General / Part 1 of 2

Set Completed / Construction On Going

Hengqin Hospitals Zhu Hai, China

Payette Associates Boston, USA

Design/Model/Visualization/Set Drawing

NATURE

The project’s strong emphasis on nature takes advantage of the environment and climate, creating a harmonious environment in which to perform highlevel healthcare.

The building heavily incorporated inside and outside relationships, with landscape elements visible throughout.

Hospital

Campus

Subtropical climate

A general hospital flanked by five specialist hospitals. The campus encompasses a central garden bisected by a storm water channel. Nature is included to create a comfortable healthcare experience for patients and staff.

CONGLOMERATE

The main hospital houses both in and out patient facilities while the 5 specialty hospitals around it houses 5 different specialised healthcare modalities owned by different owners. Concept derived from Chinese characters, the elements join together to form a campus. Creating efficiency and harmony for patients and staff alike.

ADVANCE DESIGN

The campus features biomimicry design using computational techniques. Providing a natural experience for the user while enhancing utility with generating and analyzing geometric data

PODIUM AND RIBBONS

The podium’s edges accentuate the dynamic form and extend the curvilinear language found in the plan to the user’s experience, unifying the campus between the General Hospital and surrounding Specialty Hospitals.

COMPUTATION TO PRODUCTION

All geometries are computationally generated in Grasshopper using a periodic function; the periodic character of the function permits the division of repeating modules that can be stacked in offset orders to produce a dynamic form that does not appear repetitive. This decreases construction difficulties and cost without sacrificing aesthetics. The only identifiable components are the corner pieces, which are automatically isolated for tabulation.

FABRICATION PRODUCTION

The ribbons are comprised of GFRC modular components that produce a dynamic geometry with repeating modules, minimising one off elements to maintain production costs.

横琴医院

ARCH-E-GENERAL HOSPITAL - LEVEL 1

COMPUTATIONALLY GENERATED

A custom script in Grasshopper is written to computationally generate the whole canopy, including support columns, connecting bolts, and glass penalization, with only two curves passed as input as its guiding curves.

SHADOW

Utilizing the subtropical environment with a high sun angle, the canopy creates an interactive experience with the user by casting a parallax shadow pattern as the user travels along it.

DATA TO PRODUCTION

The computation of the over 1,500 modules incorporates solar analysis to create a cloud-like effect that reduces the building’s mass and provides shading. This provides the user with optimal sunshine and temperature conditions.

A stepper algorithm rationalizes the variable dimensions to limit the number of distinct production to 12, which we found to be required to generate a dynamic aesthetic.

Health Care Project USA

Payette Associates USA

Design/Model/Facade/Structure

Lead Megan van der Linde, Senior Associate, Payette Associates

Shuan Morris, Associate, Payette Associates

COMPUTATIONAL BRICK FACADE

Computationally generated in GH, more than 100,000 bricks are individually mapped using the two available brick colours to create a gradient blend. Drawings generated to instruct masons.

GROUNDED TERRAFORM

The organic-shaped lobby entrance roots the structure, lending it an earthly feel Penalized to optimize CNC milling process from cubic stock

SKYLIGHT

The top floor acts as a large open floor-plan that houses a communal light weight maker space. Tetrahedral skylights pops up from the sloped roof towards the north to collect sunlight while minimizing heat gain

CEILING PATTERN

Dropped Ceiling provides space for MEP and Lighting. Patterned lighting accentuates the overall openness of the space and the geometry of the origami ceiling

Design Tool: Project Data Dashboards and Massing Tools

By conducting 10+ real estate development feasibility analyses and pre-offer due diligence, including development rights, zoning by-law policy research, and massing study, I was able to construct algorithms and scripts using Python, C#, and GH to automate and streamline the initial design process.

This includes continuing the creation of the Data Dashboard using Power BI and Excel form data collected from Rhino3D geometry generated with C#, as well as the construction of a second real-time dashboard that gives design-oriented feedback in Rhino GH.

Mass stacking tools produce and input massing bays with minimal input, hence improving workflow productivity.

In addition, I worked on and refined internal C# scripts that generate building components from massing modules, such as balcony structures.

Overall by streamlining production processes and implementation of computational tools productivity for project acquisition work quadrupled.

Plumbing

Plumbing swiftly iterate It generates when designing loop to the to hours.

https://www.linkedin.com/posts/ic-intelligent-city_digitaltechnologyhousingsolutions-design-activity-6895076859080515584-WZAq

**Actualworkconsistofproprietarymaterial, Allimagesshownherearetakenfrompublicposts

Plumbing Design Visualization Tool

Plumbing layout tool in Rhino Grasshopper is used to iterate through and visualise plumbing layout design. generates real-time visualisation and collision detection designing layouts, giving an immediate feedback the designer that reduces project times from days hours.

Online VR experience

Created an interactive virtual reality (VR) experience that allows the user to travel and interact with the building using stereoscopic images that provide 3D immersion in the Meta Quest 2 along with a web-based version. The experience was utilised as a primary marketing tool.

https://www.linkedin.com/posts/ic-intelligent-city_digitaltechnologyhousingsolutions-design-activity-6895076859080515584-WZAq

Exhibition Berlin

UNStudio Amsterdam

Design/ Research/ Administration/ Construction

TEAM Ren Yee Head of Innovation Strategy and Forecasting, UNStudio

Yoonjin Kim GSD

Marisa Cortright Business Development Officer, UNStudio

For UNStudio’s award for Architect of the year from A&W Magazine Research on the future of office and living design. When automation take over jobs, the future turn our focus back onto human faculties

REFLECTION

Reflective motifs and all mural lets the user look back at themselves and other people around them, to reflect upon the human faculties

