main_AWE_HPS_connected.m

% main_AWE_HPS calculates the economic performance of a grid-connected HPS with ground-gen fixed-wing AWE power and power smoothing storage

  % This function performs energy yield, storage performance, arbitrage revenue and storage degradation
  % to compute the economic output of a fixed-wing airborne wind energy system 
  % over one year of operation at a certain DAM and wind environment.

%   Author
%   Bart Zweers, 
%   Delft University of Technology

%   clc; 
clearvars;

% addpath(genpath([pwd '/inputFiles']));
% addpath(genpath('C:\Users\bartz\Documents\GitHub\MSc_Bart_Zweers\src'));
% addpath(genpath('C:\Users\bartz\Documents\GitHub\MSc_Bart_Zweers\inputFiles'));
% addpath(genpath('C:\Users\bartz\Documents\GitHub\MSc_Bart_Zweers\lib'));

% Add the source code folders of AWE-Power and AWE-Eco to path
addpath(genpath('C:\Users\bartz\TU Delft\Sustainable Energy Technology\Thesis\Msc Thesis hybrid power using AWE\HPP model\Git\AWE-Power/src'));
addpath(genpath('C:\Users\bartz\TU Delft\Sustainable Energy Technology\Thesis\Msc Thesis hybrid power using AWE\HPP model\Git\AWE-Power/lib'));
addpath(genpath('C:\Users\bartz\Documents\GitHub\AWE-Eco'));

% Add inputFiles to path
addpath(genpath([pwd '/inputFiles']));

% Run AWE-Power
% Load defined input file
inputs = loadInputs('inputFile_100kW_baseCase.yml');

% Run AWE-Power
[inputs, outputs, optimDetails, processedOutputs] = main_awePower(inputs);

% Run AWE-Eco
% Import inputs
inp = eco_system_inputs_awePower(inputs, processedOutputs);

% Run EcoModel by parsing the inputs
[inp,par,eco] = eco_main(inp);

%% System inputs

% inputs = loadInputs('inputFile_100kW_AWEHPS.yml');
inputs.subsidy = 110;                          % Subsidized electricity price [EUR/MWh] 110 from german AWE

inputs.batt_size        = 140;                % kWh
inputs.batt_type        = 1;                    % P/E or C rate
inputs.batt_price       = 130;                % [EUR/kWh]  source: https://www.nrel.gov/docs/fy21osti/79236.pdf
inputs.batt_eff         = 0.90;                 % Round trip efficiency [%]
inputs.N_li_cycles = 1e4;                       % [lifetime cycles]
inputs.N_li_years = 10;                         % [lifetime years]

inputs.UC_price       = 6e4;                % [EUR/Wh]  source: https://www.nrel.gov/docs/fy21osti/79236.pdf
inputs.UC_eff         = 1;                  % Round trip efficiency [%]
inputs.N_UC_cycles = 1e6;                     % [lifetime cycles]
inputs.N_UC_years = 16;                       % [lifetime years]

inputs.batt_min     = 0.1;      % SoC lower limit strage system [-]
inputs.batt_max     = 0.9;      % SoC upper limit strage system [-]

  inputs.business.N_y     = 25; % project years
  inputs.business.r_d     = 0.08; % cost of debt
  inputs.business.r_e     = 0.12; % cost of equity
  inputs.business.TaxRate = 0.25; % Tax rate (25%)
  inputs.business.DtoE    = 70/30; % Debt-Equity-ratio 

inputs.r = inputs.business.DtoE/(1+ inputs.business.DtoE)*inputs.business.r_d*(1-inputs.business.TaxRate) + 1/(1+inputs.business.DtoE)*inputs.business.r_e; 

Scen1.ICC = 439e3;          % Capital cost kite system without intermediate storage
Scen1.OMC = 12.2e3;         % Operational cost kite system without intermediate storage


%% Scenario parameters


[inputs.DAM, inputs.vw, inputs.vol] = Param(readtable('DAM_NL_2019.csv'), ncread('NL_Wind.nc','u100'),ncread('NL_Wind.nc','v100'));

Scen3.w = 4;
Scen3.var = 0.17;

Scen4.w = 4;
Scen4.var = 0.17;

%% AWE performance


% AWE kite power hourly [kW]

