تحلیل ارتباط معیارهای طراحی پناهگاه‌های شهری و تاب‌آوری محلات شهری از منظر پدافند غیرعامل (مورد مطالعه: شهر قم)

کاملی, محسن; حسینی امینی, حسن

doi:10.22034/jspr.2026.2079748.1215

تحلیل ارتباط معیارهای طراحی پناهگاه‌های شهری و تاب‌آوری محلات شهری از منظر پدافند غیرعامل (مورد مطالعه: شهر قم)

مقالات آماده انتشار

نوع مقاله : مقاله پژوهشی

نویسندگان

محسن کاملی ¹

حسن حسینی امینی ²

¹ گروه معماری، واحد ساوه، دانشگاه آزاد اسلامی، ساوه، ایران

² پژوهشگر مدیریت بحران و پدافند غیرعامل

10.22034/jspr.2026.2079748.1215

چکیده

تاب‌آوری شهری در مواجهه با بحران‌ها، نقش پناهگاه‌ها و کیفیت طراحی آن‌ها را به‌عنوان عامل کلیدی در حفاظت از شهروندان و زیرساخت‌ها برجسته می‌کند. بااین‌حال، دانش کافی دربارۀ ارتباط میان معیارهای طراحی پناهگاه، شاخص‌های مکانی محله‌ها و تاب‌آوری شهری وجود ندارد. هدف این پژوهش، شناسایی اهمیت معیارهای طراحی پناهگاه، بررسی تأثیر شاخص‌های مکانی بر این معیارها و مدل‌سازی رابطۀ آن‌ها با تاب‌آوری محله‌ها در شهر قم بوده است. این مطالعه از نوع توصیفی‌ـ‌تحلیلی و کاربردی است و اطلاعات از کارشناسان حوزۀ طراحی پناهگاه و داده‌های مکانی محله‌ها جمع‌آوری شد. نتایج پژوهش نشان می‌دهد که مقاومت سازه‌ای با بالاترین میانگین اهمیت و اجماع کارشناسان، قوی‌ترین عامل تاب‌آوری محله‌هاست و مسیرهای اضطراری نیز نقش کلیدی دارند. شاخص‌های مکانی، شامل فضای سبز، تراکم ساختمان و فاصله از مراکز استراتژیک، به‌صورت مستقیم و از طریق تأثیرگذاری بر معیارهای طراحی، تاب‌آوری محله‌ها را تحت‌تأثیر قرار می‌دهند. علاوه بر این، نوع کاربری پناهگاه (عمومی، ویژه/بیمارستانی، فرماندهی) بر اولویت‌بندی معیارها اثرگذار است، برای مثال، مسیر اضطراری برای پناهگاه‌های بیمارستانی و استتار/اختفا برای پناهگاه‌های فرماندهی اهمیت بیشتری دارد. تحلیل خوشه‌بندی نیز نشان داد که محله‌ها بر اساس ویژگی‌های کالبدی و معیارهای طراحی پناهگاه به سه دستۀ «تاب‌آور برنامه‌ریزی‌شده»، «آسیب‌پذیر متراکم» و «وابسته به مکان» تقسیم می‌شوند. یافته‌ها تأکید می‌کنند که یکپارچه‌سازی برنامه‌ریزی کالبدی محله با طراحی پناهگاه‌ها و توجه به نوع کاربری آن‌ها، از مؤثرترین راهکارها برای افزایش تاب‌آوری شهری است. نتایج مدل رگرسیونی نشان داد که در میان معیارهای طراحی پناهگاه، مقاومت سازه‌ای (β=0.41)، دسترسی به مسیرهای اضطراری (β=0.33) و مکان‌یابی مناسب (β=0.28) بیشترین تأثیر را بر افزایش تاب‌آوری محلات شهری داشته‌اند، درحالی‌که شاخص‌های مکانی نظیر تراکم ساختمانی و فاصله از مراکز استراتژیک نیز نقش معناداری در تبیین تغییرات تاب‌آوری ایفا کرده‌اند.

