The sensitivity of UAV-borne thermal imagery for early detection of the bark beetle-infested spruce trees

Tomáš Klouček; Roman Modlinger; Markéta Zikmundová; Kristýna Štěpánová; Petra Pracná; Jiří Rous; Giorgi Kozhoridze; Přemysl Štych; Josef Laštovička; Jan Komárek

doi:10.1007/s11676-026-02068-1

Journal of Forestry Research ›› 2026, Vol. 37 ›› Issue (1) :129 DOI: 10.1007/s11676-026-02068-1

Original Paper

research-article

The sensitivity of UAV-borne thermal imagery for early detection of the bark beetle-infested spruce trees

Author information +

History +

PDF

Abstract

Bark beetle outbreaks pose a severe threat to spruce forests, with the European spruce bark beetle (Ips typographus L.) being the dominant pest in the Czech Republic. Although multispectral imagery using visible (VIS) and near-infrared (NIR) wavelengths has been employed for early detection, it primarily captures visible infestation symptoms rather than the underlying physiological stress, which can, however, be detected using thermal measurements, highlighting the benefit of integrating or complementing multispectral with thermal imagery. We compared a time series of Unmanned Aerial Vehicle (UAV) based thermal and multispectral imagery over a 650—ha coniferous stand in Central Bohemia, acquired at key phases of infestation (a) a year before infestation (August 2020); (b) closely before bark beetle infestation (April 2021); (c) in the initial phase of the green-attack (May 2021); and (d) in green-attack stage, early detection (June 2021), based on the species phenological model and field survey. Comparisons of canopy temperature and Normalised Difference Vegetation Index (NDVI) showed that thermal imagery successfully discriminated between healthy and infested trees seven weeks after beetle attack (green-attack), whereas NDVI differences remained negligible. These results confirm that UAV thermal imaging outperforms multispectral data for the early, individual-tree detection of bark beetle infestation.

Keywords

Stress detectability / Drone / Thermal signature / Time-series analysis / NDVI / Biotic disturbance

Cite this article

Download citation ▾

Tomáš Klouček, Roman Modlinger, Markéta Zikmundová, Kristýna Štěpánová, Petra Pracná, Jiří Rous, Giorgi Kozhoridze, Přemysl Štych, Josef Laštovička, Jan Komárek. The sensitivity of UAV-borne thermal imagery for early detection of the bark beetle-infested spruce trees. Journal of Forestry Research, 2026, 37(1): 129 DOI:10.1007/s11676-026-02068-1

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Abdullah H, Darvishzadeh R, Skidmore AK, Groen TA, Heurich M. European spruce bark beetle (Ips typographus, L.) green attack affects foliar reflectance and biochemical properties. Int J Appl Earth Obs Geoinf, 2018, 64: 199-209

[2]	Abdullah H, Darvishzadeh R, Skidmore AK, Heurich M. Sensitivity of Landsat-8 OLI and TIRS data to foliar properties of early stage bark beetle (Ips typographus, L.) infestation. Remote Sens, 2019, 11(4): 398

[3]	Abdullah H, Skidmore AK, Darvishzadeh R, Heurich M. Sentinel-2 accurately maps green-attack stage of European spruce bark beetle (Ips typographus, L.) compared with Landsat-8. Remote Sens Ecol Conserv, 2019, 5(1): 87-106

[4]	Abdullah H, Skidmore AK, Darvishzadeh R, Heurich M. Timing of red-edge and shortwave infrared reflectance critical for early stress detection induced by bark beetle (Ips typographus, L.) attack. Int J Appl Earth Obs Geoinf, 2019, 82: 101900

[5]	Anderson MJ. A new method for non-parametric multivariate analysis of variance. Austral Ecol, 2001, 26(1): 32-46

[6]	Baier P, Pennerstorfer J, Schopf A. PHENIPS—a comprehensive phenology model of Ips typographus (L.) (Col., Scolytinae) as a tool for hazard rating of bark beetle infestation. For Ecol Manage, 2007, 249(3): 171-186

[7]	Bárta V, Lukeš P, Homolová L. Early detection of bark beetle infestation in Norway spruce forests of Central Europe using Sentinel-2. Int J Appl Earth Obs Geoinf, 2021, 100: 102335

[8]	Bárta V, Hanuš J, Dobrovolný L, Homolová L. Comparison of field survey and remote sensing techniques for detection of bark beetle-infested trees. For Ecol Manag, 2022, 506: 119984

[9]	Bi PY, Yu LF, Zhou Q, Kuang JJ, Tang R, Ren LL, Luo YQ. Early detection of Dendroctonus valens infestation with UAV-based thermal and hyperspectral images. Remote Sens, 2024, 16(20 3840

