The Sustainable City XII

The Sustainable City XII

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Twelfth International Conference on Urban Regeneration and Sustainability SUSTAINABLE CITY XII Conference Chairmen C.A. Brebbia Wessex Institute, UK J. J. Sendra University of Seville, Spain

International Scientific Advisory Committee Ö Özcevik G Passerini G Perillo N Quaranta E C Rada R Rojas-Caldelas F Russo G Rzevski S Turgut Y Villacampa S S Zubir

R Barełkowski D Bogunovich C Booth J Diaz V Echarri R Fistola A Furman A Kocabas D Longo J L Miralles i García G Musolino

Organised by

Wessex Institute, UK University of Seville, Spain

Sponsored by WIT Transactions on Ecology and the Environment The International Journal of Sustainable Development and Planning

WIT Transactions Transactions Coordinator Carlos Brebbia Wessex Institute Ashurst Lodge, Ashurst Southampton SO40 7AA, UK

Senior Editors H Al-Kayiem

W J Mansur

Universiti Teknologi PETRONAS, Malaysia

Federal University of Rio de Janeiro, Brazil

G M Carlomagno

J L Miralles i Garcia

University of Naples Federico II, Italy

Universitat Politècnica de València, Spain

A H-D Cheng

G Passerini

University of Mississippi, USA

Università Politecnica delle Marche, Italy

J J Connor

F D Pineda

Massachusetts Institute of Technology, USA

Complutense University, Spain

J Th M De Hosson

D Poljak

University of Groningen, Netherlands

University of Split, Croatia

P De Wilde

F Polonara

Vrije Universiteit Brussel, Belgium

Università Politecnia delle Marche, Italy

N A Dumont

D Proverbs

PUC-Rio, Brazil

Birmingham City University, UK

A Galiano-Garrigos

T Rang

University of Alicante, Spain

Tallinn Technical University, Estonia

F Garzia

G Rzevski

University of Rome “La Sapienza”, Italy

The Open University, UK

M Hadfield

P Skerget

University of Bournemouth, UK

University of Maribor, Slovenia

S Hernández

B Sundén

University of A Coruña, Spain

Lund University, Sweden

J T Katsikadelis

Y Villacampa Esteve

National Technical University of Athens, Greece

Universidad de Alicante, Spain

J W S Longhurst

P Vorobieff

University of the West of England, UK

University of New Mexico, USA

E Magaril

S S Zubir

Ural Federal University, Russia

Universiti Teknologi Mara, Malaysia

S Mambretti Politecnico di Milano, Italy

Editorial Board

B Abersek University of Maribor, Slovenia Y N Abousleiman University of Oklahoma, USA K S Al Jabri Sultan Qaboos University, Oman D Almorza Gomar University of Cadiz, Spain J A C Ambrosio IDMEC, Portugal A M Amer Cairo University, Egypt S A Anagnostopoulos University of Patras, Greece E Angelino A.R.P.A. Lombardia, Italy H Antes Technische Universitat Braunschweig, Germany M A Atherton South Bank University, UK A G Atkins University of Reading, UK D Aubry Ecole Centrale de Paris, France J Augutis Vytautas Magnus University, Lithuania H Azegami Toyohashi University of Technology, Japan J M Baldasano Universitat Politecnica de Catalunya, Spain J Barnes University of the West of England, UK J G Bartzis Institute of Nuclear Technology, Greece S Basbas Aristotle University of Thessaloniki, Greece A Bejan Duke University, USA M P Bekakos Democritus University of Thrace, Greece G Belingardi Politecnico di Torino, Italy R Belmans Katholieke Universiteit Leuven, Belgium C D Bertram The University of New South Wales, Australia D E Beskos University of Patras, Greece S K Bhattacharyya Indian Institute of Technology, India H Bjornlund University of South Australia, Australia E Blums Latvian Academy of Sciences, Latvia J Boarder Cartref Consulting Systems, UK B Bobee Institut National de la Recherche Scientifique, Canada H Boileau ESIGEC, France M Bonnet Ecole Polytechnique, France C A Borrego University of Aveiro, Portugal A R Bretones University of Granada, Spain J A Bryant University of Exeter, UK F-G Buchholz Universitat Gesanthochschule Paderborn, Germany

M B Bush The University of Western Australia, Australia F Butera Politecnico di Milano, Italy W Cantwell Liverpool University, UK C Capilla Universidad Politecnica de Valencia, Spain D J Cartwright Bucknell University, USA P G Carydis National Technical University of Athens, Greece J J Casares Long Universidad de Santiago de Compostela, Spain M A Celia Princeton University, USA A Chakrabarti Indian Institute of Science, India F Chejne National University, Colombia J-T Chen National Taiwan Ocean University, Taiwan J Chilton University of Lincoln, UK C-L Chiu University of Pittsburgh, USA H Choi Kangnung National University, Korea A Cieslak Technical University of Lodz, Poland C Clark Wessex Institute, UK S Clement Transport System Centre, Australia M C Constantinou State University of New York at Buffalo, USA D E Cormack University of Toronto, Canada M da C Cunha University of Coimbra, Portugal D F Cutler Royal Botanic Gardens, UK W Czyczula Krakow University of Technology, Poland L D’Acierno Federico II University of Naples, Italy L Dávid Károly Róbert College, Hungary A Davies University of Hertfordshire, UK M Davis Temple University, USA A B de Almeida Instituto Superior Tecnico, Portugal E R de Arantes e Oliveira Instituto Superior Tecnico, Portugal L De Biase University of Milan, Italy R de Borst Delft University of Technology, Netherlands G De Mey University of Ghent, Belgium A De Montis Universita di Cagliari, Italy A De Naeyer Universiteit Ghent, Belgium N De Temmerman Vrijie Universiteit Brussel, Belgium D De Wrachien State University of Milan, Italy L Debnath University of Texas-Pan American, USA

G A Degan Università Roma Tre, Italy G Degrande Katholieke Universiteit Leuven, Belgium S del Giudice University of Udine, Italy G Deplano Universita di Cagliari, Italy M Domaszewski Universite de Technologie de Belfort-Montbeliard, France K Dorow Pacific Northwest National Laboratory, USA W Dover University College London, UK C Dowlen South Bank University, UK J P du Plessis University of Stellenbosch, South Africa R Duffell University of Hertfordshire, UK A Ebel University of Cologne, Germany V Echarri University of Alicante, Spain G K Egan Monash University, Australia K M Elawadly Alexandria University, Egypt S Elghobashi University of California Irvine, USA K-H Elmer Universitat Hannover, Germany D Elms University of Canterbury, New Zealand M E M El-Sayed Kettering University, USA D M Elsom Oxford Brookes University, UK F Erdogan Lehigh University, USA D J Evans Nottingham Trent University, UK J W Everett Rowan University, USA M Faghri University of Rhode Island, USA R A Falconer Cardiff University, UK M N Fardis University of Patras, Greece A Fayvisovich Admiral Ushakov Maritime State University, Russia P Fedelinski Silesian Technical University, Poland H J S Fernando Arizona State University, USA S Finger Carnegie Mellon University, USA W F Florez-Escobar Universidad Pontifica Bolivariana, South America E M M Fonseca Instituto Politécnico de Bragança, Portugal J I Frankel University of Tennessee, USA D M Fraser University of Cape Town, South Africa M J Fritzler University of Calgary, Canada U Gabbert Otto-von-Guericke Universitat Magdeburg, Germany G Gambolati Universita di Padova, Italy C J Gantes National Technical University of Athens, Greece L Gaul Universitat Stuttgart, Germany A Genco University of Palermo, Italy N Georgantzis Universitat Jaume I, Spain P Giudici Universita di Pavia, Italy L M C Godinho University of Coimbra, Portugal

