Portfolio_Work by Yi Liu

PORTFOLIO YI LIU

Master of Landscape Architecture Robert Reich School of Landscape Architecutre Louisiana State University March 18 2014

Yi Liu Email:yliu92@lsu.edu Tel:225-276-2639 Address:1855 Brightside Dr. #B6, Baton Rouge, LA 70820

01\\//10

Climate DefenceEmerald Belt_Marsh

11\\//24

Responsive LandscapeDatascape

25\\//32

Reclaimed LandscapeWharf Reclamation

33\\//43

Other WorksInternship, Construction, Hand-drawing

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fly fo r vis ter win

colorful warbler

ro ay th i t, s t

Location:

Galveston Bay, Houston

Mar. ugh Nov. to

Type:

Academic, Individual

Duration:

16 weeks, 01 - 05/2013

Instructor:

blue winged teal

Rob Holmes

Ecosystem

all fly south

EMERALD BELT / MARSH

mer and f

th sou

Climate Defence

blue winged teal

swainson’s hwak

Habitat Distribution Galveston Bay is a large estuary, rich in sub-tropic marshes and prairies, located along the upper coast of Texas in the United States. The water in the Bay is a complex mixture of sea water and fresh water which supports a wide variety of marine life.

juvenile shrimp

Trend of Wetland The total areas of wetland continue to declined even though people realized the importance and began to put efforts to restoration in recent years.

sandhill crane

adolescent shrimp

mysis postmysis

protozoa

nauplius larva oyster reef

nest on adult oyster

sea-turtle eggs

mature brown shrimp the b eac h

shrimp eggs

ulf

bottlenose dolphin

erica & northern fly from Central Am erica South Am

spat

ass

egg

at p

th s to

Kemp’s ridley sea-turtle female

young Kemp’s ridley sea-turtle

Trend of Wetland inland forest

1996

2005

coastal prairie freshwater wetland brackish wetland salt wetland

-8% -2% +2%

Brackish /Salt Marsh Edges of the brackish and salt marshes serve as refuges and nurseries for juvenile of many species and important feeding grounds for wading birds. Research also shows that marsh can play an important role in the hard fight with storm surges. smooth cordgrass Microorganism

periwinkle snails

Nutrients Sediment

detritus plant decay

Height of Surge (ft) 21 15 12 6 0

Frequency of H5/10 yrs 20 10 5 2 1 0.5 0.2 0.1 Year

T(Â°C)

Katrina

2 1 0 -1

Current Temperature

1900

1950

2000

2050

Trend of Hurricane Global warming will result in more frequent and severer storm surges in the next 100 years. Meanwhile, the relative sea level rise will continuously push the inundation zones to landward.

2100

Storm Surge and Marsh

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Marshes in front of the coastline can dramatically decrease the storm surge height as well as attenuate the simultaneous wave energy which will damage facilities and structures, which can cause great loss to the society as well as the environment.

4 7

6 3

Site Plan

Site Analysis

Legend 1. marsh island 2. mudflat 3. storm water channel 4. existing bike trail 5. proposed pedestrian trail 6. wood deck 7. fishing dock

Bathymetry & Archipelago /1

direct flow

3 hold flow Bathymetry & Archipelago /2

intertidal marsh mudflat

Habitat Distribution

high/low marsh

5 2 Open Space Network

water treatment

industry

1000

2000

5000(ft)

Programs

community education

school

recreation 04

View of Mud Flats The mud flats enclosed by marsh islands will be periodically inundated because of tidal change, which is ideal place for juvenile shrimps and fishes. Then wading birds will be attracted here, eating and nesting. So it is a best place for bird watching. Meanwhile, other programs, like mud flat hiking, can also happen in this area. The upper land, which sometimes is dry and grown vegetation, provides space for drawing, photographing and other activities.