[10]

Bijou S, Kupková L, Potůčková M, Červená L, Lysák J (2023) Evaluation of the bark beetle green attack detectability in spruce forest from multitemporal multispectral uav imagery. ISPRS Ann Photogramm Remote Sens Spatial Inf Sci X-1/W1-2023: 1033–1040. https://doi.org/10.5194/isprs-annals-x-1-w1-2023-1033-2023

[11]	Bozzini A, Brugnaro S, Morgante G, Santoiemma G, Deganutti L, Finozzi V, Battisti A, Faccoli M. Drone-based early detection of bark beetle infested spruce trees differs in endemic and epidemic populations. Front for Glob Change, 2024, 7 1385687

[12]	Bozzini A, Huo LN, Brugnaro S, Morgante G, Persson HJ, Finozzi V, Battisti A, Faccoli M. Multispectral drone images for the early detection of bark beetle infestations: assessment over large forest areas in the Italian South-Eastern Alps. Front for Glob Change, 2025, 8 1532954

[13]

Chakhvashvili E, Machwitz M, Antala M, Rozenstein O, Prikaziuk E, Schlerf M, Naethe P, Wan QX, Komárek J, Klouek T, Wieneke S, Siegmann B, Kefauver S, Kycko M, Balde H, Paz VS, Jimenez-Berni JA, Buddenbaum H, Hänchen L, Wang N, Weinman A, Rastogi A, Malachy N, Buchaillot ML, Bendig J, Rascher U. Crop stress detection from UAVs: best practices and lessons learned for exploiting sensor synergies. Precision Agric, 2024, 25(5): 2614-2642

[14]	Doležal P, Sehnal F. Effects of photoperiod and temperature on the development and diapause of the bark beetle Ips typographus. J Appl Entomol, 2007, 131(3): 165-173

[15]	Döpper V, Gränzig T, Kleinschmit B, Förster M. Challenges in UAS-based TIR imagery processing: image alignment and uncertainty quantification. Remote Sens, 2020, 12(10 1552

[16]	Finch H. Comparison of the performance of nonparametric and parametric MANOVA test statistics when assumptions are violated. Methodology, 2005, 1(1): 27-38

[17]	Fritscher D, Schroeder M. Thermal sum requirements for development and flight initiation of new-generation spruce bark beetles based on seasonal change in cuticular colour of trapped beetles. Agric for Entomol, 2022, 24(3): 405-421

[18]	Gurevitch J, Hedges LV. Statistical issues in ecological meta-analyses. Ecology, 1999, 80(4): 1142-1149

[19]	Hais M, Kučera T. Surface temperature change of spruce forest as a result of bark beetle attack: remote sensing and GIS approach. Eur J for Res, 2008, 127(4): 327-336

[20]	Hladky R, Lastovicka J, Holman L, Stych P. Evaluation of the influence of disturbances on forest vegetation using Landsat time series; a case study of the Low Tatras National Park. Eur J Remote Sens, 2020, 53(1): 40-66

[21]	Hlásny T, Merganičová K, Modlinger R, et al.. Prognosis of bark beetle outbreak and a new platform for the dissemination of information about the forests in the Czech republic. Zprávy Lesnického Výzkumu, 2021, 66: 197-205

[22]	Hlásny T, Krokene P, Liebhold A, et al (2019) Living with bark beetles: impacts, outlook and management options. From Science to Policy 8 European Forest Institute 52. https://doi.org/10.36333/fs08

[23]

Honkavaara E, Näsi R, Oliveira R, Viljanen N, Suomalainen J, Khoramshahi E, Hakala T, Nevalainen O, Markelin L, Vuorinen M, Kankaanhuhta V, Lyytikäinen-Saarenmaa P, Haataja L (2020) Using multitemporal hyper- and multispectral uav imaging for detecting bark beetle infestation on Norway spruce. Int Arch Photogramm Remote Sens Spatial Inf Sci XLIII-B3-2020: 429–434. https://doi.org/10.5194/isprs-archives-xliii-b3-2020-429-2020

[24]	Huang S, Tang LN, Hupy JP, Wang Y, Shao GF. A commentary review on the use of normalized difference vegetation index (NDVI) in the era of popular remote sensing. J for Res, 2021, 32(1): 1-6

[25]	Huo LN, Persson HJ, Lindberg E. Early detection of forest stress from European spruce bark beetle attack, and a new vegetation index: normalized distance red & SWIR (NDRS). Remote Sens Environ, 2021, 255 112240

[26]

Huo LN, Koivumäki N, Oliveira RA, Hakala T, Markelin L, Näsi R, Suomalainen J, Polvivaara A, Junttila S, Honkavaara E. Bark beetle pre-emergence detection using multi-temporal hyperspectral drone images: green shoulder indices can indicate subtle tree vitality decline. ISPRS J Photogramm Remote Sens, 2024, 216: 200-216

[27]	Jiang ZY, Chen YH, Li J, Dou W (2005) The impact of spatial resolution on NDVI over heterogeneous surface. In: Proceedings of 2005 IEEE International Geoscience and Remote Sensing Symposium, 2005. IGARSS '05. Seoul, Korea. IEEE: 1310–1313.

