Accurate damage localization remains a critical and challenging task within electromechanical impedance-based structural health monitoring (ISHM), particularly in multiple simultaneous damage scenarios. While numerous methods have been proposed for single-damage localization using electromechanical impedance (EMI) measurements, approaches specifically designed to identify several damage sites remain scarce and underdeveloped. To address this gap, the present study introduces a novel localization framework based on the indicator kriging technique to assess the location of multiple damages. The methodology is experimentally validated using an aluminum plate subjected to up to three concurrent damage scenarios. The influence of frequency interval selection on the performance of the kriging-based probability models is systematically assessed through three distinct frequency band selection strategies. The results demonstrate that the proposed framework effectively identified multiple damage locations with good adherence to the real positions, comparable to or even superior to other advanced methodologies for multi-damage localization. The proposed method advances the current state of the art in multi-damage localization. At the same time, comprehensive experimental investigations offer valuable insights to guide future research efforts toward implementing robust solutions to industrial-scale environments.
AbzalovM (2016) Applied Mining Geology, Modern Approaches in Solid Earth Sciences. Springer International Publishing.
2.
AiDZhangDZhuH (2024a) A damage localization approach for concrete structure using discrete wavelet transform of electromechanical admittance of bonded PZT transducers. Mechanical Systems and Signal Processing218: 111531.
3.
AiDZhangDZhuH (2024b) Damage localization on reinforced concrete slab structure using electromechanical impedance technique and probability-weighted imaging algorithm. Construction and Building Materials424: 135824.
4.
AlazzawiOWangD (2021) Damage identification using the PZT impedance signals and residual learning algorithm. Journal of Civil Structural Health Monitoring11(5): 1225–1238.
5.
AnnamdasVGRadhikaMA (2013) Electromechanical impedance of piezoelectric transducers for monitoring metallic and non-metallic structures: A review of wired, wireless and energy-harvesting methods. Journal of Intelligent Material Systems and Structures24(9): 1021–1042.
6.
BaptistaFBudoyaDAlmeidaV, et al. (2014) An experimental study on the effect of temperature on piezoelectric sensors for impedance-based structural health monitoring. Sensors14(1): 1208–1227.
7.
Batista da SilvaRFerreiraFIBaptistaFG, et al. (2018) Electromechanical impedance (EMI) technique as alternative to monitor workpiece surface damages after the grinding operation. International Journal of Advanced Manufacturing Technology98: 2429–2438.
8.
Bharathi PriyaCLikhith ReddyARama RaoGV, et al. (2014) Low frequency and boundary condition effects on impedance based damage identification. Case Studies in Nondestructive Testing and Evaluation2: 9–13.
9.
CaoPZhangSWangZ, et al. (2023) Damage identification using piezoelectric electromechanical Impedance: A brief review from a numerical framework perspective. Structures50: 1906–1921.
10.
ChenDHuoLSongG (2020) EMI based multi-bolt looseness detection using series/parallel multi-sensing technique. Smart Structures and Systems25(4): 423–432.
11.
CherrierOSelvaPPommier-BudingerV, et al. (2013) Damage localization map using electromechanical impedance spectrums and inverse distance weighting interpolation: Experimental validation on thin composite structures. Structural Health Monitoring12(4): 311–324.
12.
ChilèsJPDelfinerP (2012) Geostatistics: Modeling Spatial Uncertainty, 2nd edn. John Wiley & Sons, Inc.
13.
de CastroBABaptistaFGCiampaF (2020) New imaging algorithm for material damage localisation based on impedance measurements under noise influence. Measurement163: 107953.
DjemanaMHrairiMAl JeroudiY (2017) Using electromechanical impedance and extreme learning machine to detect and locate damage in structures. Journal of Nondestructive Evaluation36(2): 39.
16.
DuFWangGWengJ, et al. (2022) High-precision probabilistic imaging for interface debonding monitoring based on electromechanical impedance. AIAA Journal60(7): 3950–3960.
17.
FanSZhaoSQiB, et al. (2018) Damage evaluation of concrete column under impact load using a piezoelectric-based EMI technique. Sensors18(5): 1591.
18.
FanXLiJHaoH (2021) Review of piezoelectric impedance based structural health monitoring: Physics-based and data-driven methods. Advances in Structural Engineering24(16): 3609–3626.
19.
Finzi NetoRMSteffenVRadeDA, et al. (2011) A low-cost electromechanical impedance-based SHM architecture for multiplexed piezoceramic actuators. Structural Health Monitoring10(4): 391–402.
20.
