Globally, forests cover 31% of the

Globally, forests cover 31% of the total land area [1] and account for 77% of all terrestrial
above ground carbon [2,3]. Loss of forest carbon through deforestation and degradation is recognised
as a key driver of human-induced climate change [4,5]. Forest-related land-use
changes can also have deleterious effects on biodiversity richness, water dynamics and other
ecosystem services [6,7]. Hence, to enable sustainable management of forest resources, a common
challenge is to quantify spatial and temporal patterns of forest cover [8–10].
Recent research has focused on large-scale mapping of forest cover and change detection on
continental [11–13] and global scales [14–16], and in deforestation sensitive regions [17–19].
Data from these studies can provide valuable information on climate regulation, carbon storage
and socio-economic trends [20,21]. Advances in Earth Observation (EO) technologies are
likely to improve such extensive geographic estimates of forest cover and associated parameters
(such as forest biomass) over the coming years [22,23]. However, accurate estimation of forest
cover on a national level is also required to meet international reporting requirements and
assist country specific sustainable forest management targets. For example, under the United
Nations Framework Convention on Climate Change (UNFCCC) and Kyoto Protocol, Parties
are required to submit annual inventories of forest land-use area and associated changes
[24,25]. The monitoring of spatial and temporal changes in the distribution of forests on a local
scale can also be a key component of biodiversity/ecosystem services management [26–28].