Jieru He Hedy-Portfolio-2018

MY MANIFESTO TOWARDS BETTER CITY, INFRASTRUCTURE & ENVIRONMENT

IN LANDSCAPE Jieru He (Hedy) Selected Work from 2012-2018 Graduate of Master in Landscape Architecture & Regional Planning, 2018 PennDesign School, University of Pennsylvania

Reservoir

River

Terrain

City

Island Beach Park, New Jersey Hand Sketch 501 Ecology Workshop

IN LANDSCAPE IS...

URBAN DESIGN

1-14

SEEDS OF LEARNING The University Campus Planning & Design of Rio de Janeiro - Studio 701

2017 Fall

3-6

PORT SLIPS Pilot Plots - Interim Urbanisms in the Port of LA - Studio 602

2017 Spring

7-10

GROUND VARYING OVER TIME Groundwork - South Philadelphia Riverfront Design - Studio 502

2016 Spring

11-14

LANDSCAPE IN LAYERS Imagination & Craft - Studio 501 & Garden Design Competition

2018 Fall

15-16

WATER INFRASTRUCTURE

17-34

DRAMA ALONG THE FLOODWAY Green Stimuli - Watershed Planning & Design of The Slate Belt - Studio 601

2016 Fall

19-24

IN-BETWEEN WATERS/ INTERCEPTING WETNESS Liberating & Inventing Wetness in Mining Landscapes of Western Ghats, India & Shanxi Province, China -Overview - Independent Studio 702

2017 Spring - 2018 Spring

25-34

REGIONAL PLANNING

35-42

THE TRIBORO CORRIDOR Fourth Regional Plan of Regional Plan Association (RPA)

2017 Summer * Professional Work

37-40

INTERWEAVE THE CITY & THE RIVER E’erguna Landscape Planning

2013 * Professional Work

41-42

PROFESSIONAL WORK

43-48

TECHNIQUES

49-54

PERSONAL EXPERIENCE

55-58

AWARD: EXHIBITED AT LES TURBULENCES, FRAC CENTRE IN ORLEANS LINK: http://www.design.upenn.edu/news/post/penndesign-video-workshop-fresh-look-paris-landmarks

21c. POSTCARD PARIS RHYTHMANALYSIS OF THE TERRASSE [JE SUIS EN]

Course: Arch Study Abroad Program from May. - Jul.2015 Location: Sidewalk on Place Du Carrousel Defining Ground & Underground, In-between Pyramid Louvre & Tuileries Garden, Paris, France Type: Team Work with Alyssa Appel & Mattew Paul Price Instructor: Annette Fierro (Associate Professor of Architecture & Associate Chair, PennDesign)

1

IN LANDSCAPE IS...

URBAN DESIGN

I.

URBAN DESIGN

II.

WATER INFRASTRUCTURE

III.

REGIONAL PLANNING

IV.

PROFESSIONAL WORK

V.

TECHNIQUES

VI.

PERSONAL EXPERIENCE 2

AWARD: PENNDESIGN PUBLICATION PROCESS 22

PROJETO SEMENTE

URBAN LANDSCAPES OF LEARNING OF THE UNIVERSITY CAMPUS IN RIO DE JANEIRO

Course: Larp Studio 701 from Aug. - Dec.2017 Location: Rio de Janeiro, Brazil Type: Team Work with Allison Koll & Rivka Weinstock Instructors: Maria Altagracia Villalobos & Oscar Grauer

L

L

Materials

Education Type

I

S

N

S

Enclosure

F

N

Scale

Hardscape

F

Formal

Full Shelter

L

Large Scale

Hard + Soft

N

Non-Formal

Partial Enclosure

M

Medium Scale

Softscape

I

Informal

Open

S

Small Scale

INTRODUCE QUALITY OF PUBLIC SPACE IN RIO DOWNTOWN TO CAMPUS DESIGN

URBAN DESIGN PROJECT 1

I

S

M

REDEFINE RIO COASTLINE BY CONNECTING CAMPUS WITH DOWNTOWN AREA Seed Learning Experiences in the City Scale & Build Minimal Transportation Connections

URBAN DESIGN PROJECT 1

Supports different sized groups, informal to formal learning structure including workshops, meeting spaces, organized play, encounter + recreation.

TYPOLOGY OF PEDAGOGICAL & LEARNING SPACE

2.5

m

2.5

m

Small Group - Enclosed Learning Supports small groups, informal to formal learning structure including classes, workshops, meeting spaces, reading, encounter .

6m

6m

6m

7.

7.

7.

Large Group-Public Space Learning Supports different sized groups, informal to formal learning structure including workshops, meeting spaces, organized play, encounter + recreation. 7.6

7.6

m

m

1.2

m

1.2

1.2

m

1.2

7.6

m

m

1.2 m

m

Individual Learning Supports learning through individual experiences, including bicycle riding, small reading spaces, viewing art and and ecountering the other. Large Group-Public Space Learning Supports different sized groups, informal to formal learning structure including workshops, meeting spaces, organized play, encounter + recreation.

Corresponding to cumulative, assimilative, accommodative & transformative pedagogical programs, placemaking should be of specific dimensions and experience.

SPATIO-PEDAGOGICAL PALETTE 2. 5m 2. 5m

Small Group - Enclosed Learning Supports small groups, informal to formal learning structure including classes, workshops, meeting spaces, reading, encounter . 2.5

m

2.5

m

Small Group - Enclosed Learning Supports small groups, informal to formal learning structure including classes, workshops, meeting spaces, reading, encounter .

1.2

m

2m

2m

m

1.

1.

1.2

1.2

m

Individual Learning 1.2

m

1.2

m

1.2

m

1.2

m

1.2

Supports learning through individual experiences, including bicycle riding, small reading spaces, viewing art and and ecountering the other.

m

Individual Learning Supports learning through individual experiences, including bicycle riding, small reading spaces, viewing art and and ecountering the other.

SPATIO-PEDAGOGICAL PALETTE

SPATIO-PEDAGOGICAL PALETTE

Room 3: Architectural Building

1

2

URBAN DESIGN PROJECT 1

SEED ROOMS WITH LEARNING & ECOLOGICAL FUNCTION ON THE CAMPUS SCALE

Dune Mangrove Extension

17

16

1

Rooms &Connections

14

13 15 12 10

18

2

11

9

8 7

3 6

4 5

1 3

2

4

Main Road Biking Lane Boardwalk Natural Trail

N 100

3

400

800m

4

7.6m

1.2m

7.6m 1.2m

MAIN ROAD

1.2m

BIKING LANE BOARDWALK NATURAL TRAIL

DUNE AREA

MANGROVE EXTENSION

ARCHIPELAGO

NETWORKS

URBAN DESIGN PROJECT 1

ROOMS OF LAYERS

TRANSIT CENTER

CLASSROOM

EXPERIMENT GARDEN

WATER FUNCTIONAL

PORT SLIPS

PILOT PLOTS - INTERIM URBANISMS IN THE PORT OF LA

Course: Larp Studio 602 from Jan. - May.2017 Location: Los Angeles Type: Team Work with Ya Chen (the drawings below are done by Jieru He individually) Instructor: Christopher Marcinkoski (Associate Professor, Landscape Architecture Department)

SLIP 2

TRANSFORMED PARCEL PLAN

SLIP I: TRANSFORM CITY PARCEL AS THE FIRST MOVE Development Strategy in Downtown Area

RCEL PLAN

Administration CommunityClub Blender Enterprises Llc _Restaurant Apratments Omninet San Pedro Llc 140 160 West 6Th Street Llc May Enterprises Llc

Administration Community Club

Blender Enterprises Llc_Restaurant

Apartments Omninet San Pedro Llc

140 160 West 6th Street Llc May Enterprises Llc

B’

Hotel

Commercial

Civic

Civic

th

w6

Office

Courtyard

Living

Shoppping

Culture

Existing Gibson Park

th

w5

More Retails

scale 1”=100’

A Co

Blender En

Omninet S

140 160 West 6 May En

URBAN DESIGN PROJECT 2

sh

arb

or

st.

SLIP II: DIVERSIFY LANDUSE & ACTIVATE THE PORT BY TERRACED LANDSCAPE LONG TERM

SHORT TERM

URBAN DESIGN PROJECT 2

COLLECT MULTIPLYING EFFECTS OF INCOPORATING OPEN SPACE & BUILDINGS

400’ 800’

1600’

URBAN DESIGN PROJECT 2

ACTIVATE THE INTERFACE BETWEEN PUBLIC SPACE & BUILDINGS

Section A-A’

Section B-B’

Section C-C’

Section D-D’

Section E-E’

50’

100’

200’

URBAN DESIGN PROJECT 2

AWARD: PENNDESIGN PUBLICATION PROCESS 20

GROUND VARYING OVER TIME GROUNDWORK - SOUTH PHILADELPHIA RIVERFRONT DESIGN Course: Larp Studio 502 from Feb. - Apr.2016 Location: Delaware Riverfront, South Philadelphia Scale: 37 ha Type: Individual Work Instructor: Keith VanDerSys (Senior Lecturer, Landscape Department, PennDesign)

REINTERPRET INDUSTRIAL SITE HISTORY BY GREEN INFRASTRUCTURE

URBAN DESIGN PROJECT 3

gy

Interact

Performance Reed St.

water from site

FROM SITELESS PATTERN EXPERIMENT TO TOPOGRAPHIC MATRIX by decay and grow 14

FLIP EXPERIENCE

15

16

LINES INTO UNOVERLAPPED ZONE

17

lines 4

water from neighbour

As Group: Enhanced by Topo

Sunken 3 Raingarden

18

19

20

21

Dickinson St.

Rainwater Garden With Z Shape Path 22

23

As Individuals: Decays by Multiple Vegetation or Materials

lines 5

Performance Reed St.

24

25

water from site

FLIP EXPERIENCE

platform on the marshland

27

stormwater from site

Decays for Bloosom & Falling Season

Engage River

lines 6

26

lower land submerged by disappearing lines

introduce tidal into site

water from neighbour

LINES INTO OVERLAPPED ZONE

TARGET GROUP

Delaware River Trail

marshland rebuild area

Children-Play & Education

As Group: Dickinson St.

