Journal of Graphics ›› 2026, Vol. 47 ›› Issue (3): 641-652.DOI: 10.11996/JG.j.2095-302X.2026030641
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LU Dehui1, SONG Zhuo1, HUANG Zhichao1, TIAN Shiyu1, LI Huimin2, TIAN Mao3, DENG Yichuan2,4(
)
Received:2025-11-12
Accepted:2026-02-09
Online:2026-06-30
Published:2026-06-30
Contact:
DENG Yichuan
Supported by:CLC Number:
LU Dehui, SONG Zhuo, HUANG Zhichao, TIAN Shiyu, LI Huimin, TIAN Mao, DENG Yichuan. Subjective visual perception prediction of green construction sites based on TrueSkill ranking and deep learning[J]. Journal of Graphics, 2026, 47(3): 641-652.
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URL: http://www.txxb.com.cn/EN/10.11996/JG.j.2095-302X.2026030641
| 感知指标 | 目的 |
|---|---|
| 安全 (Safety) | 测量观察施工现场时的安全感程度 |
| 美观 (Beauty) | 测量施工现场的美观程度 |
| 效率 (Efficiency) | 测量现场工人合作效率的感受程度 |
Table 1 Perception indicator list
| 感知指标 | 目的 |
|---|---|
| 安全 (Safety) | 测量观察施工现场时的安全感程度 |
| 美观 (Beauty) | 测量施工现场的美观程度 |
| 效率 (Efficiency) | 测量现场工人合作效率的感受程度 |
Fig. 7 Q-Score correlation test results based on demographic characteristics ((a) Men and women; (b) Around the median age; (c) Construction industry vs. other industries)
| 感知维度 | AlexNet | VGG16 | GoogleNet | LeNet |
|---|---|---|---|---|
| 安全性 | 0.65 | 0.68 | 0.66 | 0.63 |
| 美观性 | 0.63 | 0.70 | 0.66 | 0.62 |
| 效率性 | 0.69 | 0.63 | 0.64 | 0.60 |
Table 2 CNN-based prediction accuracy on perception indicators
| 感知维度 | AlexNet | VGG16 | GoogleNet | LeNet |
|---|---|---|---|---|
| 安全性 | 0.65 | 0.68 | 0.66 | 0.63 |
| 美观性 | 0.63 | 0.70 | 0.66 | 0.62 |
| 效率性 | 0.69 | 0.63 | 0.64 | 0.60 |
| CNN架构 | 安全性 | 美观性 | 效率性 |
|---|---|---|---|
| VGG16 (安全性子集训练) | 0.68 | 0.62 | 0.49 |
| VGG16 (美观性子集训练) | 0.63 | 0.70 | 0.51 |
| AlexNet (效率子集训练) | 0.52 | 0.51 | 0.69 |
Table 3 Cross-prediction results in perception quality
| CNN架构 | 安全性 | 美观性 | 效率性 |
|---|---|---|---|
| VGG16 (安全性子集训练) | 0.68 | 0.62 | 0.49 |
| VGG16 (美观性子集训练) | 0.63 | 0.70 | 0.51 |
| AlexNet (效率子集训练) | 0.52 | 0.51 | 0.69 |
| [1] |
MIR M, NASIRZADEH F, ZAKERI M, et al. Assessing neural markers of attention during exposure to construction noise using machine learning classification of electroencephalogram data[J]. Building and Environment, 2024, 261: 111754.
DOI URL |
| [2] |
ZHANG F, LU Y, WANG Y P, et al. Study on dust pollution law and chemical dust suppression technology of non hard pavement in urban construction sites[J]. Building and Environment, 2023, 229: 109938.
DOI URL |
| [3] |
ZHONG B T, GUO J D, ZHANG L, et al. A blockchain-based framework for on-site construction environmental monitoring: proof of concept[J]. Building and Environment, 2022, 217: 109064.
