tragenden Konstruktionsteile sind auf die Peripherie begrenzt und schaffen so eine maximale Grundrissflexibilität. Der Nutzer kann daher leicht auf veränderte Wohnsituationen reagieren. Die Kombination aus außenliegender Textilbetonschale und innenliegenden Boxen erzeugt ein Raumgefüge ohne eindeutig fixierte Grenzen zwischen dem ‚Außen‘ und ‚Innen‘. Dennoch bieten die Boxen Raum für ausschließlich private Nutzung (Schlafen, Arbeiten) von der sich halböffentliche Flächen (Wohnen, Essen) abgrenzen.
Schematischer Schnitt
‚Out of the Box‘ denken , heißt neue Wege gehen ...
Struktur
Die Form ist mittels digitalem Hängemodell gefunden und unterliegt damit den natürlichen Gesetzen der Schwerkraft. Durch die gezielte Anpassung von Formfindungsparametern entstehen interessante Bauelemente wie beispielsweise ein kreisförmiges Schalenlager. Bewusst spielt der architektonische Ausdruck mit dem Kontrast zwischen der organischen, fließenden Schalenform und der eckigen Kubatur im Inneren, deren Unterschiedlichkeit sich nicht nur in der Formgebung, sondern auch im Material und der Farbigkeit widerspiegelt. Formensprache und Nutzungskonzept stehen so im Einklang.
Konstruktion
Als umgekehrte Hängeform erfolgt der Lastabtrag im Eigengewichtszustand lediglich über Drucknormalkräfte. Ungleichmäßige Lasten aus Wind und Schnee erzeugen in der Schale Biegezugkräfte, für die eine Carbonbewehrung bemessen wird. Die Form ist für den Eigengewichtszustand optimiert, was den Materialeinsatz von Beton und Carbonbewehrung minimiert.
Digitale Formfindung mittels umgekehrtem Hängemodell und anschließender Zenitöffnung und Randausbildung
Sieben Bauelemente bereichen die Gestaltung und das Wohnkonzept
Schalenlager
Statisches System
Raumboxen
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Schalenecke
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Beijing Performance Center World Horticultural Show 2019
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Beijing Performance Center World Horticultural Show 2019 Structural and architectural Proposal
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Beijing Performance Center World Horticultural Show 2019 Architectural concept
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Beijing Performance Center World Horticultural Show 2019 Parametric digital design chain
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Beijing Performance Center World Horticultural Show 2019 Technical innovations
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Beijing Performance Center World Horticultural Show 2019 3D-Printed Connections Mock-Ups
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Beijing Performance Center World Horticultural Show 2019 Interior Views
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Internship gmp-Architects
Al-Bayt Stadium - Al-Khor City, FIFA WM 2022 Qatar 3D-Modeling / Construction Documentation
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Internship gmp-Architects
Sport- und Freizeitbad Potsdam 3D-Modeling / Construction Documentation
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KPM Competition
To Be A Student In Berlin Room 4 2
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AIV Schinkelwettbewerb 2014 Neue SpreebrĂźcke
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Solar Decathlon Europe 2014 Team Rooftop
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Muse 04 - Pastel on black paper
Muse 04 - Pastel on black paper