Section Section A-A

upland forest

The slope of both sides of marsh islands are different. The side to the bay is steeper so to better attenuate the wave energy, while the other side is slower so intertidal marsh shallow chan to increase the interface area.

upland forest

intertidal marsh

shallow chan

upland forest

intertidal marsh

shallow chan

Section B-B

high tide mean level pre-bottom high tide

mean level pre-bottom

marsh high tide mean level pre-bottom

ne gh s u o s e r ttohmne c n g o ha bou en bacye r tom ohfan bot n e bay ss of ne h g tidal creek ou m r ce tto deep channelhansalt island tidal creek bo marsh en bay of

marsh deep channel

salt marsh island

The archipelago increases the roughness of the bay bottom, which will help reduce the wave energy. It also provide various habitats due to the different depth.

deep channel

salt marsh

deep channel

salt marsh

deep channel

salt marsh

tidal creek

marsh deep channel

high tide mean level pre-bottom high tide

mean level pre-bottom

high tide mean level 07 pre-bottom

salt marsh island

e s es a a e n d o os i is im a b itim t o i r r r r c a t i m a e a t m n u s m ti th us s cri palideoliusm ium ia bfronedasa matriima a m itim a e o o l o s ri tima ar ia p ri a ar tim ornnarSuuatic cum Inu inerlilthmr trliust Lim cm r o m n f e ca c st pa liuarc iu ia Ju da Sp ari a m c PIunul eAllia tripo Simo orn uae us m rtim S nc pa L oc r in rc cc Aste Juese S a u s a P eS n m d o i b cosa ritim a s o i r riti r a t i m a a t m n s i h u t t m u cri pal olium ium ia fr da mari a m a e o l n a im i p a r Inu inell r tri Lim oco Su ncus art p c te rc Ju S uc As Sa P salt marsh island mudflat

salt marsh island

mudflat

y rg

it ab

intertidal

nnel

intertidal

nnel

h t % ase 1 ita < re b a in%c se h <1 rea inc tidal creek high low t a t i ab tidal creek high low salt marsh h % ase 1 < re inc salt marsh

intertidal tidal creek

nnel

high

low

e y av erg w n e e %, uat ave 3 n > te w a%t , ate >3 tenu gy at er n mudflat e ve a w mudflat , ate % >3 tenu at

deep channel high tide mean level pre-bottom

deep channel

s es

island + mudflat

ma ma

high tide mean level pre-bottom high A tide mean level pre-bottom

mudflat

salt marsh

hn ug e ss o r c e ce rfgahn n ha suou en bacye r face ohfan sur n e bay ss of ne h g ou ce r ce rfa an + island sumudflat h en bay of island + mudflat

e en

B B

deep channel

salt marsh island + mudflat

deep channel

salt marsh island + mudflat

deep channel

salt marsh island + mudflat C

Section C-C

C C

The slow slope of marsh islands enables a wide range of salt marsh plants to grow on the different elevation of islands.

C C

shallow channelintertidal marsh

salt marsh

residential

shallow channelintertidal marsh

salt marsh

residential 08

View of Fishing Deck The elevation of the wood deck is between the mean high tide level and low tide level, so when low tide, people can approach close to the water, even get down into the bay because of the shallow depth. There are some big rectangular spaces on the deck to allow plants grow through the deck, which can also separate the space. When high tide coming, the elevated path allows people close to the water. The plants that grow through the holes on the deck, reachable at low tide, will be intangible at the high tide.

a - Low Tide

a,b

b - High Tide

LOOP / before_after

credit: y,L yt,W

FRAMEWORK credit: yt,W

credit: MA,W

phase I: schools

RESPONSIVE LANDSCAPE

SENSING SYSTEM PHASES

DATASCAPE

LOCATION:

West Oakland, CA

TYPE:

Practical, Group of Three Partners: Yitian Wang, Matty A. Williams

DURATION:

15 weeks, 08 - 12/2013

INSTRUCTOR:

Bradley Cantrell, Justin Holzman phase II: main St. intersection

TECHNOLOGY INSTRUCTOR: Binyan Chen

C C ONTEXT

We propose a framework that will bring forward hidden information in order to create a virtual landscape. In order to unveil â&#x20AC;&#x2DC;hiddenâ&#x20AC;&#x2122; data, in real-time, we are creating a tool for use by various parties interested in environmental justice for West Oakland, CA. Community members are physically impacted by poor air quality, but have no way of understanding the real-time data, to a degree that enhances the ability to sense their environment. phase III: open spaces

L L OOP left-top

phase IV: secondary St. intersection

Large amounts of pollutants spread into W.O. and particulate matter makes up the largest concentration. Our research identified that 1) current data recording methods do not allow for data interaction at the community scale, and 2) citizens are unable to comprehend and react to environmental stressors. Overall, access to clear data communicating the quality of the air at any given site throughout W.O. is needed. The proposed framework allows the W.O. community to understand ambient environmental conditions, in real-time, and thereby make healthier commuting decisions.

