A.Nadh Ha Naseer _ Architect/Urbanist_Portfolio 2021

SELECTED WORKS

A. NADH HA NASEER.

INDEX

Academic 1.Energy Exchange- Flattening the curve 2.Extreme Urbanism 2.1 Hacking Broadacre city 2.2 Farms in the sky

3.Barcelona Wet. Ware 4.Renaturing Llobregat River 5.Resilent Waterfront 6.Interlocking Filterations- Digital Fabrication 7.Robo Mano- Creative Constructions 8.Reefscapes - A distributed mitigation strategy for the Maldives

Professional 1.Alia Residence Interior Architecture 2.Tropical Island guesthouse 3.Residential Building 4.Island Data Analysis + Visualisations

A. Nadh-Ha Naseer Architect and Computational Urban designer.

Softwares Rhino

Grasshopper

Qgis

Autocad

Revit

Archicad

Sketchup Email : Tel : linkdin: nationality:

anadhhanaseer@gmail.com +34 658334217 www.linkedin.com/in/nadhhanaseer1510 Maldives

Barcelona, Spain 2018-present

Illustrator

Photoshop

Premier Pro My main interest lies in the application of climate responsive , bottom up design strategies integrating data driven approaches with the use computational tools at Urban and Architectural scale.

After Effects

Team player and flexible to work at different scales within the field and willing to learn more.

Indesign

Python

Languages

Arduino

English Basic

Native

Microsoft Office

Dhivehi Basic

Native

Spanish Beginner A1

Other: Native

CEASAR listflood Wallacei Urbano

Workshops

Education

2018 - 2020

2009-2010

Bifurcation//A force of nature_Faculty:Mark Burry, Rodrigo Aguirre

GCE O’ Levels, Highschool Diploma//Sayfol International School, Kuala Lumpur, Malaysia

Data Informed Structures//Himalayan Retreat_Faculty: Manja Van De Worp

2011-2013

New Intefaces VR/AR//_ALT//Faculty:Starsky Lara

Foundation in Build Environment // Limkokwing Univerity, Malaysia

Machine Learning with OWL grasshopper//Faculty: Mateusz Zwierzycki

2012-2014

Llum BCN 2020//Faculty : Luis Fraguada and Cristian Rizzuti

Bachelors in Applied Sciences, Architectural Science// Curtin University, Australia

Cross-platform collaborative techniques for AEC with open source data platform Speckle // Faculty : Paul Poinet

2018-2020

2020 - 2021

2020-2021

Urban Ecology // The New Old: Envisioning the future of our past For The Why Factory (T?F) run by Winy Mass MVRDV co-founder and principal architect and Delft University of Technology _Faculty: Winy Maas, Javier Arpa, Adrien Ravon,

Masters in City and Technology (MACT)//Institute of Advanced Architecture for Catalonia (IAAC), Barcelona, Spain

Urban Intelliegence-data driven spatial planning Workshop by Foster+Partners //Multifunctional Hub _ Faculty : Andy Bow, Bruno Moser, Laura Narvaez Zertuche

Masters in Advanced Architecture (MAA02)//Institute of Advanced Architecture for Catalonia (IAAC), Barcelona, Spain

2021-Present - (part time) Master in BigData with Python // CIPSA

Wallacei Workshop // Simulating New Hong Kong _ Faculty: Milad Showkatbakhsh co-founder of ‘Wallacei’, an evolutionary and analytic engine with embedded machine learning algorithms Urban AI // llobregat River _Faculty: Dr. Sandra Manninger & Dr. Matias del Campo Platform Urbanism // 4th death _Faculty: Nicolay Boyadjiev, Co Director at Strelka Institute Urban Panopticons//Interaction Evaluation tool_Faculty: Aldo Sollazo, Souroush Garivani, Iacopo Neri

Work Experience 2012 + 2013 (3 months) Architectural Intern Riyan Pvt.Ltd, Male’ , Maldives

2015-2018

Awards The Award of Excellence for the Final Studio project “Energy Exchange, Flattening the Curve” by the Institute for Advanced Architecture for the Masters in Cities and Technology. http://www.iaacblog.com/programs/flatten-thecurve/

Winning project for C40 Students Reinventing Cities Competition for the project “22”a time” in Barcelona https://www.c40reinventingcities.org/en/students/ winning-projects/22-innovation-district-1471.html

Associate Architect M.S.P.A.C.E Architecture and Engineering Studio, Male’ Maldives Part time Architect Charrette Studio, Male, Maldives

2021 (3 months) Part time Student Assistant - EU Projects at Institute of Advanced Architecture for Catalonia

2021 - present (Remote) Pro bono Data Analysis and Visualisation Collaboration, 4d-Island, London, United Kingdom Data Analysis and Visualisation Collaboration, Atollscapes, Male’, Maldives

Individual Contribution & Softwares used:

Data management , cleaning and Visualisation

Type of Project : Group

Video Editing

layouting

Project developed for : https://iob.iaac.net/

See Video at: https://www.youtube.com/ watch?v=AUaokLqCJPM

see full project at : http://www.iaacblog.com/programs/flatten-the-curve/

Energy Exchange Barcelona

Energy Exchange

SEMESTER 3 /MASTER IN CITY AND TECHNOLOGY

FLATTEN THE CURVE

Flatten the curve//Internet of buildings//year 1 semester 3/2020 //Institute of Advanced Architecture for Catalonia// Tutor:Angelos Chronis, Iacopo Neri, Mahsa Nikoufar and Androniki Pappa//Students: Riccardo Palazzolo, Marta Maria Galdys, Nadh Ha Naseer, Juan Pablo Pintado, Alvaro Cereza//Duration: 3 months

Context In the project “Flattening the curve” our aim is to analyze the energy consumption and energy production data to propose active and passive strategies that can bring a new and more sustainable energy model. We saw huge technological advances in green energy production from biomass technologies to photovoltaics, in spatial terms, bigger energy output per m² with much lower costs. This could be a game-changer on energy production and distribution. The current system consists of big production nodes owned by electrical companies transferring energy to consumers by the grid but is transitioning from many production nodes (photovoltaic) to consumers. It is a more decentralized system. Some of its benefits are greener energies and savings in transportation costs. But that comes with some challenges as well.

Flattening the Curve One of the most challenging problems with the rise of photovoltaics is the duck curve problem. This has accentuated a spike in production (or less consumption during the day) and a high in demand for traditional grid electricity during the night, these variances of energy create a “bottleneck on which electrical grids can cope but with high costs. Stop Starting at the beginning of the day and ramping at dawn. Microgrid technology is part of the solution to make the system more adaptable and resilient, but it’s not enough. Experts believe to get to at least 80% renewable we would need spatial diversity and short duration storage; this is only possible with a mix of strategies, that go from building scale to district-scale. Without these measures, the costs associated with the ramp-up would outrun the benefits of photovoltaic production.

Methodology The analysis part is divided into 2 categories: consumption and production. For the consumption part, we have land use, the total buildings’ surface (m²), buildings’ energy certificates, and energy use patterns. For the production part, we analyzed the solar radiation which gives us an amount of potential production of energy. For both, a time pattern was added, daily as well as seasonal. The next step was evaluating the data and visualizing consumption and generation patterns. On this basis, we created the catalog of consumption & production per building. To do that, from the value of production we subtracted the consumption value and classified them. It helped us to identify the biggest producer and consumer in the area of Poblenou.