TOPOGRAPHICAL Blurred by Topo inMATRIX Rainy Days STRATEGY

Marshland Restoration

Rainwater Garden With Z Shape Path

Zone

Zones

Interact

Neighbour-Gathering

Elevation Highest

Middle

Lowest

Water Index Ground

Division stormwater from site

introduce tidal into site

Sunken 2 Delaware Marshalnd River Trail

LINES INTO UNOVERLAPPED ZONE Sunken 3 Raingarden

20% Import

60% Enlarge Boundary

marshland rebuild area

90% Block

Children-Play & Education

Neighbour-Gathering

Line

BI-ECOLOGICAL stormwater Ecological from Legibilityneighbour

Marshland Restoration As Individuals: Distinct by Featured One Vegetation or Material Raise

Import Public

Buffer Sea Rise

Water Channel

Vegetation

Delaware River Trail Thickness 3'

6'

12'

Character

Blur

Break

Reed St. LINES INTO OVERLAPPED ZONE

Water Bed

Swale

Cascade

20% Move

45% Pour

Stop

sea level buffer with water index

Ex

Temporal Change

Marshland Area 2: Stormwater & Tidal Surging, Lines Blurring

BI-ECOLO

Ecological Performance 2% Soothe

C

Water Index Area1: Water as Ever-exisitng Lines 24'

stormw Ec

Raingarden 3: Two Stormwaters Surging, Lines Blurring

Slope for Circulation

TARGET G

N

stormwater Ecological from Legibilityneighbour Form Surface

storm

As Group: Blurred by Topo in Rainy Days

Component

BI-ECOLOGICAL

Decays for Bloosom & Falling Season

Sea Rise Buffer With Water Playground

Explorer & Scientist-Analyze

Continuous

Engage River

Ecological Performance

Lines

Path

As Individuals: Decays by Multiple Vegetation or Materials

Delaware River Trail

Differentiate Function

Aspect

Press

As Group: sea level buffer with water index Enhanced by Topo

Enhance Boundary

Cut for Marshland Build

Edge & Surface

TARGET GROUP

Reed S

FLIP EXPE

Explorer & Scientist-Analyze

Overlap & Contrast

platform on the marshland Sunken 1

2% Traverse

Perfo

by decay and grow

lower land submerged by disappearing lines

Juxtapose

As Individuals: Distinct by Featured One Vegetation or Material

Reed St.

Sea Rise Buffer With Water Playground

Hardscape Area: Material Contrasted

URBAN DESIGN PROJECT 3

Ec

egy

CREATE EMERGENT LANDSCAPE DESIGN

1

1. sea rise buffer forest 2. overlooking piers 3. parking lot 4. water index playground 5. welcoming plaza 6. trail playground 7. rest plaza 8. bird attracting line 9. tree alee woods 10. sloping lawn 11. grass 12. meadow ground 13. meadow decorated pier 14. blooming underlayer 15. interactive raingarden 16. stormwater & tidal garden 17. tidal indication line 18. rainwater garden 19. water surface gliding area 20. interactive marshland area 21. submerged marshland pier 22. neighbour garden 23. gathering lawn 24. forest 25. marshalnd protection area 26. platform 27. small shading space

2

line lines 11 line lines 22 3

4

Scale 1"=250'

20 40

80

120

200

N

Line lines 3 3 5

line 4

9

10

14

15

11

6

7

12

13

8

16

17

lines 4

22

18

19

23

24

20

21

25

26

line lines 55

27

line lines 66

TOPOGRAPHICAL MATRIX STRATEGY

Zone

Zones

Interact

Performance Reed St.

water from site

by decay and grow FLIP EXPERIENCE Elevation Middle

Highest

LINES INTO UNOVERLAPPED ZONE

Overlap & Contrast

Lowest

Sunken 1 Water Index Ground

Sunken 2 Marshalnd

Sunken 3 Raingarden

As Group: Enhanced by Topo

water from neighbour

Division Enhance Boundary

Cut for Marshland Build

Dickinson St.

Rainwater Garden With Z Shape Path

Edge & Surface 2% Traverse

20% Import

60% Enlarge Boundary

As Individuals: Decays by Multiple Vegetation or Materials

90% Block

lower land submerged by disappearing lines

Differentiate Function

Aspect Press

Raise

Lines

Line

platform on the marshland

Import Public

Buffer Sea Rise

Engage River

Decays for Bloosom & Falling Season

URBAN DESIGN PROJECTLINES 3 INTO OVERLAPPED ZONE

stormwater from site

TARGET GROUP

Path

Water Channel

Vegetation

marshland rebuild area

Delaware River Trail

Children-Play & Education

As Group: Blurred by Topo in Rainy Days

Component

introduce tidal into site

Marshland Restoration Neighbour-Gathering

CONTOUR MODEL AS PRECISE AS 1 FEET

URBAN DESIGN PROJECT 3

AWARD: PENNDESIGN PUBLICATION PROCESS 20

LANDSCAPE IN LAYERS

IMAGINATION & CRAFT - GARDEN DESIGN COMPETITION

VOCABULARY OF LANDSCAPE & OVERLAY LAYERS In the first semester at Penn, I have learned the vocabulary of landscape such as materials, spatial sequence design & histories embedded and overlaid them to create a memorable design.

Reintepret History for Modern Use and Future Ecology

Water Layer as A Consistant Driver Groundwater, the source of the existing site stream, is extended to be a longer main stream throughout the design. Stormwater, separated from original urban sewage system, can be purified by vegetation layer and be rainy day’s scenery, compared to constant groundwater scenery.

purified water into Schukill River

underneath stormwater delivery

- existing stormwater inlet - stormwater system using existing inlets

- close to main stream by stairs - groundwater from upperland creating waterfall on wall surface

water terrace - location same as the source of e

ramp going into the sunken plaza, with eye level water surface pond

gradient platform level changes with ramps

main path along the water terrace, with second

- the ending point of existing site stream being transformed into sunken water plaza - stormwater of inlets from industrial history, being guided into ponds

- historical wall reintepreted as a wall with waterfall on its surface - historical wall on the upperland, creating small garden with same water geometry, as a clue for lowerland waterfall

- water terrace - location same as the source o - historic wall and stairs for structure use bf wat

Path Layer Creating Diverse Experiences Path layer, consisted of ramps, slopes, stairs and platform, creates various space and perceptual experiences by height level differences and distance changes.

follow sunken ramp to the platform on the river surface, framing space by sides’ wall

introduce more users into the site by redirecting former pedestrian

Reinterpret Historical Elements - Historical infrastructure reuse - Borrow historical geometry - Make least impact on existing site

hard edge of Schukill River being broke down into platform close to water

Reorganize Materials & Trees - Materials of the existing site reorganized to have a sequential and consistent repeat - Trees selected by canopy layer and ground layer, to frame the space needed

Sections & Plans Zoomed In

moment 5

moment 4

moment 3

section 8

section 9

section 10

section 11

section 12

section 13

section 14

URBAN DESIGN PROJECT 4 & 5

moment 2

Course: Larp Studio 501 from Dec. - Sep.2015 Location: Glendining Rock Garden by Schukill River, Philadelphia Scale: 6 ha Type: Individual Work Instructor: Nicholas Pevzner (Lecturer, Landscape Department, PennDesign)

URBAN DESIGN PROJECT 4 & 5

LINK: https://vimeo.com/248661759

The Mines

Infrastructure

The Terrain

The Mind

Extract &Fill

MINESINDIVIDUAL ANDESSAY THE MIND FILM Course: Fine Arts School Elective “On Thoughts Occasioned by” as A Part of The Project “In-between Waters/ Intercepting Wetness” Location: Bangalore, Kudremukh, Mangalore & Goa, Western Ghats, India Instructors: Timothy Corrigan (Professor of English, Cinema Studies, and History of Art, Upenn) & David Hartt (Assistant Professor of Fine Arts, Upenn)

17

IN LANDSCAPE IS...

WATER INFRASTRUCTURE

I.

URBAN DESIGN

II.

WATER INFRASTRUCTURE

III.

REGIONAL PLANNING

IV.

PROFESSIONAL WORK

V.

TECHNIQUES

VI.

PERSONAL EXPERIENCE 18

AWARDS: PENNDESIGN PUBLICATION PROCESS 21; WORK SELECTED ON THE EXHIBITION WITH LEHIGH VALLEY PLANNING COMMISSION http://www.lehighvalleylive.com/slate-belt/index.ssf/2017/05/design_students_focus_on_futur.html#incart_river_home

DRAMA ALONG THE FLOODWAY GREEN STIMULI - WATERSHED PLANNING & DESIGN OF THE SLATE BELT Course: Larp Studio 601 from Sep. - Dec.2016 Location: Bangor, Slate Belt, Lehigh Valley, Pennsylvania Type: Individual Work Instructor: Ellen Neises (Adjunct Associate Professor; Executive Director, PennPraxis)

P

IMP SF GWL^GWSCON ET GWWGW-GWRQGWW EXP Chart Title

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24

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2.5

50

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18

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43

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3

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4

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30

ski industry&population growth 0.15

46

Pocono Creek

0.2

SWD

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51

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3

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Martins Creek

44.5

quarry dewatering quarry dewatering 64

Wissahickon Creek

East Branch Brandywine Creek

SWWSWEXP

Percent of streamflow as base flow

1.8

50

1.6

49

1.4

48

1.2

44

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Greenwood Branch Rancocas Creek

Cooper River

50

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DECREASING GROUNDWATER QUANTITY & QUALITY OF THE DELAWARE WATERSHED Analyze The Water Budget of The Creeks along The Delaware Watershed

WATER INFRASTRUCTURE PROJECT 1

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51

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1

PROCESS OF TRANSFORMING FLOODS INTO LANDSCAPE DRAMA

Manage Runoff & Design Landscape Programs (Theatres as Drama) According to Rainfall Intensities

Common Rainfall 3-3.5’

