get_building_air_conditioning ----------------------------- path: ``inputs/building-properties/air_conditioning_systems.dbf`` The following file is used by these scripts: ``demand`` .. csv-table:: :header: "Variable", "Description" ``cool_ends``, "End of the cooling season - use 00|00 when there is none" ``cool_starts``, "Start of the cooling season - use 00|00 when there is none" ``heat_ends``, "End of the heating season - use 00|00 when there is none" ``heat_starts``, "Start of the heating season - use 00|00 when there is none" ``Name``, "Unique building ID. It must start with a letter." ``type_cs``, "Type of cooling HVAC assembly (relates to ""code"" in HVAC assemblies)" ``type_ctrl``, "Type of heating and cooling control HVAC assembly (relates to ""code"" in HVAC assemblies)" ``type_dhw``, "Type of hot water HVAC assembly (relates to ""code"" in HVAC assemblies)" ``type_hs``, "Type of heating HVAC assembly (relates to ""code"" in HVAC assemblies)" ``type_vent``, "Type of ventilation HVAC assembly (relates to ""code"" in HVAC assemblies)" get_building_architecture ------------------------- path: ``inputs/building-properties/architecture.dbf`` The following file is used by these scripts: ``demand``, ``emissions``, ``radiation``, ``schedule_maker`` .. csv-table:: :header: "Variable", "Description" ``Name``, "Unique building ID. It must start with a letter." ``Es``, "Fraction of gross floor area with electrical demands." ``Hs``, "Fraction of gross floor area air-conditioned." ``Ns``, "Fraction of net gross floor area." ``occupied_bg``, "True if the basement is occupied/conditioned, False if not." ``type_base``, "Basement floor construction assembly (relates to ""code"" in ENVELOPE assemblies)" ``type_cons``, "Type of construction assembly (relates to ""code"" in ENVELOPE assemblies)" ``type_floor``, "Internal floor construction assembly (relates to ""code"" in ENVELOPE assemblies)" ``type_leak``, "Tightness level assembly (relates to ""code"" in ENVELOPE assemblies)" ``type_part``, "Internal partitions construction assembly (relates to ""code"" in ENVELOPE assemblies)" ``type_roof``, "Roof construction assembly (relates to ""code"" in ENVELOPE assemblies)" ``type_shade``, "Shading system assembly (relates to ""code"" in ENVELOPE assemblies)" ``type_wall``, "External wall construction assembly (relates to ""code"" in ENVELOPE assemblies)" ``type_win``, "Window assembly (relates to ""code"" in ENVELOPE assemblies)" ``void_deck``, "Number of floors (from the ground up) with an open envelope (default = 0, should be lower than floors_ag.)" ``wwr_east``, "Window to wall ratio in in facades facing east" ``wwr_north``, "Window to wall ratio in in facades facing north" ``wwr_south``, "Window to wall ratio in in facades facing south" ``wwr_west``, "Window to wall ratio in in facades facing west" get_building_comfort -------------------- path: ``inputs/building-properties/indoor_comfort.dbf`` The following file is used by these scripts: ``demand``, ``schedule_maker`` .. csv-table:: :header: "Variable", "Description" ``Name``, "Unique building ID. It must start with a letter." ``RH_max_pc``, "Upper bound of relative humidity" ``RH_min_pc``, "Lower_bound of relative humidity" ``Tcs_set_C``, "Setpoint temperature for cooling system" ``Tcs_setb_C``, "Setback point of temperature for cooling system" ``Ths_set_C``, "Setpoint temperature for heating system" ``Ths_setb_C``, "Setback point of temperature for heating system" ``Ve_lsp``, "Minimum outdoor air ventilation rate per person for Air Quality" get_building_internal --------------------- path: ``inputs/building-properties/internal_loads.dbf`` The following file is used by these scripts: ``demand``, ``schedule_maker`` .. csv-table:: :header: "Variable", "Description" ``Ea_Wm2``, "Peak specific electrical load due to computers and devices" ``Ed_Wm2``, "Peak specific electrical load due to servers/data centres" ``El_Wm2``, "Peak specific electrical load due to artificial lighting" ``Epro_Wm2``, "Peak specific electrical load due to industrial processes" ``Ev_kWveh``, "Peak capacity of electric battery per vehicle" ``Name``, "Unique building ID. It must start with a letter." ``Occ_m2p``, "Occupancy density" ``Qcpro_Wm2``, "Peak specific process cooling load" ``Qcre_Wm2``, "Peak specific cooling load due to refrigeration (cooling rooms)" ``Qhpro_Wm2``, "Peak specific process heating load" ``Qs_Wp``, "Peak sensible heat load of people" ``Vw_ldp``, "Peak specific fresh water consumption (includes cold and hot water)" ``Vww_ldp``, "Peak specific daily hot water consumption" ``X_ghp``, "Moisture