Data , tools and Methods We built 2 datasets ( one for winter and one for summer). the land use for each building on our site. To be more precise with calculations we determined more categories, so for example not only say it’s retail but to check what kind of retail is it, if it is a hotel or a shopping mall, because the energy patterns for this function are completely different. We also considered if the building is mixed-use (ex. residential and office). After gathering this information we run it through the time pattern, daily and seasonal (because of the difference between summer and winter). We also consider the energy certificates, which determine how energy efficient each building is. And finally, based on the roof’s surface of each building and its sun radiation, we estimate the production capacity, getting both energy production and energy consumption per building and at aggregated value.

0kWh

10000kWh

Consumption Production Balance

Type of Project : Individual

Softwares used:

Imagine spacious lanscapes highways, giant roadsm themslves great architecture, pass public service stations, no longer eyesores, expanded to include all kinds of services and comfort, they unite and separate. separate and unite the series of diversified units, the farm units, the factory units, the roadside markets, the garden schools, the garden schools , the dwelling plaves places for pleasure and leisure, all of these units so arranged and so integrated that each citizen of the future will have all forms of production, distribute m self improvement , enjoyment , within a radius of a hundred and fifty miles of his home now easily and speedily available by means of his car or plane. the integral whole composes the great city that I see embracing all of this country- the broadacre city of tomorrow.

see video at: https://www.youtube.com/ watch?v=ZN4mZEmx-dI https://www.youtube.com/ watch?v=n-QdBPv3A8Y

see full project at : http://www.iaacblog.com/programs/x-urban-cities-broadacre-city/

Hacking Frank LLoyd Wright’s

EXTREME URBANISM

SEMESTER 1 /MASTER IN ADVANCED ARCHITECTURE

BROADACRE CITY

X URBAN/Speculative Urban Design //year1 semester 2-3/2019 July //Institute of Advanced Architecture for Catalonia/Tutor;Jordi Vivaldi Piera, Willy Muller// Student:A, Nadh ha Naseer// Duration : 6 months

“The

idea

was

to

give

each person at least one acre of land on which to raise his own food.”

Reimagining of Wright’s Broadacre City The project explores the potential to maintain the aspect of self sufficiency interms of food production imagined by Wright but by increasing dramatically the density in order to adapt to the projection that by 2050, 70% of the worl’s populations will live in cities. This aspect is explored with the integration of new technologies and strategies such as hydroponics and vertical farming that will allow to decrease the space acquired for food production while maintaining the production potential,

Future Densities Original Density

Strategies

1 acre = 80 x 50m2

5% built area

Hydroponic Faming

up

can reduce by 5 times the space used for crop farming.

95% open space

1/8 acre = 100sqm

Cellular Agriculture

Wright’s density : Family of 4 ( 2 adults, 2 kids)

per person / 5

a process in which animal products are produced from cels than whole animals, this process can reduce the land needed to raise a cow from calf to slaughter.

/ acre

Original size : 2560 acres (2.5sqkm) Original population target 5600 persons Inhabitation : 5600/4 = 1400 acres Circulation 20% / 2560 acre = 512 acres Gardens, orchard, recreational spaces, 1400acres+512 acres 0 2560= 648 acres

A typical 1 acre farm layout

Proposed Density Living Units Ratio M i n dwelling Area per Person 50sqm

Min Farm Area Per Person 100sqm

1 person = 40-50sqm Unit = Farm area = 100sqm Maximum amount of units per inhabitable acres: 1400 acres / 50 units = 28 units per acre Density Increase: 28 x 10 Floors = 280 Inhabitants/acre

Livestock Farming

Proposed Typologies Production units. Pasture

Crop Farming

Roof top Farming Hydroponic aand Vertical farming.

10.Horizontal Private Farming from units

9.Public Farming/Garden spaces

8.Folded Vertical farming space on rooftops

7.Double Floor units

6.Single Floor Units

5.Hydroponic farming pods on every other floor on top of walkways.

4.Horizontal shortest pathways to units on each floor

3.Circulation paths around the center with 3 floors in the middle accessing roads

2.Vertical Circulation

1 acre 50m x 80m base

Form Finding & Optimisation The project explores the optimisation of a form for the distrubution of functions integrating dwellings and farms for food production. An environmental Analysis tool (Ladybug) combined with a Genetic optimisation tool (Galapagos) was used to locate the horizontal farms and garden spaces in the structure to accomodate for maximum solar gain.

Genetic Optimisation Objectives: Add Farms to the context for analysis to avoid shadows cast from the farms on top to the ones below

7.Create Farms of Varying sizes that will be optimised according shadow study from the center points

Matrix 6. Create planes on xy on the center of the selected curves

5. divide the unit bases by 2 and extract center points

4. Extract base surface of all housing units

3. select units

all

2. center floors

points

1. curves of the taken to analyse

housing

of

5 floors

Existing Urban Context

Urban Structure

all

Distribution of functions and mobility

Private/Public production farms orchards and gardens

Walkable network Every acre to the center of the blocks and edges

Walkable network Residential blocks to production hubs

Tram network 3 Direct tram to hyperloop

ty ci k. al or in tw ig p ne r o oo l e th per y of a h y o wa int gh hi med or in Ma ansf tr

Tram network 2 Production hubs direct tram

to

Tram network 1 Production blocks

hubs

to

Service network Production hubs to residential blocks

Production farms orchards and gardens. Voids in between Production Farms to allow for sunlight to filter through to the animals farms below.

Agricultural drone, [unmannered aerial to applied vehicle farming in order to crop increase help productio and monitor crop growth.]

Animal Farms

Production hubs.

self modular aibuspiloting vehicle that can be summonded on demand. Capsule based design can connect to either ground or air conveyance modules.

“With today’s modern technology, transportation and

communications

systems,

Mr.

Wright

felt

that there was no longer any need for people to huddle together in cities as they did in the dark ages. He felt that the whole idea of space was so important-that people should be out in the air and light.”

Type of Project : Individual

Softwares used:

see full project at : http://www.iaacblog.com/programs/farms-in-the-sky/

reprograaming segundo piso Mexico City

EXTREME URBANISM

SEMESTER 1 /MASTER IN ADVANCED ARCHITECTURE

SKY FARMS

X URBAN/Speculative Urban Design //year1 semester 2-3/2019 July //Institute of Advanced Architecture for Catalonia/Tutor;Jordi Vivaldi Piera, Willy Muller// Student:A, Nadh ha Naseer// Duration : 6 months

Adaptation to City Segundo Piso

Mexico

An urban intervention in Mexico city by incoperating a green network as a first floor between the segundo piso and ground and a new network on the ground inside the lots using the existing network allowing for low income housing existing on the site to produce food by methods of Self sufficient production by available methods in today’s technology. The intervention is introduced into a very dense urban fabric by example taken from the historical concept city Broadacre city designed by Frank lloyd Wright. A Site was Chosen in the Mexico City that crosses the Segundo Pisos to Adapt the programes explored in the first phase of the project based on the broadacre city.

site analysis & methodolgy

The site featured low income housing in a dense urban fabric. Existing courtyard spaces was firstly selected so as to not interrupt the existing site and the buildings to introduce the new programs. area

An area that consisted mostly of abandoned buildings were removed to also introduce the new programs. the selected areas were calculated to identify the density. maximmum area available = 182359 sqm individual units to fit = 18235

Form

Adaptation process

Landscape Gardens, Private and shared farms optimised by Solar Analysis of Site

Hydropnonics on the network connecting between roof top farms

roof top farms above residential units

Proposal Proposal of a new intervention by introducing a first floor between the ground and the second floor highway which acts as a public space. Introduction of New levels connecting housing units.

