Semantic segmentation of hyperspectral data for identifying mineral alterations in the Kuhpanj porphyry copper deposit using an improved U-Net architecture
Restricted accessResearch articleFirst published online 2026
Semantic segmentation of hyperspectral data for identifying mineral alterations in the Kuhpanj porphyry copper deposit using an improved U-Net architecture
Accurate mapping of hydrothermal alteration zones is critical for improving the efficiency of porphyry copper exploration. In the Kuhpanj porphyry copper district (Kerman, Iran), distinguishing phyllic, argillic and propylitic alterations from surrounding lithologies using satellite data remains challenging due to spectral complexity and spatial heterogeneity. This study proposes an improved semantic segmentation framework for spaceborne hyperspectral imagery, exploiting 41 bands of PRISMA data to delineate alteration zones at the deposit scale. A modified U-net architecture was developed that employs a dual-path design for the concurrent extraction of spectral and spatial features: one branch processes pixel-wise spectra across the 41 bands, while the second branch captures local spatial context within 256 × 256 × 41 patches. The performance of the proposed network was benchmarked against a V-net architecture using a confusion-matrix-based evaluation. The proposed model achieved an F1-score of 86% while being trained on a limited labelled dataset, and it requires substantially fewer trainable parameters than the reference architecture, highlighting its efficiency for data-constrained exploration scenarios. The results demonstrate that the new dual-path U-net significantly enhances the reliability of alteration mapping from PRISMA hyperspectral data and provides a computationally efficient deep-learning solution for processing high-dimensional geoscientific imagery. This contribution extends current applications of convolutional neural networks in mineral exploration by introducing a tailored architecture that improves both accuracy and model compactness for hyperspectral semantic segmentation.
YanNZhaoJLiZ, et al.Optimization of geological and mineral exploration by integrating remote sensing technology and borehole database. Wirel Commun Mob Comput2022; 2022: 1–11.
2.
WangWWangJZhouK, et al. (2015) Analysis and research on mineral hyperspectral features. 10.2991/ism3e-15.2015.3
3.
BeiranvandPourAHashimM. Identification of hydrothermal alteration minerals for exploring of porphyry copper deposit using ASTER data, SE Iran. J Asian Earth Sci2011; 42: 1309–1323.
4.
ShirmardHFarahbakhshEPourAB, et al.Integration of selective dimensionality reduction techniques for mineral exploration using aster satellite data. Remote Sens (Basel)2020; 12: 1261.
5.
BediniEChenJ. Application of PRISMA satellite hyperspectral imagery to mineral alteration mapping at Cuprite, Nevada, USA. J Hyperspectr Remote Sens2020; 10: 87–94.
6.
VangiED’AmicoGFranciniS, et al.The new hyperspectral satellite PRISMA: imagery for forest types discrimination. Sensors2021; 21: 1182.
7.
LazzeriGFrodellaWRossiG, et al.Multitemporal mapping of post-fire land cover using multiplatform PRISMA hyperspectral and Sentinel-UAV multispectral data: insights from case studies in Portugal and Italy. Sensors2021; 21: 3982.
8.
BahetiBInnaniSGajreS, et al. Eff-UNet: A novel architecture for semantic segmentation in unstructured environment. 2020 IEEE/CVF conference on computer vision and pattern recognition workshops (CVPRW). IEEE. June 2020. 10.1109/cvprw50498.2020.00187
9.
PatelMJKothariAMKoringaHP. A novel approach for semantic segmentation of automatic road network extractions from remote sensing images by modified UNet. Radioelectron Comput Syst2022. 10.32620/reks.2022.3.12
10.
DeckerKTBorghettiBJ. Composite style pixel and point convolution-based deep fusion neural network architecture for the semantic segmentation of hyperspectral and lidar data. Remote Sens (Basel)2022. 10.3390/rs14092113
11.
DeckerKTBorghettiBJ. Hyperspectral point cloud projection for the semantic segmentation of multimodal hyperspectral and lidar data with point convolution-based deep fusion neural networks. Appl Sci2023. 10.3390/app13148210
12.
BidariIChickerurSKadamS. Semantic segmentation using U-net architecture for change detection on hyperspectral imagery. 2023 International conference on sustainable communication networks and application (ICSCNA). IEEE. 15 November 2023. 10.1109/icscna58489.2023.10370358
13.
ForsonEAmponsahPWemegahD, et al.Random forest-based mineral. Appl Earth Sci2024; 133: 30–45.
14.
MuljaTHeriawanMHawu HedeA. Porphyry and skarn Cu prospectivity of Sumatra with GIS spatial modelling techniques. Appl Earth Sci2024; 133: 4–29.
15.
DimitrijivicM. Geology of Kerman region, geological survey of Iran. Report1973; No yu/52: 334p.
KhosraviA. Statistical geological and alteration map of Kuh Panj copper deposit. Exploration Department, 2007.
18.