F Gomez Universidad Politecnica de Valencia, Spain R Gomez Martin University of Granada, Spain A Gonzales Aviles University of Alicante, Spain D Goulias University of Maryland, USA K G Goulias Pennsylvania State University, USA F Grandori Politecnico di Milano, Italy W E Grant Texas A & M University, USA S Grilli University of Rhode Island, USA R H J Grimshaw Loughborough University, UK D Gross Technische Hochschule Darmstadt, Germany R Grundmann Technische Universitat Dresden, Germany A Gualtierotti IDHEAP, Switzerland O T Gudmestad University of Stavanger, Norway R C Gupta National University of Singapore, Singapore J M Hale University of Newcastle, UK K Hameyer Katholieke Universiteit Leuven, Belgium C Hanke Danish Technical University, Denmark Y Hayashi Nagoya University, Japan L Haydock Newage International Limited, UK A H Hendrickx Free University of Brussels, Belgium C Herman John Hopkins University, USA I Hideaki Nagoya University, Japan D A Hills University of Oxford, UK W F Huebner Southwest Research Institute, USA J A C Humphrey Bucknell University, USA M Y Hussaini Florida State University, USA W Hutchinson Edith Cowan University, Australia T H Hyde University of Nottingham, UK M Iguchi Science University of Tokyo, Japan L Int Panis VITO Expertisecentrum IMS, Belgium V Iribarren University of Alicante, Spain N Ishikawa National Defence Academy, Japan H Itoh University of Nagoya, Japan J Jaafar UiTm, Malaysia W Jager Technical University of Dresden, Germany Y Jaluria Rutgers University, USA P R Johnston Griffith University, Australia D R H Jones University of Cambridge, UK N Jones University of Liverpool, UK

N Jovanovic CSIR, South Africa D Kaliampakos National Technical University of Athens, Greece D L Karabalis University of Patras, Greece A Karageorghis University of Cyprus M Karlsson Linkoping University, Sweden T Katayama Doshisha University, Japan K L Katsifarakis Aristotle University of Thessaloniki, Greece E Kausel Massachusetts Institute of Technology, USA H Kawashima The University of Tokyo, Japan B A Kazimee Washington State University, USA F Khoshnaw Koya University, Iraq S Kim University of Wisconsin-Madison, USA D Kirkland Nicholas Grimshaw & Partners Ltd, UK E Kita Nagoya University, Japan A S Kobayashi University of Washington, USA T Kobayashi University of Tokyo, Japan D Koga Saga University, Japan S Kotake University of Tokyo, Japan A N Kounadis National Technical University of Athens, Greece W B Kratzig Ruhr Universitat Bochum, Germany T Krauthammer Penn State University, USA C-H Lai University of Greenwich, UK R Laing Robert Gordon University, UK M Langseth Norwegian University of Science and Technology, Norway B S Larsen Technical University of Denmark, Denmark F Lattarulo Politecnico di Bari, Italy A Lebedev Moscow State University, Russia L J Leon University of Montreal, Canada D Lesnic University of Leeds, UK D Lewis Mississippi State University, USA K-C Lin University of New Brunswick, Canada A A Liolios Democritus University of Thrace, Greece D Lippiello Università degli Studi Roma Tre, Italy S Lomov Katholieke Universiteit Leuven, Belgium G Loo The University of Auckland, New Zealand J Lourenco Universidade do Minho, Portugal J E Luco University of California at San Diego, USA H Lui State Seismological Bureau Harbin, China C J Lumsden University of Toronto, Canada

L Lundqvist Division of Transport and Location Analysis, Sweden T Lyons Murdoch University, Australia L Mahdjoubi University of the West of England, UK Y-W Mai University of Sydney, Australia M Majowiecki University of Bologna, Italy D Malerba Università degli Studi di Bari, Italy G Manara University of Pisa, Italy B N Mandal Indian Statistical Institute, India Ü Mander University of Tartu, Estonia H A Mang Technische Universitat Wien, Austria G D Manolis Aristotle University of Thessaloniki, Greece N Marchettini University of Siena, Italy J D M Marsh Griffith University, Australia J F Martin-Duque Universidad Complutense, Spain T Matsui Nagoya University, Japan G Mattrisch DaimlerChrysler AG, Germany F M Mazzolani University of Naples “Federico II”, Italy K McManis University of New Orleans, USA A C Mendes Universidade de Beira Interior, Portugal J Mera Polytechnic University of Madrid, Spain R A Meric Research Institute for Basic Sciences, Turkey J Mikielewicz Polish Academy of Sciences, Poland R A W Mines University of Liverpool, UK C A Mitchell University of Sydney, Australia K Miura Kajima Corporation, Japan A Miyamoto Yamaguchi University, Japan T Miyoshi Kobe University, Japan G Molinari University of Genoa, Italy F Mondragon Antioquin University, Colombia T B Moodie University of Alberta, Canada D B Murray Trinity College Dublin, Ireland G Nakhaeizadeh DaimlerChrysler AG, Germany M B Neace Mercer University, USA D Necsulescu University of Ottawa, Canada F Neumann University of Vienna, Austria B Ning Beijing Jiatong University, China S-I Nishida Saga University, Japan H Nisitani Kyushu Sangyo University, Japan B Notaros University of Massachusetts, USA P O’Donoghue University College Dublin, Ireland R O O’Neill Oak Ridge National Laboratory, USA M Ohkusu Kyushu University, Japan

G Oliveto Universitá di Catania, Italy R Olsen Camp Dresser & McKee Inc., USA E Oñate Universitat Politecnica de Catalunya, Spain K Onishi Ibaraki University, Japan P H Oosthuizen Queens University, Canada E L Ortiz Imperial College London, UK E Outa Waseda University, Japan O Ozcevik Istanbul Technical University, Turkey A S Papageorgiou Rensselaer Polytechnic Institute, USA J Park Seoul National University, Korea F Patania Universitá di Catania, Italy B C Patten University of Georgia, USA G Pelosi University of Florence, Italy G G Penelis Aristotle University of Thessaloniki, Greece W Perrie Bedford Institute of Oceanography, Canada R Pietrabissa Politecnico di Milano, Italy M F Platzer Naval Postgraduate School, USA D Prandle Proudman Oceanographic Laboratory, UK M Predeleanu University Paris VI, France R Pulselli University of Siena, Italy I S Putra Institute of Technology Bandung, Indonesia Y A Pykh Russian Academy of Sciences, Russia A Rabasa University Miguel Hernandez, Spain F Rachidi EMC Group, Switzerland K R Rajagopal Texas A & M University, USA J Rao Case Western Reserve University, USA J Ravnik University of Maribor, Slovenia A M Reinhorn State University of New York at Buffalo, USA G Reniers Universiteit Antwerpen, Belgium A D Rey McGill University, Canada D N Riahi University of Illinois at UrbanaChampaign, USA B Ribas Spanish National Centre for Environmental Health, Spain K Richter Graz University of Technology, Austria S Rinaldi Politecnico di Milano, Italy F Robuste Universitat Politecnica de Catalunya, Spain J Roddick Flinders University, Australia A C Rodrigues Universidade Nova de Lisboa, Portugal F Rodrigues Poly Institute of Porto, Portugal G R Rodríguez Universidad de Las Palmas de Gran Canaria, Spain C W Roeder University of Washington, USA

J M Roesset Texas A & M University, USA W Roetzel Universitaet der Bundeswehr Hamburg, Germany V Roje University of Split, Croatia R Rosset Laboratoire d’Aerologie, France J L Rubio Centro de Investigaciones sobre Desertificacion, Spain T J Rudolphi Iowa State University, USA S Russenchuck Magnet Group, Switzerland H Ryssel Fraunhofer Institut Integrierte Schaltungen, Germany S G Saad American University in Cairo, Egypt M Saiidi University of Nevada-Reno, USA R San Jose Technical University of Madrid, Spain F J Sanchez-Sesma Instituto Mexicano del Petroleo, Mexico B Sarler Nova Gorica Polytechnic, Slovenia S A Savidis Technische Universitat Berlin, Germany A Savini Universita de Pavia, Italy G Schleyer University of Liverpool, UK G Schmid Ruhr-Universitat Bochum, Germany R Schmidt RWTH Aachen, Germany B Scholtes Universitaet of Kassel, Germany W Schreiber University of Alabama, USA A P S Selvadurai McGill University, Canada J J Sendra University of Seville, Spain S M Şener Istanbul Technical University, Turkey J J Sharp Memorial University of Newfoundland, Canada Q Shen Massachusetts Institute of Technology, USA X Shixiong Fudan University, China I V Shtangeeva St Petersburg University, Russia G C Sih Lehigh University, USA L C Simoes University of Coimbra, Portugal A C Singhal Arizona State University, USA J Sladek Slovak Academy of Sciences, Slovakia V Sladek Slovak Academy of Sciences, Slovakia A C M Sousa University of New Brunswick, Canada H Sozer Illinois Institute of Technology, USA P D Spanos Rice University, USA T Speck Albert-Ludwigs-Universitaet Freiburg, Germany C C Spyrakos National Technical University of Athens, Greece J Stasiek Technical University of Gdansk, Poland G E Swaters University of Alberta, Canada