Courtyard space Proposed Public spaces with Ramp Access to the ground from the first floor

adaptation of the proposed Geometry and form explored in the first phase of the project to the void spaces in order to create a fabric that co exists with private and shared farms, orchards, gardens, vineyards and rooftop farms together with Hydroponic Farming to allow for self sufficiency in terms of food production in a dense urban fabric.

Distribution of functions and mobility Public spaces, and critical Infrastructure such as commercial, schools hospitals and public gardents branching from the first floor network into

Introduction of the First floor network by shortest Path from the Main road Network to all the detected courtyard spaces. First floor is perforated at the center to allow for sunlight to pass through to the existing ground floor under it. This floor consists of different Public Proframs such as markets, gardens and orchards reflective of the broadacre city concept. ground floor of the site previously of abandoned factories dedicated for production units. Introduction of a New Network within the lots for walkability and bike access, allowing for the negative spaces in between to be used for farming and food production on the ground floor for the existing buildings. Extraction of primary road from Existing for only Vehicular access. Detection of open spaces in the dense fabric and calculating the surface area to determine the maximum amount of residential units and other Programs that can be introduced to each of these ares without disrupting the existing buildings on site.

Individual Contribution & Softwares used:

Computational Design

Type of Project : Group

Render and Graphics

Video Editing

Ubiquitous computing enables us to decipher the Biopshere’s anthropogenic dimension, the so-called Urbansphere. In the Anthropocene, we know our civilisation reached global impact because the machines that we built to sense it, tell us so. In this respect, we are already in a post-anthropocenic condition, where the impact of the artificial system on the natural Biosphere is indeed global, but their agency is no longer entirely human. In the Anthropocene Age, we, therefore, need more than ever a non-anthropocentrism mode of reasoning and deploying design technologies as the anthropocentrism immanent in their explorative mobilisation in architecture limits its operative scope. Claudia Pasquero, Marco Polleto

see video at: https://www.youtube.com/ watch?v=s2Cnp4TSdvU https://www.youtube.com/ watch?v=qi23tIjP94o&t=1s

see full project at : http://www.iaacblog.com/programs/wet-ware-bcn/

barcelona

WET WARE BARCELONA

SEMESTER 1 /MASTER IN ADVANCED ARCHITECTURE

WET.WARE

Barcelona Wet,Ware// Computational Urban Design //year1 semester 1/2018//Institute of Advanced Architecture for Catalonia/ utors: Marco Poletto, Claudia Pasquero//Students: Aishath Nadh Ha Naseer, Holly Carton , Fiona Demeur //Duration : 3 Months

At the turn of the century, Barcelona started to grow and transform the surrounding villages and landscapes, creating its current distinctive grid. Barcelona systematically changed its environment imposing a new network throughout the city which would not provide many relief spaces in the dense urban network.

Context & Approach In this studio, both digital and biological intelligence are explored using computer generated algorithms and Physarum Polycephalum, a mould. The process begins with with an analysis of a satellite image exploring different data sets, before creating path systems. The aim is to create a proposal for the specific area within Barcelona as well as exploring the use of Physarum Polycephalum as a biological tool. Each group was allocated a specific site of Barcelona. Through our analysis of the existing networks and structures using gradient fields and path systems in Grasshopper, we were able to understand the current city. Following this, our proposal to create a new network became a new way of looking at the city. Below are a series of images depicting our process of exacting and creating information.

Proposal First, the 10 points with the greatest intensity of existing green were found using the gradient field extracted from the satellite image. Following the mesh of the topography, the minimal path system was calculated from the building centre points to these 10 new points. This new network resembles an agricultural system that begins to overgrow the city, allowing for the propagation of seeds and new circulation routes for fauna. Below is the final drawing proposal as well as the render created in Keyshot. The short video explains the build up of layers.

Biological Networks Slime Mould (Physarum Polycephalum) Experiments

Experiment: Taking the 10 starting points of the proposal, we wanted to see how the Physarum Polycephalum would create its own biological network between the same points. Oats are placed at these 10 points to entice the slime mould towards them. Over the course of the week, the slime mould began to expand and contract as it started to navigate across the agar to find its food. Furthermore, when some other organism started growing in the petri dish, the slime mould went straight for it.

Conclusions Through the experimentation we were able to compare the biological map created by the slime mould with the computer generated algorithm and see the similarities and differences between them. This also gave us an understanding into how a combination of these methods could be used to create plans for cities in a new and different way. Below is a video clip of the slime mould experiments.

Individual Contribution & Softwares used:

Type of Project : Group

Computation design + Data analysis + Visualisation

River Simulation CEASAR

Graphics

see full project at : http://www.iaacblog.com/programs/renaturing-bcn/

LLobregat River

SEMESTER 1 /MASTER IN CITY AND TECHNOLOGY

RENATURING LLOBREGAT RIVER BCN

RENATURING

Renaturing Rivers// Landscape Urbanism //year1 semester 1/2020 Oct //Institute of Advanced Architecture for Catalonia/ Tutors: Eduardo Rico, Mathilde Marengo// student: Aishath Nadh Ha Naseer, Hebah Qatanany, Laura Guimaraes, Mario Jose Gonzalez, Sinay Coskun// Duration:3 months

the problem and scale

Project is built upon two main problems. Flooding caused by climate change and urban expansion towards rivers. Both the problems, and proposals are defined and developed based on different scales that can be followed as

Global, Regional, Territorial,

and

Local.

River Anatomy Our challenge was to do a river renaturing project in the area of Barcelona, so we chose to work with a river that has the critical problems previously defined in our case study analysis. We selected to work with the Llobregat River in Catalonia. It is an 170km river with large flood risk areas, that affect many Catalonia municipalities, not just Barcelona. Moreover, it has dams all along its course, representing a river with high human intervention.

Methodology Considering the complexity of our project, we have developed a series of analytical processes that have helped us transform our analysis into design parameters. Each part of the procedure is tasked with either transforming information into a decision or in transforming a decision from one scale of intervention to another

Potential Risk Map

Based on mapping studies and analysis we did, we summarized the main risks and opportunities this river provides allowing us to clearly point out five sites where most of of the risk and opportunities are concentrated. We opted for working with the last one- the Llobregat Delta which contains a conservation zone, agricultural park and industry hub with the airport. In the Delta, Barcelona’s desire for expansion meets farmland of immense economic importance, while it also faces water quality issues brought down stream from mining facilities. All of these issues play out in a territory that has been recognized as being of exceptional ecological value.

Stakeholder Analysis

Starting from the main projects and going deeper in the analysis of the river, by first dividing it in five regions according to their common characteristics and the river shape, we identified the stakeholders that control the Llobregat. We were able to conclude the high influence the agricultural and industrial areas (green and orange circles) have on the river, as well as some entities and facilities controlled by the Metropolitan Area of Barcelona and the Catalan Water Agency, and even the Airport and Port of Barcelona, which flank the river on both sides of its mouth and strengthen the agriculture and industry hub of the lower Llobregat.