RoshaniPMokhtariARTabatabaeiSH. Objective-based geochemical anomaly detection – application of discriminant function analysis in anomaly delineation in the Kuh Panj porphyry Cu mineralization (Iran). J Geochem Explor2013; 130: 65–73.
19.
BaiocchiVGiannoneFMontiF. How to orient and orthorectify PRISMA images and related issues. Remote Sens (Basel)2022; 14: 1991.
20.
KokhanovskyAAMauroBDColomboR. Snow surface properties derived from PRISMA satellite data over the Nansen Ice Shelf (East Antarctica). Front Environ Sci2022; 10. 10.3389/fenvs.2022.904585
21.
AmiciSSpillerDAnsaloneL, et al.Wildfires temperature estimation by complementary use of hyperspectral PRISMA and thermal (ECOSTRESS & L8). J Geophys Res Biogeosci2022; 127. 10.1029/2022jg007055
22.
KokalATIsmailogluIMusaoğluN. Comparison of Landsat-9 and PRISMA satellite data for land use / land cover classification. Int Arch Photogramm Remote Sens Spat Inf Sci2022; XLVI-M-2-2022: 197–201.
23.
ManninoAMBorfecchiaFMicheliC. Tracking marine alien macroalgae in the Mediterranean sea: the contribution of citizen science and remote sensing. J Mar Sci Eng2021; 9: 88.
24.
CusworthDHDurenRThorpeAK, et al.Quantifying global power plant carbon dioxide emissions with imaging spectroscopy. AGU Adv2021; 2. 10.1029/2020av000350
25.
NesmeNMarionRLezeauxO, et al.Joint use of in-scene background radiance estimation and optimal estimation methods for quantifying methane emissions using PRISMA hyperspectral satellite data: application to the Korpezhe industrial site. Remote Sens (Basel)2021; 13: 4992.
26.
RomanielloVSilvestriMBuongiornoMF, et al.Comparison of PRISMA data with model simulations, hyperion reflectance and field spectrometer measurements on ‘Piano delle Concazze’ (Mt. Etna, italy). Sensors2020; 20: 7224.
27.
ValentiniETaramelliAMarinelliC, et al.Hyperspectral mixture models in the chime mission implementation for topsoil texture retrieval. J Geophys Res Biogeosci2023; 128. 10.1029/2022jg007272
28.
GiardinoCBrescianiMBragaF, et al.First evaluation of PRISMA level 1 data for water applications. Sensors2020; 20: 4553.
29.
BohnNMauroBDColomboR, et al.Glacier ice surface properties in south-west Greenland ice sheet: first estimates from PRISMA imaging spectroscopy data. J Geophys Res Biogeosci2022; 127. 10.1029/2021jg006718
30.
MzidNCastaldiFTolomioM, et al.Evaluation of agricultural bare soil properties retrieval from landsat 8, sentinel-2 and PRISMA satellite data. Remote Sens (Basel)2022; 14: 14.
31.
AcitoNDianiMCorsiniG. PRISMA spatial resolution enhancement by fusion with sentinel-2 data. IEEE J Sel Top Appl Earth Obs Remote Sens2022; 15: 62–79.
32.
Niroumand-JadidiMBovoloFBruzzoneL. Water quality retrieval from PRISMA hyperspectral images: first experience in a turbid lake and comparison with sentinel-2. Remote Sens (Basel)2020; 12: 3984.
33.
ZhangTYiGLiH, et al.Integrating data of ASTER and Landsat-8 OLI (AO) for hydrothermal alteration mineral mapping in Duolong porphyry Cu-Au deposit, Tibetan Plateau, China. Remote Sens (Basel)2016; 8: 90.
34.
AbediMNorouziGFathianpourN. Mineral potential mapping in central Iran using fuzzy ordered weighted averaging method. Geophys Prospect2014; 63: 461–477.
35.
BoloukiSMRamaziHMaghsoudiA, et al.A remote sensing-based application of Bayesian networks for epithermal gold potential mapping in Ahar-Arasbaran Area, NW Iran. Remote Sens (Basel)2019; 12: 05.
36.
EsmaeiliMFathianpourNSoltani-MohammadiS. PRISMA hyperspectral imagery for mapping alteration zones associated with Kuhpanj porphyry copper deposit, Southern Iran. Eur J Remote Sens2024; 57. 10.1080/22797254.2023.2299369
37.
SultanaAAsariVKSudakowI, et al.R2unet for melt pond detection. Pattern Recognit Tracking XXXIV2023. 10.1117/12.2663982
38.
DuJ. Road crack detection based on improved u-net. In: Third international conference on computer vision and pattern analysis (ICCPA 2023), 2023. 10.1117/12.2684288
39.
LiX. Brain tumor segmentation by combining mri multimodal information and improved unet network. In: Fourth international conference on computer vision and data mining (ICCVDM 2023)2024. 10.1117/12.3021391
40.
WangSHeJHeX, et al.AES-CSFS: an automatic evaluation system for corneal sodium fluorescein staining based on deep learning. Ther Adv Chronic Dis2023; 14: 204062232211482.