F RAMEWORK left-bottom F

The framework contains five major components including a Sensing System, Data Platform, Communication Platform, Data Visualizations, and Infrastructural Implementation.

phase IV: intersection within community

SENSING SYSTEM right

This system archives environmental data from the Bay Area Air Quality Management District (BAAQMD) and air sensors dispersed throughout W.O. Sensors enable pollution concentrations (PM2.5, PM10, DPM, and Ozone) to be recorded in real-time, with geo-tagged coordinates. Weather attributes including temperature, humidity, wind, and photochemical smog. Each sensor has proximity of 250 feet. 12

TIMESCALES credit: y,L

DATA PLATFORM The data platform provides the definition of visualization and implementation. Xively, a customizable data hosting site, allows us to crowd-source data from our sensing system and compile this data at different time scales (left-top). The visualization of this data temporally allows for easier comparison, and a better understanding of fluctuating air quality.

Data-Color Range right-top

Within this platform, we have created an Air Quality Index (AQI) color range and a monochromatic color range. Utilizing Grasshopper parametric modeling to determine the monochromatic range, we created a relationship between X (real time data) and Y (time interval) coordinates based on the data provided by one central monitoring tower within West Oakland. In addition, we developed a bar graph of the AQI set by EPA, which indicates PM levels and their associated health risk.

Data-Color Proximity right-bottom

A voronoi definition in grasshopper defines the proximity of the colors converted from our monochromatic range. The mid-perpendicular of each line of connecting sensors intersects and forms cells of colors, which read as a heat map of environmental quality when blurred.

DATA-COLOR RANGE credit: yt,W

DATA-COLOR PROXIMITY credit: y,L yt,W

VISUALIZATION MODULES

Through three user interfaces and one plug-in for the Google Map API, this portion of our framework includes the communication platform and real-time visualization modules, including map interface, perspective interface, route choosing interface.

Communication Platform

It is in the form of a private web forum for sensor users and W.O. residents at large. In addition to providing a virtual space for interaction, and collecting information from social media site postings and hashtags to determine the ‘virtual’ mood with respect to air quality.

Map Interface

The map interface provides an overview of PM levels in West Oakland. The chart at the bottom shows pollution data at different timescales overlaid in a perspective interface. Interactive icons enable easy toggle between an individual sensor’s readings, identification of nearby emission sources, and health risk levels within the given proximity. The exported interface is shown in the example as a composite map displaying temperature, PM levels, health risk, direction, and emission sources simultaneously. left-top:

MAP INTERFACE credit: y,L yt,W

left-bottom:

EXPORT OF DATA credit: yt,W

right-top:

FOOTAGE OF INTERFACE credit: yt,W

right-bottom:

EXPORT OF MAP DATA credit: yt,W

see the animation of the map interface -credit: yt,W https://vimeo.com/81238689

>> pm2.5 /hr

>> pm2.5+10 /hr

> pm /month

>> pm /yr

>> sensor data

> emission source

>> health risk

>> download

start

>> PM data & health risk ranking in real time

>> PM data & health risk ranking in the past time

>> weather attributes and other information

Perspective Interface left

Route Choosing right

see the animation of the perspective interface -credit: yt,W https://vimeo.com/81238690 see the animation of the plug-in -credit: y,L https://vimeo.com/81238691

The second interface utilizes perspectives to illustrate PM levels and the associated health risk when people hold their phones out to scan the environment. The intensity of the color gradient overlaid on the interface, along with the health bar slider atop the interface, communicate the perceived health risk at that locale. Animated particle densities indicate fluctuating PM levels. Emission sources are highlighted, while other basic components further help people internalize their surroundings.

The third component is a route-choosing plug-in for Google Maps, utilizing gHowl, the Google Map API, and proposed sensing system, to make recommendation of which route to take is now considers routes with lower exposure to PM concentrations. Ideally the route choosing protocol should encourage healthier decision making abilities on behalf of W.O. residents.

START: search destination A

>> drop a pin on destination A

>> search destination B

>> get direction from A to B

>> get 3 routes with respective health risk rankings

>> choose a route (healthiest route)

>> get a closer and clear view of the chosen routes

>> mark the point with maximum PM value

>> mark the point with minimum PM value

left: perspective top INTERFACE credit: y,L yt,W

bottom FOOTAGE

credit: yt,W

right: plug-in top FOOTAGE credit: y,L

bottom PRINCIPLE

credit: yt,W

INFRASTRUCTURAL IMPLEMENTATION The implementation of our strategy encompasses a website, mobile app, site installation, and public infrastructure. The product of this framework, we hope, will result in real-time data accessible by designers, scientists, community members, artists, and policy makers.

