Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning

Gilberth Temba; Ernest Mauya

doi:10.33904/ejfe.1364534

EN

Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning

Abstract

Mechanized timber harvesting involves various activities including road planning, and selection of harvesting systems and machineries. The emergence of geospatial technology (GSPT) i.e., geographical information system (GIS) and remote sensing in the recent decades, has been considered as the best tools to facilitate timber harvesting planning in plantation forests. GSPT provide accurate stand information enabling better decision-making and optimizing forest operations. This study was conducted at Sao hill Forest Plantation (SHFP) in Tanzania, with the objective of determining relative efficiency (RE) between geospatial approach (GSPA) and conventional approach (CA) on planning mechanized timber harvesting. 120 grapple skidders (GS) in 30 sample plots within different elevation terrain ranges were studied with time study observations in both approaches. Productivity and costs under the two approaches were estimated and modelled using generalized linear model (GLM) approach. To obtain large scale estimates of productivity and costs, Inverse Distance Weighted (IDW) interpolation approach was used. The results showed that, GSPA demonstrated higher productivity and lower unit skidding costs (i.e., 71.1 m3/hr and 2.121 USD/m3) compared to CA (i.e., 67.5 m3/hr and 2.914 USD/m3) respectively. Skidding distance and slope (p-value < 0.05) were significant predictors of the GS performance in both approaches. The pseudo R2 ranging from 58.1% to 64.3% under CA, and from 62.9% to 60.8% under GSPA. Likewise, relative root mean square error (RMSEr) for the models under CA ranged from 49.3% to 50.4% and 33.4% to 35.2% under GSPA. Generally, the results showed that, models under GSPA have better fits and accuracy, compared to CA. Furthermore, the GSPA provided a raster representation of productivity and costs over the entire study area. Moreover, computed RE values (i.e., 1.18 and 6.17) indicated that parameter estimates for the GS productivity and costs were more precise in geospatial models (GSPM) compared to conventional models (CM). These findings highlight the potential of GSPT for an efficient large scale timber harvesting planning, by considering terrain constraints.

Keywords

Convectional, Geospatial, Grapple skidder, Productivity, Costs, Relative efficiency

Project Number

NONE

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Details

Primary Language

English

Subjects

Forest Products Transport and Evaluation Information

Journal Section

Research Article

Authors

Gilberth Temba ^*
0009-0006-8296-0882
Tanzania

Ernest Mauya This is me
0000-0003-3998-2542
Tanzania

Early Pub Date

March 16, 2024

Publication Date

June 27, 2024

Submission Date

September 22, 2023

Acceptance Date

December 12, 2023

Published in Issue

Year 2024 Volume: 10 Number: 1

DOI

https://doi.org/10.33904/ejfe.1364534

IZ

https://izlik.org/JA78DF85NK

APA

Temba, G., & Mauya, E. (2024). Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning. European Journal of Forest Engineering, 10(1), 1-14. https://doi.org/10.33904/ejfe.1364534

AMA

1.Temba G, Mauya E. Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning. Eur J Forest Eng. 2024;10(1):1-14. doi:10.33904/ejfe.1364534

Chicago

Temba, Gilberth, and Ernest Mauya. 2024. “Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning”. European Journal of Forest Engineering 10 (1): 1-14. https://doi.org/10.33904/ejfe.1364534.

EndNote

Temba G, Mauya E (June 1, 2024) Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning. European Journal of Forest Engineering 10 1 1–14.

IEEE

[1]G. Temba and E. Mauya, “Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning”, Eur J Forest Eng, vol. 10, no. 1, pp. 1–14, June 2024, doi: 10.33904/ejfe.1364534.

ISNAD

Temba, Gilberth - Mauya, Ernest. “Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning”. European Journal of Forest Engineering 10/1 (June 1, 2024): 1-14. https://doi.org/10.33904/ejfe.1364534.

JAMA

1.Temba G, Mauya E. Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning. Eur J Forest Eng. 2024;10:1–14.

MLA

Temba, Gilberth, and Ernest Mauya. “Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning”. European Journal of Forest Engineering, vol. 10, no. 1, June 2024, pp. 1-14, doi:10.33904/ejfe.1364534.

Vancouver

1.Gilberth Temba, Ernest Mauya. Potential of Geospatial Technologies in Mechanized Timber Harvesting Planning. Eur J Forest Eng. 2024 Jun. 1;10(1):1-14. doi:10.33904/ejfe.1364534

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