It is hot and humid in the long hot season in Taiwan. Heat stress is very common in hot season and is a problem must be solved first in dairy industry. Heat stress will increase rectal temperature and respiration rate. Panting is a typical behavior in heat stressed goats. Dry matter intake (DMI) decreases and water consumption increases during heat stress. Heat stress also decreases lactation performance. Milk production, milk fat, milk protein, and milk solids-non-fat (SNF) decline during heat stress. There are three methods to reducing the effects of heat stress: selecting heat tolerant goat breed/strain, physical modification of environment such as water sprinkling and mist cooling, and nutritional management to counteract the declined intake during hot season. There are two parts of this experiment. First part was at NTU farm. Twelve Alpine dairy goats were assigned according to milk yields and parities into two different two treatment groups (control diet and nutrition-modified diet). During the experiment period, we recorded temperature and relative humidity to calculate THI. Refusals, milk samples, and respiration rate of goats were also collected and measured. Then we monitored changes in compositions of nutrient intake and milk compositions. The second part of the experiment was conducted at three commercial farms in Chiayi and Tainan. The monitored items were the same as first part of experiment. The nutrition modification included decreasing forage to concentrate ratio, increase crude protein density and energy density. About a month after feeding nutrient-modified diet, we collected all the items again to compare the differences before and after diet modification. In the first part, DMI increased 36% and milk production increased 11.7% significantly in nutrient-modified group with water mist and fan cooling. Milk protein and SNF increased a little. When the mist cooling turned off, DMI and milk production decreased immediately. Besides, in control group, DMI and respiration rate were unstable. This implicated the importance of evaporative cooling. However, respiration rate was not significantly different with mist cooling or not. It was not effective as we expected. So, it still needs more experiments to find out the best settings for better cooling. In the second part, the forage: concentrate ratio in A farm in 2016 was lowered (76:24 vs 65:35), and the protein ratio increased (10.51% vs 15.11%) by adding rumen undegradable protein (RUP). As a result, DMI increased and milk production increased 20%. Milk protein and SNF also increased. The concentrate ratio in B farm in 2017 was 60%. We increased protein ratio and RUP of the diet (14.16% vs 17.45%) and we found that DMI and milk production increased. Milk protein and SNF increased a little. We increased protein ratio and RUP in A farm in 2017 and found that milk production increased 8% with no change in milk contents. In C farm in 2017, we changed high quality alfalfa forage to raise dietary protein content (12.36% vs 16.45%). Milk yield was increased by 3.6% with higher milk protein and SNF. In conclusion, by increasing concentrate: forage ratio, protein ratio, and RUP in diet, there were positive effects on lactation performance such as milk yields, milk protein, and SNF in hot season. It could be a useful principle in hot season for nutritional modification for dairy goats. Evaporative cooling as water mist can help to decrease the negative effects of heat stress, but it needs more experiments to find out water mist settings for better cooling effect.