Adaptation Program Ceasar Simulation We used a simulation program that allowed us to visualize how and where the river would potentially flow over different time spans, and naturally the landscape starts to form wetlands, at this point we also identify that this new meandering will have an impact on existing agricultural areas. Further calculations were done to identify by how much the agricultural fields will be affected by the new river meandering in each of its phases. This was done in order to guide the potential adaptations scenarios that could be presented to the affected farmers.

Analysis Simulate River meandering

ceasar

Evaluate the percentage of agriculatural land affected by the meandering of the river over time qgis

+

grasshopper

Tools Adaptation strategies Compensation for temporary land loss through tax benefits

Education benedits by NGOD for teaching farmers to adapt to aquaculture.

Adaptation solutions proposed to farmers on percentage of affect

More at:

on

the

computational

process

Legend Meanders

http://www.iaacblog.com/programs/ river-meander-analysis-agricultural-areas-affected-meadering-river/ Phase 1

Phase 2

Phase 3

Phase 4

Phase 5

Agricultural Areas Affected

Low

High

Compensated for economic loss

Merge with other partnerships

landowners

in

joint

Adapt to Aquaculture on the new wetlands

Phase 2 Phase 3

The process begins with blocking the water with terrace edges to prevent the flow of water towards surrounding urban areas. Then we start to see the first meanders and the formation of a new channel. In the first phase, wetlands provide new habitats for flora and fauna and at the end of this phase, an educational program is proposed that trains the farmers affected. With the formation of more water bodies and changes in the landscape, we start introducing river engineering mechanisms such semimetal zones that help control river flow and erosion levels. As time passes, the river starts taking up more land and creating more meandering. So at this stage start to introduce bio-filtering mechanisms and also introducing off-site solutions that will allow compensations for the loss of food production by introducing urban farms in different available voids in the city. This further strengthens the connection of the citizens with food production and to the site itself. Once the river bed is stabilized, we can focus more on engaging the public by creating agricultural educational programs and aqua-tourism programs that will help fund the maintenance of the wetlands. Finally, we can begin to focus on community building by designing recreational areas connecting rural and urban and open the site for the public engagement.

Phase 1

Proposal

Phase 5

Phase 4 Having identified the affected farms we started looking at potential adaptation programs. Firstly, while the channels are being formed AMB (metropolitan area of BCN) could compensate these farmers for the temporary land loss through tax benefits and Education programs. Secondly, the farmers would be a part of the decision making process By choosing one of the suggested scenarios. For example; Least affected and medium could choose to stay on their land or merge with another farm. While the highly affected are equipped with tools and knowledge to switch to aquaculture on the new wetlands formed. The scenario on the right is a long term vision of the new food production system where the river functions as a link connecting the people to agriculture.

Phase 6

The Enhancement of a system

Individual Contribution & Softwares used:

Data Analysis + Data Visualisation

Type of Project : Group

Computational Design

Graphics + Layout

Video Editing

Waterfronts are seen as multifunctional locations for economical and environmental activities, this growing uncertainity needs a long term resiliency, Floating technology is not something new in addressing resiliency

in the waterfront .

see video at: https://www.youtube.com/ watch?v=Juu0CX7hepk&t=11s see full project at : http://www.iaacblog.com/programs/resilient-waterfront/

Cellular Automata urban exploration

Resilient Waterfront

SEMESTER 2 /MASTER IN CITY AND TECHNOLOGY

RESILIENT WATERFRONT.

Resilient Waterfrong//Computational Urban Design//year1 semester 2/2021 //Institute of Advanced Architecture for Catalonia// Tutor: Alex Mademo,Iacopo Neri, Eugenio Bettucchi//Student:A, Nadh ha Naseer, Marta Galdys, Arina Novikova, Sridhar Subramami

Site Selection The area that was used for this simulation is Barceloneta, dockyard in front of passeig de colom. This particular location has a multifunctional characteristic throughout the year being to address the local people’s need for functional spaces or the tourist demands and also the seasonal changes. The project focuses on the redistribution of the existing density of inhabitants into the waterfront for better living conditions. So, the study location boundary is demarcated within 20 min walkable radius from the waterfront. In this way, the project could control the redistribution within a specific zone identifying the highest inhabitants blocks and redistribute them on the water

Methodology & Psuedo Code

1.Data collection and Site Analysis .shp files

.csvfiles

2.Archipelago Generator with Cellular Automata Set boundaries

Set Dispersion

3.User Interaction Select preferred configuration Set occupancy 4.Generate Archipelago

4a. Fixed Configuration [longterm modules]

4b. Moving configuration [Temporal Modules] 4b.1 Set Field for Moving 4b.2 Remove fixed cells from the path for movable modules

4a.1 Define Functions

4b.3 Define Scenarios for moving

Public Space

Size of islands

Private modules

Functions

Shared Modules

Density Strengh

Interface Set Views

Emma@gmail.com

OCCUPANCY

SCATTER

Starting curve 1

Manual settings Occupancy

Scatter

Select a preferred distribution of fixed and moveable floaters by generating Archipelago configurations

Emma@gmail.com

OCCUPANCY

SCATTER

Starting curve 2

Manual settings Occupancy

Scatter

Interface

Set functions for fixed modules

Interface

Emma@gmail.com

OCCUPANCY

SCATTER

Starting curve 1

Manual settings Occupancy

Scatter

Select typologies from the catalogue

Select scenarios for the moving modules

Type of Project : Group

Individual Contribution & Softwares used:

Concept Development and Drawings

Fabrication process & casting

see full project at : http://www.iaacblog.com/programs/interlocking-filtration/

digital fabrication

INTERLOCKING FILTERATION

SEMESTER 1 /MASTER IN ADVANCED ARCHITECTURE

INTERLOCKING FILTERATIONS

Interlocking Filterations//Digital Fabrication//year1 semester 1/2018 //Institute of Advanced Architecture for Catalonia// Tutor; Ricardo Valbuena, Sujal Kodamadanchirayil, Alexandre Dubor//Student:A, Nadh ha Naseer, Oana Taut, Eszter Olah, Anaisa Franco// Duration : 3 weeks

Methodology CONVEX

SH

By creating convex and concave surfaces we observed ways that the object can have a shadow on its surface and perforations create shadows off the surface.

BJECT

1 WALL , 1 MOLD , 6 BRICKS. BASE POINTS

HADOW

ONCAVE

MO

CONVEX

ADOW

OBJECT

Base points

BASE POINTS

OBJECT

CONCAVE

CONVEX

750mm

SH

CONNECTIONS FRAME Form Finding To optimise a form, we took the actual frame the bricks were to be installed on , and used the “connection” points as our “base points” to guide the creation of convex and concave surfaces.