released by occupancy at peak conditions" get_building_supply ------------------- path: ``inputs/building-properties/supply_systems.dbf`` The following file is used by these scripts: ``decentralized``, ``demand``, ``emissions``, ``system_costs`` .. csv-table:: :header: "Variable", "Description" ``Name``, "Unique building ID. It must start with a letter." ``type_cs``, "Type of cooling supply assembly (refers to ""code"" in SUPPLY assemblies)" ``type_dhw``, "Type of hot water supply assembly (refers to ""code"" in SUPPLY assemblies)" ``type_el``, "Type of electrical supply assembly (refers to ""code"" in SUPPLY assemblies)" ``type_hs``, "Type of heating supply assembly (refers to ""code"" in SUPPLY assemblies)" get_building_weekly_schedules ----------------------------- path: ``inputs/building-properties/schedules/B001.csv`` The following file is used by these scripts: ``demand``, ``schedule_maker`` .. csv-table:: :header: "Variable", "Description" ``METADATA``, "TODO" ``MONTHLY_MULTIPLIER``, "Monthly probabilities of occupancy throughout the year" get_database_air_conditioning_systems ------------------------------------- path: ``inputs/technology/assemblies/HVAC.xlsx`` The following file is used by these scripts: ``demand`` .. csv-table:: Worksheet: ``CONTROLLER`` :header: "Variable", "Description" ``code``, Unique ID of the controller ``Description``, Describes the type of controller ``dT_Qcs``, correction temperature of emission losses due to control system of cooling ``dT_Qhs``, correction temperature of emission losses due to control system of heating .. csv-table:: Worksheet: ``COOLING`` :header: "Variable", "Description" ``class_cs``, Type or class of the cooling system ``code``, Unique ID of the heating system ``convection_cs``, Convective part of the power of the heating system in relation to the total power ``Description``, Describes the type of cooling system ``dTcs0_ahu_C``, Nominal temperature increase on the water side of the air-handling units ``dTcs0_aru_C``, Nominal temperature increase on the water side of the air-recirculation units ``dTcs0_scu_C``, Nominal temperature increase on the water side of the sensible cooling units ``dTcs_C``, Set-point correction for space emission systems ``Qcsmax_Wm2``, Maximum heat flow permitted by cooling system per m2 gross floor area ``Tc_sup_air_ahu_C``, Supply air temperature of the air-handling units ``Tc_sup_air_aru_C``, Supply air temperature of the air-recirculation units ``Tscs0_ahu_C``, Nominal supply temperature of the water side of the air-handling units ``Tscs0_aru_C``, Nominal supply temperature of the water side of the air-recirculation units ``Tscs0_scu_C``, Nominal supply temperature of the water side of the sensible cooling units .. csv-table:: Worksheet: ``HEATING`` :header: "Variable", "Description" ``class_hs``, Type or class of the heating system ``code``, Unique ID of the heating system ``convection_hs``, Convective part of the power of the heating system in relation to the total power ``Description``, Description ``dThs0_ahu_C``, Nominal temperature increase on the water side of the air-handling units ``dThs0_aru_C``, Nominal temperature increase on the water side of the air-recirculation units ``dThs0_shu_C``, Nominal temperature increase on the water side of the sensible heating units ``dThs_C``, correction temperature of emission losses due to type of heating system ``Qhsmax_Wm2``, Maximum heat flow permitted by heating system per m2 gross floor area ``Th_sup_air_ahu_C``, Supply air temperature of the air-recirculation units ``Th_sup_air_aru_C``, Supply air temperature of the air-handling units ``Tshs0_ahu_C``, Nominal supply temperature of the water side of the air-handling units ``Tshs0_aru_C``, Nominal supply temperature of the water side of the air-recirculation units ``Tshs0_shu_C``, Nominal supply temperature of the water side of the sensible heating units .. csv-table:: Worksheet: ``HOT_WATER`` :header: "Variable", "Description" ``code``, Unique ID of the hot water supply system ``Description``, Describes the Type of hot water supply system ``Qwwmax_Wm2``, Maximum heat flow permitted by hot water system per m2 gross floor area ``Tsww0_C``, Typical supply water temperature. .. csv-table:: Worksheet: ``VENTILATION`` :header: "Variable", "Description" ``code``, Unique ID of the type of ventilation ``Description``, Describes the Type of ventilation ``ECONOMIZER``, Boolean, economizer on ``HEAT_REC``, Boolean, heat recovery on ``MECH_VENT``, Boolean, mechanical ventilation on ``NIGHT_FLSH``, Boolean, night flush on ``WIN_VENT``, Boolean, window ventilation on get_database_construction_standards ----------------------------------- path: ``inputs/technology/archetypes/CONSTRUCTION_STANDARDS.xlsx`` The following file is used by these scripts: ``archetypes_mapper`` .. csv-table:: Worksheet: ``ENVELOPE_ASSEMBLIES`` :header: "Variable", "Description" ``Es``, Fraction of gross floor area with electrical demands. ``Hs``, Fraction of above ground gross floor area air-conditioned. ``Ns``, Fraction of net gross floor area. ``occupied_bg``, Fraction of below ground gross floor area air-conditioned ``STANDARD``, Unique ID of Construction Standard ``type_base``, Basement floor construction assembly (relates to "code" in ENVELOPE assemblies) ``type_cons``, Type of construction assembly (relates to "code" in ENVELOPE assemblies) ``type_floor``, Internal floor construction assembly (relates to "code" in ENVELOPE assemblies) ``type_leak``, Tightness level assembly (relates to "code" in ENVELOPE assemblies) ``type_part``, Internal partitions construction assembly (relates to "code" in ENVELOPE assemblies) ``type_roof``, Roof construction assembly (relates to "code" in ENVELOPE assemblies) ``type_shade``, Shading system assembly (relates to "code" in ENVELOPE assemblies) ``type_wall``, External wall construction assembly (relates to "code" in ENVELOPE assemblies) ``type_win``, Window assembly (relates to "code" in ENVELOPE assemblies) ``void_deck``, Number of floors (from the ground up) with an open envelope (default = 0) ``wwr_east``, Window to wall ratio in in facades facing east ``wwr_north``, Window to wall ratio in in facades facing north ``wwr_south``, Window to wall ratio in in facades facing south ``wwr_west``, Window to wall ratio in in facades facing west .. csv-table:: Worksheet: ``HVAC_ASSEMBLIES`` :header: "Variable", "Description" ``cool_ends``, End of the cooling season - use 00|00 when there is none ``cool_starts``, Start of the cooling season - use 00|00 when there is none ``heat_ends``, End of the heating season - use 00|00 when there is none ``heat_starts``, Start of the heating season - use 00|00 when there is none ``STANDARD``, Unique ID of Construction Standard ``type_cs``, Type of cooling HVAC assembly (relates to "code" in HVAC assemblies) ``type_ctrl``, Type of heating and cooling control HVAC assembly (relates to "code" in HVAC assemblies) ``type_dhw``, Type of hot water HVAC assembly (relates to "code" in HVAC assemblies) ``type_hs``, Type of heating HVAC assembly (relates to "code" in HVAC assemblies) ``type_vent``, Type of ventilation HVAC assembly (relates to "code" in HVAC assemblies) .. csv-table:: Worksheet: ``STANDARD_DEFINITION`` :header: "Variable", "Description" ``Description``, Description of the construction standard ``STANDARD``, Unique ID of Construction Standard ``YEAR_END``, Upper limit of year interval where the building properties apply ``YEAR_START``, Lower limit of year interval where the building properties apply .. csv-table:: Worksheet: ``SUPPLY_ASSEMBLIES`` :header: "Variable", "Description" ``STANDARD``, Unique ID of Construction Standard ``type_cs``, Type of cooling supply assembly (refers to "code" in SUPPLY assemblies) ``type_dhw``, Type of hot water supply assembly (refers to "code" in SUPPLY assemblies) ``type_el``, Type of electrical supply assembly (refers to "code" in SUPPLY assemblies) ``type_hs``, Type of heating supply assembly (refers to "code" in SUPPLY assemblies) get_database_conversion_systems ------------------------------- path: ``inputs/technology/components/CONVERSION.xlsx`` The following file is used by these scripts: ``decentralized``, ``optimization``, ``photovoltaic``, ``photovoltaic_thermal``, ``solar_collector`` .. csv-table:: Worksheet: ``Absorption_chiller`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``a_e``, parameter in the characteristic equations to calculate the evaporator side ``a_g``, parameter in the characteristic equations to calculate the generator side ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``Description``, Describes the Type of Absorption Chiller ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``e_e``, parameter in the characteristic equations to calculate the evaporator side ``e_g``, parameter in the characteristic equations to calculate the generator side ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``m_cw``, external flow rate of cooling water at the condenser and absorber ``m_hw``, external flow rate of hot water at the generator ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``r_e``, parameter in the characteristic