DOI URL |
| [4] |
OBIOZO R N, SMALLWOOD J J. Biophilic construction site model: enhancing the motivational and humanistic value of the green construction site[J]. Journal of Construction Engineering and Management, 2015, 141(3): 05014018.
DOI URL |
| [5] |
FU H L, XIA Z J, TAN Y B, et al. Influence of cues on the safety hazard recognition of construction workers during safety training: evidence from an eye-tracking experiment[J]. Journal of Civil Engineering Education, 2024, 150(1): 04023009.
DOI URL |
| [6] | NEWTON S. Measuring the perceptual, physiological and environmental factors that impact stress in the construction industry[J]. Construction Innovation: Information Process Management, 2024, 24(3): 684-701. |
| [7] |
JEBELLI H, HWANG S, LEE S. EEG-based workers’ stress recognition at construction sites[J]. Automation in Construction, 2018, 93: 315-324.
DOI URL |
| [8] |
YANG L, HONGYU C. Research on factors influencing total carbon emissions of construction based on structural equation modeling: a case study from China[J]. Building and Environment, 2025, 275: 112396.
DOI URL |
| [9] |
XU H J, KIM J I, CHEN J Y. Improved framework for estimating carbon emissions from prefabricated buildings during the construction stage: life cycle assessment and case study[J]. Building and Environment, 2025, 272: 112599.
DOI URL |
| [10] |
LI X J, WU J J, LIN C X. Decarbonizing provincial construction industry under the “dual carbon” goals: assessing reduction capacities and charting optimal pathways[J]. Building and Environment, 2025, 272: 112639.
DOI URL |
| [11] |
VAN TAM N, QUYNH T T H, TOAN N Q. How Vietnam can achieve net-zero carbon emissions in construction and built environment by 2050: an integrated AHP and DEMATEL approach[J]. Building and Environment, 2025, 274: 112752.
DOI URL |
| [12] |
GU X R, CHEN C, FANG Y, et al. CECA: an intelligent large-language-model-enabled method for accounting embodied carbon in buildings[J]. Building and Environment, 2025, 272: 112694.
DOI URL |
| [13] |
DONG Y H, NG S T. A life cycle assessment model for evaluating the environmental impacts of building construction in Hong Kong[J]. Building and Environment, 2015, 89: 183-191.
DOI URL |
| [14] |
FANG W L, WU D R, LOVE P E D, et al. Physiological computing for occupational health and safety in construction: review, challenges and implications for future research[J]. Advanced Engineering Informatics, 2022, 54: 101729.
DOI URL |
| [15] | ABAS N H, AHMAD JALANI A F, MOHD AFFANDI H. Construction stakeholders’ perceptions of occupational safety and health risks in Malaysia[J]. International Journal of Sustainable Construction Engineering and Technology, 2022, 11(1): 300-311. |
| [16] |
GUO P, TIAN W, LI H M, et al. Global characteristics and trends of research on construction dust: based on bibliometric and visualized analysis[J]. Environmental Science and Pollution Research, 2020, 27(30): 37773-37789.
DOI |
| [17] | ZOU Z B, ERGAN S. Impact of construction projects on urban quality of life: a data analysis method[C]//Construction Research Congress 2018. New Orleans: American Society of Civil Engineers, 2018: 34-44. |
| [18] |
CARDOSO TEIXEIRA J M. Construction site environmental impact in civil engineering education[J]. European Journal of Engineering Education, 2005, 30(1): 51-58.
DOI URL |
| [19] |
PEDERSEN M. The tyranny of scarcity: learning and economy at the construction site[J]. Journal of Education and Work, 2014, 27(4): 392-408.
DOI URL |
| [20] | MALLAWAARACHCHI H, SENARATNE S. Importance of quality for construction project success[EB/OL]. [2025-07-12]. http://www.civil.mrt.ac.lk/web/conference/ICSECM_2015/volume_4/Extract/SECM-15-129.pdf. |
| [21] |
CHAN A P C, SCOTT D, LAM E W M. Framework of success criteria for design/build projects[J]. Journal of Management in Engineering, 2002, 18(3): 120-128.
