type A: the 10th, 50th, and 90th percentile Test Reference Years (pTRYs) and Design Summer Years (pDSY) for the control year (i.e. 1961 - 1990)  
?	Description: pTRY is the most typical year representing 30-year long weather while pDSY is the fourth hottest year of 30-year long weather. pTRY is used for predicting year-round building energy performance while pDSY is used for assessing overheating risk. 
?	Reference: Eames, M., Kershaw, T. and Coley, D., 2011. On the creation of future probabilistic design weather years from UKCP09. Building Services Engineering Research and Technology, 32(2), pp.127-142.
type B: the 10th, 50th, and 90th percentile Test Reference Years (pTRYs) and Design Summer Years (pDSY) for the 2080s (i.e. 2070 - 2099) 
?	Description: pTRY is the most typical year representing 30-year long weather while pDSY is the fourth hottest year of 30-year long weather. pTRY is used for predicting year-round building energy performance while DSY is used for assessing overheating risk. 
?	Reference: Eames, M., Kershaw, T. and Coley, D., 2011. On the creation of future probabilistic design weather years from UKCP09. Building Services Engineering Research and Technology, 32(2), pp.127-142.
type C: the 10th, 50th, and 90th percentile TRY-max and TRY-min for the control year (i.e. 1961 - 1990) 
?	Description: pTRY-max and pTRY-min contain realistic and typical maximum and minimum temperature respectively. pTRY-max and pTRY-min could be used for looking at spatial variation in peak heating and cooling load across the UK. 
?	Reference:   Liu, C., Chung, W., Cecinati, F., Natarajan, S., & Coley, D. (2019). Current and future test reference years at a 5 km resolution. Building Services Engineering Research and Technology. https://doi.org/10.1177/0143624419880629
type D: the 10th, 50th, and 90th percentile TRY-max and TRY-min for the 2080s (i.e. 2070 - 2099) 
?	Description: pTRY-max and pTRY-min contain realistic and typical maximum and minimum temperature respectively. pTRY-max and pTRY-min could be used for looking at spatial variation in peak heating and cooling load across the UK. 
?	Reference:   Liu, C., Chung, W., Cecinati, F., Natarajan, S., & Coley, D. (2019). Current and future test reference years at a 5 km resolution. Building Services Engineering Research and Technology. https://doi.org/10.1177/0143624419880629
type E:  the 10th, 50th, and 90th percentile Hot Summer Years (pHSY) for the control year (i.e. 1961 - 1990) 
?	Description: pHSY is selected based on the weighted cooling degree hours. pHSY is suitable for evaluating severity of overheating risk. 
?	Reference: Liu, C., Kershaw, T., Eames, M.E. and Coley, D.A., 2016. Future probabilistic hot summer years for overheating risk assessments. Building and Environment, 105, pp.56-68.
type F:  the 10th, 50th, and 90th percentile Hot Summer Years (pHSY)  for the 2080s (i.e. 2070 - 2099) 
?	Description: pHSY is selected based on the weighted cooling degree hours. pHSY is suitable for evaluating severity of overheating risk. 
?	Reference: Liu, C., Kershaw, T., Eames, M.E. and Coley, D.A., 2016. Future probabilistic hot summer years for overheating risk assessments. Building and Environment, 105, pp.56-68.
type G:  Super Synthetic Heat Wave for the control year (i.e. 1961 - 1990) 
?	Description: SSHW contains heatwaves with different intensity and duration. 
?	Reference: The references for type G and H will be published in 2020. 
type H:  Super Synthetic Heat Wave for the 2080s (i.e. 2070 - 2099) 
?	Description: SSHW contains heatwaves with different intensity and duration. 
?	Reference: The references for type G and H will be published in 2020. 
type I:  All the above weather types: pTRY, pDSY, pTRY-max, pTRY-min, pHSY and SSHW for the 2020s (2010 - 2039)