equations to calculate the evaporator side ``r_g``, parameter in the characteristic equations to calculate the generator side ``s_e``, parameter in the characteristic equations to calculate the evaporator side ``s_g``, parameter in the characteristic equations to calculate the generator side ``type``, type of absorption chiller ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``BH`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``Description``, Describes the type of borehole heat exchanger ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``Boiler`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``Description``, Describes the type of boiler ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``CCGT`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``Description``, Describes the type of combined-cycle gas turbine ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``Chiller`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``Description``, Describes the source of the benchmark standards. ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``CT`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``Description``, Describes the type of cooling tower ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``FC`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``Description``, Describes the type of fuel cell ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``Furnace`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``Description``, Describes the type of furnace ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``HEX`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``a_p``, parameter in the pressure loss function, f(x) = a_p + b_p*x^c_p + d_p*ln(x) + e_p*x*ln*(x), where x is the capacity mass flow rate [W/K] ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``b_p``, parameter in the pressure loss function, f(x) = a_p + b_p*x^c_p + d_p*ln(x) + e_p*x*ln*(x), where x is the capacity mass flow rate [W/K] ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``c_p``, parameter in the pressure loss function, f(x) = a_p + b_p*x^c_p + d_p*ln(x) + e_p*x*ln*(x), where x is the capacity mass flow rate [W/K] ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``d_p``, parameter in the pressure loss function, f(x) = a_p + b_p*x^c_p + d_p*ln(x) + e_p*x*ln*(x), where x is the capacity mass flow rate [W/K] ``Description``, Describes the type of heat exchanger ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x) ``e_p``, parameter in the pressure loss function, f(x) = a_p + b_p*x^c_p + d_p*ln(x) + e_p*x*ln*(x), where x is the capacity mass flow rate [W/K] ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``HP`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``Description``, Describes the source of the heat pump ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``Pump`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``Description``, Describes the source of the benchmark standards. ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``PV`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``Description``, Describes the source of the benchmark standards. ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``misc_losses``, losses from cabling, resistances etc... ``module_length_m``, length of the PV module ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``PV_a0``, parameters for air mass modifier, f(x) = a0 + a1*x + a2*x**2 + a3*x**3 + a4*x**4, where x is the relative air mass ``PV_a1``, parameters for air mass modifier, f(x) = a0 + a1*x + a2*x**2 + a3*x**3 + a4*x**4, where x is the relative air mass ``PV_a2``, parameters for air mass modifier, f(x) = a0 + a1*x + a2*x**2 + a3*x**3 + a4*x**4, where x is the relative air mass ``PV_a3``, parameters for air mass modifier, f(x) = a0 + a1*x + a2*x**2 + a3*x**3 + a4*x**4, where x is the relative air mass ``PV_a4``, parameters for air mass modifier, f(x) = a0 + a1*x + a2*x**2 + a3*x**3 + a4*x**4, where x is the relative air mass ``PV_Bref``, cell maximum power temperature coefficient ``PV_n``, nominal efficiency ``PV_noct``, nominal operating cell temperature ``PV_th``, glazing thickness ``type``, redundant ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``PVT`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``Description``, Describes the type of photovoltaic thermal technology ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``SC`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``aperture_area_ratio``, ratio of aperture area to panel area ``assumption``, items made by assumptions in this technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``c1``, collector heat loss coefficient at zero temperature difference and wind speed ``c2``, ctemperature difference dependency of the heat loss coefficient ``C_eff``, thermal capacity of module ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, identifier of each unique equipment ``Cp_fluid``, heat capacity of the heat transfer fluid ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``Description``, Describes the type of solar collector ``dP1``, pressure drop at zero flow rate ``dP2``, pressure drop at nominal flow rate (mB0) ``dP3``, pressure drop at maximum flow rate (mB_max) ``dP4``, pressure drop at minimum flow rate (mB_min) ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``IAM_d``, incident angle modifier for diffuse radiation ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of this technology ``mB0_r``, nominal flow rate per aperture area ``mB_max_r``, maximum flow rate per aperture area ``mB_min_r``, minimum flow rate per aperture area ``module_area_m2``, module area of a solar collector ``module_length_m``, length of a solar collector module ``n0``, zero loss efficiency at normal incidence ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``t_max``, maximum operating temperature ``type``, type of the solar collector (FP: flate-plate or ET: evacuated-tube) ``unit``, unit of the min/max capacity .. csv-table:: Worksheet: ``TES`` :header: "Variable", "Description" ``a``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``assumption``, items made by assumptions in this storage technology ``b``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``c``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``C_mat_%``, Working fluid replacement cost factor (fraction of the investment cost) ``cap_max``, maximum capacity ``cap_min``, minimum capacity ``code``, Unique code that identifies the thermal energy storage technology ``Cp_kJkgK``, heat capacity of working fluid ``currency``, currency-year information of the investment cost function, should be unified to USD ``d``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``Description``, Describes the thermal energy storage technology ``e``, parameter in the investment cost function, f(x) = a + b*x^c + d*ln(x) + e*x*ln*(x), where x is the capacity ``HL_kJkg``, Lantent heat of working fluid at phase change temperature ``IR_%``, interest rate charged on the loan for the capital cost ``LT_mat_yr``, lifetime of the working fluid of this storage technology ``LT_yr``, lifetime of this storage technology ``O&M_%``, operation and maintnance cost factor (fraction of the investment cost) ``Rho_T_PHCH_kgm3``, Density of working fluid at phase change temperature ``T_max_C``, Maximum temperature of working fluid at full discharge ``T_min_C``, Minimum temperature of working fluid at full charge ``T_PHCH_C``, Phase change temperature of working fluid ``type``, code that identifies whether the storage is used for heating or cooling (different properties of the transport media) ``unit``, unit which describes the minimum and maximum capacity get_database_distribution_systems --------------------------------- path: ``inputs/technology/components/DISTRIBUTION.xlsx`` The following file is used by these scripts: ``optimization``, ``thermal_network`` .. csv-table:: Worksheet: ``THERMAL_GRID`` :header: "Variable", "Description" ``code``, pipe ID from the manufacturer ``D_ext_m``, external pipe diameter tolerance for the nominal diameter (DN) ``D_ins_m``, maximum pipe diameter tolerance for the nominal diameter (DN) ``D_int_m``, internal pipe diameter tolerance for the nominal diameter (DN) ``Inv_USD2015perm``, Typical cost of investment for a given pipe diameter. ``pipe_DN``, Nominal pipe diameter ``Vdot_max_m3s``, maximum volumetric flow rate for the nominal diameter (DN) ``Vdot_min_m3s``, minimum volumetric flow rate for the nominal diameter (DN) get_database_envelope_systems ----------------------------- path: ``inputs/technology/assemblies/ENVELOPE.xlsx`` The following file is used by these scripts: ``demand``, ``radiation``, ``schedule_maker`` .. csv-table:: Worksheet: ``CONSTRUCTION`` :header: "Variable", "Description" ``Cm_Af``, Internal heat capacity per unit of air conditioned area. Defined according to ISO 13790. ``code``, Type of construction ``Description``, Describes the Type of construction .. csv-table:: Worksheet: ``FLOOR`` :header: "Variable", "Description" ``code``, Type of roof ``Description``, Describes the Type of roof ``GHG_FLOOR_kgCO2m2``, Embodied emissions per m2 of roof.