Excessive Rainfall -6’

volumn control

rate control

WATERWAY Direct Human Flow

RUNOFF From Dump & City

BASIN & POND

QUARRY LAKE

Aquifer Underneath

WATERWAY

Drama Exposed I

Drama Exposed II

Input is Cleaned before Running into the Aquifer

BASIN & POND Drama Exposed III Drama Exposed IV

Public Space

Flood Experience

Future Irrigation Source

QUARRY LAKE Flood Experience

VEGETATION

Flood Experience

Succesion Allowed

recharge groundwater

Dry Season COLLECTED WATER

CREEK

Discharge to Martins Creek

VEGETATION Irrigation

martins creek

bold way

Drama II:Cascade Theatre

PROGRAMS

Pennsylvania cut earth Ave.(filled)

existing secion line

high box seats circulation

Runoff from the Dump

Runoff from Town

Reorient Runoff Flow

Creek Flow

Bushly Meadow Creek Creek Flow

WATER INFRASTRUCTURE PROJECT 1

low circulation pattern overlooking

Life-style Strategy

Rating Point of Interest Area

Watershed-Level Related to Downstream Impacts Creating More Landscape Opportunities than At-Site Runoff Control

Overlapping Related Layers to Get Pilot Seven Sites

Discharge

Discharge Discharge

Life-style Strategy Rating Point of Interest Area BANGOR QUARRY ANALYZED AS THE POINT OF INTEREST ON WATERSHED-LEVEL MANAGEMENT & Bangor Has the Most HeaviestSTORMWATER Weight to Intervene Flood Issue life-style stormwater control Up-subwatershed Up-subwatershed

after control decreased V

before control total volumn watershed B after control decreased V watershed A-urbanized at-site control watershed B watershed-level control

Discharge

before control total volumn

At-Site Runoff Control

Discharge

Time

Discharge

Discharge Discharge

Watershed-Level Related to Downstream Impacts Different Stormwater Management Strategies According to Specific Location & Rainfall Stage Creating More Landscape Opportunities than developed condition

developed condition

“controlled” developed condition

Time

Time

“controlled”existing developed condition condition

watershed A-urbanized at-site control

Time

watershed-level control

Time Time

peak time

Time

Time

existing condition

Time

Time peak time condition: - individual drainage area peaks much later than the point of interest peak - does not contribute to the point of interest

3

Discharge

Discharge

strategy: - for cost-effectiveness, no control approach provided that the increased peak can be safely transported to the main runoff channel Pre-Development Hydrograph

Recommended Post-Development Pre-Development Hydrograph

Discharge

Discharge

strategy: condition:- for cost-effectiveness, no control approach provided that the increased peak can be safely trans- individual drainage area peaks much later than the point of interest peak ported to the main runoff channel - does not contribute to the point of interest

3

total hydrograph at confluence A-B

3

total hydrograph at confluence A-B

release-unnecessary

Recommended Post-Development

Time

control rising limb

Time

watershed A

Time Time

Time

Up2-subwatershed Up2-subwatershed

Discharge

Discharge

2

1

1

Landscape Experience Education Monitor Mixed Use including Changing Residential Density Landscape Experience Artery Education

1!!! 1!!!

detention

Water Management

Water Management Landscape Experience Education

Discharge

-2 -2

detention

strategy: condition:- detension needed to be provided equals to at-site control - release rate =100% - the time to peak of the drainage area quals the time to peak of point of Time interest

Discharge

Time

Time

Time

-3

free flood

Landscape Experience Mixed Use including Changing Residential Density Artery

Mixed Use including Changing Residential Density Artery

Discharge

Discharge

Discharge

Discharge

Discharge Discharge

Discharge

Landscape Experience Discharge

Discharge Discharge

strategy: - at-site control in not enough-still causing increase in peak flow at point of interest - only through this increased level of control would point of interest peak flows not be exceeded

Time

-3

condition: - peaks early(before the point of interst peak) - contribute to the point of interest peak strategy: condition:- at-site control in not enough-still causing increase in peak flow at point of interest - only through increased level of control would point of interest peak flows not be - peaks early(before thethis point of interst peak) exceeded - contribute to the point of interest peak

-2

Monitor Mixed Use including Changing Residential Density Artery

Time

Time

-2

Education Monitor Water Management Mixed Use including Changing Residential Density EducationArtery

Time

Time

Time

Water Management

Time

Time

Time

Monitor Mixed Use including Changing Residential Density Artery

Discharge

Time

Discharge

Discharge Discharge

1

Discharge

Discharge Discharge

Discharge Discharge

1

strategy: - detension needed to be provided equals to at-site control

Mixed Use including Changing Residential Density Landscape Experience Artery Water Management

Water Management Mixed Use including Changing Residential Density Landscape Experience Artery Monitor Education Mixed Use including Changing Residential Density Water Management Artery

Time

condition: - release rate =100% - the time to peak of the drainage area quals the time to peak of point of interest

Time

Time

Time

Time Time

Time

Time Time Time

Time

free flood

Discharge

Discharge

Discharge

Discharge

Time

Discharge

Discharge

Discharge

-3

-3 Landscape Experience

strategy: - “0” release rate control - allowing the drainage area to peak higher and recede in an uncontroled fashion in a more effective approach at the point of interest

Discharge

Discharge

-3

Discharge

Time

Time

condition: - peaks very early(before the point of interst peak) - not contribute to the point of interest peak strategy: condition:- “0” release rate control - allowing the drainage areaoftointerst peak higher - peaks very early(before the point peak) and recede in an uncontroled fashion a more effective approach at the point of interest - not contribute to the in point of interest peak

-3

Monitor Mixed Use including Changing Residential Density Landscape Experience Artery Monitor Mixed Use including Changing Residential Density Artery

Time

Time

Time

Time Time

Time

Mixed Use including Changing Residential Density Artery

Mixed Use including Changing Residential Density Landscape Experience Artery

zone ae

Time

Monitor

Mixed Use including Changing Residential Density Landscape Experience Artery

zone ae

Discharge

Middle-subwatershed Middle-subwatershed

2 1

Water Management

2

Time

Down2-subwatershed Down2-subwatershed

2

Landscape Experience

strategy: -provide detension for the drainage area designed to slow down the rise of the hydrograph to the pre-development level, which means control of rising limb to pre-development condition - control to pre-development peak

Time

Time

Time

Discharge

Time

Discharge

point of interest-subwatershed point of interest-subwatershed

3

condition:strategy: -provide detension for later the drainage to slow - individual drainage area peaks than thearea pointdesigned of interest peakdown the rise of the hydrograph to the pre-development level, which means control of rising limbarea to pre-development condition - the tendency of new development to raise the peak of the drainage - control pre-development peak - and decrease theto time to peak

Time

Time

1

detention

condition: - individual drainage area peaks later than the point of interest peak - the tendency of new development to raise the peak of the drainage area - and decrease the time to peak

3

3

watershed B

watershed B watershed A

Time

Overlapping Related Layers to Get Pilot Seven Sites

& Bangor Has the Most Heaviest Weight to Intervene Flood Issue

Disc

Discharge

Disc

Discharge

WATER INFRASTRUCTURE PROJECT 1

PRECISE HYDROLOGIC BALANCE CALCULATION BY JIERU HE (HEDY) XXX

Yellow Numbers: Streambed/Flood Elevation , from Engineering Calculation

path temporarily delivering water made of slate piles & used as human access tower for lighting and uased as ladder

creek-quarry-creek

gabion wall consisted of slate permanent platform & lower-level stage wall made of slate & clay three steps as temporary stages with moss indicationg 1 feet rise 8 feet waterfall high & low level elevation

Regrading Plan Theatre Cut into the Land

embedded, invented & revived theatres

538

balance earth by cutting & filling

525

518

streambed ele.

100 yr

513

518

510

allow irrigation & succession

522

516 540

514

510 historic trees preserved temporary stage locating into the water theatre made of slate tunnel & sequential landing

terraced meadow land water force controlled by topo & material ephermal path & pond

back to martins creek by checked dams slowing down speed N 50 100

100 200

200 F detailed plan 400 F masterplan

Theatres For Delivering Excessive Stormwater

WATER INFRASTRUCTURE PROJECT 1

THEATRES (DRAMA II) FOR DIVERTING FLOODWAY TO THE QUARRY LAKE

WINDOW OF THE QUARRY

522

524

8 FEET WATERFALL

522

518

510

WATER INFRASTRUCTURE PROJECT 1

523

540

MULTI-FUNCTIONAL & SYSTEMATIC WATER INFRASTRUCTURE 516

513

510

540

QUARRY LAKE TRANSFORMED INTO THEATRE 513

510

516

540

525 516 510

540

525 slate on steeper slope forcing water speed

516

tunnel for excessive flood to pass to drama III indicating incremental water level of 6 feet range

510

temporary theatre

drama II which is cut into the land hanging bridge over the lake is in the background of the scenery

EXCESSIVE RAINFALL INTO TERRACED MEADOW LAND

513

510

507

513

510

507

path made of slate piles

detention pond made of vegetation or stones

slate sheet accelerating water speed

water can be used for irrigation

WATER INFRASTRUCTURE PROJECT 1

excessive rainfall allowing the second succession

“Two or three tim usually presaged by a re often be encircled by rometer dropped

Ara

Oc

Nov

Nov.15

Dec.1

The landscape research and design project, which has been one and a half year long, explores two seemingly contrasting terrains with the only apparant similarity at first glance being mining. Ghats are very humid with surficial iron mining but Shanxi is extremely dry with underground coal mining. However, the two terrains share two common ground. One common ground is the one in problem-flooding and aridity. Both countries are constructing mega-water infrastructure to solve the “problem”. While nations are separate, the other common ground is the one in opportunity-monsoon rain. The project aspires to draw out and to recover the embedded wetness in gradients for both countries with the goal to prevent further flooding and “drought”.

500 Ma_Late Precambrian Separation Between O

350-250 Ma_Early C

1. INDEPENDENT STUDY I (SPRING 2017) Study two terrains & two types of extraction from geographic, material, hydrologic, tectonic and meteorologic analysis. 2. FIELD TRIP TO WESTERN GHATS, INDIA (SUMMER 2017) 3. INDEPENDENT STUDY II (FALL 2017) Study post-colonial & traditional water infrastructures (mines, dams, national inter-link river system, piping network, urban drainage system and tradional tank system) through photoworks & one essay film. 4. FIELD TRIP TO SHANXI PROVINCE, CHINA (WINTER 2018) 5. INDEPENDENT LANDSCAPE RESEARCH, DESIGN & PLANNING STUDIO (SPRING 2018) Gather the knowledge from previous study and apply them on designing arid Shanxi Terrain. See the following pages.

