Thilina Herath - Full Portfolio - 2024

THILINA HERATH

Resume & Portfolio

2024

Hello. I am Thil.

I am an Architectural Studies graduate from Carleton University and a Master of Biomedical Innovation cadidate at McMaster University. I am deeply thankful for your time to view my work.

As technology continues to evolve so does our vision of the future. Nonetheless, nature still has us beat at just about every corner. I am passionate in taking inspiration from what has already been and wish to see it merge elegantly with what we create. Many solutions to existing problems can be found in pairing distant technologies. This is why I always seek to have a wide range of disciplines and interests and continue to broaden my skills.

I believe that thoughtful designs can resolve pressing local and global issues by embracing emergent technologies.

Thilina Herath

herathtp@mcmaster.ca (289) 795 -7942

Issuu // YouTube

SEPT 2024AUG 2025

2022-2023

EDUCATION

Master of Biomedical Innovation

McMaster University, Hamilton ON

٠ will not conflict with work

Machine Learning Specialization

Deeplearning.AI, Coursera

Mathematics for Machine Learning Specialization

Imperial College of London, Coursera

2020

Bachelor of Architectural Studies

Carleton University, Ottawa ON

٠ Admission Scholarship

٠ Dean's List (2017-2018)

EXPERIENCE

SEPT 2021JUL 2022

JUL-AUG 2021

R.V. Anderson - North York, ON

Student Engineer

٠ CAD design and revision for municipal water

٠ Geotechnical and worksite report review

٠ Site visit and survey

٠ Record maintenance and city correspondence

Randstad - CertainTeed, Oakville, ON

Machine Operator

٠ Operated and troubleshooted production machines

٠ Maintenance for production line

SKILLS

Software

٠ Microstation

٠ Adobe Suite

٠ Revit

٠ AutoCAD

٠ Rhino + Vray

٠ Fusion360

٠ SketchUP

٠ Unreal Engine 5

Fabrication

٠ Hand Drafting

٠ Physical Modelling

٠ 3D Printing

٠ Laser Cutting

٠ Woodworking

٠ Metalworking

٠ CNC Milling

٠ Photogrammetry

Programming

٠ Python

٠ C/C++

٠ Machine Learning Interests

٠ Swimming

٠ Gardening

EMG Forearm

CNN Multiclass Classification & Prosthetic

Celestial Journey

Prosthetic to Transhuman Analysis

Bari[UP]ti

Urban Mixed-Use Development

Centre de la Terre

Suburban Research and Tourism

High-Tech Park Bridge Model

Physical Modelling

EMG Forearm

Using OpenBCI's Cyton board with IDUN Technologies' Dyrodes, I prepared a setup to gather EMG data from my forearm in four positions. In VSCode, I used the Brainflow library to stream data from the device and process the signal. With the Tensorflow and TSFEL libraries, I built and trained a convolutional neural network to recognize the four trained positions when data was streamed live.

Electrode Placements

A total of 6 channels on the board were used, with pairs of electrodes for each plus a reference electrode

Trained Positions

Four positions were trained in the CNN: relaxed, clenched, wrist extension and wrist flexion

Prosthetics to Humanoid Robotics

Evidently, these pages show a work in progress. The images show an unfinished model of the assembled prosthetic which is not much to look at yet but I decided to include anyway.

The design involved 3D-printed bones with 40% cubic infill balancing strength, weight and printing time. These were joined by 4-way stretch fabric replicating ligaments. Actuators would be McKibben's pneumatic muscles in varying diameters. Latex balloons will be used for their bladders with nylon braided sleeving as the contracting sheath. Pneumatic connections shall be polyvinyl tubing and channels within the bones.

Due to a decision to pivot to humanoid robotics, I am currently doing a redesign into a fully electric prototype. This is due to a need for precise control which pneumatics do not provide but was tolerable for the prosthetic. Dexterity will remain the primary focus.

Materials and Model Materials for making and powering the artificial muscles are shown above the 3d-printed bones

PROFESSOR: JOHAN VOORDUOW

WINTER 2020

Celestial Journey

Technology has and will continue to broaden our horizons. Still, nature’s greatest mysteries remain hidden and are waiting to be discovered. I truly believe that all our most pressing global issues can be resolved by embracing technology but only if we appreciate and respect the natural world that has brought us this far. I have faith that future advancements can both solve existing problems and further evolve our species.

The degeneration of the human form into an unmoderated digital nightmare.

Anatomical Study

Handmade wood model to develop understanding of body mechanics to produce a prosthetic that can be quickly acclimated to.

above left. Paleolithic Tool Progression

Evolution of hafting techniques and tool advancements

above right. Electroencephalography

EEG technology can provide synthesis between the brain and state of the art prosthetics.