S Syngellakis Wessex Institute, UK J Szmyd University of Mining and Metallurgy, Poland S T Tadano Hokkaido University, Japan H Takemiya Okayama University, Japan I Takewaki Kyoto University, Japan C-L Tan Carleton University, Canada E Taniguchi Kyoto University, Japan S Tanimura Aichi University of Technology, Japan J L Tassoulas University of Texas at Austin, USA M A P Taylor University of South Australia, Australia A Terranova Politecnico di Milano, Italy A G Tijhuis Technische Universiteit Eindhoven, Netherlands T Tirabassi National Research Council, Italy S Tkachenko Otto-von-Guericke-University, Germany N Tomii Chiba Institute of Technology, Japan N Tosaka Nihon University, Japan T Tran-Cong University of Southern Queensland, Australia R Tremblay Ecole Polytechnique, Canada I Tsukrov University of New Hampshire, USA R Turra CINECA Interuniversity Computing Centre, Italy S G Tushinski Moscow State University, Russia E Van den Bulck Katholieke Universiteit Leuven, Belgium D Van den Poel Ghent University, Belgium R van der Heijden Radboud University, Netherlands

R van Duin Delft University of Technology, Netherlands P Vas University of Aberdeen, UK R Verhoeven Ghent University, Belgium A Viguri Universitat Jaume I, Spain J F V Vincent University of Bath, UK S P Walker Imperial College, UK G Walters University of Exeter, UK B Weiss University of Vienna, Austria H Westphal University of Magdeburg, Germany T W Wu University of Kentucky, USA Z-Y Yan Peking University, China S Yanniotis Agricultural University of Athens, Greece A Yeh University of Hong Kong, China B W Yeigh SUNY Institute of Technology, USA J Yoon Old Dominion University, USA K Yoshizato Hiroshima University, Japan T X Yu Hong Kong University of Science & Technology, Hong Kong M Zador Technical University of Budapest, Hungary R Zainal Abidin Infrastructure University Kuala Lumpur, Malaysia K Zakrzewski Politechnika Lodzka, Poland M Zamir University of Western Ontario, Canada G Zappalà National Research Council, Italy R Zarnic University of Ljubljana, Slovenia G Zharkova Institute of Theoretical and Applied Mechanics, Russia N Zhong Maebashi Institute of Technology, Japan H G Zimmermann Siemens AG, Germany

The Sustainable City XII Editors C.A. Brebbia Wessex Institute, UK J.J. Sendra University of Seville, Spain

Editors:

C.A. Brebbia Wessex Institute, UK J.J. Sendra University of Seville, Spain Published by WIT Press Ashurst Lodge, Ashurst, Southampton, SO40 7AA, UK Tel: 44 (0) 238 029 3223; Fax: 44 (0) 238 029 2853 E-Mail: [email protected] http://www.witpress.com For USA, Canada and Mexico Computational Mechanics International Inc 25 Bridge Street, Billerica, MA 01821, USA Tel: 978 667 5841; Fax: 978 667 7582 E-Mail: [email protected] http://www.witpress.com

British Library Cataloguing-in-Publication Data A Catalogue record for this book is available from the British Library ISBN: 978-1-78466-217-2 eISBN: 978-1-78466-218-9 ISSN: 1746-448X (print) ISSN: 1743-3541 (online) The texts of the papers in this volume were set individually by the authors or under their supervision. Only minor corrections to the text may have been carried out by the publisher. No responsibility is assumed by the Publisher, the Editors and Authors for any injury and/or damage to persons or property as a matter of products liability, negligence or otherwise, or from any use or operation of any methods, products, instructions or ideas contained in the material herein. The Publisher does not necessarily endorse the ideas held, or views expressed by the Editors or Authors of the material contained in its publications. © WIT Press 2018 Printed in Great Britain by Lightning Source, UK. All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, recording, or otherwise, without the prior written permission of the Publisher.

Preface

This Volume contains some of the papers presented at the 12th International Conference on Urban Regeneration and Sustainability held in Seville, organised by the Wessex Institute, UK and the University of Seville. The Conference was sponsored by the International Journal of Sustainable Development & Planning and WIT Transactions on Ecology and the Environment. The Sustainable City 2017 conference follows a series of very successful meetings that started in Rio (2000), followed by Segovia (2002), Siena (2004), Tallinn (2006), Skiathos (2008), A Coruña (2010), Ancona (2012), Kuala Lumpur (2013), Siena (2014), Medellin (2015) and Alicante (2016). The meeting addresses the multidisciplinary components of urban planning, the challenges presented by the increasing size of the cities, the amount of resources required and the complexity of modern society. It always attracts a substantial number of contributions from participants from different backgrounds and countries and aims to address all the aspects of urban environment aiming to provide solutions leading towards sustainability. The variety of topics and experiences is one of the main reasons behind the success of the series. The challenge of planning sustainable contemporary cities lies in considering the dynamics of urban systems, exchange of energy and matter, and the function and maintenance of ordered structures directly or indirectly supplied and maintained by natural systems. The task of researchers, aware of the complexity of the contemporary city, is to improve the capacity to manage human activities, pursuing welfare and prosperity in the urban environment. Any investigation or planning on a city ought to consider the relationships between the parts and their connections with the living world. The dynamics of its networks (flows of energy matter, people, goods, information and other resources) are fundamental for an understanding of the evolving nature of today’s cities. Large cities are probably the most complex mechanisms to manage. They represent a fertile ground for architects, engineers, city planners, social and political scientists, and other professionals able to conceive new ideas and time them according to technological advances and human requirements. Papers contained in this book, as well as those from previous conferences since 2000, have been archived in the eLibrary of the Wessex Institute (http://www.witpress.com/elibrary) where they are permanently accessible to the international scientific community. The Editors are grateful to the reviewers, as well as to the authors for their contributions. The Editors Seville

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Contents Section 1: Urban strategies Accelerating urban transition: an approach to greening the built environment Andrea Boeri, Jacopo Gaspari, Valentina Gianfrate & Danila Longo ................................. 3 The city of Ostrava (Czech Republic): a sustainability assessment based on vitality Martin Nedvěd & Martina Peřinková .................................................................................. 15 Urban roads and social metabolism: a sustainable development strategy for San Juan, Puerto Rico María Helena Luengo De Arreaza ...................................................................................... 27 Sustainable development for recovering economic crisis: a possible solution for Brazil Amanda Campelo & Diego Fontenele ................................................................................. 39 Alternative solutions for urban housing: the case of Batıkent settlement, Ankara, Turkey Melike Atici .......................................................................................................................... 47 Saharan city and the problems of urban structure: a case of the micro-region of Sidi Okba, Algeria Bensmina Latoui & Farhi Abdallah .................................................................................... 59 Section 2: Urban conservation and regeneration Considering new urbanism, new ruralism and green urbanism in response to multifunctionality: the case of Verkykerskop, South Africa Jako Viviers, Selna G. Cornelius & Elizelle J. Cilliers ....................................................... 73 Adaptive reuse as an effort to preserve an historical district: a case study of the Braga corridor in the city centre of Bandung, Indonesia Nurtati Soewarno, Taufan Hidjaz & Eka Virdianti ............................................................. 89 Hedonic pricing model for the economic valuation of conservation land in Mexico City Estebania Teyeliz Martínez-Jiménez, Enrique Pérez-Campuzano & Alonso Aguilar Ibarra ................................................................................................... 101