Concept

The new BART armature uses strips of LED lights to illustrate regional and local PM levels at different time scales. The BART station forms a confluence of different user experiences, specifically with relation to passage time through, or by the station. User experience with this site can range from minutes to an entire day. As such, we

wanted to make the armature respond to this time sensitivity. Each individual strip is used to represent a one-minute change of both regional and local data. Local PM levels are translated as a certain color intensity within a monochromatic gradient. The length of each strip is determined by the regional PM level, every minute. Each minute throughout the day a new PM level reading is disseminated from the centerline of the station.

Plan

The plan shows the installation and infrastructure we propose; a new armature for the BART Station and a new lighting system for the streets of West Oakland.

Infrastructure

We have the opportunity to integrating sensing technology and light responsive systems into existing Oakland public infrastructure. Tube lights, attached to street lights at pedestrian intersections, can alert pedestrians of air quality at a distance. Ground lighting, embedded within street curbs, will connect to open spaces and intersections as well. The curbs themselves can indicate whether or not the current route is a healthy route, or, a harmful one. As air quality changes, the hue and brightness of the curb lighting change to reflect present air quality levels. By incorporating sensing technology into the raised pavement

markers on main streets and truck routs, we are able to educate drivers about PM levels. Small led face indicators at eye level will be continuously illuminated at residential intersections. During times of significant PM levels, this face indicates to viewers whether or not a face mask is recommended. Overall, our strategy takes advantage of existing infrastructure embedding data in a way that educates travelers about their environment, as they move through it.

left-top: PLAN credit: yt,W right-top: INFRASTRUCTURE credit: yt,W 20

BART STATIONâ&#x20AC;&#x2122;S FACADE

credit: y,L

see the animation of the facade -credity: yt,W http://vimeo.com/81239000 see the 3D model -credity: yt,W y,L https://sketchfab.com/show/cb415737587e412b8a1718c9654094a0 22

BART STATION’S INTERIOR credit: y,L

STRIP SAMPLE MODEL credit: y,L instructor: by,C

WATER INFRASTRUCTURE

Haiti

Location:

City of Pedernales

Dominican Republic

Type:

Practical, Group of Two

Duration:

15 weeks, 08 - 12/2012

Resort 1

Instructor:

Wes Michaels

400 units urban area, waterfront

ile

Context The site, a wharf, used to be a marina exporting limestones from the nearby mine which is planning to close in the near future. After researching the wharfâ&#x20AC;&#x2122;s positions in the country and regional scale, and its own advantages, some great potential stood out. The main concept is to make maximum use of the existing conditions to create the landscape benefiting both the environment, social economy and the life of local people.

ity

Gas Pump

Loading Cranes Site

Background Information

1.5 m

Mine

Resort 2

Cabo Rojo

400 units high point, cliff

4 mile

+ Pedernales City /pop. 30,000 + designed resorts /total 1,200 units + only entrance to the national park + total area: 25 acres /450ft x 2,000ft

iles

Water Feature

Resort 3

400 units unique cliff

El Partio

Jaragua National Park

-Entrance

RECLAIMED LANDSCAPE

Opportunities Research Haiti

Port-au-Prince

Dominican Republic Jimani

Jacmel

Santo Domingo Barahona

53.97 m

Pedernales

2hrs ride 3hrs ride 4hrs ride waterways

74.77 mi 1

4 0.

Country Scale /Joint Tourism Europe and the United States are the major sources of visitors to Dominican Republic and Haiti, whose tourist cities only have poor road connections. Developing new waterways which stops at Pedernales before crossing the border have a great potential to make the entire trip safer and more beautiful than road trip because of the Caribbean Sea.

Treat Discharge

Collect

Supply

freshwater black /gray water suppliers/ consumers water treatment

hotel

Sources of Grey/black Water

mine

Regional Scale /Infrastructure The anticipated resorts and the reclaimed mine will have a strong demand for water treatment and supply, while the region is lack of infrastructure concerning water and power. The site is an ideal location to build water treatment facilities which can solve the problems and make the tourism development more sustainable.

