Enhancing street-level interactions in smart cities through interactive and modular furniture

  • Oihane Gómez-CarmonaEmail author
  • Juan Sádaba
  • Diego Casado-Mansilla
Original Research


The idea of smart cities is becoming part of our reality and it represents the transformation that urban areas should undergo to create more sustainable and efficient spaces. Through the combination of technology to gather data, people to produce them and stakeholders’ creativity, the smart cities provide tools and mechanisms that bring greater value to the environment and, in the end, improve citizens quality of life. Although the concept of a smart city is evolving fast in terms of technology adoption and user involvement, the new interactive objects that will be deployed in those smart environments to create street-level interactions are still dubious. Hence, this article contributes to presenting the implementation of a multifunctional digital system, in the form of smart furniture, to be deployed in the smart cities. The proposed smart object is a modular and customizable kiosk, resembling a totem, specifically designed to fit into this digital transformation and to respond to users’ needs by offering contextualized information and services. The included integrated hardware elements interact digitally and physically with users, sense environmental conditions and send the captured data to the cloud, where remote management tools allow to control and configure the whole setup. The presented smart totem has been customized for two different use-cases to highlight the adaptability of the system to fit for different purposes. Moreover, one of the use-cases has been thoroughly evaluated after being deployed for 6 months in the wild at the Chinese and Japanese Garden of Singapore. The quantitative data gathered throughout this study along with the obtained qualitative users’ feedback, help to provide insights for the convenience of deploying new interactive furniture in smart cities, the adoption barriers of such physical systems, and the new opportunities that these street-level interactions can elicit.


Smart cities Interactive kiosk Smart furniture Digital signage E-services 



Birloki System is a project of Nerei Emotional Intelligent SL. Special thanks to Nerei Emotional Intelligent for all the information provided, to Force 21, its partner in Asia and the teams helping in developing software, hardware, prototypes and both electric and electronic components, specially EBI talleres electrotécnicos, Enaiden, Fuhtah and DeustoTech.