Form Exploration

300 mm

CONNECTIONS CONVEX-CONCAVE

300 mm

250mm 750mm

150mm

FRAME

CONCEPT

CONCE

CNC MILLING_LIGHT FILTRA

ANAISA FR AISHATH NADH HA NA ESZTER OANA

CONC

CNC MILLING_LIGHT FILTRA

ANAISA FR

Fabrication Process & Results

7.Sanded and waxed. 6.Divided pieces glued together

8.Drill ho the legs Exudoro

1.Boolen split from 1000x500x160mm box 5.Mold Milled in 2 hours

2.Neg

Rhino Cam Settings -Horizontal Roughing 12mm Ball point -Parallel Finishing 12mm Ball point -Horizontal Finishing 6mm Flat mill (to obtain sharp edges) -2 Axis Profiling 6mm Flat mill (in order to cut the mill)

3.Mold split in drill depth con and the depth 4. 2 of 1000x500x80cm foam placed on Milling machine

ole through to pour o

9.Put mold together

gative 10.Insert funnel into mold through drilled holes

11.Plywood box to cover edges from leaking and to keep from mold expanding

nto 4 due to nstraint h of the foam

12. Exoduro mix in 1:2 ratio with water Water

Exoduro

Module

Type of Project : Group

Individual Contribution & Softwares used:

Render and Graphics

Video Making and editing

Robots have been a crucial part of the technical-economic evolution of humanity,counting from the first industrial revolution. Although robotic fabrication processes have enabled great freedom infabrication, emerging collaborative interfaces which combine robot and human capabilities have the potential to reconnect design exploration with materialization.

see video at: https://www.youtube.com/ watch?v=zBtC8-KxRcQ&t=75s see full project at : http://www.iaacblog.com/programs/robomano-creative-construction/

Creative Constructions

ROBO MANO

ROBOMANO

SEMESTER 6 /MASTER IN ADVANCED ARCHITECTURE

Explores the intuiton of muscle memory with hand movements and finger gestures through robotic interactions to provide opportunities for craftsmen and laborers to replicate handscrafts in large scale design processes.

ROMOMANO//Advanced Robotics and Creative Constructions//year2 semester 2/2020 //Institute of Advanced Architecture for Catalonia// Tutor; Kunalit Singh Chahdha, Alexandre Dubor//Student:A, Nadh ha Naseer, Surayyn Selvan, Timothy Ka kui lam, Haresh Ragunathan

Potential Applications Focusing on activities that are carried out by hand such as texturing, carving and painting, the vision of ROBOMANO was to create a synergy between the human and the robot. Extracting the fluidity and emotion from the human tasks and replicating these motions using the robot in a back and forth relationship between man and machine. Through this project, we foresee an increase in productivity for labor intensive design processes.

Methodology

Interface procedure

SandBox Project With the context and constraints of the Post-COVID strategy for the seminar, a sand box set up is used to execute our project strategies. Here is the process executed with the SANDBOX project context:-

Results

Type of Project : Individual

Softwares used:

The Paris agreement in 2015 United Nations Climate Change Conference central aim was to strengthen the global response to the threat of climate change by keeping global temperature rise below 2°C above pre industrial levels and to pursue efforts to limit the temperature increase even further to 1.5°C. Intergovernmental

panel

on

climate

change(IPCC) 1.5°C report has since revealed

that

limiting

to

1.5°C

enables

greater opportunities for adaptation in the human and ecological systems of small islands ,low lying coastal areas and deltas.

see video at: https://www.youtube.com/ watch?v=BIrOJHOQWpE&t=2s see full project at : http://www.iaacblog.com/programs/reefscapes-distributed-mitigation-development-strategy-maldives/

A distributed mitigation strategies for the Maldives

THESIS // ReefScapes

2020, / MASTER IN ADVANCED ARCHITECTURE

[REEF] SCAPES

Reefscapes/ Research and Urbanism //year2 semester 1,2,3/2020 //Institute of Advanced Architecture for Catalonia/ // Tutors: Mathilde Marengo, Eugenio Bettuchi//Student :A,Nadh Ha Naseer//Duration: 9 months

Research Statement The research “ReefScapes” sets itself as a critical analysis of the existing centralized model in the Maldivian archipelago confronting the circumstances that are causing for impending challenges arising from climate change to be addressed as a secondary issue by proposing an adaptive decentralized model with self sufficient strategies.

Aims To propose an alternative to the existing centralised model practiced in the Maldives which proves to be impacting the challenges related to climate change and achieving economies of scale. To provide a method for distribution of resources in a holistic manner within an atoll system with an adaptive strategy to compensate for the impact of climate change.

Objective 1 Identification of the challenges to be addressed in the project proposal. The three main challenges being the global threat of :

1.sea level rise,

2.Loss of natural resources due to global and anthropogenic stresses

3.challenges in achieving economies of scale, due the dispersed nature of the geographical territory.

Objective 2 Analysis of the current centralised model to get a perspective on current state of flows in relation to the territory.

Objective 3 To propose a decentralised and then a distributed system at different scales, decentralised at the scale of Maldives and a distributed model at the scale of an atoll.

Research and Methodology

Analysis through Multiscalar Mapping Scale: Country The research is done through a multiscalar analysis by a generating a series of mappings based on data related to the urban flows at a global, national and an atoll in order to have a clearer overview of the current state of flows to assist in the identification of where there may be challenges, resources and potential synergies within the territory that can be put to better use to mitigate the issue of sea level rise

“Mappings discover new worlds within past and present ones; they inaugurate new grounds upon the hidden traces of a living context. The capacity to reformulate what already exists. What already exists is more than just the physical attributes of terrain but includes also the various hidden forces that underlie the workings of a given place” (Corner.J, 2002)

LEGEND Island reef Variable Depth Reef Deep reefs Variable Depth Non Reef (Sandy zones) Deep Non Reef Total

Combined Land

Area = 233 sqkm

Total Number of Islands = 1190 Total number of resorts = 154 as of 2019 Total number of inhabited islands = 200 (Largest island = Gan in Laamu Atoll) Total number of uninhabited = approxmiately 800 Admininstrative capitals Total Number of natural atolls = 26 Total number of admin atolls = 20 Total large channels mapped

= 9

Total Exclusive Economic Zone (EEZ ) = 859,000sqkm Frequent ships crossing the channels through Maldivian territory without stopping as there is only one existing port in the center. Population <more than >less than >less than >less than

by atoll 100,000 20,000 15,000 10,000

Note : Circles Area increase by area of corresponding islans Figure : Components of territory Image Source : A.N.H. Naseer, 2020 Data source: Maldives National Bureau of Statistics, Water Solutions Private Limited

Analysis through Multiscalar Mapping Scale: Regional Mapping of geographical resources across the country was performed in order to understand the potentials of different regions and the synergies such as the interaction between the different types of geographical entities with an atoll system and existing substance flows, tangible, intangible and dynamic to identify how they can contribute to a better urban life in the context. Beyond that the mapping was narrowed down to a regional scale where existing geographical resources along with the existing infrastructures and the shipping channels that flow through the territory are identified to assist in the intervention for new programs

Atoll options The north has a concentration of islands with higher agricultural potential. Centric Atolls has a an existing higher Economic potential due to years of centralisation, Most resorts are concentrated here and there are smaller atolls in this region which accomodates for reef fishing.

South is closest to the deep sea fishing channels and has a high concentration of larger inhabited islands with mangroves.

LEGEND Inhabited island Administrative atoll capitals Resorts Uninhabited islands Uninhabited islands leased for agricultural purpises Uninhabited islands leased for fishing

Resort islands closest to inhabited islands Agricultural islands closest to resort islands Inhabited islands closest to deep sea tuna fishing chanIslands reef fishing Shallow reef lagoons Deep reefs Island reefs

Figure : Potential Synergies Image Source : A.N.H. Naseer, 2020 Data source: Ministry of Fisheries and Agriculture Maldives Bureau of National Statistics 2018

Analysis through Multiscalar Mapping Scale: Atoll

Figure : Resource Map Data source: Google Earth Satellite Imagery, Nasa Bathymetric Data

Resource Mapping and Island Selection To proceed into the design phase, a small atoll that comprises of all the geographical entities was chosen to be analysed further for its resources. At this atoll scale the analysis of resources were done per island by calculating areas of vegetation,and reef, urbanisation along with the current population and bathymetric data. This data was collected in order to identify a mid point within the atoll that is within a 10 minute radius from all other inhabited islands and a 20 minute radius from the International airport by speed boat.