210-90 Ma_Norian-La

80-55 Ma_Upper C Merged Ocean

55-40 M Hidden Water & Unpred

40-30 M

STUDY 701 : RAIN LIB (INDIA)

25-16 M Wetness & Dr

Part II

16Ma-Fut Disappearing C

WETNESS IN SPACE AND TIME ACROSS THE HIMALAYA MOUNTAIN

Monsoonal Moments along Western Ghats, with a Moment Connected to the Arid Shanxi Province in North China In-Between Waters/Intercepting Wetness\ Instructor: Anuradha Mathur & Dilip Da Cunha Student: Jieru(Hedy) He Chasing the Monsoon Settled the Monsoon

mes a year, in season, we got a bravura climatic performance of our own. Hurricanes were ed moon, a purple dawn and oily green morning cloud. The sun - if glimped at all - would y a halo, its open side announcing the quarter from which the blow should come. The baso fast it almost fell off the wall. The sea became glassy and a curious stillness set in...” - Alexander Frater

The Sky

Shanxi Province is slightly affected by the monsoon season due to the protection from its surrounding mountains. It concentrates drought, if we can also imagine drought as a certain degree of wetness, in a space. There are great temperature differences between day and night, but with mild seasonal variations of monsoon winds.

Himalaya Mountain

Goa, Western Ghats

Shanxi Province, North China

Retreat of Monsoon July.15 Sep.1 Sep.15 Jun.1

Jun.10 Bombay

Oct.1

El Nino Goa

abian Sea

Himalaya Mt.

Shanxi Province

Jun.5

ct.15

v.1

Calicut

Jun.1

Bay of Bengal

Cochin

Alleppey Quilon Trivandrum

Onset of Monsoon

TECTONIC MOVEMENT AS AN INCESSANT NATURAL PROCESS The Changing Topography and Hidden Wetness In-Between Waters/Intercepting Wetness Instructor: Anuradha Mathur & Dilip Da Cunha Student: Jieru(Hedy) He

n & the Palaeozoic Ocean & Land India

Neo-Tethys

Oceanic ridge

Karakoram Lhasa

Meso-Tethys

Asia

Carboniferous the Indian Subcontinent was part of Gondwana and was separated from Eurasia by the Paleo-Tethys Ocean. During that period, The northern part of India was affected by a late phase of the Pan-African orogeny which is marked by an unconformity between Ordovician continental conglomerates and the underlying Cambrian marine sediments.Numerous granitic intrusions dated at around 500Ma are also attributed to this event.

an early stage of rifting developed between the Indian continent and the Cimmerian Superterranes. During the Early Permian, this rift developed into the Neotethys ocean. From that time on, the CS drifted away from Gondwana towards the north. Nowadays, Iran, Afghanistan and Tibet are partly made up of these terranes.

Oceanic ridge subduction India

Neo-Tethys

Volcanic arc

Karakoram Batholith Backarc

Asia

ate Cretaceous

Cretaceous & Land

a major rifting episode split Gondwana in two parts. The Indian continent became part of East Gondawana, together with Australia and Antarctica. However, the separation of East and West Gondwana, together with the foramtion of oceanic crust, occurred later, in the Callovia(160-155Ma).

The Indian plate then broke off from Australia and Antarctica in the Early Cretaceous(130-125Ma) with the opening of the “South Indian Ocean”.

Indain passive margin India

Andean type margin of Asian plate

Asia

10 Ma

38 Ma

55 Ma

71 Ma “India” Landmass

In the Upper Cretaceous, the India plate began its very rapid northward drift. The change of the relative speed between the Indian and Asian plates from very fast(18-19.5 cm/yr) to fast(4.5cm/yr) at about 55Ma is circumstantial support for collision then.

The oceanic subduction continued until the final closure of the oceanic - oceanic basin and the obduction of oceanic ophiolote onto India and the begining of continent - continent tectonic interaction starting at about 65Ma in the Central Himalaya.

The trasition between the generally low-grade sediments of the Tethys Himalaya and the underlying low-to-high-grade rocks of the High Himalayan Crystalline Sequence is usually progressive. But in many places along the belt, this transition zone is marked by the Central Himalayan Detachment.

Ma

The metasediments of the High Himalayan Crystalline Sequence represent the metamorphic equivalents of the sedimentary series forming the base of the overlying Tethys Himalaya.

ture Continent

Volcanic arc accretion, Andean type volcanism

0 Ma

Ma dictable Eruption

Ma rought

obduction of ophiolites Neo-Tethys

Eurasian Plate

Folding of Tethyan shelf sediments

Oceanic crust & ophiolite fragments

Tethyan zone

Continental collision Indus Tsangpo suture zone

Subduction of Indian Basement

magmas

Crustal thickening Formation of Tibetan Plateau

IN-BETWEEN WATERS/ INTERCEPTING WETNESS Greater Himalaya

Zone of partial melting in mid crust

STUDIO 702 : RAIN INVENT (CHINA)

LIBERATING & INVENTING RAIN IN MINING LANDSCAPES OF WESTERN GHATS, INDIA & SHANXI PROVINCE, CHINA Siwaliks forms the foothills of the Himalayan Range and is essentially composed of Miocene to Pleistocene molassic sediments derived from the erosion of the Himalaya.

The Lesser Himalaya is formed by Upper Proterozoic to lower Cambrian detrital sediments from the passive Indian margin intercalated with some granites and acid volcanics. The subhimalayan is thrust along the Main Frontal Thrust over the Quaternary alluvium deposited by the rivers coming from the Himalaya(Ganges, Indus, Brahmaputra and others),

Goa, Western Ghats

The Himalayas are still rising by more than 1 cm per year as India continues to move northwards into Asia, which explains the occurrence of shallow focus earthquakes in the region today. However the forces of weathering and erosion are lowering the Himalayas at about the same rate.

Lesser Himalaya

MFT

MBT

MCT

STD

crust melting

MHT

Part I - III Instructor: Anuradha Mathur Advisors: Dilip Da Cunha, Fritz Steiner

Part III

1 cm rise/yr

Himalaya Mountain

Tibetan Plateau

Shanxi Province, North China

The Sea

RAIN INVENT

INDEPENDENT LANDSCAPE DESIGN STUDIO: SHANXI PROVINCE, CHINA

Course: Independent Studio 702 from Jan. - May.2018 Location: Shanxi Province, China Type: Individual Work Instructor: Anuradha Mathur (Professor, Landscape Architecture Department, PennDesign School)

scale I

scale 2

SHANXI REGION

TAIYUAN-GUJIAO CITY

WATER INFRASTRUCTURE PROJECT 2

SIGNIFICANCE OF THE PROJECT

Research & Representation as A Way of Finding Next Project & of Connecting Design & Planning Decision

scale 3

scale 4

SYNERGIZED LANDSCAPE INFRASTRUCTURE

INTERVENTIONS ON EXISTING MINING AREA

WATER INFRASTRUCTURE PROJECT 2

TWO FRAMEWORKS

Scale 2-4 // Autonomy of Water, Crops & Coal Mines & The Interaction between City & Rural Area concept & three issues: in-between waters intercepting wetness - water(from mining) meets wetness on the terrain (mountains)

Gradients of Wetness Everywhere & Scale II

scale I SHANXI REGION 0

Least Wet // Transform Mining Water into Wetness

S1

Datong

Though no wetness can be gained from the southern monsoon in summer and it costs a lot for regional water delivering project to transfer water to Datong, Datong has the opportunity to get water from mountains.

S2

S3

S4

S5

S6

Medium Wet // Transform Mining Water into Wetness + Monsoon Wetnss

scale 2 Taiyuan-Gujiao City

Water is gained from regional water delivering project & there is opportunity for wasted and polluted water from mining operation to be transformed. Also, there is monsoon wetness, though less than the lower stream, to be captured.

Taiyuan

S7

scale 2 Taiyuan-Gujiao City

S8

S9

Most Wet // Opportunity from Monsoon Wetness

Linfen

No water obtained from regional water delivering project (because there is no increase on river elevation on section9 & because of a lot of mining operation nearby), but Linfen has opportunity from monsoon wetness.

S10

If Linfen can capture wetness, the upper stream can be wet too.

WATER INFRASTRUCTURE PROJECT 2

ACHIEVE AUTONOMY OF WATER-FOOD-ENERGY BETWEEN CITY & RURAL AREA

Scale 2-4 // Frameworks of Nested Scales

scale 2 TAIYUAN-GUJIAO CITY scale 3 SYNERGIZED LANDSCAPE INFRASTRUCTURE

1150 Fen Reservoir

Reservoir 1000 800 GUJIAO CITY

TAIYUAN CITY

scale 4 Fen River

MOUNTAIN

1300

scale 3

scale 2

AUTONOMY

INTERACTION

1000 COUNTY 800 Wenyu Reservoir

750

COUNTY

WATER INFRASTRUCTURE PROJECT 2

FLOW OF WATER INTERCEPTED BY FIELD OF MONSOON RAIN

Scale 2 // Transform Wasted & Polluted Mining Water into Wetness on The High Ground + Inventing Wetness from Monsoon Rain on The Foothills

scale 2 TAIYUAN-GUJIAO CITY

scale 3 Synergized Landscape Infrastructure

WATER INFRASTRUCTURE PROJECT 2

“WATER” THINKING CAUSING FLOOD & DROUGHT FROM UPPER- TO LOWER- STREAM Scale 2 // Problematic & Repetitive Water Infrastructure across Multiple Scales

ms & the terrain

tened Flow & Its Related Topography

less water (dryness) & more water (flooding)

Relating On- & Under-ground Disasters

1200

1200

800

800

S1

1150 Fen Reservoir_Stage I

1200

1200

800

Shrink

800

1200

S2

1200

800

800

1200

S3

1200

Gujiao City 800

1200

Relieve

800

Threshold mining affecting aquifers under the city

800

800

1200

S4

Low ground // Drought

1200

S5

Low ground // Drought

1200

Relieve 800

800

S6

Low ground // Drought 1200

1200

Relieve 800

800

1200

1200

800

800

1200

800

Fen Reservoir_Stage II 1200

800

800

1200

1st Water Supply Plant Above the Taiyuan City

800

800

800

1200

-7:30

S10

1200

800

800

S9

1200

Shrink

1200

S8

1200

800

950

S7

Mining on elevation > 1200m with extraction 400m will not affect the low-ground city of 800m, but affect the nearby river . Safely ele.1200-1300M is the threshold.