Impact of gentrification on the degree of satisfaction of residents in residential areas Noory Han, Yong-Hee Kim, Jea-Sun Lee .......................................................................... 113 Urban regeneration with carbon economy Bülent Yalazi, Tuğçe Sönmez Saner, Ayşe Şeyma Manap, Evren Sayin & Onat Çağatay Muşta...................................................................................................... 125 The relationship between conservation-revitalization projects and site management plan: a case study for Suleymaniye Mosque and its environs Koray Özcan & Şaziye Bal ................................................................................................ 135 Revitalisation of historic public cemeteries in central zones of urban areas Ivona Dlábiková, Klára Frolíková-Palánová & Martina Peřinková................................. 147 Section 3: Urban transportation and planning Managing the environmental adaptation of vehicle operations Alla Golubeva, Elena Magaril, Romen Magaril, Deborah Panepinto & Francesca Viggiano....................................................................................................... 161 A new look in designing sustainable city logistics road pricing schemes Armando Carteni ............................................................................................................... 171 Section 4: Architectural issues Sustainable architecture: building design method integrating user’s comfort, adaptive building, passive optimized building and building integrated PV – experiences from a university course Udo Dietrich & Miriam Posselt ........................................................................................ 185 Emerging trends of tropical residential buildings in the Pacific-Rim region in the age of globalization: based on case analysis in China, Costa Rica and Australia Zeyang Yu .......................................................................................................................... 199 Urban landscape: from urban beautification to sustainable landscape development Esa Ahmad & Mazifah Simis ............................................................................................. 207 Let in the wind: a passive design paradigm for large buildings in the inner city of Shanghai and Singapore Qianning Zhang & Stephen Siu Yu Lau ............................................................................. 215 Section 5: Spatial conflicts in the city Cultural conflict and public space: a new conceptualization Francisco González de Canales & Nuria Álvarez Lombardero ........................................ 229

Considering planning approaches in the global south and learning from co-production in South Africa’s informal backyard rental sector Louis G. Lategan & Elizelle J. Cilliers .............................................................................. 241 Section 6: Intelligent environment The importance of design in helping humanity become a multi-planetary species Camilo Cerro ..................................................................................................................... 255 Implementation of augmented reality and location-based services to regional development Michal Gregor & Jakub Trojan ......................................................................................... 265 Section 7: Quality of life Liveable public urban spaces: criteria for assessment and design Udo Dietrich & Greta Kirchberg Erto .............................................................................. 273 Quality of urban life and its relationship to spatial conditions Ana L. Alvarez & Daniela Müller-Eie ............................................................................... 285 The role of the people’s park in promoting conviviality and quality of life in increasingly diverse urban neighbourhoods Maria Beltran-Rodriguez & Madlen Simon ...................................................................... 297 Criteria for sustainable interior design solutions Wael Rashdan & Ayman Fathy Ashour ............................................................................. 311 Convenience stores as an urban culture space for young people in West Jakarta, Indonesia Puguh Hariyanto, Jachrizal Soemabrata, Komara Djaja & Ahmad Zubair ..................... 323 Section 8: Cultural heritage sites Urban transport vibrations and cultural heritage sites in Rome: the cases of the Temple of Minerva Medica and of the Catacomb of Priscilla Ivan Roselli, Vincenzo Fioriti, Irene Bellagamba, Marialuisa Mongelli, Angelo Tatì, Mariarosaria Barbera, Marina Magnani Cianetti & Gerardo De Canio ......................................................................................................... 335 Progress, mobility and urban regeneration in a traditional neighbourhood: El Encino, Mexico Alejandro Acosta Collazo .................................................................................................. 345

Urban problematic of cultural management in historical fragments in Istanbul: a case study in Fener-Balat and Süleymaniye Canan Gülseren İnan......................................................................................................... 357 Historic masonry monitoring by motion magnification analysis Vincenzo Fioriti, Ivan Roselli, Angelo Tatì & Gerardo De Canio .................................... 367 Editing the ordinary: exceptional rendition of the Ngo-Ka-Ki House Mohd Fairus Kholid, Puteri Mayang Bahjah Zaharin & Kartini Kasmuri ....................... 377 Surabaya old town new life: reconstructing the historic city through urban artefacts Puteri Mayang Bahjah Zaharin & Noor Izzati Mohd Rawi............................................... 389 Urban stage transcript: mapping performance spaces in a heritage urban parcel Kartini Kasmuri, Nur Atiqah Husaini & Fairuz Reza Razali ............................................ 401 Section 9: The community and the city Considering complexities in unique African planning approaches: abstracting the role of African urban residents Selna G. Cornelius, Jako Viviers, Juanee Cilliers & Christi Niesing................................ 415 Feeling of being out of place: a case study of Kampung in Bumi Serpong Damai, Indonesia Dian Alin Mulyasari & Antony Sihombing ........................................................................ 427 Bottom up approach: KANCIL, the strive of local informal communities Daniel Mambo Tampi, Widyawati Sumadio, Jachrizal Sumabrata, Joe Anggiat & Esty Suyanti ............................................................................................... 437 Health Fair: community involvement and ownership in event planning Abu Hasib Mostafa Jamal, Zeenat Sultana & A. K. Shafiqur Rahman.............................. 447 Section 10: Environmental management The use of the DPSIR framework to estimate impacts of urbanization on mangroves: a case study from La Paz, Baja California Sur, Mexico Giovanni Ávila-Flores,Gustavo Hinojosa-Arango, Judith Juárez-Mancilla & Oscar Arizpe-Covarrubias ............................................................................................ 459 Temporal analysis of the effect of urbanization on surface runoff in four neighbourhoods in the city of Umuarama in Paraná, Brazil Thays Mitsuko Tsuji, Carlos Henrique Oliva Grudzin Braga & Christopher Yuity Kuroda ............................................................................................. 471

Impact performance of low cement ultra-high-performance concrete Norzaireen Mohd Azmee & Muhd Fadhil Nuruddin ......................................................... 481 Section 11: Planning, development and management Land-use planning for zero-energy-buildings: comparison of four high-density cities Hsiao-Hui Chen & Udo Dietrich ....................................................................................... 491 Section 12: Planning for risk and natural hazards Mitigating projected impacts of climate change and building resiliency through permaculture: a community ‘Bee Inspired Gardens’ movement in the desert southwest, USA Roslynn Brain, Jeffrey Adams & Jeremy Lynch ................................................................ 505 A comparative analysis of the level of urban resilience in the city comprehensive plan Kim Min-Seok, You-Mi Jeon & Jea-Sun Lee ..................................................................... 517 Section 13: Waste management A case study of innovative businesses involved with efficient municipal solid waste management in Islamabad, Pakistan Ghulam Sarwar Sandhu & Malik Asghar Naeem .............................................................. 529 Thermal performance, usage behaviour and food waste of domestic refrigerators in a university student community: findings towards cities sustainability Diogo Galvão, Pedro Dinis Gaspar, Pedro Dinho da Silva & Luís Pires ........................ 539 Material management practices for construction waste reduction Lilliana Abarca-Guerrero & Ana Grettel Leandro-Hernandez......................................... 551 Transshipment station for urban solid waste: an analysis considering city logistics concepts Leise Kelli De Oliveira, Renata Lúcia Magalhães De Oliveira & Lilian Silvia Teixeira De Avelar Rueda ......................................................................... 559 Section 14: Water resources Climate changes and drinking water in sustainable cities: impacts and adaptation Manuel Rodriguez & Ianis Delpla ..................................................................................... 573

Membrane selection for organic contaminants removal from Hartbeespoort dam water in South Africa Amos Adeniyi, Richard Mbaya, Maurice Onyango, Patricia Popoola & Thabo Brooms ............................................................................................................... 583 Author index .................................................................................................................... 593

SECTION 1 URBAN STRATEGIES


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URBAN ROADS AND SOCIAL METABOLISM: A SUSTAINABLE DEVELOPMENT STRATEGY FOR SAN JUAN, PUERTO RICO MARÍA HELENA LUENGO DE ARREAZA Puerto Rico University, Puerto Rico

ABSTRACT The present work explores the relationship between an urban road with both, socio-metabolic processes and natural systems patterns. The premise is that roads have a decisive impact on energy, material flows and connectivity between biological structures. Therefore, urban metabolism - Social and natural processes measured out of energy use, material flows and land use - becomes the appropriate instrument to assess and analyze the functionality of the different components operating in artificial and natural systems. The case study traces the metabolic behaviors that result from the cross of Juan Ponce de León Avenue through the water system composed by the estuary of Martin Peña and Río Piedras River. A theoretical framework based on social equity, economy, and ecology is being applied in data collection and analysis. Parametric methodologies and GIS information are used to describe the structural and functional properties of both natural and urban systems. The collected data enable the understanding that the simultaneous loss of energy efficiency and land-use efficiency from the mid20th century to the present affects the resilience of the area. Consequently, this exploration demonstrates the importance of urban metabolism in maintaining the ecological quality of natural systems. As a result, it proposes an urban metabolism strategy to develop more sustainable urban schemes for the systems composed of urban roads and natural ecosystems. The organized complexity of the water system, necessary to host biodiversity and fundamental ecological processes, cannot be guaranteed if the urban metabolism is not taken into account. Keywords: urban metabolism, urban roads, resilience, urban sustainability.