The transition for humanity into the future

The Evolution of Prosthetics

DO WE BECOME WHAT WE DO, OR DO WHAT WE ARE?

Technological advancement has driven our adaptive nature, subsequently allowing us to adapt nature to our means and desires. Analyzing this progression from archaeological discoveries into modern innovations, the trend appears: technology approaches closer to us until inevitably manifesting within us. I have collected prosthetic hands, portraying how technology attempts to close the gap, replacing the natural. We must acknowledge that nature still remains well beyond our comprehension and before altering our implicit memory forged by it, we must fully appreciate its value.

I began by examining prosthetic arms and observed their technological progression. Initially, functionality replicates the natural form. Having produced an acceptable replacement, newer designs pursue ornateness while retaining the same performance. Some later designs even seek to minimalize the arm to is simplest function, an appendage for gripping. As prosthetics shift to modern technologies and manufacturing, it is interesting to note how their mechanics have advanced. At the moment, all the designs which mimic the human arm fail

to deliver the same range of motion in their joints, especially at the knuckles, as their biological inspiration. The lack of biomechanics in their design inevitably prevents the same interaction with our world as a natural limb.

Some scientists have opted for biomimetic designs which offer far more mobility and associative function with the existing anatomy. While they are rare and currently prototypes, they are gaining traction in their respective fields. One such example that carried forward my project was Zhe Xu and Emmanuel Todorov’s prosthetic arm which they built at the University of Washington. Bones are 3D-printed to softened versions of their biological curvatures. They considered the biomechanics of these geometries to understand how the joints work. While some bones are conjoined for simplicity, the overall function retains accuracy to a real arm. Muscles and tendons are also simplified but, in this case, can perform the same motions as their biological counterparts. By doing this, Xu and Todorov iteratively discovered the shortcomings of existing prosthetics, “During this process, we first identified two crucial constraints that have been limiting the development of anthropomorphic robotic hands: the lack of properly translated engineering knowledge of the human hand and the restrictions caused by conventional mechanical joints.”1 The arm was

then mechanized using electromyographical measurements which were translated to electronic controls through a computer.2

Furthering my admiration of the human hand, I studied how humans had descended through lineages of evolving species. It is evident how this trend was not linear and how nature had several periods of experimentation and adaptation to culminate at the form we take on today: The evolution of modern planning capabilities can be investigated by analyzing the decision steps used to produce ancient tools. There are, for example, many different ways of making stone artifacts. Over the last 200,000 years a variety of reduction techniques in different combinations were used to make stone tools. This resulted in different techno-complexes, but all with the same degree of complexity.3

Various iterations of technological advancement likely enabled cultural traditions and in turn a strengthened relationship between the mind and the hand. Additionally, these practices may have also driven a heightened intelligence to generate further technology, “When considering when and how modern behavior developed, it is essential to take into account how the brain could have evolved to support modern capabilities...Evolutionary biology and neuroscience studies suggest that hominin symbolic com-

municative capabilities co-evolved with the brain, resulting in some parts of the brain becoming proportionally larger.”4 Cultural processes such as tool-making likely allowed more efficient expenditure of energy and therefore more time to create better tools. This positive feedback may have contributed to increased dexterity and intelligence.

In order to familiarize myself with the arm’s natural mechanics, I first studied several x-rays and images from anatomical diagrams. From here, I analyzed digital models and traced over them to consolidate the general contours of the arm bones, revealing the function behind their form. Using my newfound insight, I carved anatomically accurate bones at a 1:1 scale from wood. Conveniently, this manual learning corresponded well with my project just as it had for Xu and Todorov:

Although there is still no consensus about the definition of human hand dexterity, the biological variations found in length of bones, branching of tendons, and insertion of muscles all suggest that dexterity is a highly personal property that is not only shaped by individual’s motor control ability, but also inherently bonded to the unique biomechanical characteristics of its very owner, and therefore can not be generalized without considering the biological difference.5

I started to appreciate what I was able to do and create with my own hands and how significant our dexterity and precision enables us to build the world we live in.

A model arm, while anatomically functional, needs power and control to operate as a prosthetic. To control the prosthetic by the user’s own intent, there must be a correlation of mind to body. Electroencephalography (EEG) and electromyography (EMG) have existed for a several decades but only relatively recently are being used in prosthetics, whereby neurological measurements are translated into electronic controls through computers. These electronic controls correspond to mechanical actuators in an advanced prosthetic.