S11

1200

800

S12

1200

800

S20

1200

800

800

1200

1200

800

800

1200

1200

Relieve

S13

Taiyuan City S14

Low ground // Flooding & Drought

800

1200

Counties Under the Water Counties are not only in lack of water resource but also get easily flooded.

800

800

800

1200

1200

800

800

1200

1200

800

800

1200

1200

800

800

750 Relieve

WATER INFRASTRUCTURE PROJECT 2

S15

1200

S16

S17

Flooding

S18

Flooding

S19

Flooding

MATERIALS FOR INVENTING RAIN FROM THE SKY TO THE EARTH BY DIFFERENT SCENARIOS

Scale 3 // Possible Small Interventions & Deducting The Project in Next Scale

Type 1: Gujiao Downtown & Government-owned Mines

scale 3 SYNERGIZED LANDSCAPE INFRASTRUCTURE

Type 2: Big-scale Mines Private/Government-owned

Type 3: Farmland & Small Mines

Type 4: Small Mines within County Area

Type 5: Reservoir

WATER INFRASTRUCTURE PROJECT 2

- Find More Investment by Engaging with More Operators

Tourism Recreation

Tourism for the Regional Benefit....

Private-Owned Mines Transformed its Function

1/1

Administraion

Environment Department: RESILIENT IMPLEMENTATION MODE OF LANDSCAPE INFRASTRUCTURE sewage & water supply Transportation Department City Planning Commission Forest Department Agriculture Department

Scale 3 //Partnership Between Different Operators

County Government Big Mining Enterprises

More Automous Mode

MORE AUTONOMOUS MODE

$$$$

Trail Fully Developed till the Mountain Top

Government $

more future interest

1/4-1/2 - Across the City/County Border - Discover the Potential of Counties - Find More Investment by Engaging with More Operators * existing policy: four types of land transfer mode RISK SHARED BY MULTIPLE OPERATORS

regulated

Trail Expanding from

environment recovered which reduce the pollution burden

$$

regulated

mostly government-owned

Farmer

land prepared in the early stage located closer to each other share interests on the same land

Private-Owned Mines Other Landuses such as agriculture/tourism intercept into the mining site which provide the illegal company other future opportunities

Normal Public from the city Tourism Recreation

Administraion Environment Department: sewage & water supply Transportation Department City Planning Commission Forest Department Agriculture Department

County Government

SITE DESIGN EXPERIMENT

Scale 4 // Testing Topographic Change & Vegetation to Hold the Rain on the Ground

scale 4 INTERVENTIONS ON EXISTING MINING AREA

WATER INFRASTRUCTURE PROJECT 2

1/2-1/1

Engaged into Multiple Resilience Design & Planning Projects In the United States & Traditional Planning Projects in China

35

IN LANDSCAPE IS...

REGIONAL PLANNING

I.

URBAN DESIGN

II.

WATER INFRASTRUCTURE

III.

REGIONAL PLANNING

IV.

PROFESSIONAL WORK

V.

TECHNIQUES

VI.

PERSONAL EXPERIENCE 36

LINK: https://4c.rpa.org/corridors/city PROFESSIONAL WORK

THE TRIBORO CORRIDOR

FOURTH REGIONAL PLAN OF REGIONAL PLAN ASSOCIATION (RPA)

Summer Internship: One Architecture fromMay. - Aug.2017 Location: the Triboro, New York States Key Words: Industrial Corridor Transformation, Community Design, Green Corridor Design Supervisor: Matthijs Bouw

TARGETS HEALTH BENEFITS

SOCIAL COHESION * SCORE index

* global Sustainable Development Goals of NYC

- HUMAN SECURITY

- ACTIVE LIFESTYLE

feeling safe from violence, economic security having a secure basic income, being able to cover their needs...

- SATISFACTION WITH CIVIC LIFE

- A NUTRITIOUS DIET

satisfaction with various elements of public life, such as the administration of justice, the state of the economy, and the direction of the peace talks

grow nyc regional greenmarket food hub as part of the city’s strategy to increase the share of regional food in the new york city food system

- SATISFACTION WITH PERSONAL LIFE

- A HEALTHY HOME

satisfaction with life in general (e.g., personal life, work life, their health levels)

SOCIAL VULNERABILITY

URBAN MOBILITY

- SOCIOECONOMIC STATUS

- TRANSPORTATION

* SOCIAL VULNERABILITY INDEX SVI

below poverty/ unemployed/ income/ no high school diploma

eplace vehicle-serving cities with urban environments that put people first

- HOUSING TRANSPORTATION

- TARMAC(ASPHALT) CONVERTED (PERVIOUS SURFACES)

multi-unit structure/ mobile homes/ crowding/ no vehicle/ group quarters

* projected by RPA

cut the trend of consuming open space to 93sqmi

ENERGY PERFORMANCE - CLEAN ENERGY

SOCIAL MOBILITY - ANTI-DISPLACEMENT

- BUILDING CONSERVATION AND EFFICIENCY (ACE) PROGRAM

by creating innovative and cost effective programs to create sustainable affordable housing for the very lowest-income families. - more than a quarter of all affordable housing financed under the mayer’s plan are serving new yorkers making less than $31,100 for an individual or $40,800 for a family of three. - more than 14 percent serve new yorkers making less than $19,050 a year, or $24,500 for a family of three.

* SDGs Affordable and Clean Energy Goal 80*50 - achieve an 80 % reduction on greenhousegas emissions by 2050

* The Housing New York plan

since april 2016, the department of citywide administrative services has awarded $85.4 million in two rounds of solicitations through its accelarated conservation and efficiency(ace) program to projects in city-owned buildings that are expected to reduce more than 22,750 metric tons of carbon dioxide equivalent(tco2e), and result in approximately $7.2 million in annual energy costs savings.

METRICS_numbers+targets TARGET “The Triboro Corridor, extending from Brooklyn to Queens to the Bronx, is over 24 miles in length with 2.6 million current residents. By 2040, the Regional Plan Association (RPA) anticipates that its population will increase by 400,000 people.” The project is to redefine the often-overlooked territory. Rotating the map produces an unexpected and non- Manhattan-centric view of the corridor and brings into focus the outer boroughs and their importance for the City.

REGIONAL PLANNING PROJECT 1

ESTABLISH PROCESS FOR THE NEXT ECONOMIES by creating new relationships and proximities between the workforce and workplaces, particularly for economic sectors which are not necessarily centered in Manhattan, such as education, health care, logistics, manufacturing, and food, and by investing in workforce development for the circular economy.

REGIONAL PLANNING PROJECT 1

TRIBORO LOW CARBON CORRIDOR that uses the right-of-way and other adjoining green space including demapped streets for a signature linear park that paves the way for a “bicycle superhighway” for commuters and recreational users, and enhances open space to mitigate negative health and climate change impacts.

REGIONAL PLANNING PROJECT 1

REGIONAL PLANNING PROJECT 1

PROFESSIONAL WORK

INTERWEAVE THE CITY & THE RIVER E’ERGUNA LANDSCAPE PLANNING Team: Junior Landscape Architect, Halcrow Group Ltd. Responsibilities: Masterplan & Graphics Location: E’erguna, Innermogolia Autonomous Region, North China Scale: 445 ha Status: Schematic Design, Completed in April, 2013

0

REGIONAL PLANNING PROJECT 2

100

200

1 gold tent 2 conference center 3 hot spring hotel 4 ecological revetment 5 wetland museum 6 visitor service center 7 test-drive community 8 enterprise club 9 international community 10 residential community 11 neighborhood center 12 riverfront park 13 sports center 14 soul-purifing river 15 central lake 16 school 17 the wild theatre 18 boutique hotel group 19 wetland hotel 20 visitor service centernity 21 Russia-style town 22 administrative center 23 Gen River left shore 24 commercial center 25 mass media center N Meters 500

DERIVE CITY IDENTITY & PROGRAMS FROM MARKET ANALYSIS

HE CITY water element featured architecture local plants

a.Exibition Zone in Business Core

b.Artificial Lakeshore in Leisure Core

c.Traditional Culture Town in Leisure Core

e.Natural Lakeshore in Leisure Core

d.Municipal Axis in Adminstrative Core

f.Residential Area in Community Cluster

a

c

b

d

e

f

Water Penetrating to Show Natural Features

REGIONAL PLANNING PROJECT 2

PROFESSIONAL WORK

LANDSCAPE

ARCH -ITECTURE Contributed to Complete Phases of Landscape Design, Architecture & Urban Planning Projects during One-year Full-time Position & Three Internship Programs

43

URBAN PLANNING

44

10.1 F

10.2 F

Roof View

LEAD LANDSCAPE ARCHITECT @ JDS ARCHITECTS Time: Jul. 2013 - Apr. 2014

RICHNESS IN SPACE & TIME

URBAN PLANNER & DESIGNER @ HALCROW GROUP Time: Feb. 2012 - Apr. 2014

CONSTRUCTION DESIGNER @ LAUDAU INTERNATIONAL DESIGN Time: July. 2012 - Nov. 2014

COMPETITION GARDEN DESIGN Time: Oct. 2018

Competition: VERSATILE WISTERIA GARDEN DESIGN Location: Nanchang City, China Type: Quick Photoshop Renderings