LEGEND Vegetated area Urbanised area Reef area

Figure (77) Island of H.A Uligan Data source: Google Earth Satellite Imagery

Implemetation plan Multiscalar mitigation approach to the Maldives

The purpose of identifying a mid point is to place critical infrastructures in a point that is accesible to nearby islands. due to only few hundred living in most of the inhabited islands, it is hard to place critical infrastructures for each island. therefore the research takes place by introducing critical infrastructure to one accessible point but does it through a master plan strategy that incorporated mitigation and tipping point strategies to address the issue of rising sea levels. The master plan template is meant to be applicable to all islands in terms of what it provides as mitigation measures although the programs differ between islands based on its resources

and strengths

Mitigation Strategies Scale: Island

Phase1

Phase 2

Phase 3

Horizontal Mitigation strategies With Habitat regeneration

Vertical mitigation strategies In parallel with phase 1 strategies

Tipping point strategy

Coastal protection

Raised ground

Floating typologies

Horizontal mitigation strategies, mostly coastal protection strategies by means of coastal protection vegetation and also available bio technological methods such as tetrapods.

Vertical mitigation strategy explores the shifting of the programs from the sinking land to raised level.

Expanding the urban territory into the reef area

Year 2020-2030

Year 2030-2070

Year 2050-2120

Sea level 0.3 Meter

Sea level 1/2 Meter

Sea level 1 Meter

.

Scale of Intervention Existing Island Anaylsis Scale: Island

Existing state and resources of the island is analysed revealing high vegetation concentration in the center of the island. The island inner reef consists of high seagrass concentration.

In land Vegetation concentration

Two variable depth water bodies are on the South west and the North East side of the island, with an existing reef on the North East where as the waterbody on the South west at of 5-10meters detects no reef growth. This is considered a potential area to place a bio rock reef as part of phase 1 of the mitigation strategies.

LEGEND NE dry monsoon prevailing wind

1 Meter

SW Wet monsoon prevailing wind

50 Meter Deep Non Reef

Seagrass concentration

10-20 Meter Deep Reef Variable depth between 5-20 Meter Non reef Sandy area 1-5 Meter Island Reef

20 Meter

2020 1000m

Implementation and life cycle assesment Phase 1 - Horizontal Mitigation strategies Scale: Island

Protection Barrier

Phase 1 Involves implementation of horizontal mitigation strategies that involves coastal protection strategies, 1. Placement of biorock reef structure on to the non reef 10meter deep water body. This will act as a protection barrier, slowdown erosion and promote habitat regeneration

Slows down erosion

Habitat regeneration

2. A protection buffer zone is placed on the perimeter of the island , starting with floodable plains, mangrove plantation and shrubs, These strategies allows to slow down effects of sea level rise and hopefully buy more time to adapt the existing land.

1 Meter 1. Biorock Reef Installation on non reef area

LEGEND Shrubs Mangrove Forest Floodable plains

0.3 M

2020 - 2050 1000m

20 Meter

Implementation and life cycle assesment Phase 2 - Vertical Mitigation strategies Scale: Island

Phase 2 is divided into sub phases, First part is to elevate only the proposed housing areas by 4 meters allowing for a shift of programs.

LEGEND

10-20 Meter Deep Reef

1 Meter 0.5 M

2020-2050

Variable depth between 5-20 Meter Non reef Sandy area 1-5 Meter Island Reef

2020 - 2070 1000m

20 Meter

2030-2070

50 Meter Deep Non Reef

Implementation and life cycle assesment Phase 2a - Vertical mitigation Strategies Scale: Island

Second part of the Phase 2 is to raise the entire ground level, and create new areas for forestation as well on the elevated layer as with rising sea levels the existing vegetation areas will be affected as well.

LEGEND

1 Meter

2050-2080

0.8 M

2020-2050

Elevated Road Network at 8 Meters from housing units to forestation and recreational areas

20 Meter

2030-2070

Elevated Road Network at 4 Meters, replicating the existing road network of the island.

2050 - 2080 1000m

Implementation and life cycle assesment Phase 3 - Tipping Point strategies Scale: Island

Phase 3 implements urbanization of the reef area by means of floating and over water structures, To determne the placement for the over water structures, the grid from the island was extended on to the ocean and a new grid was generated avoiding the seagrass concentration.

The areas to place overwater structures were deermined by filtering out the the largest areas within the grid and orienting the pods to avoid south west prevailing wind mainly as the island it self is in the way of the north east prevailing wind. 200Sqm pods are placed and an approximate density of 80/ha can be achieved on this area

Implementation and life cycle assesment Phase 3 - Tipping point Strategies Scale: Island

LEGEND 200sqm pods Accomodates up to 800 people. (80/HA)

10-20 Meter Deep Reef

1-5 Meter Island Reef

5-20

Meter

2020-2050

Variable depth between Non reef Sandy area

2050 - 2100

2030-2070

2050-2080

50 Meter Deep Non Reef

2050-2100

1 Meter

Distribution of functions and programs Population and Density calculations Scale: Household

To calculate a projection for a population to design for, how much space required per person to be self-sufficient at a household scale was determined, With this calculation, the population of land area already dedicated for residency island increased by 3 times, with the addition of the reef area as habitable space, an extra 2 times increase, therefore the projected population is 5 times more than the current. 1 Person Required 134sqm atleast to be self suffcient at a houseCurrent population of the Island = 380 people Projected population with the above calculation with: Designated area for Residency on land 1120 people Designated area on Reef for Habitation 785 people Total 1900 people (5x increase from the original population) Existing Urbanised area LEGEND Habitable Area Outdoor Farming Aquaponic systems Open Space Indoor Farming Livestock Farming Tourist

and

Individual

Division of a134 sqm area to determine the rationsfor the required spaces for self sufficiency at a house hold scale

Commercial Other Outdoor deck Storage Solar Panels Water storage

The required percentages of spaces were then divided into separate floors to achive maximum open area for some of programs that would require sunlight.

Spatial Configurations Scale: neighborhood

15 % Aquaponic system 15 % Aquaponic system

25 % outdoor farming 136sqm 7.5 % livestock farming

40 % commercial spaces and 40 % storage

15%

50 % shared public space Connecting path the shared space

in

40%

Level 1 Elevated at 4 meters Commercial and Storage

40%

Level 2 (public space)

50 % open areas on level 4 for sunlight

Outdoor decks facing the beach

7.5 % Outdoor Open Deck

20 % each Individual Units 134sqm

7.5 % Indoor farming 40sqm

4 units/ plot Accomodating 4 people

37 % Family unit 200 sqm

Level 3 (Family Units)

80%

10%

Level 4 (Individual Units)

Outdoor decks facing the beach 20% SolarPanel 40sqm 25% each Tourist units 134 sqm 4 units/plot Accomodating 8 people/plot 2 person/ unit

80%

10%

Level 5 (Tourist unis

Guesthouse)

Rooftop

Distribution of functions and programs Private spaces Scale: Island

Structure

Roof

The existing units dedicated for residency maintains its position and proposes a mixed use housing strategy elevated 4 meters from ground with programs for commercial use, community shared areas, private use, areas for tourists and agricultural production LEGEND 10 minute Radius by walking 5 minute Radius by walking

+24 Meter Roof for Storage and Solar Panels

Fifth Floor +20 Meter Private Residence (Tourist Units)

Fourth floor +16 Meter Private Residence (Individual Units)

Third Floor +12 Meter Private Residence (Family Units)

16 people 12 people

Second Floor +8 Meter Community shared

8 people First Floor +4 Meter

1120 people 240/HA

Commercial & storage

Spatial Configurations Public spaces Distribution hub Transfer hub

Public Infrastructures and Services Mixed h o u s i n g units

Port for import/export Boat building Restaurant /cafe Areas

Open Air Market

Ferry Docks Elevated Forestation Area

Mixed housing, and public infrastructure in the inner island within 5 minute walking distance from the ferry . Floating Platforms reserves programs for future housing needs as well.

