Litterfall plays a crucial role in the carbon and nutrient cycles of forest ecosystems. The amount of litterfall governs the amount of carbon and nutrient to be returned in a forest ecosystem. However, when it comes to quantifying forest litterfall, collection of canopy characteristic parameters for existing litterfall models is usually time-consuming and labor-intensive. Recent studies indicated that, in metabolic scaling theory, there is a common relationship between terrestrial plant production and biomass; a major part of the production is contributed by litterfall. Therefore, there could be a relationship between litterfall and biomass, which could facilitate large spatial scale estimation of litterfall since biomass may be assessed using remote sensing. To investigate this relationship, we acquired monthly litterfall of a hinoki (Chamaecyparis spp.) dominant montane forest in the northeastern Taiwan (23.98 N, 120.97 E) across the elevation range of 1267–2080 m a.s.l. Monthly litterfall data were recorded from fifteen 0.09 ha plots and each plot consisted from four randomly arranged 0.5 m2 litterfall traps. In addition, diameter at breast height of each live hinoki tree (n = 1,128) within all plots was measured and total biomass was derived using an in-situ species-specific allometry. Species-specific hinoki litterfall regression models were developed for two seasons (growing season: March–June, typhoon season: July–October) across a wide range of biomass density. We found that the relationship between biomass and litterfall might depend on the amount of total biomass. In both seasons, increase of litter production with increase of biomass density could be found when biomass is less than about 200 Mg ha-1, after that, inverse relationship appears. With the aid of high spatial resolution airborne light detection and ranging (lidar) data, we may be able to provide a spatial layer of hinoki biomass and map monthly litterfall over a vast region based on this biomass-litterfall relationship. At the end, the litterfall map were verified by three ground truth litterfall measurements with satisfactory results (R2 = 0.98, p < 0.05, RMSE = 23.12 Mg ha^-1 month^-1). Furthermore, the study could facilitate our understanding of the mechanism governing the litter production and improve future prediction of metabolic scaling theory on ecosystem function.