TECHNIQUES

PHOTOGRAPHY Materials, Space & Views

49

Soil 3

1 2

MakAt

PHG

LakB

AtsA

MakAt

PHG

Qs

Qe

LakB

AptAv

HorsC

Surficial Geology

AtsA

cb

Qca 1b

Qs

Qca2

Qca3

Qcm1

cb

Qcm1

Qca2

Qca3

Qm

Qb

Bedrock

1 Batsto River

Ch

Ch

2 Wading River

Kw

3 Island Beach State Park

Kw

Section 1 Batsto River

Kw

Section 2 Wading River

Section 3 Island Beach State Park

Concept Soil Color

Soil Textural Classes

Soil Water Flow & Retention

DEPTH & FORMING REASON

This map explores the link between subsurface texture and water retention in the New Jersey coastal plain. The Kirkwood-Cohansey water-table aquifer underlies each of the two inland sites. Portraits were taken of the various soil CwB ChC2 ChB2 WaA CpA GdB CwB ChC2 ChB2 WaA CpA GdB CwB ChC2 ChB2 WaA CpA GdB CwB ChC2 ChB2 WaA CpA GdB profiles, surficial geologic conditions, and bedrock geologic layers present within the three sites. Each was made to express primary texture features. White space represents the space between particles, and hence the capacity to retain water. In plan and section one sees where water may percolate and pool throughout the subsurface layers. underneath dry serpentine

underneath wet serpentine underneath wet geniss

underneath dry geniss

high topo

high topo

low topo

formed in residuum from basic rocks high in magnesium, usually serpentine

formed in residuum weathered mosly from serpentine

formed in residuum weathered mosly from serpentine

formed in residuum from basic rocks

formed in either in old till or on driftless landscapes in colluvium from primarily granite gneiss

formed in colluvium and residuum from granite gneiss

O horizon

dark olive brown

dark brown

dark greyish brown

silt loam

silt loam

dark olive brown

dark reddish brown

silt loam

friable & slightly sticky

friable & sticky

silt loam

dark greyish brown

friable & sticky

4''

friable & slightly sticky

gravelly loam

brown

dark brown

Krista Reimer, Zhoufei Zhu, Jieru He

friable

8''

friable & slightly sticky

gravelly loam

silty clay

A horizon

friable & sticky 12''

yellowish brown

slit clay loam

firm & sticky

16''

dark yellowish brown

clay loam

friable & moderately sticky 20''

light grey

extremely firm & brittle

coarse sandy loam brown

dark yellowish brown

friable & moderately sticky

clay loam silt loam

light reddish brown

dark yellowish brown

dark yellowish brown

yellowish brown

pale brown

dark yellowish brown

silt loam

clay loam

clay loam

silt loam very gravelly sandy loam

gravelly sandy loam

friable & slightly sticky

friable & slightly sticky

firm & moderately sticky

firm & moderately sticky

firm & sticky

extremely firm & brittle

B horizon

24''

very friable & nonsticky

28''

32''

36''

40''

44''

48''

60''

C horizon 64''

68''

72''

Serpentine Pine-Oak Forest Conowingo(CwB)

Serpentine Grassland Forb Chrome(ChC2)

Serpentine Gravel Forb Chrome(ChB2)

Serpentine Seepage Wetland Watchung(WaA)

Gneiss Redmaple Swamp Cokesbury(CpA)

Gneiss Tuliptree Forest Gladstone(GdB)

76''

EACH SOIL LOCATION ON THE MAP 80''

SOIL PROFILES: PIEDMONT

56''

Representation Material: Pastel, Watercolor & Watercolor Paper He Jieru(Hedy), Individual Work

52''

GEOLOGY & SOIL

Surficial Geology & Water Retention Study Of New Jersey Coastal Plain

50

Plants & Design

Th攀 猀攀氀攀挀琀椀o渀 of o甀爀 瀀氀愀渀琀椀渀最 d攀猀椀最渀 椀渀挀氀甀d攀猀 愀 瀀o爀琀椀o渀 of 甀瀀瀀攀爀 氀愀渀d w椀琀h d爀y攀爀 猀o椀氀 o渀 琀h攀 挀氀椀ff 愀渀d 愀 瀀o爀琀椀o渀 of 氀ow攀爀 氀愀渀d w椀琀h w攀琀 猀o椀氀 o渀 琀h攀 爀椀v攀爀 b愀渀k. Th攀 攀渀琀爀愀渀挀攀 of 甀瀀瀀攀爀 氀愀渀d 椀猀 o瀀攀渀 愀渀d w攀氀挀o洀椀渀最. I琀 b攀挀o洀攀猀 d攀渀猀攀爀 瀀椀渀攀 fo爀攀猀琀 w椀琀h 最爀椀d 瀀氀愀渀琀椀渀最 fo爀洀 wh攀渀 洀ov椀渀最 琀ow愀爀d猀 琀h攀 挀氀椀ff. Th攀 琀愀氀氀 猀琀爀愀椀最h琀 最爀椀d 瀀椀渀攀 fo爀攀猀琀 of ㈀ f攀攀琀 猀瀀愀挀椀渀最 愀氀氀ow 瀀攀o瀀氀攀 Th攀 猀攀氀攀挀琀椀o渀 of o甀爀 瀀氀愀渀琀椀渀最 椀渀挀氀甀d攀猀 愀 瀀o爀琀椀o渀 of 甀瀀瀀攀爀 氀愀渀d w椀琀h d爀y攀爀 猀o椀氀琀爀攀攀猀 o渀 琀h攀 愀渀d 猀甀b-挀愀渀o瀀y, 愀 瀀o爀琀椀o渀 of甀渀d攀爀猀琀o爀y 氀ow攀爀 氀愀渀d 愀渀d w椀琀h猀h爀甀b w攀琀 猀o椀氀 o渀 Th攀 琀h攀 爀椀v攀爀 f攀攀氀 f爀攀攀do洀 of 猀琀爀愀椀最h琀 v椀攀w猀 愀渀d 洀ov攀洀攀渀琀. I琀 洀ov攀猀 琀od攀猀椀最渀 琀h攀 d攀渀猀攀猀琀 愀爀攀愀 o渀 琀h攀 甀瀀瀀攀爀 氀愀渀d, 最爀攀w w椀琀h 洀椀x攀d 椀渀 挀氀椀ff 挀愀渀o瀀y, 氀愀y攀爀猀. 琀爀愀渀- b愀渀k. Th攀 攀渀琀爀愀渀挀攀 of 甀瀀瀀攀爀 o瀀攀渀 愀渀d w攀氀挀o洀椀渀最. b攀挀o洀攀猀 瀀椀渀攀 fo爀攀猀琀 w椀琀h瀀愀琀h猀 最爀椀d 最o 瀀氀愀渀琀椀渀最 fo爀洀 洀ov椀渀最 琀ow愀爀d猀 琀h攀 挀氀椀ff. Th攀 琀愀氀氀 猀琀爀愀椀最h琀 最爀椀d fo爀攀猀琀 猀椀琀椀o渀 椀猀 氀o猀椀渀最 琀h攀 最爀椀d fo爀洀氀愀渀d 愀渀d 椀猀 b爀椀渀最椀渀最 洀o爀攀 v愀爀椀攀琀椀攀猀 I琀 v攀爀琀椀挀愀氀氀y of d攀渀猀攀爀 琀h攀 v椀攀w. M攀愀渀d攀爀椀渀最 琀h爀o甀最h 琀h攀wh攀渀 fo爀攀猀琀猀 攀xh椀b椀琀椀渀最 愀 d椀v攀爀猀攀 攀x瀀攀爀椀攀渀挀攀 of v椀攀w猀 愀渀d瀀椀渀攀 猀瀀愀挀攀 猀甀挀hof愀猀㈀ f攀攀琀 猀瀀愀挀椀渀最 愀氀氀ow 瀀攀o瀀氀攀 f攀攀氀琀o f爀攀攀do洀 v椀攀w猀 洀ov攀洀攀渀琀. I琀 洀ov攀猀 琀o 琀h攀 d攀渀猀攀猀琀 愀爀攀愀 愀渀d o渀 琀h攀 甀瀀瀀攀爀fo爀攀挀愀猀琀椀渀最 氀愀渀d, 最爀攀w 琀h攀 w椀琀h洀o猀琀 洀椀x攀d 琀爀攀攀猀 椀渀 挀愀渀o瀀y, 猀甀b-挀愀渀o瀀y, o瀀攀渀 猀瀀愀挀攀 椀渀 b攀琀w攀攀渀. C氀o猀攀爀 琀h攀 挀氀椀ff,of椀琀猀琀爀愀椀最h琀 b攀挀o洀攀猀 氀o猀攀愀渀d 椀渀 琀h攀 猀瀀愀挀攀 愀最愀椀渀 w椀琀h 氀攀猀猀 瀀氀愀渀琀猀 椀渀 猀瀀攀挀椀攀猀 愀洀o甀渀琀, 洀愀最渀椀f椀挀攀渀琀 洀o洀攀渀琀 - 琀h攀 f椀渀愀氀甀渀d攀爀猀琀o爀y o瀀攀渀 瀀氀愀琀- 愀渀d 猀h爀甀b 氀愀y攀爀猀. Th攀 琀爀愀渀猀椀琀椀o渀琀h攀 椀猀 洀o猀琀 氀o猀椀渀最o瀀攀渀 琀h攀 最爀椀d fo爀洀 愀渀d b爀椀渀最椀渀最 洀o爀攀 v愀爀椀攀琀椀攀猀 v攀爀琀椀挀愀氀氀y of 琀h攀 v椀攀w. M攀愀渀d攀爀椀渀最 瀀愀琀h猀 最o 琀h爀o甀最h 琀h攀 fo爀攀猀琀猀 攀xh椀b椀琀椀渀最 愀 d椀v攀爀猀攀 攀x瀀攀爀椀攀渀挀攀 of v椀攀w猀 愀渀d 猀瀀愀挀攀 猀甀挀h 愀猀 fo爀洀. I琀 椀猀 琀h攀 猀甀洀洀椀琀 猀瀀o琀 w椀琀h v椀攀w. o瀀攀渀 猀瀀愀挀攀 椀渀 b攀琀w攀攀渀. C氀o猀攀爀 琀o 琀h攀 挀氀椀ff, 椀琀 b攀挀o洀攀猀 氀o猀攀 椀渀 琀h攀 猀瀀愀挀攀 愀最愀椀渀 w椀琀h 氀攀猀猀 瀀氀愀渀琀猀 椀渀 猀瀀攀挀椀攀猀 愀渀d 愀洀o甀渀琀, fo爀攀挀愀猀琀椀渀最 琀h攀 洀o猀琀 洀愀最渀椀f椀挀攀渀琀 洀o洀攀渀琀 - 琀h攀 f椀渀愀氀 o瀀攀渀 瀀氀愀琀fo爀洀. I琀 椀猀 椀渀 琀h攀 猀甀洀洀椀琀椀猀猀瀀o琀 w椀琀h w椀琀h 琀h攀 洀o猀琀 o瀀攀渀 v椀攀w. Th攀 氀ow攀爀 瀀o爀琀椀o渀 o渀 琀h攀 爀椀v攀爀 b愀渀k, 挀o渀琀爀愀猀琀, 瀀氀愀渀琀攀d 猀瀀攀挀椀攀猀 w椀琀h 洀o爀攀 f爀攀攀do洀 椀渀 fo爀洀.V攀最攀琀愀琀椀o渀 挀h愀渀最攀 f爀o洀 瀀椀渀攀 fo爀攀猀琀猀 琀o f爀甀椀琀 猀h爀甀b猀 愀渀d 洀椀x攀d 洀攀愀dow猀, 挀o爀爀攀猀瀀o渀d椀渀最 琀o 琀h攀 攀氀攀v愀琀椀o渀 d椀ff攀爀攀渀挀攀.V愀爀椀o甀猀 f爀甀椀琀 猀h爀甀b猀 挀爀攀愀琀攀 愀 渀愀琀甀爀愀氀 h愀b椀琀愀琀 fo爀 d椀ff攀爀攀渀琀 猀瀀攀挀椀攀猀. 䄀 w椀d攀 瀀爀o洀攀渀愀d攀 氀攀愀d猀 琀o 琀h攀 爀椀v攀爀 攀渀氀椀最h琀攀渀攀d 琀h攀 爀椀v攀爀b愀渀k 愀渀d 挀爀攀愀琀攀猀 Th攀 氀ow攀爀 瀀o爀琀椀o渀 o渀 琀h攀 爀椀v攀爀 b愀渀k, 椀渀 挀o渀琀爀愀猀琀, 椀猀 瀀氀愀渀琀攀d w椀琀h 猀瀀攀挀椀攀猀 w椀琀h 洀o爀攀 f爀攀攀do洀 椀渀 fo爀洀.V攀最攀琀愀琀椀o渀 挀h愀渀最攀 f爀o洀 瀀椀渀攀 fo爀攀猀琀猀 琀o f爀甀椀琀 猀h爀甀b猀 愀渀d 洀椀x攀d 洀攀愀dow猀, 挀o爀洀o爀攀 o瀀瀀o爀琀甀渀椀琀椀攀猀 fo爀 w愀琀攀爀 瀀爀o最爀愀洀猀. 爀攀猀瀀o渀d椀渀最 琀o 琀h攀 攀氀攀v愀琀椀o渀 d椀ff攀爀攀渀挀攀.V愀爀椀o甀猀 f爀甀椀琀 猀h爀甀b猀 挀爀攀愀琀攀 愀 渀愀琀甀爀愀氀 h愀b椀琀愀琀 fo爀 d椀ff攀爀攀渀琀 猀瀀攀挀椀攀猀. 䄀 w椀d攀 瀀爀o洀攀渀愀d攀 氀攀愀d猀 琀o 琀h攀 爀椀v攀爀 攀渀氀椀最h琀攀渀攀d 琀h攀 爀椀v攀爀b愀渀k 愀渀d 挀爀攀愀琀攀猀 洀o爀攀 o瀀瀀o爀琀甀渀椀琀椀攀猀 fo爀 w愀琀攀爀 瀀爀o最爀愀洀猀.