1 INTRODUCTION The cultural landscapes have been imprinting its traces on a palimpsest that reminiscent of different times in which human activity has shaped the environment. In this palimpsest, the streets have left their indelible mark. The problem that concerns this work lies in the purpose of these traces. Accordingly, with the fundamental aim of connecting and facilitating displacement, other functions of the street linked to natural and social processes occurring in the city should be recognized. In this sense, are developed four key themes. The first theme is presented a historical view of the street, highlighting its role in the urban metabolism. The second theme addresses the change in the relationship between street and urban metabolism from the industrial revolution due to the creation of new materials, the intensity of vehicular use and the growth of the city. The third theme sketches the importance of the vehicular routes in the model of urban development of San Juan, a pattern that can be recognized similar in different Latin American cities and the industrialized world in general. The fourth theme presents the case study and finally is presented a proposal that exposes the opportunities of the street to become a concatenator of the metabolic processes in a case study: Juan Ponce de León Avenue in the city of San Juan in Puerto Rico. 2 STREETS AND URBAN METABOLISM The urban metabolism has its origin in recognition of the limits that impose the natural and social resources to the industrial models of making the city. Fisher-Kowalski [1], defines it

WIT Transactions on Ecology and The Environment, Vol 223, © 2017 WIT Press www.witpress.com, ISSN 1743-3541 (on-line) doi:10.2495/SC170031

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as a process composed of biophysical inputs and outputs summarized in the materials and energy that are extracted from the environment and are treated (ingested) by society. Some of these materials are accumulated as a socioeconomic stock while another part is thrown into the environment in the form of waste or polluting emissions. Beyond the accounting of raw materials, manufacturing, waste, and energy, urban metabolism should understand as a social practice. Therefore, there is a visible and quantifiable part that manifested in material and energy flows beside an immaterial part determined by the institutions and the ensuing symbolic and social systems. Both parts, material and immaterial, determine each other [2]. Thus, each society shapes its urban metabolism regarding the relationships establishes with its environment. Organic-based pre-industrial cities teach that the street was an essential part of the urban metabolism configuration. So, the artificial basins defined by the layout of the streets concerning the system of fountains and channels work as an orchestrated machinery that contributed to feeding the orchards of the urban periphery. Fig. 1 below shows an orchard feeding a pond that collects runoff water from areas of higher elevation in Brañas del Sar, Santiago de Compostela. Next, to this image, Fig. 2 shows the layout of the Castillo del Morro’s floor, its configuration reflects the intended gesture of water collection, integrating aesthetics and functions values. The hydrological system determined for a long time the scheme for spatial organization of houses, cultivation areas, morphology, and plot of streets, in general terms, the relationship between the city and its surroundings. The preponderance of water in the design of the city is why this has always been the most quantitatively significant flow of those circulate through its metabolism. Consequently, the street, in the pre-industrial city, the concatenator. It was not, as at present, strictly a means of displacement. The slopes were oriented to lead the runoff to the orchards in the agricultural fields that bordered the city and fed with the fertility of the organic material carried by the water and deposited there. The level of permeability modified with the intention that was having concerning the water. Thus, the street worked, in some cases, as a channel, to lead the water toward the orchards or cisterns, in other cases worked as a permeable surface that by absorption allowed the reduction of the runoff. The street was part of an articulated urban design and natural processes; on the one hand, its benefits were taken advantage of, such as irrigation and water storage, and on the other, phenomena such as torrential rains were reduced. For organically based societies - those that still survive -, the primary resources for its subsistence come from a biosphere management that must ensure maintenance and

Figure 1: Water Management. Brañas del Sar Santiago de Compestela.

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Figure 2: Layout of Castillo del Morro’s floor. San Juan, Puerto Rico. reproduction. The balance in relationships to the environment not only allows the meeting needs but also represent a guarantee of survival. These societies depend on its surroundings, so, the closure of metabolic cycles should be a condition. Therefore, the lessons of these societies, allow us to recognize that is important to recover some kindness of the street. This reading can contribute to responding to the challenges of the present city and advanced towards sustainable future. 3 THE DEVELOPMENT PROCESS OF THE CITY LINKED TO THE STREETS AND THE IMPACTS ON URBAN METABOLISM For pre-industrial or organic-based society, the resource management was the basis of its survival, more not for industrial-based society, which can become independent of the fertility of its soils because the resources are obtained from distant lands. The discovery of new ways of achieving energy on a larger scale has generated great changes in the relationship between human habitat and natural processes. Industrial system has progressed in a type of knowledge and technology appropriate to a society independent of the organic basis. The new model considered energy and material flow as inputs and not as part of processes that require a continuous regeneration. This unlinking between natural and social processes was possible because of the accessibility to fossil fuels as energy, a source capable of providing work and energy. Organic technical systems must have nutrient recycling strategies, the closure of material cycles and the waste returns to the environment to ensure future resources. Nothing similar occurs to an industrial system: the availability of the resource in the mines does not depend on the return to waste to it. On the contrary, waste is a nuisance that distorts the efficiency of the industrial system, therefore should be removed as soon as possible. The productive value of the waste was shattered with linear metabolism, in which the materials are extracted from the earth's crust, are transformed into usefulness products by the industrial processes to meet social needs, are consumed, and, consequently, degraded and discharged into the environment. So, this mineral-based industrial technical system is a waste production system. As a result, has led a cut with natural processes that cause the deterioration of the environment that supports life on earth.



This linear metabolism that characterizes the current urban model has transformed the landscape faster than any other process of any another time of history. New materials allowed the rapid infrastructures construction. The asphalt enables the extension of the road network by all the confine, and with this, increase the use of private vehicle use, access to a significant percentage of the population. Linear metabolism also made it possible to create new types of roads other than the street. The change in the intensity of vehicular use resulted in new needs for faster movement, which were covered by the expressway, in which the relationship between persons and environment changed completely. The fragment produced by these roads to the landscape is very evident. However, it is not the only fragment, these roads also affect the sociocultural level, as ancestral customs. There were a lot of ancient grazing routes, linked to a cultural landscape, that has been modified or eliminated. Something different happens to the arteries or main streets of the city, defined as those that connect and distribute the vehicles between the various areas. These roads allow a different relationship between the public space, the urban elements, and the pedestrian. The main street gives entry to the city and connects with the secondary streets. Goes through commercial, cultural, and institutional areas, and leads to public spaces. The speed of its routes allows the driver to observe the buildings and its urban identity elements, and form a sketched of the city, unlike the expressway, which, even if it passes through the downtown, does not allow its recognition. These qualities of the main street are an opportunity to make use of the unifying potential given by its functional pre-eminence and relationship with the city and concatenate it with the processes of urban metabolism. The main street, currently covered by waterproof tarmac and a usually collapsed sewerage system, could resume the channeling role of the metabolic flows and make them visible. The visibility of natural processes, such as the cycles of water and raw materials, contributes to generating links between people and the natural environment. This links translates into practice pointed to maintaining and preserving the health and the the environmental productivity. 4 BRIEF HISTORICAL REVIEW OF THE URBAN DEVELOPMENT OF THE CITY OF SAN JUAN AND ITS ROAD SYSTEM An analysis of San Juan urban development is fundamental to understand the relevance to its road system in relationship to the city model. The low density and the dispersed pattern of the residential areas stand out as a relevant feature. The pre-eminence of the metropolitan area, where more than half of the population of the island lives, have most of the services concentrated. However, this was not always the case. Initially, the inhabitants of San Juan settled on the islet, whose strategic location motivated the construction of walls, fortresses, and the establishment of administrative headquarters. It could be recognized significant reminiscences of an urban design linked to natural processes in Old San Juan. Even though cisterns are currently in disuse, there are a lot with different capacities. The antic houses collected the water through the roofs and canals of the central patios. Larger buildings such as the castles El Morro and San Cristóbal, or the barracks of Ballajá, also integrated into its design and configuration the management of this vital resource. Their patios through its impervious surfaces, slope orientation, and channel systems led the water toward huge cisterns. According to the United States Department of National Parks, the cisterns of the two castles could hold nearly one million



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gallons of water, about half of the annual rainfall of San Juan. This amount of water being able to supply all San Juan in the case of drought [3]. The cobbled street of Old City allows permeability and contribute to reducing the runoff. All these considerations related to the natural processes were lost with the rapid growth linked to industrialization. At the end of the 19th century, the city began to move outside the walls. Overpopulation caused wealthy families who had summer houses in different areas such as Miramar or Condado to settle there. Another important factor of urban expansion was the tramway, which facilitated the tour of the whole island and formed a circuit that led to an urban growth linked to its route, which also connects with other cities developed in the 18th century, such as Rio Piedras and Bayamón. Fig. 3 below shows the railway circuit of the Island, which corresponds to the occupation of the territory shown in Fig. 4.