FreitasFAJafeliceRMSilvaJWD, et al. (2021) A new data normalization approach applied to the electromechanical impedance method using adaptive neuro-fuzzy inference system. Journal of the Brazilian Society of Mechanical Sciences and Engineering43(11): 475.
21.
GianesiniBMCortezNEAntunesRA, et al. (2021) Method for removing temperature effect in impedance-based structural health monitoring systems using polynomial regression. Structural Health Monitoring20(1): 202–218.
22.
GonçalvesDRDe MouraJDRVJrPereiraPEC (2020) MONITORAMENTO DE INTEGRIDADE ESTRUTURAL BASEADO EM IMPEDÂNCIA ELETROMECÂNICA UTILIZANDO O MÉTODO DE KRIGAGEM ORDINÁRIA. HOLOS2: 1–16.
23.
GonçalvesDRDe MouraJDRVPereiraPEC, et al. (2021) Indicator kriging for damage position prediction by the use of electromechanical impedance-based structural health monitoring. Comptes Rendus. Mécanique349(2): 225–240.
24.
HamzelooSRBarzegarMMohsenzadehM (2020) Damage detection of L-Shaped beam structure with a crack by electromechanical impedance response: Analytical Approach and experimental validation. Journal of Nondestructive Evaluation39(2): 47.
25.
HanFZhangQWangC, et al. (2020) Structural health monitoring of timber using electromechanical impedance (EMI) technique. Advances in Civil Engineering2020(1): 1906289.
26.
HaqMBhallaSNaqviT (2020a) Fatigue damage and residual fatigue life assessment in reinforced concrete frames using PZT-impedance transducers. Cement and Concrete Composites114: 103771.
27.
HaqMBhallaSNaqviT (2020b) Fatigue damage monitoring of reinforced concrete frames using wavelet transform energy of PZT-based admittance signals. Measurement164: 108033.
28.
HarrisCRMillmanKJvan der WaltSJ, et al. (2020) Array programming with NumPy. Nature585(7825): 357–362.
29.
HeCYangSLiuZ, et al. (2014) Damage localization and quantification of truss structure based on electromechanical impedance technique and neural network. Shock and Vibration2014: 1–9.
30.
HunterJD (2007) Matplotlib: A 2D graphics environment. Computer Science and Engineering9(3): 90–95.
31.
HuynhT-CHoangN-DPhamQ-Q, et al. (2024) Electromechanical admittance-based automatic damage assessment in plate structures via one-dimensional CNN-based deep learning models. Frontiers of Structural and Civil Engineering18(11): 1730–1751.
32.
JiangXZhouWChenX, et al. (2024) An electromechanical impedance-based imaging algorithm for damage identification of chemical milling stiffened panel. Structural Control and Health Monitoring2024(1): 4554472.
33.
JiaoPEgbeKIXieY, et al. (2020) Piezoelectric sensing techniques in structural health monitoring: A state-of-the-art review. Sensors20(13): 3730.
34.
JinCJangSSunX (2017) An integrated real-time structural damage detection method based on extended Kalman filter and dynamic statistical process control. Advances in Structural Engineering20(4): 549–563.
Keegan-TreloarRWernerADIrvineDJ, et al. (2021) Application of indicator Kriging to hydraulic head data to test alternative conceptual models for spring source aquifers. Journal of Hydrology601: 126808.
37.
KhayatazadMLoccufierMDe WaeleW (2025) Electromechanical impedance-based measurements for damage detection and characterization in medium-thick plates. Measurement248: 116841.
38.
KimJWLeeCParkS (2012) Damage localization for CFRP-debonding defects using piezoelectric SHM techniques. Research in Nondestructive Evaluation23(4): 183–196.
39.
LiWLiuTZouD, et al. (2019) PZT based smart corrosion coupon using electromechanical impedance. Mechanical Systems and Signal Processing129: 455–469.
40.
LuoZDengHLiL, et al. (2021) A simple PZT transducer design for electromechanical impedance (EMI)-based multi-sensing interrogation. Journal of Civil Structural Health Monitoring11(1): 235–249.
41.
MartinsLGAFinzi NetoRMSteffenVJr, et al. (2012) Architecture of a remote impedance-based structural health monitoring system for aircraft applications. Journal of the Brazilian Society of Mechanical Sciences and Engineering34: 393–400.
42.
MaruoCIIGiacheroGDFSteffenVJunior, et al. (2015) Electromechanical impedance - based structural health monitoring instrumentation system applied to aircraft structures and employing a multiplexed sensor array. Journal of Aerospace Technology and Management7(3): 294–306.
43.