Plants & Design

Pinus strobus (Eastern white pine) Quercus rubra (Red oak) Cornus kousa (kousa dogwood)

- 攀v攀爀最爀攀攀渀 - 渀攀攀d氀攀猀 瀀攀爀猀椀猀琀 椀渀 ㈀ y攀愀爀猀

Pinus strobus (Eastern white pine)

- 攀v攀爀最爀攀攀渀 - 渀攀攀d氀攀猀 瀀攀爀猀椀猀琀 椀渀 ㈀ y攀愀爀猀

- 爀甀猀猀攀琀-爀攀d, y攀氀氀ow 愀渀d 琀愀渀 椀渀 f愀氀氀

Quercus rubra (Red oak)

- 爀甀猀猀攀琀-爀攀d, y攀氀氀ow 愀渀d 琀愀渀 椀渀 f愀氀氀

Cornus kousa (kousa dogwood)

- wh椀琀攀 f氀ow攀爀猀 椀渀 攀愀爀氀y J甀渀攀 - 爀攀d 椀渀 f愀氀氀

- wh椀琀攀 f氀ow攀爀猀 椀渀 攀愀爀氀y J甀渀攀 - 爀攀d 椀渀 f愀氀氀

- wh椀琀攀 f氀ow攀爀猀 f爀o洀 䄀瀀爀椀氀 琀o M愀y Cornus florida (Eastern flowering dogwood) - 爀攀d 椀渀 f愀氀氀 Cornus florida (Eastern flowering dogwood) - 攀v攀爀最爀攀攀渀 Rhododendron Sp.

- wh椀琀攀 f氀ow攀爀猀 f爀o洀 䄀瀀爀椀氀 琀o M愀y - 爀攀d 椀渀 f愀氀氀

- 渀攀愀氀y wh椀琀攀 o爀 爀攀d f氀ow攀爀猀 椀渀 氀愀琀攀 J甀氀y

Kalmia latifolia (Mountain laurel) Acer rubrum (Red maple)

Rhododendron Sp.

- 攀v攀爀最爀攀攀渀 - 渀攀愀氀y wh椀琀攀 o爀 爀攀d f氀ow攀爀猀 椀渀 氀愀琀攀 J甀氀y - 攀v攀爀最爀攀攀渀 - wh椀琀攀 w椀琀h 瀀甀爀瀀氀攀 f氀ow攀爀猀 椀渀 氀愀琀攀 J甀氀y

Kalmia latifolia (Mountain laurel)

- 攀v攀爀最爀攀攀渀 - wh椀琀攀 w椀琀h 瀀甀爀瀀氀攀 f氀ow攀爀猀 椀渀 氀愀琀攀 J甀氀y

- 爀攀d 椀渀 f愀氀氀

Acer rubrum - 爀攀d 椀渀 f愀氀氀 (Red maple) - o爀愀渀最攀, 爀攀d 椀渀 f愀氀氀 Liquidambar stryraciflua (Sweetgum) - o爀愀渀最攀, 爀攀d 椀渀 f愀氀氀 Liquidambar stryraciflua 倀氀愀渀琀 匀瀀攀挀椀攀猀 倀氀愀渀琀 匀瀀攀挀椀攀猀 (Sweetgum) - 瀀椀渀k f氀ow攀爀猀 f爀o洀 䄀瀀爀椀氀 琀o 攀愀爀氀y M愀y Cercis canadensis - b爀椀最h琀 y攀氀氀ow 椀渀 f愀氀氀 (Eastern redbud) - 瀀椀渀k f氀ow攀爀猀 f爀o洀 䄀瀀爀椀氀 琀o 攀愀爀氀y M愀y Cercis canadensis - b爀椀最h琀 y攀氀氀ow 椀渀 f愀氀氀 洀甀氀琀椀 猀琀攀洀攀d (Eastern- redbud) Cornus mas - y攀氀氀ow f氀ow攀爀猀 f爀o洀 氀愀琀攀爀 M愀爀挀h 琀o 攀愀爀氀y 䄀瀀爀椀氀

(Cornelian cherry dogwood) - 爀攀d, o爀愀渀最攀, y攀氀氀ow 椀渀 f愀氀氀 Cornus mas - 洀甀氀琀椀 猀琀攀洀攀d dogwood) (Cornelian cherry Ilex verticillata - y攀氀氀ow 椀渀 f愀氀氀 (Winter berry) - f爀甀椀琀攀 f爀o洀 f愀氀氀 琀o w椀渀琀攀爀 Ilex verticillata (Winter -berry) 攀v攀爀最爀攀攀渀 Ilex glabra (Ink berry)

Clethra alnifolia (Sweet pepperbush)

Section A

Grid

Dense

Path

Room

Loose

Open

Mixed meadow

㄀”=㈀ ’ ㄀”=㈀ ’

Section A

Grid

Dense

Path

Room

Loose

Open

Section A

Grid

Dense

Path

Room

Loose

Open

Section A

Grid

Dense

Path

Room

Loose

Open

夀攀愀爀  夀攀愀爀

㔀 夀攀愀爀 㔀 夀攀愀爀

Section B

High Canopy

Multiple Understory

Flowering Shrub

Path

㄀㔀 夀攀愀爀 ㄀㔀 夀攀愀爀

Section B

High Canopy

Multiple Understory

Flowering Shrub

Path

Section B

High Canopy

Multiple Understory

Flowering Shrub

Path

Section B

High Canopy

Multiple Understory

Flowering Shrub

Path

㈀㔀 夀攀愀爀 ㈀㔀 夀攀愀爀

Section C

Flowering Meadow

Tidal Water

Wetland

Bridge

Section C

Flowering Meadow

Tidal Water

Wetland

Bridge

匀瀀爀椀渀最 匀瀀爀椀渀最

Section C

Flowering Meadow

Tidal Water

Wetland

Bridge

Section C

Flowering Meadow

Tidal Water

Wetland

Bridge

Section D

Open Meadow

Wetland

Section D

Open Meadow

Wetland

䄀甀琀甀洀渀 䄀甀琀甀洀渀

PLANTING & VEGETATION

Course: Larp Workshop 502 from Apr. - Jan.2015 Section D

Open Meadow

Wetland

Section D

Open Meadow

Wetland

- d甀氀氀 wh椀琀攀 f氀ow攀爀猀 椀渀 J甀渀攀

- 洀甀氀琀椀 猀琀攀洀攀d - y攀氀氀ow f氀ow攀爀猀 f爀o洀 氀愀琀攀爀 M愀爀挀h 琀o 攀愀爀氀y 䄀瀀爀椀氀 - 爀攀d, o爀愀渀最攀, y攀氀氀ow 椀渀 f愀氀氀 - 洀甀氀琀椀 猀琀攀洀攀d - y攀氀氀ow 椀渀 f愀氀氀 - f爀甀椀琀攀 f爀o洀 f愀氀氀 琀o w椀渀琀攀爀

Ilex glabra - 洀甀氀琀椀 猀琀攀洀攀d (Ink berry)