Amputees often note the presence of a phantom limb, the vague memory of an arm of leg that was lost yet still feels as if it was there when they think of moving it. This strongly relates to implicit memory, “Examples of implicit memory are: perceiving a picture or a face more quickly after it was seen, though the person may deny that the face or word was familiar (perceptual priming); learning a repeated, complex motor sequence, even though the individual may not be aware of the sequence or that it was repeated (procedural memory).”6 This implicit memory may still prove valuable though, because existing neurons can be connected to a prosthetic with EMG and possibly sup-

port by EEG, providing motor control comparable to the natural limb.

Altogether, I used my research to create my final drawings based on the past versus present and dystopian versus utopian futures for humanity as technology continues to shape us. “As a result, technologies will vary according to the task at hand, the possible solutions known to the population, the cost of failure, as well as myriad other factors. In turn, and of great interest to the archaeologist, technologies will often reflect aspects of the biology and/or culture of their creators.”7 The future beyond the natural is only possible through appreciating how far it has brought us, or it will be our undoing.

1. Zhe Xu and Emmanuel Todorov, “Design of a highly biomimetic anthropomorphic robotic hand towards artificial limb regeneration,” IEEE International Conference on Robotics and Automation (ICRA) (2016): 8, accessed May 3, 2020, https://homes.cs.washington.edu/~todorov/ papers/XuICRA16.pdf

2. Ibid., 2.

3. Sarah Wurz, “The Transition to Modern Behaviour,” Nature Education Knowledge 3, no. 10 (2012): 15, accessed May 3, 2020, https://www. nature.com/scitable/knowledge/library/the-transition-to-modern-behavior-86614339/

4. Joseph V. Ferraro, “A Primer on Paleolithic Technology,” Nature Education Knowledge 4, no. 2 (2012): 9, accessed May 3, 2020, https:// www.nature.com/scitable/knowledge/library/a-primer-on-paleolithic-technology-83034489/.

5. Xu and Todorov, “Design of a highly biomimetic anthropomorphic robotic hand towards artificial limb regeneration,” 1.

6. Morris Moscovitch et. al., “Functional neuroanatomy of remote episodic, semantic and spatial memory: a unified account based on multiple trace theory,” Journal of Anatomy 207, no. 1 (2005): 40, accessed May 3, 2020, https://www.ncbi.nlm.nih.gov/pmc/articles/ PMC1571502/

7 .Ferraro, “A Primer on Paleolithic Technology,” 9.

LOCATION: OTTAWA, ONTARIO

PROFESSOR: ROBERTO CAMPOS

PARTNER: HASSAN HANNAWI

Parellel to the developing LRT station off of the Queensway, the site is situated within a transit oriented zone near the IKEA. Dedicated to the downsizing Ottawa Citizen newspaper, the site has been proposed for alternative development for residential use. A pedestrian bridge descends into the core while also connecting adjacent buildings with greenspace. Blending mixed-use and residential spaces, this development accomodates new urban growth provided by the transportation hub.

PLANS - RESIDENTIAL HIGHRISE

Ground and Underground Plan

Ground level entrance and sunken entrance to cave

LOCATION: OTTAWA, ONTARIO

PROFESSOR: TERRI PETERS

WINTER 2018

Centre de la Terre [04]

A recently discovered cave in the suburban park in Sainte-Léonard sparks a speleological excavation. This unique condition for an otherwise ordinary park allows for a dramatic exchange between the site’s functions. Scientists required space to gather and study their findings to ultimately present them to the public while visitors also needed to experience the cave safely. Divided by usage, visitors enter slightly below grade into a lobby open to the gallery and rock-climbing wall below. Directly across the lobby the scientists’ amenities are held in a volume above the gallery. This tiered descent through the building program eases into the cave entrance.

above. Site Plan Newly discovered cave in a suburban park

top right. Section A Museum and rockclimbing wall for visitors and labs for scientists above bottom right. Section B Descent into cave

1:200 Model

Hand-made from wood and steel for small-scale material experimentation

LOCATION: BE'ER SHEVA, ISRAEL

PROFESSOR: MANUEL BAEZ

ARCHITECT: BAR ORIAN ARCHITECTS

PARTNER: BASI BASSEY

WINTER 2017

High-Tech

Park Bridge Model [05]

This project, completed to connect the HighTech Park to the Be'er Sheva Tzafon train station, is a scenic point of reference spanning over active and planned railways. Its unique geometry created by four steel arches mirrored beneath, creating lenses 110 metres and 70 metres long, was a challenging model to reconstruct at reduced scale. Through various experiments with materials used, we learned new skills to bring this elegant model to life.

Comparison A similar angle depicts the accuracy achieved working difficult materials by hand

top left. Bending 2mm folds on sheet steel on a bending press

top right. Shaping Manually curving the folded segments into arches to form the lenses

bottom left. Soldering Delicately fusing carefully cut gemotry at precise angles

bottom right. Assembly Polished and glued, wood and steel unite