MauryaKKRawatAShankerR (2022) Review article on condition assessment of structures using electro-mechanical impedance technique. Structural Durability and Health Monitoring16(2): 97–128.
44.
MeherUMishraSKSunnyMR (2022) Impedance-based looseness detection of bolted joints using artificial neural network: An experimental study. Structural Control and Health Monitoring29(10): e3049.
45.
MeherURabius SunnyM (2024) Localization and quantification of delamination/disbond inside a composite lap-joint using novel cross and drive point mechanical impedance based feature. Mechanical Systems and Signal Processing220: 111661.
46.
MigotAGiurgiutiuV (2023) Numerical and experimental investigation of delamination severity estimation using local vibration techniques. Journal of Intelligent Material Systems and Structures34(9): 1057–1072.
47.
MohammadpourMBahroudiAAbediM, et al. (2019) Geochemical distribution mapping by combining number-size multifractal model and multiple indicator kriging. Journal of Geochemical Exploration200: 13–26.
48.
NaSLeeHK (2012a) A technique for improving the damage detection ability of the electro-mechanical impedance method on concrete structures. Smart Materials and Structures21(8): 085024.
49.
NaSLeeHK (2012b) Resonant frequency range utilized electro-mechanical impedance method for damage detection performance enhancement on composite structures. Composite Structures94(8): 2383–2389.
50.
NaWSBaekJ (2018) A review of the piezoelectric electromechanical impedance based structural health monitoring technique for engineering structures. Sensors18(5): 1307.
51.
NguyenT-TTaQBHoDD, et al. (2023) A method for automated bolt-loosening monitoring and assessment using impedance technique and deep learning. Developments in the Built Environment14: 100122.
52.
NomeliniQSSDa SilvaJWGalloCA, et al. (2021) Statistical Process Control (Spc) of damage metrics in the impedance-based structural health monitoring. Brazilian Journal of Biometrics39(1): 7–24.
53.
NomeliniQSSSilvaJWDGalloCA, et al. (2020) Non-parametric inference applied to damage detection in the electromechanical impedance-based health monitoring. International Journal of Advanced Engineering Research and Science7(9): 73–79.
54.
OyekolaPOAlbakriMI (2025) Piezoelectric-based impedance monitoring: A critical analysis of indirect electromechanical impedance measurements in non-destructive evaluation. Journal of Intelligent Material Systems and Structures36(9): 616–631.
55.
PalominoLVTsurutaKMMourJRVJr, et al. (2012) Evaluation of the influence of sensor geometry and physical parameters on impedance-based structural health monitoring. Shock and Vibration19(5): 811–823.
56.
PanHHHuangM-W (2020) Piezoelectric cement sensor-based electromechanical impedance technique for the strength monitoring of cement mortar. Construction and Building Materials254: 119307.
57.
ParidaLMoharanaS (2023) A comprehensive review on piezo impedance based multi sensing technique. Results in Engineering18: 101093.
58.
PereiraPECDe RezendeSWFDe MouraJDRVJr, et al. (2024a) SGS method applied to damage location and uncertainty modeling for sensor grid in the ISHM. Comptes Rendus. Mecánique352: 19–37.
59.
PereiraPECde RezendeSWFFernandesHC, et al. (2024b) On damage location techniques and future prospects for industrial applications utilizing the electromechanical impedance method: A systematic review. Journal of the Brazilian Society of Mechanical Sciences and Engineering46(5): 311.
60.
PereiraPECRabeloMNRibeiroCC, et al. (2017) Geological modeling by an indicator kriging approach applied to a limestone deposit in Indiara city - Goiás. REM - International Engineering Journal70(3): 331–337.
61.
PrudenteFADJafeliceRSMSilvaJW, et al. (2025) Neuro-fuzzy systems applied to structural health monitoring by electromechanical impedance. Brazilian Journal of Physics55(5): 227.
62.
PyrczMJKupenkoALiuW, et al. (2022) GeostatsPy Python Package. Version 0.0.25. Available at: www.pypi.org/project/geostatspy/0.0.25/ (accessed 29 June 2025).
63.
RavichandranJPranaviKParamanathanP (2025) Construction of Six sigma-based control chart for interval-valued data. Communications in Statistics - Simulation and Computation54(6): 2175–2192.
64.
RevueltaMB (2018) Mineral Resources: From Exploration to Sustainability Assessment. Springer International Publishing.
65.
RossiMEDeutschCV (2014) Mineral Resource Estimation. Springer Science+Business Media.
66.
SakataYKatsuraTNaganoK (2020) Estimation of ground thermal conductivity through indicator kriging: Nation-scale application and vertical profile analysis in Japan. Geothermics88: 101881.