Figure 3: Railway circuit of the Island. (Source: Rodney, 1925.)

Figure 4: Development Pattern of Puerto Rico: High density (Black) and Low density (Red). (Source: Martinuzzi, Gould and Ramos, 2007.)



These road networks facilitated that San Juan grew from poles with different functions. These poles are the north-south axis formed by the sectors of Old San Juan, Santurce, Hato Rey and Río Piedras; The urban center of Bayamón; The cities of Carolina, Guaynabo, and Trujillo Alto [6]. This growth of nuclei modified its pattern of the 1940s when the island incorporated the dispersed model of the United States, which promoted the suburb linked to a green image concerning nature, contrary to the reality due to the long occupation of the soil [7]. In the 1950s and 1960s, a sense of economic prosperity generated fostered foreign investment. The population has risen sharply from the 1970s. This growth slowed, in 2000 to start a downward trend, which is still declining [1]. The car played a significant role in the urban development process. In 1930 the population moved into collective transport. Accordingly, the private vehicle was limited to the families of high income. In 2015, registered 661 motor vehicles per 1000 people. [8] This statistics places Puerto Rico in one of the countries with the highest number of vehicles per person. The environmental consequences of the excessive car use are evident in various senses: CO2 emissions, social inequity, economic impact, and a decrease in urban environmental quality. As in the rest of the Latin American countries, Puerto Rico adopted not only the dispersed urban model but also the American way of life, which promotes an idea of development linked to the high consumption and relaxed lifestyle that promises, among other things, the car. With the car as the primary means of transport, urban sprawl has no physical limits. However, the residential areas isolated from urban centers, but dependent on its dynamics impoverish the quality of life of its inhabitants, who do not enjoy the best of the countryside because its landscape has been modified by moving away from the crops and greenery. The population shift from central urban areas into suburbs, characteristic of western cities motivated by the promise of a substantial increase in income and quality of life. San Juan suffered the same process, but with the difference that many of the poor who moved to the periphery remained poor. The urban planning of the island in general, and of the metropolitan area, is characterized by cities and towns surrounded by dispersing urban expansion [5]. This urban model led to the construction of an extensive road network that responds almost exclusively to car journeys. In the metropolitan area, the short stretches with bikelines are recent, and the pedestrianization is difficult due to the disconnection of the sidewalk, the lack of shade, and unsafely crossings. The road system of San Juan, not only does not respond to the pedestrian, but it also does not answer to the natural processes that inevitably affect the city. From its relationship to the water, the San Juan road system can be read as a waterproof tissue that covers the pavement from the highest to the lowest of the faint topography areas. This tissue alters the runoff and increases the risk of flooding. Consequently, the streets are overflowing, and, in some cases, buildings are affected. The most vulnerable areas are near the sea, lakes, and rivers, but there are also other sectors of the city affected due not to have adequate drainage. This situation could be different to a route planning relating to the qualities of climate, soil, and topography. This situation is because the street is conceived only as a connector that must provide a surface of displacement for the car, not as an urban element that can canalize social and natural processes, through which could flow and be in a harmonious way circumstances that in the present collide and hinder. 5 CASE STUDY Juan Ponce de León Avenue has features of urban archetype: The great street marked by the signs of a history that glorify its trace and that connects multiple sectors of the city, such as



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Alcalá Street in Madrid, The Seventh of Bogotá, or the Avenue of the Insurgents in México City. Juan Ponce de León Avenue was drawn in a rudimentary way before the Spanish Conquest, then it was widened during the colonization and was called “Central Road”, is the main connector of the capital with the Island. For centuries circulated by this way people and goods that served as support for the development of the capital and the country regarded as the backbone of the city. As a dirt road to the 16th century, it has been subject to several transformations. Known as Avenida Juan Ponce de Leon in the year 1913. This Avenue covering a total of 11.49 kilometers longed to begin in the Plaza Colón in Old San Juan as a continuation of the Fortaleza Street, the main artery of the islet. Runs northeastern - southeast through the Santurce neighborhood, which includes differentiated urban areas. Portions of the road pass-through business, financial, and commercial district of Hato Rey called Golden Mile and ended in the district of Rio Piedras, functional focus where there is the most important University Campus of the country. Predominate in this avenue institutional, cultural, educational, emblematic, and commercial buildings, as well as cultural activities and community and training centers. Highlights its pass over two natural water systems that are Martin Peña Channel and Río Piedras, estuaries of high ecological value. The junction with these natural systems, as well as the crossing with important streets, represent a potential to configure a broader system, in which this avenue would have a role that could respond to aimed for a more circular urban metabolism. This approaching is related to a growing concern for the protection of diversity has given rise in Puerto Rico to consideration of the most effective means for maintaining and improving biological habitat. Currently, Juan Ponce de León Avenue and the City of San Juan in general, are characterized by linear metabolism that expresses on impervious pavements, a sewer system that generate pollution and impact on water quality of local water bodies, and lack of waste management. There is a disconnection between the inhabitants and the natural processes that increase due to the lack of public spaces, which are important to promote the community involvement with the environment. San Juan presents a variety of squares, parks and public spaces, the problem is that they are far away from the activity centers. To this adds up problems that affect the continuity, image, and security of the avenue, such as deteriorated buildings or underutilized spaces along the way, which difficult it perception as public space. The intrinsic qualities of this Avenue cry out to come to light, the goal of this work is to its rescue and honour. 6 PROPOSAL Based on the recognition of the potential of the Juan Ponce de León Avenue, is proposed an urban metabolism transformation strategy for the city of San Juan. What is seeking is to reclaim the role that had once this great street, but raising the challenge to the current sustainable demand from its main scopes, namely, social, environmental, and economic. Below are explained the proposal foundations. Social field: In the public space is constructed the idea of the city, is a place where can be measured out encounter, tolerance, citizenship performance and urban environmental quality. How to pose (Borja and Muxi [9]), is one in which the society becomes visible. Is associative and relational, facilitates the integration and participation. This proposal aims at setting up this avenue as a backbone and seeks in this regard prioritize the pedestrianization to increase its usefulness as a social space. As well as articulate and give continuity to squares, parks,