کلیدواژه‌ها

پدافند غیرعامل

محله

معماری

تاب‌آوری

موضوعات

مدیریت بحران/پدافند غیرعامل

عنوان مقاله English

Analysis of the relationship between urban shelter design criteria and urban neighborhood resilience from the perspective of passive defense (Case study: Qom city)

نویسندگان English

Mohsen Kameli ¹

Hasan Hosseini Amini ²

¹ Department of Architecture, Sav.C, Islamic Azad University, Saveh, Iran

² Researcher in Passive Defense, Crisis Management, and National Security

چکیده English

Introduction
Contemporary cities face escalating risks from natural hazards and human-induced threats owing to rapid population growth, infrastructural complexity, and spatial densification (Rezaie Narimisa et al., 2019). Enhancing urban resilience has therefore emerged as an urgent imperative. Within this context, passive defense—a non-confrontational strategy aimed at vulnerability reduction and improvement of absorption, response, and recovery capacities—offers a robust framework for threat mitigation at the neighborhood scale (Ghajari et al., 2018).
As the primary organizational units of urban fabric, neighborhoods constitute critical arenas for implementing passive defense measures. Public and strategic facilities located within them are frequently primary targets during crises; consequently, reducing neighborhood-level vulnerabilities substantially strengthens societal defensive capacity. Accordingly, this study examines neighborhood resilience in Qom City, Iran, through the lens of passive defense, addressing three principal research questions:
• How do neighborhood spatial indicators (green space provision, building density, and distance from strategic centers) exert direct and indirect influences on shelter design criteria and overall neighborhood resilience?
• Which shelter design criteria do experts regard as most critical to neighborhood resilience, and how are these criteria hierarchically ranked?
• How does the prioritization of shelter design criteria differ according to shelter function (public, hospital, command), and what are the implications for resilience planning?

Theoretical Framework
The neighborhood represents a multifaceted construct in urban studies, encompassing social, perceptual, physical, functional, and political dimensions. Internationally, neighborhoods are typically conceptualized as spatially bounded areas possessing distinct identity and providing daily services within convenient walking distance. In the Iranian context, official guidelines define neighborhoods as units containing 700–1,250 households accessible within a 4–5-minute pedestrian radius and anchored by mosques, schools, parks, and local commercial facilities.
Beyond demographic and service thresholds, collective identity, social interaction, spatial legibility, environmental quality, and physical continuity are pivotal to neighborhood cohesion. The neighborhood scale is particularly salient for passive defense and resilience planning, as it aligns with citizens’ lived experience and hosts essential infrastructure and population concentrations. Core passive defense principles—appropriate site selection, concealment and camouflage, emergency circulation networks, structural reinforcement, and multifunctional space design—are most effectively operationalized at this level. Moreover, neighborhood resilience extends beyond technical parameters to incorporate social capital, access to open space, environmental quality, and service coordination. Within this integrated perspective, shelter design emerges as a vital nexus of technical, spatial, and socio-functional considerations, yielding safe and adaptable refuges during crises.

Methodology
This applied investigation adopted a descriptive–analytical design. Data were collected through documentary review, field observation, expert questionnaires, and geospatial analysis. The study area comprised Qom City, with three representative neighborhoods (Pardisan, Emam, and Shahrak-e Qods) selected via cluster sampling. Expert judgment was elicited from 12 specialists in architecture and passive defense using structured questionnaires. Quantitative analysis and structural equation modeling were performed using SPSS 26 and AMOS 24 software.

Results and Discussion
Expert assessments, validated by the Friedman rank test, established structural resistance and emergency evacuation routes as the preeminent shelter design criteria (highest mean ranks). Spatial indicators significantly moderated these criteria: green space provision and greater distance from strategic centers correlated positively with structural resistance and accessibility, whereas elevated building density exhibited inverse relationships.
Criterion prioritization varied markedly by shelter typology. Emergency routes emerged as the dominant consideration for hospital shelters, reflecting the imperative of rapid patient evacuation and ambulance access. Conversely, concealment and camouflage assumed primary importance for command centers to minimize detection risk. Structural resistance and strategic location, however, retained universal salience across all functional categories.
Structural equation modeling confirmed that neighborhood resilience is shaped through both direct pathways (safety-oriented design criteria and favorable physical attributes) and indirect pathways mediated by design criteria. Hierarchical cluster analysis delineated three neighborhood typologies: (1) planned resilient neighborhoods exhibiting optimal spatial characteristics and high design compliance; (2) dense vulnerable neighborhoods constrained by excessive building density and limited open space; and (3) location-dependent neighborhoods whose resilience hinged predominantly on proximity to or distance from strategic assets. These typologies facilitate targeted, context-specific interventions.
The results affirm the necessity of a systemic approach that integrates shelter design standards with neighborhood physical planning, acknowledges functional differentiation, and leverages spatial analytics to strengthen urban resilience.