(entire building life cycle) ``U_base``, Thermal transmittance of floor including linear losses (+10%). Defined according to ISO 13790. .. csv-table:: Worksheet: ``ROOF`` :header: "Variable", "Description" ``a_roof``, Solar absorption coefficient. Defined according to ISO 13790. ``code``, Type of roof ``Description``, Describes the Type of roof ``e_roof``, Emissivity of external surface. Defined according to ISO 13790. ``GHG_ROOF_kgCO2m2``, Embodied emissions per m2 of roof.(entire building life cycle) ``r_roof``, Reflectance in the Red spectrum. Defined according Radiance. (long-wave) ``U_roof``, Thermal transmittance of windows including linear losses (+10%). Defined according to ISO 13790. .. csv-table:: Worksheet: ``SHADING`` :header: "Variable", "Description" ``code``, Type of shading ``Description``, Describes the source of the benchmark standards. ``rf_sh``, Shading coefficient when shading device is active. Defined according to ISO 13790. .. csv-table:: Worksheet: ``TIGHTNESS`` :header: "Variable", "Description" ``code``, Type of tightness ``Description``, Describes the Type of tightness ``n50``, Air exchanges per hour at a pressure of 50 Pa. .. csv-table:: Worksheet: ``WALL`` :header: "Variable", "Description" ``a_wall``, Solar absorption coefficient. Defined according to ISO 13790. ``code``, Type of wall ``Description``, Describes the Type of wall ``e_wall``, Emissivity of external surface. Defined according to ISO 13790. ``GHG_WALL_kgCO2m2``, Embodied emissions per m2 of walls (entire building life cycle) ``r_wall``, Reflectance in the Red spectrum. Defined according Radiance. (long-wave) ``U_wall``, Thermal transmittance of windows including linear losses (+10%). Defined according to ISO 13790. .. csv-table:: Worksheet: ``WINDOW`` :header: "Variable", "Description" ``code``, Window type code to relate to other databases ``Description``, Describes the source of the benchmark standards. ``e_win``, Emissivity of external surface. Defined according to ISO 13790. ``F_F``, Window frame fraction coefficient. Defined according to ISO 13790. ``G_win``, Solar heat gain coefficient. Defined according to ISO 13790. ``GHG_WIN_kgCO2m2``, Embodied emissions per m2 of windows.(entire building life cycle) ``U_win``, Thermal transmittance of windows including linear losses (+10%). Defined according to ISO 13790. get_database_feedstocks ----------------------- path: ``inputs/technology/components/FEEDSTOCKS.xlsx`` The following file is used by these scripts: ``decentralized``, ``emissions``, ``system_costs``, ``optimization`` .. csv-table:: Worksheet: ``BIOGAS`` :header: "Variable", "Description" ``GHG_kgCO2MJ``, Non-renewable Green House Gas Emissions factor ``hour``, hour of a 24 hour day ``Opex_var_buy_USD2015kWh``, buying price ``Opex_var_sell_USD2015kWh``, selling price ``reference``, reference .. csv-table:: Worksheet: ``COAL`` :header: "Variable", "Description" ``GHG_kgCO2MJ``, Non-renewable Green House Gas Emissions factor ``hour``, hour of a 24 hour day ``Opex_var_buy_USD2015kWh``, buying price ``Opex_var_sell_USD2015kWh``, selling price ``reference``, reference .. csv-table:: Worksheet: ``DRYBIOMASS`` :header: "Variable", "Description" ``GHG_kgCO2MJ``, Non-renewable Green House Gas Emissions factor ``hour``, hour of a 24 hour day ``Opex_var_buy_USD2015kWh``, buying price ``Opex_var_sell_USD2015kWh``, selling price ``reference``, reference .. csv-table:: Worksheet: ``GRID`` :header: "Variable", "Description" ``GHG_kgCO2MJ``, Non-renewable Green House Gas Emissions factor ``hour``, hour of a 24 hour day ``Opex_var_buy_USD2015kWh``, buying price ``Opex_var_sell_USD2015kWh``, selling price ``reference``, reference .. csv-table:: Worksheet: ``NATURALGAS`` :header: "Variable", "Description" ``GHG_kgCO2MJ``, Non-renewable Green House Gas Emissions factor ``hour``, hour of a 24 hour day ``Opex_var_buy_USD2015kWh``, buying price ``Opex_var_sell_USD2015kWh``, selling price ``reference``, reference .. csv-table:: Worksheet: ``OIL`` :header: "Variable", "Description" ``GHG_kgCO2MJ``, Non-renewable Green House Gas Emissions factor ``hour``, hour of a 24 hour day ``Opex_var_buy_USD2015kWh``, buying price ``Opex_var_sell_USD2015kWh``, selling price ``reference``, reference .. csv-table:: Worksheet: ``SOLAR`` :header: "Variable", "Description" ``GHG_kgCO2MJ``, Non-renewable Green House Gas Emissions factor ``hour``, hour of a 24 hour day ``Opex_var_buy_USD2015kWh``, buying price ``Opex_var_sell_USD2015kWh``, selling price ``reference``, reference .. csv-table:: Worksheet: ``WETBIOMASS`` :header: "Variable", "Description" ``GHG_kgCO2MJ``, Non-renewable Green House