Services and commercial areas on the South East side closer to the transport hub and port

Public floating Platforms anchored to the bio rock reef below for fishing and other recreational activities on

Reef fishing and offshore fish processing units Recreational Diving services

Picnic set up Areas Swimming W a t e r sports area

Reef fishing and fish processing units along with Recreational watersports and diving facilities are placed on the outer edge of the reef

Recreational zones with dedicated areas on the edges towards the ocean

Circular Economy Parameters UN Sustainable Development goals 13(Climate Action), 14(Life Below Water) Scale: Island

In addition to the mitigation strategies that involved placement of biorock reef and a buffer zone on the island consisting of floodable area, mangrove plantation and shrubs to mitigate the effects of erosion , the proposed structures on the ocean and land are to be covered with biorock to allow for coral to graft on as the sea level rises. The strategy is adapted from the biological forces at work that maintains the geo-morphologies of coral islands. These forces are deteriorating with the rising sea levels and global temperature rise, therefore with the help of available technological advances technologies for reef restoration with bio rock are proposed to assist in habitat regeneration and recovery damaged reef areas.

Shrubs

Mangrove

Floodable plains

1000m

Circular Economy Parameters UN Sustainable Development goals Mobility Scale: Island

Ferry Dock for Tourist Transfers

Mobility within the island works by making sure most of the cirtical programs are placed within the 5 minute walking radius from the ferry docks.

Ferry Dock for Atoll Transfers

As the island is a midpoint for the rest of the atoll, there are 3 entry points to the island. 1. The port for shipping access 2.Channel for Tourist Transfers 3. Channel for Local Atoll Trasfer.

1

2

LEGEND 10 minute Radius by walking 5 minute Radius by walking Elevated Road Network at 8 Meters from housing units to forestation and recreElevated Road Network at 4 Meters, replicating the existing road network of the Platforms/Islands accesible only by water

3

Circular Economy Parameters UN Sustainable Development goals 2(No hunger) Scale: Island

Strategies proposed to achieve food security scale from a household to the enter island and potentially programs that allow for the production of food that can be distributed within the atoll where it is harder to establish the same facilities or lack resources. These strategies can have potential positice impacts such as increase of economical value ,reduce the dependance in importation and also create jobs

Household scale Mixed use housing units has dedicated zones for food production in their private levels as well as the mix use community space propose don the second level of the houseing units where programs for aquaponics, outdoor faming and live stock farming are placed.

Elevated Area dedicated for Forestation Raised ground level for new forestation can hold up to more than 80000 trees which will also contribution to the production of food. Area = 265218 sqm Approximate. Trees planted Substrate Depth = 1 meter

A local open market is placed where locally grown food can be sold

= 80,000

Total Fresh water Requirement 18litre/day (1591308 litres total) Renewable Desalination units needed 8 units (200,000 litres/36sqm)

Dedicated zones on the edge of the reef for reef fishing, fish processing units as well as Aqua farming. Under Water 3d ocean Farming allows for the growing of seaweeds, shellfish such as mussels and oysterms

1000m

Circular Economy Parameters UN Sustainable Development goals 6(Clean Water and Sanitation) Scale: Island

Due to the salination of the fresh water lens with the rising sea levels most of the islands rely on imported water from the capital island Male’ unless the island has its own desalination plant.

Distribution Network

Desalination Water storage on residential units

The proposal was to place mobile desalination plants that uses solar energy according to the basic water needs of the projected population. Additionally water storage and roof collection systems are also implemented in the proposed housing units. One person water needs per day for potable and non potable needs = total 583 litres/day (1 Renewable desalination unit of 36sqm provides 200m3/200,000 litres / day) Projected Population 2000 Desalination units Forestation area 265218 sqm Desalination units Total desalination units =

6 8 15

(Desalination units are placed between the mixed housing and Forestaion area and distributed to all the programs)

Roof

Collec-

Toilet Water Storage Desalination Waste ment

Water

Treat-

Water Storage

1000m

Circular Economy Parameters UN Sustainable Development goals 12(Responsible Consumptio) Scale: Island

Waste collected from units follow a clear path from each housing unit to collection hubs to sorting and recycling centers. Items identified as waste that can be utilised for purposes within the atoll can be taken through a distribution network to a transfer hub where they are distributed to the within the atoll system. Items such as plastic can be taken to a pick up point in the port where they may be trasported out of the country by ship as the island’s proposed port is close to 2 shipping channels.

Approximately 16kg/week is wasted as food per household, the waste can be shredded through a garborater and transported through sewerage system to be used as fertiliser

Waste collection netDistribution network Distribution hub Transfer Hub

Pick

up Solar panels

Pick up point

Collection hubs Recycling center Sorting Center

Kitchen Kitchen Garborator

Anerobic Digester Collection hubs

1000m

Circular Economy Parameters UN Sustainable Development goals 7(Renewable Energy) Scale: Island

Algae open ponds for biodiesel production

Mixed use housing and public infrastructure units have roof areas dedicated for solar panels based on the rough calculation of the energy needs of a a household. For the existing transportation methods which requires importation of fuel, options of producing biodiesel through proposal of algae open ponds are proposed. The biorock structures placed in the ocean are powered by wave energy converters and solar

(1 sqm = 1.5 gallon fuel) Area required for Algae open ponds to produce enough fuel= 720 - 1000 sqm 12 hr = 72 ferry trips 24 hr= 144 on demand trips = 216 total trips = 1080 gallon/day Powering Biorock by solar power

Solar Panels Family of 4 Energy needs Power = 4465Watt/hr Area for solar panels= 35sqm (1 panel = 1.7sqm = 250 watts)

(1sqm needs3 watt/hr to power biorock) Surface Area = 437942sqm Power = 1313826 watt/hr

12 people unit requires: Solar panels = 60 units 20 % of roof area

Area of solar =8934sqm Panels = 5255

panels

Solar Power for bio rock structure of floating pods. Wave Energy Converter (1sqm = 30,000 Watt/hr) Biorock reef structure Area= 56800sqm Wave energy converter area = 6sqm

Area = 56800sqm power= 170400w/h solar panels = 1158sqm solar panels = 681

Softwares used:

Work Experience

architecture + interior

8TH

TV

QUEEN SIZE BED 1.5 X 1.9M

2 3

SINGLE BED 0.91 X 1.9M

SINGLE BED 0.91 X 1.9M

1 4 5

KING SIZE BED 1.8 X 1.9M

H

J

G

F

E

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KING SIZE BED 1.8 X 1.9M

D

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Demolition plan NTS

Demolition plan NTS

Demolition plan NTS

Demolition plan NTS

KING SIZE BED 1.8 X 1.9M

m space. pvt. ltd,

sheet no:

date: project no:

ADNAN

XXX engineer : C O P Y R I G H T

MIS architect :

AR-A101-0

06/01/2016 M-PXXX.AL.2015

T H E A R C H I T E C T S . T H I S D R A W I N G S H O U L D B E R E A D I N C O N J U N C T I O N W I T H A L L R E L E V A N T C O N T R A C T S , S P E C I F I C A T I O N S , R E P O RT S A N D D R A W I N G S . C O P Y R I G H T I S V E S T E D I N M S P A C E P T E LT D .