[Scen1.P, Scen1.Cf, Scen1.AEP] = AWEperf(inputs.vw, [0	0	0 0 6823.05494180757	20750.8552913604	40035.5511607199	63415.6188669052	85700.7504181529	99999.9999634139	99999.9999993995	100000.000000000	99999.9999612856	99999.9999939655	99999.9999993012	99999.9999999965	100000.000000000	100000.000000000	100000.000000000	100000	100000.000000000]'...
                            , 4, 10);


% AWE power smoothing timeseries [kW]

[Scen1.P_sm, Scen1.E_sm, Scen1.E_res, Scen2.E_batt_req, Scen1.E_UC_req] = AWEsm(inputs.vw, Scen1.P, [0	0	0 0 39.2114406427936	93.0947366719285	207.022440717841	412.999777754543	702.156555319391	810.070535420744	805.462031428633	808.180879889064	809.929699115073	813.114155193377	816.935309245319	821.167178788006	825.732017996912	830.577439826927	835.618275680234	840.916791101337	847.169221886612]/1e3...
                                                              , [0	0	0 0 199.110877845002	87.6714004467267	85.5139407777646	87.3579932218051	93.3237218054094	80.8992375788376	79.9581035213846	79.4595074569484	79.1889899452987	79.0790839654564	79.0738117712405	79.1297853113387	79.2192139488680	79.3068747121754	79.3241622327488	79.2940943437130	79.9040793712790]...
                                                                 , [0,137.381331953625,137.209204335937,0,-39.7295922699621,7.03564325810917e-14,0], [0	0	0 0 6823.05494180757	20750.8552913604	40035.5511607199	63415.6188669052	85700.7504181529	99999.9999634139	99999.9999993995	100000.000000000	99999.9999612856	99999.9999939655	99999.9999993012	99999.9999999965	100000.000000000	100000.000000000	100000.000000000	100000	100000.000000000]');


%% Scenario 1 AWE + UC

% AWE+UC energy and profit performance

[Scen1.R_arb, Scen1.R_kite, Scen1.f_repl, Scen1.CapEx, Scen1.OpEx] = Scenperf(Scen1.P, zeros(8760,1), inputs.DAM, inputs.subsidy, Scen1.E_sm,...
                                                                               inputs.N_UC_years, inputs.N_UC_cycles, inputs.UC_price, Scen1.E_UC_req, Scen1.ICC, Scen1.OMC);

% AWE + UC economic metrics


[Scen1.LCoE, Scen1.LRoE, Scen1.LPoE, Scen1.Payb] = EcoMetrics(inputs.r,Scen1.R_kite,Scen1.AEP,Scen1.CapEx,Scen1.OpEx, inputs.business.N_y);
Scen1.NPV = NPV(inputs.r,Scen1.R_kite,Scen1.CapEx,Scen1.OpEx, inputs.business.N_y);
[Scen1.IRR,~] = fsolve(@(r) NPV(r,Scen1.R_kite,Scen1.CapEx,Scen1.OpEx, inputs.business.N_y),0,optimoptions('fsolve','Display','none'));



%% Scenario 2 AWE + Batt

% AWE + Batt energy and profit performance

[Scen2.R_arb, Scen2.R_kite, Scen2.f_repl, Scen2.CapEx, Scen2.OpEx] = Scenperf(Scen1.P, zeros(8760,1), inputs.DAM, inputs.subsidy, Scen1.E_sm, ...
                                                                                inputs.N_li_years, inputs.N_li_cycles, inputs.batt_price, Scen2.E_batt_req, Scen1.ICC, Scen1.OMC);


% AWE + Batt economic metrics


[Scen2.LCoE, Scen2.LRoE, Scen2.LPoE, Scen2.Payb] = EcoMetrics(inputs.r,Scen2.R_kite,Scen1.AEP,Scen2.CapEx,Scen2.OpEx, inputs.business.N_y);
Scen2.NPV = NPV(inputs.r,Scen2.R_kite,Scen2.CapEx,Scen2.OpEx, inputs.business.N_y);
[Scen2.IRR,~] = fsolve(@(r) NPV(r,Scen2.R_kite,Scen2.CapEx,Scen2.OpEx, inputs.business.N_y),0,optimoptions('fsolve','Display','none'));


%% Scenario 3 Batt arbitrage


% Batt arbitrage bidding dispatch

[Scen3.SoC,Scen3.P] = Dispatcher(Scen3.w, Scen3.var, inputs.DAM, zeros(8760,1), zeros(8760,1), inputs.batt_min*Scen2.E_batt_req, inputs.batt_max*Scen2.E_batt_req,...
                                    Scen2.E_batt_req, inputs.batt_type, inputs.batt_eff); 