Usages of Freshwater

hotel

deep channel existing structures panoramic views

Site Scale /Views and Values The extended jetty provides panoramic views out to the sea and Cabo Rojo. The large disturbed area is suitable for big scale constructions which will impact the natural system if built in surrounding areas.

view to Cabo Rojo 26

Customs Docks

Country Scale Strategies

Regional Scale

Based on the opportunities found in the three scales, six functions are decided to layout on the site. The location of each function fits the site condition respectively.

Infrastructure Restaurants

Site Scale

Stage Local Market

1 2 3 4

Custom Office Boat Dock Fisherman’s Plaza Retail Market

Master Plan 27

5 6 7 8

Clubhouse Entrance Plaza Boat Taxi Drop-off Stage

9 Restaurant 10 Viewing Plaza 11 Bar & Plaza 12 Board Walk

13 Waterfall 14 Knolls 15 Car/Bus Drop-off 16 Bus Parking Lot

50’

100’

200’

300’

700’

a b c d

Grit & Screen Primary Clarifier Pumps DAF Thickener

e f g h

Fermenter Digesters Heating Building Utility Building

i Control Room j Secondary Clarifier k Vegetated Bioreactor l Solar Bank /Parking Lot

m Boat Launch n Gas Dock o Service Center p Gas Station q Gas Silos 28 04

Reclaimed Water

Analysis Infrastructure Separating the beginning processes (dirty water) and the terminating processes (clean water) from the tourists was the main concern. Given that most will come by boat, the initial facilities are placed on the east end of the site where there is not much traffic. The final processes near the festival space and stage on the other end are reached by an open stream through the spine of the site. After the water is cleansed, it will either exit via a waterfall on the south side or be sent to the mine for irrigation.

W-E Section

Restaurants & Stage 29

Plaza

Bar

Bioreactor

Slope

Secondary Clarifiers

Rest Lawn

Retail Marke

Grid & Screen Primary Clarifiers 4 hrs.

Black Water

Bioreactor (BNR)

9 hrs.

Pumps

Secondary Clarifiers

effluent

micro-organism

sludge

Heating Building

Control Room Utility Building Solar Plant

Digester

20 ds.

Thickener Fermenters thickened sludge

Waste Water Treatment Facility

Primary Clarifier

Solar Parking Lot 30

Analysis N-S Section (A-A Section) Given the process that water should exchange several times between Bioreactors and Secondary Clarifiers, which would cost about 9 hours, the two ponds were connected in the form that Bioreactors were encircled by Secondary Clarifiers. The bottom elevation of those ponds were different - the center the lowest while the periphery the highest - but with small value. The walls which separated the ponds had holes in small radius along the bottom side. Those two detail designs enable the water to flow from higher to lower ponds in a very low speed.

Board Walk Bar 31

Seconda

ary Clarifiers

Circulation by Land and Sea Pass-by Major Road Main Road

Pedestrian Path Water Access

Road for WWTF Drop-off (Vehicle on land)

Entrance Plaza (Land Access) Entrance Plaza (Water Access)

Parking Lot A

Boat Taxi Drop-off 32

04 Other Works A

INTERNSHIP @NBBJ Type:

Master Plan Rendering, Diagram Rendering

Duration:

3 months, 06 - 08/2013

Project Team:

Shantou Urban Design

Context It is an urban design competition of Shantou New Districts which are three reclaimed islands. The idea is to connect the new development area with the historical city center through coherent urban fabric, green corridors and new transportation system; to adopt â&#x20AC;&#x2DC;smart growthâ&#x20AC;&#x2122; policy to make fewer impacts on the environment; and to emphasize human experiences.

Urb

Are

orr

Sh o

rel in

r -S ho

rov eP

res e

left: Axions of Shoreline Concept right: Framework Render 33

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tio

ido

rel in

cep

Sh o

rel in

cep

Urban Area

CBD Corridor Mangrove Preservation

Context The plan is to build a library that is accompanied with a parking lot, an outdoor reading space, a childrenâ&#x20AC;&#x2122;s playground, a cafe and bike trail. There are several huge live oaks encircle a flat land in the shade of their big crown. The side facing the main street has a slope that is a little bit steep, which is a problem when making grading solution.