[28]	Karpov A, Pirtskhalava-Karpova N, Trubin A, Surovy P, Jakuš R. Analysis of solar radiation and thermography data using tree crowns parameters for Norway spruce. For Ecol Manag, 2025, 582 122557

[29]	Kautz M, Feurer J, Adler P. Early detection of bark beetle (Ips typographus) infestations by remote sensing–A critical review of recent research. For Ecol Manag, 2024, 556 121595

[30]	Klouček T, Komárek J, Surový P, Hrach K, Janata P, Vašíček B. The use of UAV mounted sensors for precise detection of bark beetle infestation. Remote Sens, 2019, 11(13): 1561

[31]	Klouček T, Modlinger R, Zikmundová M, Kycko M, Komárek J. Early detection of bark beetle infestation using UAV-borne multispectral imagery: a case study on the spruce forest in the Czech Republic. Front for Glob Change, 2024, 7: 1215734

[32]	Kozhoridze G, Korolyova N, Jakuš R. Norway spruce susceptibility to bark beetles is associated with increased canopy surface temperature in a year prior disturbance. For Ecol Manag, 2023, 547 121400

[33]	Lastovicka J, Svec P, Paluba D, Kobliuk N, Svoboda J, Hladky R, Stych P. Sentinel-2 data in an evaluation of the impact of the disturbances on forest vegetation. Remote Sens, 2020, 12(12): 1914

[34]	León-Tavares J, Roujean JL, Smets B, Wolters E, Toté C, Swinnen E. Correction of directional effects in VEGETATION NDVI time-series. Remote Sens, 2021, 13(6): 1130

[35]	Li RB, Zeng FX, Zhao Y, Wu Y, Niu JL, Leon Wang L, Gao NP, Zhou HZ, Shi X, Huang ZS. Analyzing the impact of various factors on leaf surface temperature based on a new tree-scale canopy energy balance model. Sustain Cities Soc, 2023, 99 104994

[36]	Li MJ, Shao W, Su Y, Coenders-Gerrits M, Jarsjö J. Evidence of field-scale shifts in transpiration dynamics following bark beetle infestation: stomatal conductance responses. Hydrol Process, 2024, 38(5 e15162

[37]	Majdák A, Jakuš R, Blaženec M. Determination of differences in temperature regimes on healthy and bark-beetle colonised spruce trees using a handheld thermal camera. Iforest, 2021, 14(3): 203-211

[38]	Mann HB, Whitney DR. On a test of whether one of two random variables is stochastically larger than the other. Ann Math Stat, 1947, 18(1): 50-60

[39]	Marvasti-Zadeh SM, Goodsman D, Ray N, Erbilgin N. Early detection of bark beetle attack using remote sensing and machine learning: a review. ACM Comput Surv, 2023, 56(4): 1-40

[40]	McKnight PE, Najab J (2010) Mann‐Whitney U Test. In: The Corsini Encyclopedia of Psychology. Wiley, pp 1–1

[41]	Mikkelson KM, Bearup LA, Maxwell RM, Stednick JD, McCray JE, Sharp JO. Bark beetle infestation impacts on nutrient cycling, water quality and interdependent hydrological effects. Biogeochemistry, 2013, 115(1): 1-21

[42]	Näsi R, Honkavaara E, Lyytikäinen-Saarenmaa P, Blomqvist M, Litkey P, Hakala T, Viljanen N, Kantola T, Tanhuanpää T, Holopainen M. Using UAV-based photogrammetry and hyperspectral imaging for mapping bark beetle damage at tree-level. Remote Sens, 2015, 7(11): 15467-15493

[43]	Näsi R, Honkavaara E, Blomqvist M, Lyytikäinen-Saarenmaa P, Hakala T, Viljanen N, Kantola T, Holopainen M. Remote sensing of bark beetle damage in urban forests at individual tree level using a novel hyperspectral camera from UAV and aircraft. Urban for Urban Green, 2018, 30: 72-83

[44]