41.
SaoodAHatemI. Covid-19 lung ct image segmentation using deep learning methods: unet vs. segnet. 2020. 10.21203/rs.3.rs-56882/v2
42.
SuRMaY aand WangX. A segmentation method for building in remote sensing image based on deep learning. In: International conference on cloud computing, performance computing, and deep learning (CCPCDL 2022), 2022. 10.1117/12.2640812
43.
ZavagnoADupéFBensaidS, et al.Supervised machine learning on galactic filaments. Astron Astrophys2023; 669: A120.
44.
ZhouZSiddiqueeMRTajbakhshN, et al.Unet++: redesigning skip connections to exploit multiscale features in image segmentation. IEEE Trans Med Imaging2020; 39: 1856–1867.
45.
TranSChengCNguyenT, et al.TMD-Unet: Triple-Unet with multi-scale input features and dense skip connection for medical image segmentation. Healthcare2021; 9: 54.
46.
BeretaFRodriguesAPeroniR, et al.Automated lithological classification using UAV and machine learning on an. Appl Earth Sci2019; 128: 79–88.
47.
ZhaoCShiSHeZ, et al.Spatial-temporal V-Net for automatic segmentation and quantification of right ventricle on gated myocardial perfusion spect images. Med Phys2023; 50: 7415–7426.
48.
PanSChangCWangT, et al.Abdomen CT multi-organ segmentation using token-based MLP-Mixer. Med Phys2022; 50: 3027–3038.
49.
ShiriIArabiHSanaatA, et al.Fully automated gross tumor volume delineation from pet in head and neck cancer using deep learning algorithms. Clin Nucl Med2021; 46: 872–883.
50.
AhmadiSFreiJVivarG, et al.IE-VNet: deep learning-based segmentation of the inner ear's total fluid space. Front Neurol2022; 13. 10.3389/fneur.2022.663200
51.
ZhuGLuoXYangT, et al.Deep learning-based recognition and segmentation of intracranial aneurysms under small sample size. Front Physiol2022; 13. 10.3389/fphys.2022.1084202
52.
ZhuLXinGWangX, et al.A fast tongue detection and location algorithm in natural environment. Comput Mater Contin2022; 73: 4727–4742.
53.
LewisSInglisSDoyleS. The role of anatomical context in soft-tissue multi-organ segmentation of cadaveric non-contrast-enhanced whole body CT. Med Phys2023; 50: 5061–5074.
54.
JinLChenQShiA, et al.Deep learning for automated contouring of gross tumor volumes in esophageal cancer. Front Oncol2022; 12. 10.3389/fonc.2022.892171
55.
SunoqrotMRSSelnæsKMSandsmarkE, et al.The reproducibility of deep learning-based segmentation of the prostate gland and zones on T2-weighted MR images. Diagnostics2021; 11: 1690.
56.
DodiaSAnnappaBAnandMP. A novel receptive field-regularized v-net and nodule classification network for lung nodule detection. Int J Imaging Syst Technol2021; 32: 88–101.
57.
HendrycksDGimpelK. Gaussian error linear units (GELUS). 2016. 10.48550/arxiv.1606.08415
58.
KimSJiWDengS, et al.Stiff neural ordinary differential equations. 2021. 10.48550/arxiv.2103.15341
59.
NaveenP. Phish: a novel hyper-optimizable activation function. 2022. 10.36227/techrxiv.17283824
60.
NworuCCEkpenyongEJJohnC, et al.The effect of activation functions in a chest x-ray image classification. 2022. 10.21203/rs.3.rs-2064395/v1
61.
YangSXieYLiuJ, et al.Raman spectral classification algorithm of cephalosporin based on VGGNeXt. Analyst2022; 147: 5486–5494.
62.
YuWRenP. Vehicle and pedestrian target detection in auto driving scene. J Phys: Conf Ser2021; 2132: 012013.
63.
BabaeM.N, The Use of multivariate methods for exploratory modeling in Sar Cheshmeh and Kuh Panj areas, Supervisor: H. Ranjbar, September, 2009. 3- Mostafa Shakarami, integration of geochemical, geophysical and remote sensing data for uranium indices by using GI. Shahid Bahonar University of Kerman. 2009.
64.
YousefiMTabatabaeiSGHRikhtehgaranR, et al.Detection of alteration zones using the Dirichlet process stick-breaking model-based clustering algorithm to hyperion data: the case study of Kuh-Panj porphyry copper deposits, Southern Iran. Geocarto Int2022; 37: 9788–9816.
65.
NajafianT. Discrimination and identification of hydrothermal alteration types related to porphyry copper deposits, Sarcheshmeh, Kerman Province. MSc Thesis, Shahid Bahonar University, 2010.
66.
ChenQZhaoZZhouJ, et al.New insights into the Pulang porphyry copper deposit in southwest China: indication of alteration minerals detected using aster and worldview-3 data. Remote Sens (Basel)2021; 13: 2798.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