Gas Emissions factor ``hour``, hour of a 24 hour day ``Opex_var_buy_USD2015kWh``, buying price ``Opex_var_sell_USD2015kWh``, selling price ``reference``, reference .. csv-table:: Worksheet: ``WOOD`` :header: "Variable", "Description" ``GHG_kgCO2MJ``, Non-renewable Green House Gas Emissions factor ``hour``, hour of a 24 hour day ``Opex_var_buy_USD2015kWh``, buying price ``Opex_var_sell_USD2015kWh``, selling price ``reference``, reference get_database_standard_schedules_use ----------------------------------- path: ``inputs/technology/archetypes/schedules/RESTAURANT.csv`` The following file is used by these scripts: ``archetypes_mapper`` .. csv-table:: Worksheet: ``APPLIANCES`` :header: "Variable", "Description" ``1``, ``2``, ``3``, ``4``, ``5``, ``6``, ``7``, ``8``, ``9``, ``10``, ``11``, ``12``, ``13``, ``14``, ``15``, ``16``, ``17``, ``18``, ``19``, ``20``, ``21``, ``22``, ``23``, ``24``, ``DAY``, Day of the week (weekday, saturday, or sunday) .. csv-table:: Worksheet: ``COOLING`` :header: "Variable", "Description" ``1``, ``2``, ``3``, ``4``, ``5``, ``6``, ``7``, ``8``, ``9``, ``10``, ``11``, ``12``, ``13``, ``14``, ``15``, ``16``, ``17``, ``18``, ``19``, ``20``, ``21``, ``22``, ``23``, ``24``, ``DAY``, Day of the week (weekday, saturday, or sunday) .. csv-table:: Worksheet: ``ELECTROMOBILITY`` :header: "Variable", "Description" ``1``, Average number of electric vehicles in this hour ``2``, Average number of electric vehicles in this hour ``3``, Average number of electric vehicles in this hour ``4``, Average number of electric vehicles in this hour ``5``, Average number of electric vehicles in this hour ``6``, Average number of electric vehicles in this hour ``7``, Average number of electric vehicles in this hour ``8``, Average number of electric vehicles in this hour ``9``, Average number of electric vehicles in this hour ``10``, Average number of electric vehicles in this hour ``11``, Average number of electric vehicles in this hour ``12``, Average number of electric vehicles in this hour ``13``, Average number of electric vehicles in this hour ``14``, Average number of electric vehicles in this hour ``15``, Average number of electric vehicles in this hour ``16``, Average number of electric vehicles in this hour ``17``, Average number of electric vehicles in this hour ``18``, Average number of electric vehicles in this hour ``19``, Average number of electric vehicles in this hour ``20``, Average number of electric vehicles in this hour ``21``, Average number of electric vehicles in this hour ``22``, Average number of electric vehicles in this hour ``23``, Average number of electric vehicles in this hour ``24``, Average number of electric vehicles in this hour ``DAY``, Day of the week (weekday, saturday, or sunday) .. csv-table:: Worksheet: ``HEATING`` :header: "Variable", "Description" ``1``, ``2``, ``3``, ``4``, ``5``, ``6``, ``7``, ``8``, ``9``, ``10``, ``11``, ``12``, ``13``, ``14``, ``15``, ``16``, ``17``, ``18``, ``19``, ``20``, ``21``, ``22``, ``23``, ``24``, ``DAY``, Day of the week (weekday, saturday, or sunday) .. csv-table:: Worksheet: ``LIGHTING`` :header: "Variable", "Description" ``1``, ``2``, ``3``, ``4``, ``5``, ``6``, ``7``, ``8``, ``9``, ``10``, ``11``, ``12``, ``13``, ``14``, ``15``, ``16``, ``17``, ``18``, ``19``, ``20``, ``21``, ``22``, ``23``, ``24``, ``DAY``, Day of the week (weekday, saturday, or sunday) .. csv-table:: Worksheet: ``METADATA`` :header: "Variable", "Description" ``metadata``, .. csv-table:: Worksheet: ``MONTHLY_MULTIPLIER`` :header: "Variable", "Description" ``1``, ``2``, ``3``, ``4``, ``5``, ``6``, ``7``, ``8``, ``9``, ``10``, ``11``, ``12``, .. csv-table:: Worksheet: ``OCCUPANCY`` :header: "Variable", "Description" ``1``, ``2``, ``3``, ``4``, ``5``, ``6``, ``7``, ``8``, ``9``, ``10``, ``11``, ``12``, ``13``, ``14``, ``15``, ``16``, ``17``, ``18``, ``19``, ``20``, ``21``, ``22``, ``23``, ``24``, ``DAY``, Day of the week (weekday, saturday, or sunday) .. csv-table:: Worksheet: ``PROCESSES`` :header: "Variable", "Description" ``1``, ``2``, ``3``, ``4``, ``5``, ``6``, ``7``, ``8``, ``9``, ``10``, ``11``, ``12``, ``13``, ``14``, ``15``, ``16``, ``17``, ``18``, ``19``, ``20``, ``21``, ``22``, ``23``, ``24``, ``DAY``, Day of the week (weekday, saturday, or sunday) .. csv-table:: Worksheet: ``SERVERS`` :header: "Variable", "Description" ``1``, ``2``, ``3``, ``4``, ``5``, ``6``, ``7``, ``8``, ``9``, ``10``, ``11``, ``12``, ``13``, ``14``, ``15``, ``16``, ``17``, ``18``, ``19``, ``20``, ``21``, ``22``, ``23``, ``24``, ``DAY``, Day of the week (weekday, saturday, or