  1. Albino V, Berardi U, Dangelico RM (2015) Smart cities: definitions, dimensions, performance, and initiatives. J Urban Technol 22(1):3–21CrossRefGoogle Scholar
  2. Aleksandrov O, Dobrolyubova E (2015) Public service delivery through automated self-service kiosks: international experience and prospects for implementation in Russia. In: Proceedings of the 2015 2nd international conference on electronic governance and open society: challenges in Eurasia, ACM, pp 205–210Google Scholar
  3. Amessafi H, Jourani R, Echchelh A, Yakhlef HO (2017) Building a smart interactive kiosk for tourist assistance. Trans Mach Learn Artif Intell 5(4):622–627Google Scholar
  4. Bachiega NG, Diaz S, Montes VS (2016) Kiosk IOT for electoral consciousness. In: Proceedings of the 18th international conference on information integration and web-based applications and services, ACM, pp 405–409Google Scholar
  5. Barnaghi PM, Bermudez-Edo M, Tönjes R et al (2015) Challenges for quality of data in smart cities. J Data Inf Qual 6(2–3):1–6Google Scholar
  6. Batty M, Axhausen KW, Giannotti F, Pozdnoukhov A, Bazzani A, Wachowicz M, Ouzounis G, Portugali Y (2012) Smart cities of the future. Eur Phys J Spec Top 214(1):481–518CrossRefGoogle Scholar
  7. Blasius J, Thiessen V (2012) Assessing the quality of survey data. Sage, Thousand OaksCrossRefGoogle Scholar
  8. Branzila M, Sarmasanu C, Ciudin D, Lacatusu D (2018) Sensors and transducers laboratory kiosk. In: 2018 international conference and exposition on electrical and power engineering (EPE), IEEE, pp 0377–0380Google Scholar
  9. Carter S, Marlow J, Cooper M (2017) No app needed: enabling mobile phone communication with a tourist kiosk using cameras and screens. In: Proceedings of the 2017 ACM international joint conference on pervasive and ubiquitous computing and Proceedings of the 2017 ACM international symposium on wearable computers, ACM, pp 221–224Google Scholar
  10. Cho H, Fiorito SS (2010) Self-service technology in retailing. The case of retail kiosks. Symphonya 1:42Google Scholar
  11. Garrido P, Barrachina J, Martinez FJ, Seron FJ (2016) Smart tourist information points by combining agents, semantics and AI techniques. Comput Sci Inf Syst 14(1):1–23CrossRefGoogle Scholar
  12. Germany J, Speranza P (2014) Street portals: urban user interface ‘Test Bed’ prototype for bike shares. NITC-SS-738. Transportation Research and Education Center (TREC), Portland, ORGoogle Scholar
  13. Johnson KD, Diaz J (2012) Interactive content delivery system for a museum. In: Proceedings of the 50th annual southeast regional conference, ACM, pp 337–338Google Scholar
  14. Jones R (2009) The role of health kiosks in 2009: literature and informant review. Int J Environ Res Public Health 6(6):1818–1855CrossRefGoogle Scholar
  15. Joshi A, Trout K (2014) The role of health information kiosks in diverse settings: a systematic review. Health Inf Libr J 31(4):254–273CrossRefGoogle Scholar
  16. Kamga C, Yazıcı MA, Singhal A (2013) Implementation of interactive transit information kiosks at New York city transit facilities: analysis of user utilization and lessons learned. Transp Res Part C Emerg Technol 35:218–231CrossRefGoogle Scholar
  17. Kirk CP, Swain SD, Gaskin JE (2015) I’m proud of it: consumer technology appropriation and psychological ownership. J Market Theory Pract 23(2):166–184Google Scholar
  18. Ku EC, Chen CD (2013) Fitting facilities to self-service technology usage: evidence from kiosks in Taiwan airport. J Air Transp Manag 32:87–94CrossRefGoogle Scholar
  19. Lehofer M, Heiss M, Rogenhofer S, Weng CW, Sturm M, Rusitschka S, Dippl S (2016) Platforms for smart cities—connecting humans, infrastructure and industrial it. In: Science of smart city operations and platforms engineering (SCOPE) in partnership with global city teams challenge (GCTC)(SCOPE-GCTC), 2016 1st international workshop on, IEEE, pp 1–6Google Scholar
  20. Lerner J (2014) Urban acupuncture. Island Press, Washington, D.CCrossRefGoogle Scholar
  21. Mackrill J, Marshall P, Payne S, Dimitrokali E, Cain R (2017) Using a bespoke situated digital kiosk to encourage user participation in healthcare environment design. Appl Ergon 59:342–356CrossRefGoogle Scholar
  22. Maguire MC (1999) A review of user-interface design guidelines for public information kiosk systems. Int J Hum Comput Stud 50(3):263–286CrossRefGoogle Scholar
  23. Matos A, Pinto B, Barros F, Martins S, Martins J, Au-Yong-Oliveira M (2019) Smart cities and smart tourism: what future do they bring? In: World conference on information systems and technologies. Springer, pp 358–370Google Scholar
  24. Midgley P (2011) Bicycle-sharing schemes: enhancing sustainable mobility in urban areas. United Nations, Department of Economic and Social Affairs, pp 1–12Google Scholar
  25. Misra H (2011) Information kiosk based Indian e-governance service delivery: value chain based measurement and acceptance modelling. In: Proceedings of the 5th international conference on theory and practice of electronic governance, ACM, pp 51–60Google Scholar
  26. Mugge R, Schoormans JP, Schifferstein HN (2009) Emotional bonding with personalised products. J Eng Des 20(5):467–476CrossRefGoogle Scholar
  27. Müller J, Alt F, Michelis D, Schmidt A (2010) Requirements and design space for interactive public displays. In: Proceedings of the 18th ACM international conference on multimedia, ACM, pp 1285–1294Google Scholar