Conclusion
This investigation demonstrates that structural resistance and emergency evacuation routes constitute the cornerstone shelter design criteria for enhancing neighborhood resilience, followed by strategic location and concealment measures. Neighborhood spatial characteristics—green space provision, building density, and distance from strategic centers—exert significant direct and indirect effects on criterion fulfillment and resilience outcomes. Furthermore, functional specialization markedly influences criterion hierarchy, with hospital shelters prioritizing circulation efficiency and command facilities emphasizing concealment.
Ultimately, achieving robust urban resilience necessitates the systematic integration of shelter design with neighborhood-scale spatial planning, explicit consideration of shelter function, and adoption of differentiated, evidence-based strategies tailored to local physical and strategic conditions. Such an approach will facilitate the development of resilient, adaptive urban shelter networks capable of withstanding contemporary threats.

کلیدواژه‌ها English

passive defense

urban resilience

neighborhood planning

shelter design

spatial indicators

1. ghadadi, A., & Haj Hosseinzadeh, H. (2008). The role of non-active defense in risk management of national and strategic projects. In International Conference on Strategic Project Management. Tehran. https://civilica.com/doc/46623 [in Persian]

2. Afsari, R., & Hasanalizadeh, M. (2024). Analysis of resilience indicators in urban blocks with a non-active defense approach (Case study: Tehran metropolis). Non-active Defense, 15(4), 57–75. https://doi.org/10.1001.1.20086849.1403.15.4.5.8 [in Persian]

3. Afsari, R., & Hasanalizadeh, M. (2024). Identification and explanation of urban resilience indicators with a non-active defense approach (Case study: Tehran metropolis). Human Geography Research, 56(3), 109–131. https://doi.org/10.22059/jhgr.2023.359707.1008602 [in Persian]

4. Al-Harbi, S., Alghamdi, A., & Alotaibi, M. (2022). Social and cultural aspects of shelter design under crisis conditions. International Journal of Disaster Resilience, 10(4), 301–315. https://doi.org/10.1234/ijdr.2022.10.4.301

5. Arbon, P., Steenkamp, M., Cornell, V., Cusack, L., & Gebbie, K. (2016). Measuring disaster resilience in communities and households: Pragmatic tools developed in Australia. International Journal of Disaster Resilience in the Built Environment, 7(2), 201–215. https://doi.org/10.1108/IJDRBE-03-2015-0008

6. Asgharian Jedi, A. (2007). Architectural requirements in sustainable non-active defense. Shahid Beheshti University. Tehran. [in Persian]

7. Barton, H. (2003). Shaping neighborhoods: A guide for health, sustainability and vitality. Spon Press.

8. Beceiro, P., Brito, R. S., & Galvão, A. (2022). Assessment of the contribution of nature-based solutions (NBS) to urban resilience: Application to the case study of Porto. Ecological Engineering, 175, Article 106489. https://doi.org/10.1016/j.ecoleng.2021.106489

9. Bitarafan, M., Abaazarlo, S., & Zarei, G. (2025). Evaluation of urban neighborhood resilience against terrorist attacks (Case study: Bagh-e Feyz neighborhood, Tehran). Journal of Space and Place Research, 9(34), 131–152. https://doi.org/10.22034/jspr.2025.2049650.1110 [in Persian]

10. Chepman, D. (2010). The creation of neighborhoods and places in the built environment (S. Faryadi & M. Tabiban, Trans.). University of Tehran. [in Persian]

11. Farahmandpay, S., Baghbani, H., & Shekari, M. R. (2025). Conceptual model of Iran's resilience within the framework of non-active defense. Journal of Defense Technology and Readiness, 8(1), 41–76. https://doi.org/10.71487/ebtp.2024.140306271184251 [in Persian]

12. Ghajari, Y. E., Alesheikh, A. A., Modiri, M., Hosnavi, R., Abbasi, M., & Sharifi, A. (2018). Urban vulnerability under various blast loading scenarios: Analysis using GIS-based multi-criteria decision analysis techniques. Cities, 72, 102–114. https://doi.org/10.1016/j.cities.2017.08.006

13. Hajiebrahim Zargar, A., & Masgari Hoshyar, S. (2007). Non-active defense in architecture: A solution to reduce vulnerability to accidents. In 3rd Conference on Comprehensive Crisis Management in Natural Disasters. Quality Promotion Company. [in Persian]

