Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
Table 1: Descriptive statistics of datasets of milk yield traits of crossbred cattle
Table 2: Descriptive statistics of datasets of meteorological variables
Table 3: Analysis of variance for meteorological variables
Table 4: Linear regression of various meteorological variables on year
Table 5: Linear regression of daily milk yield (DMY) and Peak Yield (PY) on different meteorological variables in crossbred dairy cattle
Table 6: Regression of 305 days lactation milk yield (305_DMY) and total lactation milk yield (TLMY) on different meteorological variables in crossbred dairy cattle
Table 7: Regression of lactation length (LL) and dry period (DP) on different meteorological variables in crossbred dairy cattle
Table 8: Regression of days to attend peak yield (DPY) along with standard errors on different meteorological variables in crossbred dairy cattle
Figure 1: Influence of monthly adjusted temperature and humidity index (ATHI) on 305 days lactation milk yield over months of calving in crossbred dairy cattle
Figure 2: Influence of monthly adjusted temperature and humidity index (ATHI) on lactation length over months of calving in crossbred dairy cattle
Figure 3: Influence of monthly adjusted temperature and humidity index (ATHI) on peak yield over months of calving in crossbred dairy cattle
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