  28. Nabian N, Offenhuber D, Vanky A, Ratti C (2013) Data dimension: accessing urban data and making it accessible. Proc Inst Civ Eng Urban Des Plan 166(1):60–75Google Scholar
  29. Niculescu AI, Yeo KH, Banchs RE (2016) Designing muse: a multimodal user experience for a shopping mall kiosk. In: Proceedings of the fourth international conference on human agent interaction, ACM, New York, NY, USA, HAI ’16, pp 273–275.
  30. Orel FD, Kara A (2014) Supermarket self-checkout service quality, customer satisfaction, and loyalty: empirical evidence from an emerging market. J Retail Consum Serv 21(2):118–129CrossRefGoogle Scholar
  31. Orlando MS, Rothman RE, Woodfield A, Gauvey-Kern M, Peterson S, Miller T, Hill PM, Gaydos CA, Hsieh YH (2016) Public health information delivery in the emergency department: analysis of a kiosk-based program. J Emerg Med 50(2):223–227CrossRefGoogle Scholar
  32. Partarakis N, Margetis G, Zidianakis E, Sifakis M, Drossis G, Birliraki C, Chatziantoniou A, Neroutsou V, Paparoulis S, Toutountzis T et al (2018) Interactive city information point: your guide to Heraklion city. In: International conference on human–computer interaction. Springer, pp 204–212Google Scholar
  33. Pendleton BF, Labuda Schrop S, Ritter C, Kinion ES, McCord G, Cray JJ Jr, Costa AJ (2010) Underserved patients’ choice of kiosk-based preventive health information. Fam Med 42(7):488Google Scholar
  34. Petkova RP, Kaduk J, Lucero A (2016) A physical information kiosk for classical music concerts. In: Proceedings of the 20th international academic mindtrek conference, ACM, pp 122–129Google Scholar
  35. Rajendran PS (2018) Virtual information kiosk using augmented reality for easy shopping. Int J Pure Appl Math 118(20):985–994Google Scholar
  36. Rowley J, Slack F (2003) Kiosks in retailing: the quiet revolution. Int J Retail Distrib Manag 31(6):329–339CrossRefGoogle Scholar
  37. Rowley J, Slack F (2007) Information kiosks: a taxonomy. J Doc 63(6):879–897CrossRefGoogle Scholar
  38. Ruhlandt RWS (2018) The governance of smart cities: a systematic literature review. Cities 81:1–23CrossRefGoogle Scholar
  39. Sádaba Fernández JA (2017) Investigación sobre las posibilidades del espacio público, el mobiliario urbano y las nuevas tecnologías en la ciudad inteligente. caso práctico: Birloki system. Ph.D. thesis, Universidad del Pais VascoGoogle Scholar
  40. Saeheng N, Ngamyarn A, Sriboonjit J (2014) The effect of kiosks service quality and kiosk product quality on customer satisfaction. Technical report, European Real Estate Society (ERES)Google Scholar
  41. Sánchez-Corcuera R, Nuñez-Marcos A, Sesma-Solance J, Bilbao-Jayo A, Mulero R, Zulaika U, Azkune G, Almeida A (2019) Smart cities survey: technologies, application domains and challenges for the cities of the future. Int J Distrib Sens Netw 15(6):1550147719853984CrossRefGoogle Scholar
  42. Shafii T, Benson SK, Morrison DM, Hughes JP, Golden MR, Holmes KK (2019) Results from e-kiss: electronic-kiosk intervention for safer sex: a pilot randomized controlled trial of an interactive computer-based intervention for sexual health in adolescents and young adults. PloS One 14(1):e0209064CrossRefGoogle Scholar
  43. Shekhar S, Sun F, Dubey A, Gokhale A, Neema H, Lehofer M, Freudberg D (2017) Transit hub: a smart decision support system for public transit operations. Clust Comput 32:597–612Google Scholar
  44. Si N, Jia KB, Xu C (2016) A networked multimedia distributed kiosk system for commercial and home appliances. In: Computing measurement control and sensor network (CMCSN), 2016 third international conference on, IEEE, pp 40–43Google Scholar
  45. Slack F, Rowley JE (2004) Challenges in the delivery of e-government through kiosks. J Inf Sci 30(4):369–377CrossRefGoogle Scholar
  46. Smith SG, Sherwood BA (1976) Educational uses of the plato computer system. Science 192(4237):344–352CrossRefGoogle Scholar
  47. Speranza P (2016) Assembly, space, and things: urban food genome, urban. In: Konomi S, Roussos G (eds) Enriching urban spaces with ambient computing, the internet of things, and smart city design. IGI Global, Pennsylvania, pp 46–66Google Scholar
  48. Teolis MG (2010) A medlineplus® kiosk promoting health literacy. J Consum Health Internet 14(2):126–137CrossRefGoogle Scholar
  49. Vandeventer J, Barbour B (2010) Sammi: a 3-dimensional virtual human information kiosk. In: Proceedings of the 48th annual southeast regional conference, ACM, p 10Google Scholar
  50. Wilson Z, Yin H, Sarcar S, Leung R, McGrenere J (2018) Help kiosk: an augmented display system to assist older adults to learn how to use smart phones. In: Proceedings of the 20th international ACM SIGACCESS conference on computers and accessibility, ACM, pp 441–443Google Scholar
  51. Wrenn G, Kasiah F, Syed I (2015) Using a self-service kiosk to identify behavioural health needs in a primary care clinic serving an urban, underserved population. J Innov Health Inform 22(3):323–328CrossRefGoogle Scholar
  52. Wu Y, Kawaguchi T, Jing L, Wang J, Cheng Z (2017) Campus digital signage: connection of correlated information between distributor and receiver. In: Advanced information networking and applications workshops (WAINA), 2017 31st international conference on, IEEE, pp 581–582Google Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2019

Authors and Affiliations

  1. 1.DeustoTech-University of DeustoBilbaoSpain
  2. 2.Department of ArchitectureUniversity of the Basque CountrySan SebastiánSpain

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