Phalaenopsis is the major flower crop for export in Taiwan. Nobile-type dendrobium, which has various flower shapes and colors, is regarded as a potential flower crop for the international market. The ratio of C and N concentration in plant tissue is called C/N ratio. High C/N ratio is considered to promote reproductive growth and low C/N may boost vegetative growth or even inhibit flowering. However, literatures on how C/N ratio affects the flowering of orchids are limited. In this research, nobile-type dendrobium (Dendrobium spp.) and phalaenopsis (Phalaenopsis spp.) were used to investigate the changes in carbon (C) and nitrogen (N) of tissues during various development stages. The effect of carbon and nitrogen ratio (C/N) on flowering of nobile-type dendrobium and phalaenopsis was also studied. The hybrid dendrobium (Den. Lai’s Yukisakura) had the minimum C concentration of 46.2% at flower bud visible stage, but there was no significant difference of C concentration among other stages (47.1%-47.7%). The N concentration decreased from 1.03% to 0.88% during forcing then went up to 1.13% at flower bud visible stage. The C/N ratio, which was affected by the N concentration, increased from 47.2 to 54.6 during forcing and went down to 41.6 at flower bud visible stage. Nobile-type dendrobium mainly accumulated sucrose and starch during forcing for subsequent inflorescence development. The second experiment was to analysis leaf C and N concentrations of easy-flowering nobile-type dendrobium cultivars (Den. Snow Princess × Den. Lucky Angel) and not-easy-to-flower nobile-type dendrobium cultivars (Den. Oriental Smile × Den. Stardust ‘FireBird’). Based on the length of plant height, plants of each two nobile-type dendrobium cultivars was divided into four grades. Leaf C/N ratio of easy-flowering nobile-type dendrobium cultivars is higher than not-easy-to-flower nobile-type dendrobium cultivar. Leaf C/N ratio of not-easy-to-flower nobile-type dendrobium cultivar decreased as the grade decreased. No correlation between the leaf C/N ratio and days to axillary buds visible in easy-flowering nobile-type dendrobium cultivar was found. However, there was a negative correlation between the leaf C/N ratio and days to axillary buds visible (r = - 0.64**) in not-easy-to -flower nobile-type dendrobium cultivar. In addition, there was a positive correlation of the C/N ratio with number of axillary buds and number of flowers in both cultivars. The higher leaf C/N ratio, the greater number of axillary buds and flowers existed in the plant. These results indicate that the leaf C/N ratio can be used as an indicator for the number of axillary buds and the number of flowers in nobile-type dendrobium, and low leaf C/N ratio may lead to the decrease in flower quality. The third experiment was giving nobile-type dendrobium two months of short-term nitrogen fertilizer treatment before forcing, with nitrogen fertilizer concentration of 0, 10, 100, or 200 ppm. From the start of fertilization to the time of flower opening, N concentration of plants increased as nitrogen fertilizer concentration increased. The C/N ratio, which was affected by the N concentration, decreased as nitrogen fertilizer concentration increased. The dendrobium which were treated with 200 ppm nitrogen fertilizer had the lowest number but the heaviest dry weight of axillary buds, which were 3.1 and 0.04 g, respectively. Axillary buds may later develop into flower buds or keikis. Besides, nobile-type dendrobium had the least number of flowers (2.4) but the most number of keikis (2.1) after treated with 200 ppm nitrogen fertilizer. Nobile-type dendrobium under 10 ppm nitrogen treatment had the most number of node bearing inflorescence (3.1-3.4) and flowers (7.6), and flowered earlier than other treatments. To sum up, giving nobile-type dendrobium two months of 10 ppm nitrogen fertilizer treatment before forcing can make better flowering quality of nobile-type dendrobium. Small, purple-flowerd phalaenopsis (Phal. Sogo Lotte ‘F2510’) with different plant maturity were placed in phytotron at controlled day/night temperature of 25/20℃ for cool-temperature forcing. The flower-stalk emergence rate of 2 months after deflasking plants was only 42%, which indicates that the plants were not completely out of the juvenile phase. Two months after deflasking, plants had higher N concentration (1.94%), lower C/N ratio (21.7), the longest days to spiking (50.2), and minimum number of flowers (4.6) compared with plants deflasked for 3 to 5 months. No correlation of the C/N ratio with days to spiking, days to first visible bud, days to first flower open and days to 90% flower open in large, white-flowered phalaenopsis (Phal. Sogo Yukidian ‘V3’) was discovered. However, there was a positive correlation between the C/N ratio and inflorescence length (r = 0.40**), flower-stalk diameter (r = 0.36*), first flower diameter (r = 0.45*) and number of flowers (r = 0.41**). Thus, the C/N ratio has the potential for becoming flowering quality index in phalaenopsis.