commercial, cultural, and service areas. This network of public spaces would favor the appropriation, understood as a sense of belonging. The conception of the urban space in these terms, does not arise only from the “places” but of the relationships between people, with which, citing Smith [10], are shared memory, values, symbols, myths, and traditions. The rescue of the heritage value of this avenue could contribute to the development of the history of the present. As Augé [11] acquaint, a re-reading in which are told the transformations that led to the current reality, and that contributes to face the challenges of the future. It is well known the deterioration of many sectors of Juan Ponce de León Avenue by vandalism, a situation that could compare with the psycho-social experiment of the broken windows, the message which is being transmitted is: here nobody cares about this, this is abandoned. Contrary to this, if the public space is well taken care of and contributes to the increase of the quality of life, are built ties. In the words of Vidal and Pol [12], the appropriation facilitates environmentally responsible behaviours, as well as involvement and participation. Therefore, increase the experience of public space along the avenue is essential to achieve the sense of ownership and cooperation in its improvement and maintenance, these being the fundamental objectives of this proposal. Environmental field: according to the Council of Climatic Changes in Puerto Rico [13], almost 90% of the work-related travel is made in private vehicle, which generates a high amount of emissions of greenhouse gases. Incorporate sustainable mobility - like bicycle and pedestrian lanes - to Juan Ponce de León Avenue could decrease the emissions produced by cars, considering that this avenue connects a large part of the institutions that are sources of employment. However, this theme should be understood far beyond its landscape value or its contributions to environmental quality. This paper proposes that this avenue will configure as a large articulating machinery of urban metabolic processes. For this, it is necessary the reconfiguration of the street in two main senses: As a debugger capable of absorbing CO2 through the greening of its paths, and as manager of the runoff through its collection, driving, and filtering. Because of these functions would result in the reduction of urban situations as water logging, or heat islands, which affect the city and increase the impact of natural phenomena. The integration of The Martin Peña Channel and Rio Piedra's River ecosystems would give continuity to the biophysical matrix that has been fragmented with the paving. This strategy would allow the recovery of biodiversity, as well as scenic and environmental qualities. Opportunities that also would achieve with this system are the incorporation of other sustainable practices such an integrated sustainable mobility circuit between the estuaries and the Avenue, waste separation, and the integration of renewable energy and environmental education. All these practices are fundamentals to achieve the primary objectives of urban sustainability. Economic field: Revaluation of public space that would provide the system formed by Juan Ponce de León Avenue and its possible transverse axes would encourage investment and employment opportunities, which would result in economic prosperity. This avenue runs through areas of tourist value that are interrupted by broad depressed areas. The proposal of this urban corridor system would help to retrieve the value of the soil along its entire length. Recognizing the tourism as one of the primary economic sources of the island it can be identified that this proposal could contribute to increasing this potential. Participation of the community is considered fundamental to avoid the possible gentrification that tends to occur with these urban improvement processes. To be able to recognize the criteria on which guide the study of the Juan Ponce de León Avenue and its possible configuration as the backbone of the urban metabolism, its proposed



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a methodology aims at discovering and working with characteristics of a given locale. These features include the basics outlined above. 1. Spatial Criteria: Characterize the physical qualities of the place. Includes four specific topics: a) Intrinsic qualities: Recognizes characteristics of the site regarding morphology, geography, and other uses that allow defining best uses for some types of activities depending on the conditions of the street, such as tree planting, urban gardens, bikelanes, others. As McHarg [14] proposed this ecological approach sees design as an iterative process that is largely shaped by the interactions between humans and ecosystems. b) Articulation: Identifies opportunities to set up organizational structures such as axes, nodes, and edges through the definition of possible spatial sequences, as well as environments with high functional dynamics that can concatenate the social and natural processes. c) Confluence: Explores and defines spaces for the meeting, which may already be configured or not. The Avenue and the system that integrated is supposed to facilitate the identification of new areas of social interaction. d) Management of metabolic fluxes: Examines the potential for acting in the transformation of the urban metabolism from its fluxes, mainly of the energy used for transport, the raw materials, and water. The reconfiguration of the metabolism fluxes is possible from the social action, from the citizen, without the need for high technologies nor very complex processes. So, the water, for example, given its strong presence in the city, in its streets and public spaces, could, through appropriate management, transport raw materials and fertility to the soil and no contamination, as is currently the case. This water management, as a concatenator flow of many of the processes of urban metabolism, facilitates the action on other metabolic fluxes. Therefore, it is necessary to carry out a map of metabolic fluxes to identify its behaviour. In the case of water, it would reconnect its channels and give continuity to hydraulic spaces. The streets are important because they inevitably are configured as artificial basins that lead the water flows by gravity to the natural water courses, and with this fluid, the material of runoff. e) Symbolic Criteria: Define referential places from the recognition of spaces that exemplify the city and represent it in the collective imagination. The importance of these areas for the reconfiguration of the urban metabolism lies in its social value, which could be achieved by the participation and involvement of the people with the places from which they feel are part and with which they form a sense of identity [15]. These criteria, as well as the research of parametric and GIS information used to describe the structural and functional properties of the study area, were considered to propose an Urban Metabolic Corridors System, defined as an organizational structure oriented to canalizing the natural and social processes in urban space. In which the streets would serve as corridors. Consequently, it is proposed a guideline oriented to: a. b.

Describe the priorities and principles that will ensure future development achieves high design quality and design excellence. Improve habitat connectivity across the System, particularly between priority sites, and between identified habitat areas in adjoining natural ecosystems Caño de Martín Peña and Río Piedras.



c. d. e. f. g.

Increase the quality of urban life measured out from a substantially decrease a city’s transport emissions and congestion through reduced car ownership and car mileage. Protect heritage items, heritage conservation areas and other highly valued characteristics across the System. Relate the street to the public space and to the empty spaces to encourage and support biodiversity. Reflect historical and cultural context. Encourage public transport use, walking and cycling.

The main themes of the guideline proposed are: 

 

 

Turn Juan Ponce de Leon Avenue into a main ecological corridor and generate transverse connectors that allow expanding the network of bike-lines and pedestrian pathways through integrated circuits to achieve a simple approach that aims to connect the social, economic and cultural life of the city to these means of transport. Nodes with amenities as water fountains, public toilets, public telephones, garbage bins, ATMs, street vendors and street entertainers at crossing points between the main and transverse axes, related to buildings or relevant urban spaces. Green Gateways to connect the hydrological ecosystems Caño de Martín Peña and Río Piedras, this would be allowing for efficient circulation systems (streets, metros, bus lanes, cycling paths, walk paths), attracting uses and activities, thus enhancing safety, providing opportunities for recreation, thus improving general good health and well-being. Gateways would facilitate citizen participation and engagement in the conception, production and/or subsequent maintenance of the space. Detailed analysis of the heritage items and conservation areas located within the Frame Areas along the System. As well as the unfunctional spaces and their opportunities of adaptive integration. Identifying the key elements of the existing built form which are significant from a heritage perspective, including consideration of the character and fine grain, and innovative ways to celebrate heritage along the System.

Intrinsic Qualities

Articulation Spatials Confluence Management of metabolic flows

Criteria

Symbolics

Characterization of the morphological - spatial - geographical qualities of the place in relation to optimum soil uses Recognition of opportunities to configure organizational structures (axes, nodes, edges) Identification of spaces to host associative and relational activities Recognition of environments with potential to act in the transformation of the city's urban metabolism

Recognition and revaluation of the collective heritage that allows the construction of cultural identity

Figure 5: Criteria scheme.



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Figure 6: Proposal scheme. 7 CONCLUSIONS The street loses its metabolic function as the crops disappeared from the periphery and the cistern discarded because the water can be driven to the city from remote places. Most of the current roadway infrastructure was developed based on guidelines that emphasize vehicle mobility and safety and minimizing short-term upfront costs, with less consideration given to social and environmental aspects. This paper raises to retake the role that the history of the street shows us. So, this proposal is addressed to restore and enhance its original value as functional, aesthetic, social and cultural configurator of the city whit minimal impacts. Achieving sustainable urban streets can create more liveable communities. With amenities nearly located, individuals would be more likely to utilize alternative mode choices such as walking, biking or transit, which leads to improved urban health. Streets busy with pedestrian and bicycle traffic are safer and strengthen a sense of community. This work provides a view of Avenida Juan Ponce de León from its latent heritage, which can be exalted through a reconfiguration of its urban metabolism. This reconfiguration represents an opportunity to lead San Juan towards a more sustainable city scheme. Further investigations will provide planners, designers and decision makers with a precise understanding of the dynamic flow patterns in San Juan. ACKNOWLEDGEMENT Dean for Graduate Studies and Research of University of Puerto Rico supported this research. Architecture School – UPR promoting the work and allowing the results to be disseminated.