Broken Bridges Hong Kong

First Prize, Awarded To be built

University of Hong Kong Hong Kong

Design/Model/Set Drawing

Team Gao Yan, Assistant Professor, HKU Vagina Goh

Huang Wen-ying

Museum

LAAB Architects|Art

Hong Kong

Digital Craft/ Design/ Construction/ Fabrication

Clients include Hermes, Hong Kong Arts centre, Fringe Club

M+ Museum

DIGITAL TO CRAFT PRODUCTION

Computational design is used in the creation and building of art works, storefronts, and interior design. Digital fabrication techniques like CNC milling, laser cutting, and 3D printing are used on a daily basis. By combining digital and manual construction processes with in-house construction trades we are able to create bespoke work for high profile clients. Projects are created with Rhino3D and Grasshopper

Enter the Boid Academic

Team Jiho Song

Kally Wu

A virtual reality experience built in Unity that puts you in the role of a flocking member of the well-known Boids programme and features surrealistic aesthetics.

Object, 2013

Computational Design, Digital prototyping, digital design to production of the Butterfly Bracelet and Coral Light Pendent for LAAB Architect’s studio showcase.

Hospitality Project

Buro Ole Scheeren Beijing

Design/Model/Facade/Structure

Lead Dan Cheong Partner, Buro Ole Scheeren

NATURAL A high profile Exploration a natural formal Form and programme unconventional Structural model

FORMS

profile hospitality project of design of lobby and architecture shell/ various elements with formal language to create a welcoming and wonderful experience. programme must coordinate with structural strategy due to unconventional shape.

model generated in Grasshopper according to engineers drawings

Rhino Voice Control Program

Program in

To conduct modelling operations in Rhino 3D, the user must be actively engaged with a mouse and able to type commands into the command line box. This forces the user to awkwardly choose between typing efficiently by releasing the mouse or typing with one hand. This also contributes to bad ergonomics.

Therefore, if it were possible to eliminate typing and instead input via speech, the user would be able to model using only one hand.

Specific Rhino instructions, such as “DupSrf”, will not be recognised by existing speechto-text systems meant for conventional, everyday language. Therefore, a bespoke tool is required.

With C# in Visual Studios, the tool uses Microsoft’s native text to System.Speech. Recognition namescape, but common terminology and substitutes it with Rhino Commands. The application also performs Rhino-optimized macros, such as entering “return,” “space,” and numbers at required places.

The user interface is a Windows form; users can turn the application on and off and check the history of recognised instructions. When activated, Always On Top can be enabled for the programme.

Revit Import to Rhino

Tool for Rhino made in Python

Clean blocks exported from Revit to Rhino for significant increase of edibility

Projects exported from Revit comes with disorganised block structure and exploding discrete mesh.

This Python-based application will clean up the blocks, combine all mesh, and relocate them to the correct layer based on the object’s characteristics, making them significantly more editable and manageable.

The tool iterates through the Rhino block tables and the geometry table and evaluates the underlying mesh to operate on the blocks accordingly.

Typically, this will be fully skipped due to the impractical amount of time required. Instead, one will reduce the number of modifications and merely clean up the areas where they arise. However, this drastically restricts work since every move will require preperation. With this tool, the model is fully prepared to be used in seconds.

Shrink Wrap My Car

Digital production tool for 3D Print, creates approximate mesh from segregated or dirty models

1.

Model obtained from third party with complex noncontiguous volume. This cannot be 3D printed without labour intensive rebuilding process, taking hours or days

2.

Using custom mesh shrink wrapper tool to ensure topological contagious volume. Mesh points searches for collision until overlaying itself with third-party mesh

3.

Resulting topological contagious volume that can be 3D printed immediately. Reducing rebuilding time by 2 orders of magnitude

This method retains good level of detail enough for scaled model

Auto Layer Render

Full Rhino Plugin in Python. Automates render images of multiple scenes, by iterating through selected design options with selected fixed elements

User Interphase

A custom command is added to the Rhino 3D command line once the plugin has been installed in order to invoke the script.

The user install the plugin by Rhino3D’s suggested .rhi package. A new custom command will then be made available to the user.

A very challenging and important aspect is how the user can intuitively pick which elements to iterate and which to stay fixed. I have chosen to use the native layer locking/unlocking system because it should already be familiar to modelers. The state of the Master layer should also be considered when encountering sublayers. Where View(s) will be selected with a popup.

A Repository Folder will be created with the Windows OS API at the same folder as the 3DM file to collect the renders. The files will be titled based on the layer names.

Multiple renders with multiple layer setups and multiple views that previously required hours to manually configure can now be generated in seconds.

Redevelopment of social housing. Incorporation of Cultural Hub to help local resident move towards better financial standing

New Co-op housing for sustainable affordability for housing

Health /Housing New York

Academic

Distinction

Harvard GSD

Harvard GSD

TEAM Yoonjin Kim

Instructor Ben van Berkel, Founder, UNStudio

Christian Vedeller, Director, UNStudio

INTERACTIVE

App and web-page design so that the community can interact with the progress d developmet

PHASING

Step by step intervention facilitated by technology. From a physically and economically insulated community, towards a network and active participant of the city

COMPONENTS

Interventions for the community

Creates a cohesive interventions that allows the resident to procedurally introduce new elements for sustainable improvement

TOWER

Framework Design of co-op tower. Metabolic growth of amenities and communities. Units located on sides for view and health. Large common central core.

Sun Light Pavilion Research

Lead Dr Olivier Ottevaere, Faculty, HKU

Using solar analysis to perform formal folding, this pavilion explores the relationship between geomteric form and solar characteristics. Made using Rhino GH