67.
SakhriaBHamaidiBDjemanaM, et al. (2024) Harnessing neural networks for precise damage localization in photovoltaic solar via impedance-based structural health monitoring. Electrical Engineering107: 3229–3245.
68.
SałacińskiTChrzanowskiJChmielewskiT (2023) Statistical Process Control using control charts with variable parameters. Processes11(9): 2744.
69.
SelvaPCherrierOBudingerV, et al. (2013) Smart monitoring of aeronautical composites plates based on electromechanical impedance measurements and artificial neural networks. Engineering Structures56: 794–804.
70.
ShankerRBhallaSGuptaA, et al. (2011) Dual use of PZT patches as sensors in global dynamic and local electromechanical impedance techniques for structural health monitoring. Journal of Intelligent Material Systems and Structures22(16): 1841–1856.
71.
SikdarSSinghSKMalinowskiP, et al. (2022) Electromechanical impedance based debond localisation in a composite sandwich structure. Journal of Intelligent Material Systems and Structures33(12): 1487–1496.
72.
SinclairAJBlackwellGH (2002) Applied Mineral Inventory Estimation, 1st edn. Cambridge University Press.
73.
SinghSKFakihMAMalinowskiPH (2023) Damage detection and localization based on different types of actuators using the electromechanical impedance method in 3D-printed material. Smart Materials and Structures32(11): 115004.
74.
SinghSKMalinowskiPH (2022) An innovative data-driven probabilistic approach for damage detection in electromechanical impedance technique. Composite Structures295: 115808.
75.
SinghSKSomanRNMalinowskiPH (2024) A novel multi-damage localization method for polymers and composites based on electromechanical impedance. Mechanical Systems and Signal Processing216: 111508.
76.
SunRLuYLiuG, et al. (2024) Damage identification of steel-ECC composite deck incorporating piezoelectric impedance methodology and hierarchical clustering analysis. Archives of Civil and Mechanical Engineering24(3): 187.
77.
SuY-FHanGAmranA, et al. (2019) Instantaneous monitoring the early age properties of cementitious materials using PZT-based electromechanical impedance (EMI) technique. Construction and Building Materials225: 340–347.
78.
TekkalmazMErÜÇakirFH, et al. (2022) A new approach to monitor wear tracks propagation on-site with electromechanical impedance technique. Journal of Intelligent Material Systems and Structures33(2): 342–351.
79.
The Pandas Development Team (2023) pandas-dev/pandas: Pandas. Zenodo. DOI: 10.5281/zenodo.7549438.
80.
VirtanenPGommersROliphantTE, et al. (2020) SciPy 1.0: Fundamental algorithms for scientific computing in Python. Nature Methods17(3): 261–272.
81.
WangDSongHZhuH (2013) Numerical and experimental studies on damage detection of a concrete beam based on PZT admittances and correlation coefficient. Construction and Building Materials49: 564–574.
82.
WangLYuanBXuZ, et al. (2022) Synchronous detection of bolts looseness position and degree based on fusing electro-mechanical impedance. Mechanical Systems and Signal Processing174: 109068.
83.
WuJYangGWangX, et al. (2020) PZT-based soil compactness measuring sheet using electromechanical impedance. IEEE Sensors Journal20(17): 10240–10250.
84.
YangHJLiCI (2025) Nonparametric control limits incorporating exceedance probability criterion for statistical process monitoring with commonly employed small to moderate sample sizes. Quality Engineering37(1): 145–161.
85.
YangYDivsholiBS (2010) Sub-frequency interval approach in electromechanical impedance technique for concrete structure health monitoring. Sensors10(12): 11644–11661.
86.
ZamanianMSepehryNZahraiSM (2024) A multitask SHM algorithm to identify damage with random severity and location in IPE beams using EMI technique. Structures70: 107659.
87.
ZhangYZhangXChenJ, et al. (2018) Electro-mechanical impedance based position identification of bolt loosening using libsvm. Intelligent Automation & Soft Computing24(1): 81–88.
88.
ZhangYZhouKTangJ (2024) Piezoelectric impedance-based high-accuracy damage identification using sparsity conscious multi-objective optimization inverse analysis. Mechanical Systems and Signal Processing209: 111093.
89.
ZhuJWangYQingX (2019a) A real-time electromechanical impedance-based active monitoring for composite patch bonded repair structure. Composite Structures212: 513–523.
ZhuJQingXLiuX, et al. (2021) Electromechanical impedance-based damage localization with novel signatures extraction methodology and modified probability-weighted algorithm. Mechanical Systems and Signal Processing146: 107001.