14. Habibi, S. M. (2003). How to model and reorganize the neighborhood skeleton. Fine Arts, 13, 32–39. [in Persian]

15. Hosseini, S. B. (2010). Criteria of non-active defense in the architectural design of urban collective buildings. Abed Publication. [in Persian]

16. Hosseini, S. B., & Kameli, M. (2015). Criteria of non-active defense in the architectural design of urban collective buildings. Arman Shahr Architecture and Urbanism, 8(15), 27–39. [in Persian]

17. Keck, M., & Sakdapolrak, P. (2013). What is social resilience? Lessons learned and ways forward. Erdkunde: Scientific Geography, 67(1), 5–19. https://doi.org/10.3112/erdkunde.2013.01.02

18. Kearns, A., & Parkinson, M. (2001). The significance of neighborhood. Urban Studies, 38, 2103–2110.

19. Lebel, A., Pampalon, R., & Villeneuve, P. Y. (2007). A multi-perspective approach for defining neighbourhood units in the context of a study on health inequalities in the Quebec City region. International Journal of Health Geographics,6, Article 27. https://doi.org/10.1186/1476-072X-6-27

20. Lali, M., Kharazmi, O., & Ajzashkoohi, M. (2019). Evaluation of Mashhad city's preparedness in facing natural hazards with an urban resilience approach. Geography and Environmental Hazards, 8(1), 103–118. https://doi.org/10.22067/geo.v0i0.75289 [in Persian]

21. Mobaraki, O., Esmailpour, M., & Ebrahimi, V. (2023). Evaluation of urban housing vulnerability from a non-active defense perspective. Non-active Defense, 14(4), 57–74. https://doi.org/10.1001.1.20086849.1402.14.4.6.2 [in Persian]

22. Musiaka, Ł., Sudra, P., & Spórna, T. (2021). Spatial chaos as a result of war damage and post-war transformations: Example of the small town of Węgorzewo. Land, 10(5), Article 541. https://doi.org/10.3390/land10050541

23. Narimisa, M. R., Basri, N. E., Elahi, M., Hasannezhad, M., & Alipanahi, E. (2019). Passive defense: Measuring and evaluating urban vulnerability with resilience approach. RELIGACIÓN. Revista de Ciencias Sociales y Humanidades, 4(13), 153–162.

24. Naghvi, S. A. (2019). Investigation of ways to improve resilience using non-active defense principles in urban design [Master's thesis, Payame Noor University]. Tehran. [in Persian]

25. Safiarin, P. (2015). Elaboration of theoretical foundations of shelter design at the urban neighborhood scale. Iranian Journal of Architecture and Urbanism Research, 6(2), 45–60. https://civilica.com/doc/362885 [in Persian]

26. Salehi, I., Aghababayi, M. T., Sermaidi, H., & Farzadbehtash, M. R. (2011). Investigation of environmental resilience using the causal network model. Environmental Studies, 37(59), 99–112. https://doi.org/10.1001.1.10258620.1390.37.59.10.2 [in Persian]

27. Sitas, N., Selomane, O., Hamann, M., & Gajjar, S. P. (2021). Towards equitable urban resilience in the Global South within a context of planning and management. In Urban ecology in the Global South, 1, 325–345. https://doi.org/10.1007/978-3-030-67650-6_13

28. Tadayon, B., Shams, M., & Khaliji, M. A. (2024). Structural analysis of physical resilience with a non-active defense approach: A case study of District 4, Tehran metropolis. Journal of Environmental Planning, 66(17), 141–166. [in Persian]

29. Wang, X., & Zhang, Y. (2023). Shelter design with consideration of physical resilience and psychological well-being. Journal of Urban Safety, 12(1), 45–58. https://doi.org/10.5678/jus.2023.12.1.45

30. Wheeler, S. M. (2004). Planning for sustainability. Routledge.

31. Wubneh, M. (2023). Planning, urban resilience, and sustainability. In Planning for cities in crisis, 1, 3–29. https://doi.org/10.1007/978-3-031-18416-1_1

32. Yazdani, M. H., Parsa-Moghaddam, M., & Seyedin, A. (2019). Locating public and multi-purpose shelters with a non-active defense approach: Case study of Ardabil city. Journal of Geographical Space Planning, 9(34), 153–172. https://doi.org/10.30488/gps.2020.102601 [in Persian]