DOI URL |
| [22] | YIN Y, ZHANG Y. Environmental pollution evaluation of urban rail transit construction based on entropy weight method[J]. Nature Environment and Pollution Technology, 2021, 20(2): 819-824. |
| [23] |
PRASCEVIC N, PRASCEVIC Z. Application of fuzzy AHP for ranking and selection of alternatives in construction project management[J]. Journal of Civil Engineering and Management, 2017, 23(8): 1123-1135.
DOI URL |
| [24] | OLAWUMI T O, AKINRATA E B, ARIJELOYE B T. Value management - creating functional value for construction project: an exploratory study[J]. World Scientific News, 2016, 54: 40-59. |
| [25] | GUNARATHNA U. A review on risk management in sustainable construction[EB/OL]. [2025-07-12]. https://192.248.104.6/bitstream/handle/345/1292/ENG-039.pdf?sequence=1. |
| [26] | MASINGBOON M K. Relationships among communication characteristics, job performance and job satisfaction as perceived by professional nurses in government hospitals, Bangkok Metropolis[D]. Bangkok: Chulalongkorn University, 1992. |
| [27] |
FUNG I W H, TAM V W Y, SING C P, et al. Psychological climate in occupational safety and health: the safety awareness of construction workers in south China[J]. International Journal of Construction Management, 2016, 16(4): 315-325.
DOI URL |
| [28] |
IDREES M D, HAFEEZ M, KIM J Y. Workers’ age and the impact of psychological factors on the perception of safety at construction sites[J]. Sustainability, 2017, 9(5): 745.
DOI URL |
| [29] |
LOUW L A, SCHAAP P. Categories of human risk factors which impact on the psychological fitness of construction workers: a review of the evidence[J]. Journal of Psychology in Africa, 2013, 23(4): 589-599.
DOI URL |
| [30] |
GUO H L, YU Y T, XIANG T, et al. The availability of wearable-device-based physical data for the measurement of construction workers’psychological status on site: from the perspective of safety management[J]. Automation in Construction, 2017, 82: 207-217.
DOI URL |
| [31] |
LOVE P E D, EDWARDS D J. Taking the pulse of UK construction project managers’ health: influence of job demands, job control and social support on psychological wellbeing[J]. Engineering, Construction and Architectural Management, 2005, 12(1): 88-101.
DOI URL |
| [32] |
MOHAMED S. Safety climate in construction site environments[J]. Journal of Construction Engineering and Management, 2002, 128(5): 375-384.
DOI URL |
| [33] | OBIOZO R, SMALLWOOD J. Healing gardens for the construction site: an innovative organisational management strategy[C]// The 8th CIDB Postgraduate Conference. Johannesburg, South Africa: University of the Witwatersrand, 2014: 325. |
| [34] | JOKKAW N, SUTEECHARUWAT P, WEERAWETWAT P. Measurement of construction workers’ feeling by virtual environment (VE) technology for guardrail design in high-rise building construction projects[J]. Engineering Journal, 2017, 21(5): 161-177. |
| [35] |
QIU W S, LI W J, LIU X, et al. Subjectively measured streetscape perceptions to inform urban design strategies for Shanghai[J]. ISPRS International Journal of Geo-Information, 2021, 10(8): 493.
DOI URL |
| [36] |
EWING R, HANDY S. Measuring the unmeasurable: urban design qualities related to walkability[J]. Journal of Urban Design, 2009, 14(1): 65-84.
DOI URL |
| [37] |
PARK C S, SRINIVASAN V. A survey-based method for measuring and understanding brand equity and its extendibility[J]. Journal of Marketing Research, 1994, 31(2): 271-288.