- 攀v攀爀最爀攀攀渀 - d甀氀氀 wh椀琀攀 f氀ow攀爀猀 椀渀 J甀渀攀

Clethra alnifolia (Sweet pepperbush) - 氀ow 氀愀渀d, w攀琀 猀o椀氀 洀攀愀dow

- 洀甀氀琀椀 猀琀攀洀攀d - 猀洀愀氀氀 wh椀琀攀 f氀ow攀爀猀 f爀o洀 J甀氀y 琀o 䄀甀最攀猀琀

Mixed meadow

- 氀ow 氀愀渀d, w攀琀 猀o椀氀 洀攀愀dow

- 猀洀愀氀氀 wh椀琀攀 f氀ow攀爀猀 f爀o洀 J甀氀y 琀o 䄀甀最攀猀琀

Bridge Bottom Ele=525

slope for theatre changing from 1:1 to gentler 2:1

523

515

525 530

FILL HERE 520

513 521 510

515

535

511

540

520 525

512

530 535

513

540 514

515

516

515 514

518

sheet flow513after rushing through the tunnel 510 509

535

508

507 540

530

525

flow through terraced meadow land

520 510

CUT HERE 511

512 510 513

discharge back to Martins Creek 509

508

515

507

GRADING & CONSTRUCTION DRAWING Incoporated into Studio 601 & Construction Workshop Work

535

530

525 520

02

Mesh Resampled (u=50) with Color by Aspect over 15% slope

03

Rain-flow(no 04roof contribution) Intersects with Buildings, Length to Intersection w/Drains05

Non-Building Intersecting Flows: Terrain v.s. CSO Flows

Non-Building Intersecting Flows: Terrain vs. CSO Flows

STORMWATER DESIGN Grasshopper with Rhino Modeling

07

Terrain Flows ending within vacant parcels

Week 10, Exercise 07- Feedback Flows

VanDerSys, Luegering - LARP 543-001,-002,-003

INTERACTIVE LANDFORM & PAVEMENT DESIGN Grasshopper with Rhino Modeling

residential Height Min = 12 ft Max = 36 ft # buildings 240

commercial Height Min = 300 ft Max = 150 ft # buildings 14

mixed-use Height Min = 18 ft Max = 80 ft # buildings 19

warehouse Height Min = 18 ft Max = 30ft # buildings 6

mixed-use 2 Height Min = 20 ft Max = 60 ft # buildings 8

01

Alternative 1

Exercise 07 - Open Space Use and Typology

Luegering - LARP 544-001,-002,-003

commercial Height Min = 30 ft Max = 200 ft # buildings 26

mixed-use Height Min = 18 ft Max = 80 ft # buildings 31

warehouse Height Min = 18 ft Max = 30ft # buildings 4

mixed-use Height Min = 18 ft Max = 45 ft # buildings 19

01

MEDIA IV - Spring 2017

residential Height Min = 12 ft Max = 36 ft # buildings 49

Alternative 2

GRASSHOPPER IN URBAN PLANNING & ANALYSIS MEDIA IV - Spring 2017

Exercise 07 - Open Space Use and Typology

Grasshopper with Rhino Modeling for Generating Interactive Urban Forms

GIS ANALYSIS & MODELING

Find Area Alongside Highways & Near Residential Area To Collect Air Pollution Watch Video: https://vimeo.com/194971884

Luegering - LARP 544-001,-002,-003

PERSONAL EXPERIENCE

Shanxi Province, China

Western Ghats, India

MULTI-DISCIPLINES

MULTI-SCALES

With my bachelor’s major degree in environmental engineering and minor degree in landscape architecture, I am able to bridge the divide between engineering, design and planning. My undergraduate final thesis, awarded as Graduate Project Excellence, combined engineered artificial wetland with landscape spatial design.

I believe there will be enormous potential for the discipline to grow because ecological process is outside of a certain geographic boundary. Landscape architect takes responsibility of preserving sustainable nature as well as designing specific place for humans to simply perceive their living environment.

I have also engaged into all phases of architecture, planning and landscape architecture projects during one-year full-time position as landscape architect and multiple internship programs, from which I got the experience of collaborating with architects, planners and engineers.

I have led projects of a range of scales from nationwide research and planning to placemaking in landscape and urban design. More often I work on nested scales in a singular project. I have a proven track record in delivering Design Excellence including ASLS award and competition-winning projects.

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MULTI-MEDIA I am passionate about design proven by my continuous experiment on testing multimedia including video making, writing and conventional drawing work. Moreover, I am integrating design throughout the whole research, design and planning process, since design explorations can actually also contribute to problem definition and the formulation of goals. I don’t think a design project will end up with a drawing or representation. Instead, experiment on multi-media uncovers and opens a project that landscape design project will always become open.

I become more firmly believe after my three-year learning at Penn, that design is and should be on the frontier of deciding human trajectory with its environment, through our reimagination of expanding the responsibility of landscape design in infrastructure design, urban design and regional planning. I am looking forward to committing myself to professional work where I can approach my manifesto towards better city, infrastructure and environment.

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EDUCATION

RESEARCH & TEACHING ASSISTANTSHIPS

School of Design, University of Pennsylvania

In-Between Waters/Intercepting Wetness: Liberating & Inventing Wetness in Mining Landscapes of Western Ghats, India & Shanxi Province, China

Aug.2015 - Expected May.2018 Master of Landscape Architecture & Regional Planning Honor: - American Society of Landscape Architecture Awards (ASLA) Certificate of Honor - Narendra Juneja Medal for Excellence & Ecological Conscience - Projects of Studio 501,502,601,701; Workshop 501,502; Independent Study 602, 701 Selected in PennDesign Landscapes in Process Publication

Donghua University, with Distinction Sep.2009 - Jul.2013 Shanghai, China Bachelor of Environmental Engineering Honor: Award for Academic Excellence 2011-2012

Shanghai Society of Modern Landscape Architecture Feb.2012 - Jan.2013 Professional Landscape Architect Training Courses Honor: National Landscape Architect Professional Qualification

Jan.2017 - Expected May.2018 PennDesign School, University of Pennsylvania Independent Study & Studio Instructed by Pro. Anuradha Mathur Honor: School Approved & Funded Syllabus & Proposal

Teaching Assistant Theory II: History & Theory of Landscape Architecture Jan.2017 - May.2017 PennDesign School, University of Pennsylvania Pro. Raffaella Fabiani Giannetto

Research Assistant Beautiful China Research Program

Nov.2016 - Jan.2017 PennDesign School, University of Pennsylvania Pro. Richard Weller Investigate China Ecological Civilization, Definition of Beauty of Nature & Landscape Architects’ Practice in China

Research Assistant Scenario Journal

Nov.2016 - Jan.2017 PennDesign, University of Pennsylvania Instructed by Nicholas Pevzner & Stephanie Carlisle Project Review, Graphic Design

LANGUAGES & TRAVELLING

SYMPOSIA, WORKSHOPS & STUDY ABROAD PROGRAMS

English: Eloquent Business English Certificate (Higher C Level) Chinese: Mandarin

Rethinking Research & Design Practices in the Face of Rapid Urbanization

Asia: China, India, Japan, South Korea, Cambodia North America: the United States South America: Brazil Europe: France, Italy, Switzerland

Urban Texts: Rhythmanalysis of the Terrasse - Paris

May.2017 Center for the Advanced Study of India(CASI) & PennDesign

May.2016 - Jun.2016 Summer Study Abroad Program in Architecture PennDesign School, University of Pennsylvania Film Project & Essays

How Do We Design a More Equitable Philadelphia? Feb.2016 Workshop: Designing the Future with Bruce Mau PennPraxix & PennIUR

Hong Kong University

Jul.2011 - Aug.2011 Summer School of Business and Marketing

PROFESSIONAL PRACTICES

AWARDS & PUBLICATIONS

PennPraxis, University of Pennsylvania

Author & Editor Environmental Readings 2018 (to be published)

May.2018 – Expected July.2018 Design Assistant Project: Landscape Planning & Design Proposal for Western Ghats, India

One Architecture

Jan.2018 - Expected May.2018 PennDesign School, University of Pennsylvania Pro. Frederick Steiner

May.2017 - Jul.2017 Landscape Architect, Intern Projects: Fourth Regional Plan of Regional Plan Association (RPA): the Triboro Corridor (New York State), ULI Ten Principles for Resilient Land Use & Development, the Big U/Dryline (New York City): East Side Coastal Resilience

Julien De Smedt Architects @ Munich Urban Design Jul.2013 - Apr.2014 Landscape Architect Roof Garden Design (Constructed), Urban Planning & Design

Halcrow Group Ltd. @ Shanghai Branch

Feb.2013 - Apr.2013 Landscape Planner, Intern Urban Design & Planning & Regulatory Detailed Planning

Landau International Design Group Jul.2012 - Nov.2012 Landscape Architect, Intern Landscape Design & Detailed Design

Tyco Thermal Controls

Jul.2011 - Aug.2011 Marketing Department, Intern Business Marketing, Market Investigation & Website Design

SKILLS

Landscapes in Process 2015-2018

Studio 501, 502, 601, 701 & Workshop 501, 502 & Independent Study 602, 701 Selected in PennDesign School Annual Publication

The Third Idea-King Award International Landscape Planning & Design Competition Oct.2013 Collector of PM 2.5 Pollutant - Green Infrastructure for Highways Honorable Mention & Individual Entry

Graduation Project Appraisal

Jun.2013 School of Environmental Science & Engineering, Donghua University Engineering Design of Sewage Reclamation in Architecture

Water Quality Purification Effects & Mechanism of Algal-Bacterial Symbiotic Flow Constructed Wetland Dec. 2011 Environmental Science & Engineering School, Donghua University Pro. Xinshan Song Honor: Undergraduate Innovation Project, Shanghai Citywide Selected

Proposal for Environmental Protection Jan.2011 Coca-Cola Global Cup Top 10 College Activity Ambassadors, Shanghai

Modeling (Auto CAD, Rhino 3D, Grasshopper, Sketch up) Rendering (Vray) Visualisation (Photoshop, Illustrator, InDesign) Animation (After Effects, Premier) Geographic Information Analysis (ArcGIS, EqGIS) Microsoft Office Java & Database (SQL Server 2000)

HEDY HE Graduate of Master in Landscape Architecture & Regional Planning, 2018 PennDesign School University of Pennsylvania hejieru@alumni.upenn.edu 215-410-6975