The Lyfe Cycle Analysis consists of five stages.

1. Setting the goal or scope
2. Formulate the assumptions
3. Inventory analysis
4. Impact assessment
5. Interpretation & design improvement.

In the Net Energy Analysis, we compare the useful energy produced by the system (E_P) with the energy consumed by it throughout its life cycle (E_CL). The ratio between the energy developed and consumed by the system is often termed as the Energy Payback Ratio (EPR).

Input:
	Number of Turbine
	Turbine Rated Power, PR
	Cut-in Velocity, VI
	Rated Velocity, VR
	Cut-out Velocity, VO
	Ideal Velocity Power Proportionality, n
	Total Time in hour, T
	Efficiency, h
	Shape Parameter, k
	Scale Parameter, c
	Total Time in Year, L
Output:
	Capacity Factor, CF
	Total Energy Output From All Turbine, ET
	Energy consumed by it throughout its life cycle, ECL
	Energy Payback Ratio, EPR = $EPR
	Energy Payback Period, EPP = $EPP years
		

Number of Turbine(s)
Turbine Rated Power, PR		MW
Cut-in Velocity, VI		m/s
Rated Velocity, VR		m/s
Cut-out Velocity, VO		m/s
Ideal Velocity Power Proportionality, n
Shape Parameter, k
Scale Parameter, c		m/s
Total Time in Year, L		years

Materials	Unit Energy, MJ/kg	Quantity, kg	Energy, MJ
Energy Required for Disposing
Total Energy Required

Energy Output From Single Turbine, E_T = 1761.39 MWh
The Capacity Factor, C_F = 0.3351
Total Energy Output From 15 Turbine(s), E_T = 26420.8507 MWh
Energy consumed by it throughout its life cycle, E_CL = 15857.765 MWh

Energy Payback Ratio, EPR = 33.3223
Energy Payback Period, EPP = 0.6002 years