C O N T R A C T O R S S H A L L W O R K F R O M F I G U R E D D I M E N S I O N S O N LY . C O N T R A C T O R S M U S T C H E C K A L L D I M E N S I O N S O N S I T E . D I S C R E P A N C I E S M U S T B E R E P O R T E D I M M E D I A T E LY T O

I S

UNKNOWN check :

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drawn by :

REV-#001 revision:

T H I S

SKETCH LAYOUT LAILA ALI client :

8TH FLR. ALIA RESIDENCE INTERIOR

architecture.urbanism.engineering

Ground Flr. Office, Nirolhu Bldg., Fandiyaaru Magu, Male', Rep of Maldives. T +960 3336636, E info@m-s-p-a-c-e.com, W www.m-s-p-a-c-e.com

1:100

INTERIOR DESIGN

EIGHTH FLOOR LAYOUT PLAN scale:

m-s-p-a-c-e

sheet title:

project title:

Interior Architecture

ALIA RESIDENCE Interior Architect : Ishan Saeed , Nadh ha Naseer, M.S.P.A.C.E Status : Complete The project is part of an interior architecture project that required the re-orientation of a built floor plan to accomodate a family of 4. The floor plan was reoriented from the origianlly built structure to have the main living areas be in parallel to the slanting facade of the plot. to guide the reorientation the existing columns were transformed to circular ones and intergated into built in furniture. The drawings were provided to work in parallel with the contractor on site and detail drawings, and specifications were provided from flooring, wall, ceiling to lighting and furniture selection.

Eighth floor Plan NTS

Eighth floor Plan NTS

Eighth floor Plan NTS

Eighth floor Plan NTS

Eighth floor Plan NTS

Eighth floor Plan NTS

Architecture -

ISLAND GUESTHOUSE Architect : Nadh ha Naseer, Hussein Ziyath, Interior Architect : Farhad Ahmed Status : Completed The project was designed in collaboration with gabbiano guesthouse as a tropical getaway on the local island of Rasdhoo in the Maldives. A 3 storey guesthouse comprising of 17 rooms, with open to sky bathrooms with and a roof top restaurant facing the sea and the sunset. The concept of the project was to mix traditional architectural styles of the Maldivian Islands while facilitating the use of recycled materials claimed from nearby resort islands in its construction. The project was constructed solely by the loca l islanders skilled at resort construction.

SCHEMATIC DESIGN Date: MARCH 2017

2

2844 [9'-4"]

3

3053 [10']

997 [3'-3"] 4 2100 [6'-11"]

2

2844 [9'-4"]

17-30

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KIDS LOUNGE

5

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14

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STUDY KITCHEN

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MASTER BATH

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SD1D W12

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LIVING MASTER BEDROOM

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MASTER BEDROOM SD1E

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3650 [12']

TOILET 1

3650 [12']

E1

E1

1

SCHEMATIC DESIGN

Eighth floor Plan Date: MARCH 2017 m - s - p -NTS a-c-e

14-30

14-30

Y

SEVENTH FLOOR LAYOUT PLAN

sheet title:

Y

Second to Seventh Floor Plan NTS

W4B

17-30

W4A

DRY BALCONY

KIDS'S SAND AREA

W6

BEDROOM 1

4

4

5

5

7

DN

1

1

900 [2'-11"]

18

7

DN

18

10

3

11

4

12

5

13

6

14 15

16

16

2

2 3 15

10

15 4

14

14 5

13

ROOF LOUNGE

13 6

12

12

3100 [10'-2"]

20

16

17

19

E2

9 10

10

GUEST TOILET

11

9

11

E2 15-30

18

8

8

3100 [10'-2"]

8

17

8

17

LIVING

6

6

UP

3300 [10'-10"]

3

3

2400 [7'-10"]

2

2

3300 [10'-10"]

1

1

UP

900 [2'-11"]

2400 [7'-10"]

D3

D4

15-30

V1c

X

16-13

X

16-30

X

DRY STORE

16-13

X

16-30

V1B

D6

4845 [15'-11"] KITCHEN

W4B

sheet title:

E1

E1

Y

14-30

17-30

Ninth Floor Plan NTS

scale:

Roof top Plan m-s-p-a-c-e NTS m space. pvt. ltd,

architecture.urbanism.engineering

Ground Flr. Office, Nirolhu Bldg., Fandiyaaru Magu, Male', Rep of Maldives. T +960 3336636, E info@m-s-p-a-c-e.com, W www.m-s-p-a-c-e.com

NINTH FLOOR LAYOUT PLAN

project title: TERRACE FLOOR LAYOUT PLAN

SCALE : 1:100

SCALE : 1:100

Special details NTS

scale:

m-s-

architecture.u

client :

revision:

date:

check :

drawn by :

project no:

architect :

engineer :

sheet no:

D R A W I N G

sheet title:

project title

client :

T H I S

14-30

W4B

Y

DINING

17-30

4845 [15'-11"]

D6

SD1B

I S

C O P Y R I G H T

revision: check : architect : T H I S

D R A W I N G

C O N T R A C T O R S S H A L L W O R K F R O M F I G U R E D D I M E N S I O N S O N LY . C O N T R A C T O R S M U S T C H E C K A L L D I M E N S I O N S O N S I T E . D I S C R E P A N C I E S M U S T B E R E P O R T E D I M M E D I A T E LY T O

CONTRACTORS SHALL WORK FRO

T H E A R C H I T E C T S . T H I S D R A W I N G S H O U L D B E R E A D I N C O N J U N C T I O N W I T H A L L R E L E V A N T C O N T R A C T S , S P E C I F I C A T I O N S , R E P O RT S A N D D R A W I N G S . C O P Y R I G H T I S V E S T E D I N M S P A C E P T E LT D .

T H E A R C H I T E C T S . THIS DRAWING SH

Architecture

APARTMENT BUILDING Architect : Ishan Saeed, Draftsperson & Associate Architect: Nadh Ha Naseer Status : Completed The project required the design of the top 4 floors of a 10 story residential building, from architectural layout to facade design. The ground and first floors of the building will be used for commercial purposes, while the floors above second floor were residential areas.

Data Visualisations

4D-ISLAND DATA MAPPING Data Visualisation : Nadh ha Naseer Data sources : Maldives transport authority, NASA , OpenStreetMap Status : ongoing collaboration Data visualisations for the Maldives is an ongoing collaboration with the 4d-island project lead by Ben Pollock and Oscar McDonald who are investigating the use of data to inform sustainable climate resilient urban systems in the Maldives.

http://www.iaacblog.com/tag/ aishath-nadh-hanaseer/

Contact: anadhhanaseer@gmail.com +34 658334217