The analysis findings are further used in the monitoring and evaluation layer to examine forest health, biodiversity, carbon sequestration, and ecosystem services. “This information is also essential for the next phase of the system – forest management,” explains Maskeliūnas.
In practical applications, the researcher explains that by gathering data on environmental conditions such as temperature, humidity, and air quality from these sensors, the IoT system can assess forest health, monitor fire risks, and offer protection against diseases, pests, or illegal activities.
A smart monitoring system is not just sensors, according to Maskeliūnas, cameras already installed in the forest can also be used. “By analysing camera images and looking at, for example, browning needles, the IoT can detect the impact of insects on trees, identify disease through spots on leaves, and by encrypting sounds, it can indicate illegal logging,” he says.
It can also be adapted to predict changes in forest ecosystems and the spread of invasive species.
The goal – healthy, lush forest full of animals
With the aim of revolutionising forest management, the system uses new technologies to improve the efficiency, sustainability, and profitability of forest businesses, optimise resource use, reduce waste, and facilitate decision-making.
In addition, the Forest 4.0 model provides supply chain traceability management, allowing processes to be monitored at all stages, from the forest to the sawmill or even the final wood product.
Blockchain, a decentralised digital ledger technology that ensures transparency and data integrity, is the foundation of this functionality.
“The technology works without the authority and provides a transparent, secure, and unchangeable record of everything that happens to the forest and its production reducing illegal logging and ensuring sustainable practices,” adds the professor of KTU Faculty of Informatics (IF).
Despite these benefits, researchers are also facing some challenges in implementing Forest 4.0. These include high initial investment and an inert approach to innovation. “It is assumed that it is better to opt for expensive and complex solutions, while smaller and cheaper sensors are given less attention. We should be glad that a solution costing a few hundred euros is able to collect and send data by itself,” says Prof. Maskeliūnas.
Also, the use of decentralised blockchain technology requires a high level of trust from the users, however, the successful development of financial technology (Fintech) is helping to overcome these fears.
However, in other countries, such as Germany, such solutions have already gained more acceptance. This shows that Forest 4.0 has the potential to become a global standard and that Lithuania can serve as a role model for other countries in promoting responsible and sustainable forest management.
Speaking about the Forest 4.0 concept itself, Maskeliūnas says that smart forest management is about caring for the future of nature: “It is like the fourth industrial revolution in forestry, with the goal of a non-flammable, lush forest full of animals”.
The article Digital transformation of the future of forestry: an exploration of key concepts in the principles behind Forest 4.0 is published in Frontiers in Forests and Global Change and can be found here.