sunday) .. csv-table:: Worksheet: ``WATER`` :header: "Variable", "Description" ``1``, ``2``, ``3``, ``4``, ``5``, ``6``, ``7``, ``8``, ``9``, ``10``, ``11``, ``12``, ``13``, ``14``, ``15``, ``16``, ``17``, ``18``, ``19``, ``20``, ``21``, ``22``, ``23``, ``24``, ``DAY``, Day of the week (weekday, saturday, or sunday) get_database_supply_assemblies ------------------------------ path: ``inputs/technology/assemblies/SUPPLY.xlsx`` The following file is used by these scripts: ``demand``, ``emissions``, ``system_costs`` .. csv-table:: Worksheet: ``COOLING`` :header: "Variable", "Description" ``CAPEX_USD2015kW``, Capital costs per kW ``code``, Code of cooling supply assembly ``Description``, description ``efficiency``, efficiency of the all in one system ``feedstock``, feedstock used by the the all in one system (refers to the FEEDSTOCK database) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of assembly ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``reference``, reference ``scale``, whether the all in one system is used at the building or the district scale .. csv-table:: Worksheet: ``ELECTRICITY`` :header: "Variable", "Description" ``CAPEX_USD2015kW``, Capital costs per kW ``code``, Type of all in one system ``Description``, Description of Type of all in one system ``efficiency``, efficiency of the all in one system ``feedstock``, feedstock used by the the all in one system (refers to the FEEDSTOCK database) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of assembly ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``reference``, Reference of the data ``scale``, whether the all in one system is used at the building or the district scale .. csv-table:: Worksheet: ``HEATING`` :header: "Variable", "Description" ``CAPEX_USD2015kW``, Capital costs per kW ``code``, Type of all in one system ``Description``, Description of Type of all in one system ``efficiency``, efficiency of the all in one system ``feedstock``, feedstock used by the the all in one system (refers to the FEEDSTOCK database) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of assembly ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``reference``, Reference of the data ``scale``, whether the all in one system is used at the building or the district scale .. csv-table:: Worksheet: ``HOT_WATER`` :header: "Variable", "Description" ``CAPEX_USD2015kW``, Capital costs per kW ``code``, Type of all in one system ``Description``, Description of Type of all in one system ``efficiency``, efficiency of the all in one system ``feedstock``, feedstock used by the the all in one system (refers to the FEEDSTOCK database) ``IR_%``, interest rate charged on the loan for the capital cost ``LT_yr``, lifetime of assembly ``O&M_%``, operation and maintenance cost factor (fraction of the investment cost) ``reference``, Reference of the data ``scale``, whether the all in one system is used at the building or the district scale get_database_use_types_properties --------------------------------- path: ``inputs/technology/archetypes/use_types/USE_TYPE_PROPERTIES.xlsx`` The following file is used by these scripts: ``archetypes_mapper`` .. csv-table:: Worksheet: ``INDOOR_COMFORT`` :header: "Variable", "Description" ``code``, use type code (refers to building use type) ``RH_max_pc``, Upper bound of relative humidity ``RH_min_pc``, Lower_bound of relative humidity ``Tcs_set_C``, Setpoint temperature for cooling system ``Tcs_setb_C``, Setback point of temperature for cooling system ``Ths_set_C``, Setpoint temperature for heating system ``Ths_setb_C``, Setback point of temperature for heating system ``Ve_lsp``, Indoor quality requirements of indoor ventilation per person .. csv-table:: Worksheet: ``INTERNAL_LOADS`` :header: "Variable", "Description" ``code``, use type code (refers to building use type) ``Ea_Wm2``, Peak specific electrical load due to computers and devices ``Ed_Wm2``, Peak specific electrical load due to servers/data centres ``El_Wm2``, Peak specific electrical load due to artificial lighting ``Epro_Wm2``, Peak specific electrical load due to industrial processes ``Ev_kWveh``, Peak capacity of electrical battery per vehicle ``Occ_m2p``, Occupancy density ``Qcpro_Wm2``, Peak specific process cooling load ``Qcre_Wm2``, Peak specific cooling load due to refrigeration (cooling rooms) ``Qhpro_Wm2``, Peak specific process heating load ``Qs_Wp``, Peak sensible heat load of people ``Vw_ldp``, Peak specific fresh water consumption (includes cold and hot water) ``Vww_ldp``, Peak specific daily hot water consumption ``X_ghp``, Moisture released by occupancy at peak conditions