Site Plan 35

LIBRARY SITE DESIGN Type:

Site Plan and Grading

Duration:

6 weeks, 10 - 12/2012

Instructor:

Bruce Sharky

Grading Plan 36

04 Other Works B

Horizontal & Vertical Plan of Bike Trail

Horizontal Alignment of Bike Trail 1:25

Vertical Alignment of Bike Trail horizontal scale 1:30 vertical scale 1:7.5

04 Other Works C

LSU COURTYARD DESIGN

CONCRETE BENCH

VEGES-STRIP ELEVATION

p41

1”=1’-0”

Type:

Site Plan and Detail Design

Duration:

5 weeks, 03 - 14/2013

Instructor:

Wes Michaels

Context The plan is to redesign the small and long space into a court yard that can provide students both gathering spaces and passing by pathways. The challenge here is to offer a sensible solution to the drainage problem on the site especially during the heavy rain day when rain water will flush through the site.

Site Plan p41

p41

p42

p41

FINISH GRADE

1”=2’-0”

View to the South

p42

CORTEN PLATE EDGING 1”=1’-0”

04 Other Works D

GARDEN DESIGN

5 6

Type:

Chinese Traditional Garden Design

Duration:

6 weeks, 04 - 06/2012

Instructor:

Daixin, Dai

The garden is not only for relaxation and recreation but for meditation as well. An ideal 1 A setting for meditation should be featured by tranquility, artlessness and comfort. The garden is located on a mountanside, surrounded by bamboos and with a spring running through. As to stand out the atmosphere of meditation, the first half of the garden tries to draw a picture of a secular and material world, which provides a contrast for the unearthly and spiritual world built in the later half. The running spring with different shapes leads people to the top, making a connection between the two worlds.

ANALYSIS Type:

Slope Map

GIS Analysis, Rhino Terrian, Photoshop, Illustrator

Duration:

15 weeks, 08 12/2013

Instructor:

Forbes Lipschitz

DEM

Aspect Map Population Heat Map

Urban Proximity

Road Heat Map

Rhino Terrian

Service Area & Network Analysis

Ecological Buffer & Overlays

Road Density Grid Map

04 Other Works E

YL- RESUME

YI LIU! Student ASLA, MLA, LSU

OBJECTIVE!

!! ! EDUCATION!

begin from July 7, 2014

May 2014 June 2013

! !! !

June 2012

EXPERIENCE!

June 2013 - August 2013 Columbus, OH

!! !! !! !!

July 2011 - August 2011 Shanghai, China

July 2012 Pingfeng village (extremely poor), Ningxia Province, China

!! SKILLS! !! ! !

LANGUAGE! REFERENCE

Ad: E : T : L :

1635 177th Ave. NE, Bellevue, WA 98008 yliu92@tigers.lsu.edu (225)276-2639 https://www.linkedin.com/pub/yi-liu/66/975/367

Seeking an entry level, full-time position as a landscape designer in an active, innovative, mutual promotive and supportive ﬁrm where I can be engaged in with my passion and ideas.!

! !

Robert Reich School of Landscape Architecture, Louisiana State University! Master of Landscape Architecture! - Third Prize of RRSLA Design Week!

! !!

Collage of Architecture and Urban Planning, Tongji University, China! Bachelor of Engineering in Landscape Architecture!

NBBJ | Shantou Urban Design Competition, Guangdong Province, China! Intern Landscape Designer! - Plan developing and rendering / AutoCAD, Illustrator - Diagram and collage making / SketchUp, Photoshop - Weekly work organizing and summarizing / Indesign - English-Chinese translation

Pandscape | Park Design, Qingdao, Shandong Province, China! Intern Landscape Designer! - Site visit and research - Chief designer of master plan / Hand-drawing, AutoCAD - Plan and section rendering / Photoshop

Xiaoshu (Little Tree) Non-proﬁt Organization Volunteer!

- Helped to design the website for the organization - Brought dictionary and stationary to the middle school’s students

Adobe Photoshop, Illustrator, InDesign, AutoCAD, Google SketchUp, Artlantis, ArcGIS, Rhino Terrain, Grasshopper, MS Ofﬁce! Physical model skill, Hand-drawing! English (Professional working proﬁciency)! Chinese (Native)!

Bradley Cantrell Director & Associate Professor, LSU! (225)614-4080, cantrell@lsu.edu

Bruce G. Sharky FASLA & PLA & Professor, LSU (225)578-1441, bshark2@lsu.edu

Sasan Norouzi Architect & Urban Design, NBBJ! SNorouzi@nbbj.com

Yi Liu

Email: yliu92@lsu.edu Telephone: 225-276-2639 Address: #B6, 1855 Brightside Dr. Baton Rouge, LA 70820