[1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15]

REFERENCES Fischer-Kowalski, M., Society’s Metabolism. The Intellectual History of Materials Flow Análisis. Part I, 1860-1970., Journal of Industrial Ecology, 1(2), pp. 61–78, 1998. Garrido, F., Gonzalez, M., Serrano, J. & Solana, J., El Paradigma Ecológico en las Ciencias Sociales. Barcelona : Icaria Antrazyt, 2007. Puerto Rico Historic Buildings Drawings Society. Online, http://www.prhbds.org/. Accessed on: 15 Jun. 2017. Rodney, W., Long - Railways of Central America and the West Indies. Washington DC US Department of Commerce, p. 336, 1925. Martinuzzi, S., Gould W. & Ramos, O.L., Development, land use, and urban sprawl in Puerto Rico integrating remote sensing and population census data. ScienceDirect, 79, pp. 288–297, 2007. Estudios Técnicos, Inc. Puerto Rico: En ruta al Desarrollo Inteligente. San Juan: Estudios Técnicos, Inc., 2001. Moreno, G., El Urbanismo como elemento clave en el nuevo paradigma ambiental. Revista Umbral, 1, pp. 238–253, 2009. World Bank. The World Bank, International Road Federation, World Development Indicators: Traffic and Congestion. Online, http://www.worldbank.org. Accessed on: 14 Apr. 2015. Borja, J. & Muxi, Z., Espacio Público, Ciudad y Ciudadanía. Barcelona: Electa, 2003. Smith, A., The formation of national identity. [book auth.] H. Harris. Identities. Oxford: Clarendon Press, 1995, pp. 129–164. Augé, M., Hacia una antropología de los mundos contemporáneos. Argentina: Gedisa, 1995. Vidal, T. & Pol, E., La apropiación del espacio: Una propuesta teórica para comprender la vinculación entre las personas y los lugares. Anuario de psicología, pp. 281–297, 2005 CCCPR. Puerto Rico Climate Change Council. San Juan: CCCPR, 2013. McHarg, I., Design with nature. New York: American Museum of Natural History by the Natural History Press, 1969. Silva, A., Imaginarios Urbanos: Hacia el desarrollo de un urbanismo desde los ciudadanos. Metodoligía. Bogotá: Gente Nueva Editorial, 2006.



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Author index Abarca-Guerrero L. .......................... 551 Abdallah F. ......................................... 59 Acosta Collazo A. ............................ 345 Adams J. ........................................... 505 Adeniyi A. ........................................ 583 Aguilar Ibarra A. .............................. 101 Ahmad E. ......................................... 207 Alvarez A. L. .................................... 285 Álvarez Lombardero N..................... 229 Anggiat J. ......................................... 437 Arizpe-Covarrubias O. ..................... 459 Ashour A. F. ..................................... 311 Atici M. .............................................. 47 Ávila-Flores G.................................. 459 Azmee N. M. .................................... 481 Bal Ş. ................................................ 135 Barbera M. ....................................... 335 Bellagamba I. ................................... 335 Beltran-Rodriguez M. ...................... 297 Boeri A. ................................................ 3 Brain R. ............................................ 505 Brooms T.......................................... 583 Campelo A. ........................................ 39 Carteni A. ......................................... 171 Cerro C. ............................................ 255 Chen H.-H. ....................................... 491 Cilliers E. J. ................................ 73, 241 Cilliers J. .......................................... 415 Cornelius S. G. ........................... 73, 415 De Canio G............................... 335, 367 De Oliveira L. K............................... 559 Delpla I............................................. 573 Dietrich U. ........................ 185, 273, 491 Dinho da Silva P............................... 539 Dinis Gaspar P. ................................ 539 Djaja K. ............................................ 323 Dlábiková I. ...................................... 147 Fioriti V. ................................... 335, 367 Fontenele D. ....................................... 39 Frolíková-Palánová K. ..................... 147

Galvão D. .......................................... 539 Gaspari J. .............................................. 3 Gianfrate V. .......................................... 3 Golubeva A. ...................................... 161 González de Canales F...................... 229 Gregor M. ......................................... 265 Han N................................................ 113 Hariyanto P. ...................................... 323 Hidjaz T. ............................................. 89 Hinojosa-Arango G........................... 459 Husaini N. A. .................................... 401 İnan C. G. ......................................... 357 Jeon Y.-M. ........................................ 517 Juárez-Mancilla J. ............................. 459 Kasmuri K. ............................... 377, 401 Kholid M. F. ..................................... 377 Kim Y.-H. ......................................... 113 Kirchberg Erto G. ............................. 273 Kuroda C. Y...................................... 471 Lategan L. G. .................................... 241 Latoui B. ............................................. 59 Lau S. S. Y........................................ 215 Leandro-Hernandez A. G.................. 551 Lee J.-S. .................................... 113, 517 Longo D. ............................................... 3 Luengo De Arreaza M. H. .................. 27 Lynch J. ............................................ 505 Magalhães De Oliveira R. L. ............ 559 Magaril E. ......................................... 161 Magaril R. ......................................... 161 Magnani Cianetti M. ......................... 335 Manap A. Ş. ...................................... 125 Martínez-Jiménez E. T. .................... 101 Mayang Bahjah Zaharin P. ....... 377, 389 Mbaya R. .......................................... 583 Min-Seok K. ..................................... 517 Mongelli M. ...................................... 335 Mostafa Jamal A. H. ......................... 447 Müller-Eie D. .................................... 285


Mulyasari D. A. ................................ 427 Muşta O. Ç. ...................................... 125 Naeem M. A. .................................... 529 Nedvěd M. .......................................... 15 Niesing C.......................................... 415 Nuruddin M. F.................................. 481 Oliva Grudzin Braga C. H. ............... 471 Onyango M. ..................................... 583 Özcan K............................................ 135 Panepinto D. ..................................... 161 Pérez-Campuzano E. ........................ 101 Peřinková M. .............................. 15, 147 Pires L. ............................................. 539 Popoola P. ........................................ 583 Posselt M. ......................................... 185 Rahman A. K. S. .............................. 447 Rashdan W. ...................................... 311 Rawi N. I. M. ................................... 389 Razali F. R........................................ 401 Rodriguez M. ................................... 573 Roselli I. ................................... 335, 367 Sarwar Sandhu G.............................. 529 Sayin E. ............................................ 125

Sihombing A. .................................... 427 Simis M. ........................................... 207 Simon M. .......................................... 297 Soemabrata J. .................................... 323 Soewarno N. ....................................... 89 Sönmez Saner T. ............................... 125 Sultana Z. .......................................... 447 Sumabrata J. ..................................... 437 Sumadio W. ...................................... 437 Suyanti E. ......................................... 437 Tampi D. M. ..................................... 437 Tatì A. ....................................... 335, 367 Teixeira De Avelar Rueda L. S......... 559 Trojan J. ............................................ 265 Tsuji T. M. ........................................ 471 Viggiano F. ....................................... 161 Virdianti E. ......................................... 89 Viviers J. ..................................... 73, 415 Yalazi B. ........................................... 125 Yu Z. ................................................. 199 Zhang Q. ........................................... 215 Zubair A............................................ 323

...for scientists by scientists

Sustainable Development and Planning IX Edited by: C.A. BREBBIA, Wessex Institute, UK; J. LONGHURST, University of the West of England, UK; E. MARCO, University of the West of England, UK and C. BOOTH, University of the West of England, UK

Containing papers presented at the 9th International Conference on Sustainable Development and Planning this volume brings together the work of academics, policy makers, practitioners and other international stakeholders and discusses new academic findings and their application in planning and development strategies, assessment tools and decision making processes. Problems related to development and planning are present in all areas and regions of the world. Accelerated urbanisation has resulted in both the deterioration of the environment and quality of life. Taking into consideration the interaction between different regions and developing new methodologies for monitoring, planning and implementation, new strategies can offer solutions mitigating environmental pollution and non-sustainable use of available resources. Energy saving and eco-friendly buildings have become an important part of modern day progress with emphasis on resource optimisation. Planning is a key part in ensuring that these solutions along with new materials and processes are efficiently incorporated. Planners, environmentalists, architects, engineers and economists have to work collectively to ensure that present and future needs are met. The papers in the book cover a number of topics, including: City planning; Urban architecture; Regional planning; Sustainability and the built environment; Environmental management; Cultural heritage; Quality of life; Sustainable solutions in emerging countries; Sustainable tourism; Transportation; Community planning; Timber structures; Governance; Socio-economic issues; Mobility in the city; Energy efficiency; Education for sustainable development; Case studies; Sustainable development indicators. WIT Transactions on Ecology and the Environment, Vol 226 ISBN: 978-1-78466-231-8 eISBN: 978-1-78466-232-5 Published 2017 / 862pp

WIT eLibrary Home of the Transactions of the Wessex Institute, the WIT electronic-library provides the international scientific community with immediate and permanent access to individual papers presented at WIT conferences. Visitors to the WIT eLibrary can freely browse and search abstracts of all papers in the collection before progressing to download their full text. Visit the WIT eLibrary at http://library.witpress.com

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