Östersund M, Honkavaara E, Oliveira RA, Näsi R, Hakala T, Koivumäki N, Pelto-Arvo M, Tuviala J, Nevalainen O, Lyytikäinen-Saarenmaa P. Exploring forest changes in an Ips typographus L. outbreak area: insights from multi-temporal multispectral UAS remote sensing. Eur J for Res, 2024, 143(6): 1871-1892

[45]	Pieper M, Manolakis DG, Truslow E, Cooley T, Brueggeman M, Jacobson J, Weisner A. Effects of wavelength calibration mismatch on temperature-emissivity separation techniques. IEEE J Sel Top Appl Earth Obs Remote Sens, 2018, 11(4): 1315-1324

[46]	Pivovar M, Näsi R, Honkavaara E, Blaženec M, Škvarenina J, Modlinger R, Rožnovský J, Jakuš R. Spectral signatures discrimination of Norway spruce trees under experimentally induced drought and acute thermal stress using hyperspectral imaging. For Ecol Manag, 2025, 586 122692

[47]	Shapiro SS, Wilk MB. An analysis of variance test for normality (complete samples). Biometrika, 1965, 52(3–4): 591-611

[48]

Singh VV, Naseer A, Mogilicherla K, Trubin A, Zabihi K, Roy A, Jakuš R, Erbilgin N. Understanding bark beetle outbreaks: exploring the impact of changing temperature regimes, droughts, forest structure, and prospects for future forest pest management. Rev Environ Sci Bio/technol, 2024, 23(2): 257-290

[49]	Smigaj M, Agarwal A, Bartholomeus H, Decuyper M, Elsherif A, de Jonge A, Kooistra L. Thermal infrared remote sensing of stress responses in forest environments: a review of developments, challenges, and opportunities. Curr for Rep, 2024, 10(1): 56-76

[50]	Song Y, Imanishi J, Hashimoto H, Morimura A, Morimoto Y, Kitada K. Spectral correction for the effect of crown shape at the single-tree level: an approach using a lidar-derived digital surface model for broad-leaved canopy. IEEE Trans Geosci Remote Sens, 2013, 51(2): 755-764

[51]	Sprintsin M. Combining land surface temperature and shortwave infrared reflectance for early detection of Mountain Pine Beetle infestations in western Canada. J Appl Remote Sens, 2011, 5(1 053566

[52]	Stych P, Jerabkova B, Lastovicka J, Riedl M, Paluba D. A comparison of WorldView-2 and Landsat 8 images for the classification of forests affected by bark beetle outbreaks using a support vector machine and a neural network: A case study in the Sumava Mountains. Geosciences Basel, 2019, 9(9): 396

[53]	Stych P, Lastovicka J, Hladky R, Paluba D. Evaluation of the influence of disturbances on forest vegetation using the time series of Landsat data: A comparison study of the Low Tatras and Sumava National Parks. ISPRS Int J Geo-Inf, 2019, 8(2): 71

[54]	Trubin A, Kozhoridze G, Zabihi K, Modlinger R, Singh VV, Surový P, Jakuš R. Detection of green attack and bark beetle susceptibility in Norway spruce: Utilizing PlanetScope multispectral imagery for tri-stage spectral separability analysis. For Ecol Manage, 2024, 560 121838

[55]	Vošvrdová N, Johansson A, Turčáni M, Jakuš R, Tyšer D, Schlyter F, Modlinger R. Dogs trained to recognise a bark beetle pheromone locate recently attacked spruces better than human experts. For Ecol Manage, 2023, 528 120626

[56]	Wang JX, Meng SW, Lin QN, Liu YY, Huang HG. Detection of Yunnan pine shoot beetle stress using UAV-based thermal imagery and LiDAR. Appl Sci Basel, 2022, 12(9 4372

[57]	Wang JX, Lin QN, Meng SW, Huang HG, Liu YY. Individual tree-level monitoring of pest infestation combining airborne thermal imagery and Light Detection and Ranging. Forests Basel, 2024, 15(1 112

[58]	Washaya P, Modlinger R, Tyšer D, Hlásny T. Patterns and impacts of an unprecedented outbreak of bark beetles in Central Europe: A glimpse into the future?. For Ecosyst, 2024, 11 100243

[59]	Woods HA, Saudreau M, Pincebourde S. Structure is more important than physiology for estimating intracanopy distributions of leaf temperatures. Ecol Evol, 2018, 8(10): 5206-5218

[60]	Zakrzewska A, Kopeć D. Remote sensing of bark beetle damage in Norway spruce individual tree canopies using thermal infrared and airborne laser scanning data fusion. For Ecosyst, 2022, 9 100068