DOI URL |
| [38] | LIN L, MOUDON A V. Objective versus subjective measures of the built environment, which are most effective in capturing associations with walking?[J]. Health & Place, 2010, 16(2): 339-348. |
| [39] | APPLETON J. The experience of landscape[M]. United Kingdom: Wiley, 1996: 69-74. |
| [40] |
GRIEW P, HILLSDON M, FOSTER C, et al. Developing and testing a street audit tool using Google street view to measure environmental supportiveness for physical activity[J]. International Journal of Behavioral Nutrition and Physical Activity, 2013, 10(1): 103.
DOI |
| [41] |
SALESSES P, SCHECHTNER K, HIDALGO C A. The collaborative image of the city: mapping the inequality of urban perception[J]. PLOS One, 2013, 8(7): e68400.
DOI URL |
| [42] |
RUNDLE A G, BADER M D M, RICHARDS C A, et al. Using Google street view to audit neighborhood environments[J]. American Journal of Preventive Medicine, 2011, 40(1): 94-100.
DOI PMID |
| [43] |
SERESINHE C I, PREIS T, MOAT H S. Using deep learning to quantify the beauty of outdoor places[J]. Royal Society Open Science, 2017, 4(7): 170170.
DOI URL |
| [44] | NAIK N, PHILIPOOM J, RASKAR R, et al. Streetscore - predicting the perceived safety of one million streetscapes[C]// 2014 IEEE Conference on Computer Vision and Pattern Recognition Workshops. New York: IEEE Press, 2014: 793-799. |
| [45] | DONG Z, SHEN X, LI H Q, et al. Photo quality assessment with DCNN that understands image well[C]// The 21st International Conference on Multimedia Modeling. Cham: Springer, 2015: 524-535. |
| [46] |
ONUBI H O, YUSOF N, HASSAN A S. Adopting green construction practices: health and safety implications[J]. Journal of Engineering, Design and Technology, 2019, 18(3): 635-652.
DOI URL |
| [47] |
KARAKHAN A A. LEED-certified projects: green or sustainable?[J]. Journal of Management in Engineering, 2016, 32(5): 02516001.
DOI URL |
| [48] |
ONUBI H O, YUSOF N, HASSAN A S. Understanding the mechanism through which adoption of green construction site practices impacts economic performance[J]. Journal of Cleaner Production, 2020, 254: 120170.
DOI URL |
| [49] | HOX J J, BOEIJE H R. Data collection, primary vs. secondary[M]//KEMPF-LEONARD K. Encyclopedia of Social Measurement. Amsterdam: Elsevier, 2005: 593-599. |
| [50] |
STEWART N, BROWN G D A, CHATER N. Absolute identification by relative judgment[J]. Psychological Review, 2005, 112(4): 881-911.
PMID |
| [51] | HERBRICH R, MINKA T, GRAEPEL T. TrueSkillTM: a Bayesian skill rating system[C]// The 20th International Conference on Neural Information Processing Systems. Cambridge: MIT Press, 2007: 569-576. |
| [52] | MINKA T, ZAYKOV Y, TIMS J. TrueSkillTM ranking system[EB/OL]. (2005-11-18) [2025-02-25]. https://www.microsoft.com/en-us/research/project/trueskill-ranking-system/. |
| [53] | DUBEY A, NAIK N, PARIKH D, et al. Deep learning the city: quantifying urban perception at a global scale[C]// The 14th European Conference on Computer Vision. Cham: Springer, 2016: 196-212. |
| [54] |
DUAN R, DENG H, TIAN M, et al. SODA: a large-scale open site object detection dataset for deep learning in construction[J]. Automation in Construction, 2022, 142: 104499.
DOI URL |
| [55] | ELKAPELLI S S, DAMAHE L B. A review: region of interest based image retrieval[C]// 2016 Online International Conference on Green Engineering and Technologies. New York: IEEE Press, 2016: 1-6. |
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