% Batt arbitrage energy and profit performance

[Scen3.R_arb, Scen3.R_kite, Scen3.f_repl, Scen3.CapEx, Scen3.OpEx] = Scenperf(zeros(8760,1), Scen3.P, inputs.DAM, inputs.subsidy, zeros(8760,1), ...
                                                                                inputs.N_li_years, inputs.N_li_cycles, inputs.batt_price, Scen2.E_batt_req, 0, 0);

% Batt arbitrage economic metrics


Scen3.arb_E = sum(abs(min(Scen3.P,0)))/1e3;

[Scen3.LCoE, Scen3.LRoE, Scen3.LPoE, Scen3.Payb] = EcoMetrics(inputs.r,Scen3.R_arb,Scen3.arb_E,Scen3.CapEx,Scen3.OpEx, inputs.business.N_y);
Scen3.NPV = NPV(inputs.r,Scen3.R_arb,Scen3.CapEx,Scen3.OpEx, inputs.business.N_y);
[Scen3.IRR,~] = fsolve(@(r) NPV(r,Scen3.R_arb,Scen3.CapEx,Scen3.OpEx, inputs.business.N_y),0,optimoptions('fsolve','Display','none'));
[Scen3.LF, Scen3.VoSA] = StorageMetrics(Scen3.R_arb,Scen3.P,Scen2.E_batt_req,inputs.batt_type);


%% Scenario 4 AWE + Batt arbitrage

% AWE + Batt arbitrage bidding dispatch

[Scen4.SoC,Scen4.P] = Dispatcher(Scen4.w, Scen4.var, inputs.DAM, Scen1.P_sm, Scen1.E_res, inputs.batt_min*Scen2.E_batt_req, inputs.batt_max*Scen2.E_batt_req,...
                                    Scen2.E_batt_req, inputs.batt_type, inputs.batt_eff); 

% AWE + Batt arbitrage energy and profit performance

[Scen4.R_arb, Scen4.R_kite, Scen4.f_repl, Scen4.CapEx, Scen4.OpEx] = Scenperf(Scen1.P, Scen4.P, inputs.DAM, inputs.subsidy, Scen1.E_sm, ...
                                                                                inputs.N_li_years, inputs.N_li_cycles, inputs.batt_price, Scen2.E_batt_req, Scen1.ICC, Scen1.OMC);


% AWE + Batt arbitrage economic metrics

Scen4.R = Scen4.R_arb + Scen4.R_kite;
Scen4.arb_E = sum(abs(min(Scen4.P,0)))/1e3;
Scen4.E_dis = Scen1.AEP + Scen4.arb_E;

[Scen4.LCoE, Scen4.LRoE, Scen4.LPoE, Scen4.Payb] = EcoMetrics(inputs.r,Scen4.R,Scen4.E_dis,Scen4.CapEx,Scen4.OpEx, inputs.business.N_y);
Scen4.NPV = NPV(inputs.r,Scen4.R,Scen4.CapEx,Scen4.OpEx, inputs.business.N_y);
[Scen4.IRR,~] = fsolve(@(r) NPV(r,Scen4.R,Scen4.CapEx,Scen4.OpEx, inputs.business.N_y),0,optimoptions('fsolve','Display','none'));
[Scen4.LF, Scen4.VoSA] = StorageMetrics(Scen4.R_arb,Scen4.P,Scen2.E_batt_req,inputs.batt_type);



%% Display

Scen4.f_cycles = (sum(abs(Scen4.P)) + sum(Scen1.E_sm))/(Scen2.E_batt_req*inputs.N_li_cycles);
Scen2.f_cycles = sum(Scen1.E_sm)/(Scen2.E_batt_req*inputs.N_li_cycles);
Scen4.arbprof = Scen4.R_arb - inputs.batt_price*Scen2.E_batt_req*(Scen4.f_cycles-Scen2.f_cycles);

% disp('---------------------------------------------------------')
% disp(['window = ',num2str(round(Scen4.w,2)),' hrs'])
% disp(['variance = ',num2str(round(Scen4.var,4)),' EUR/MWh'])
% disp(['Scenario 4 E_{dis} = ',num2str(round(Scen4.arb_E,4)),' MWh'])
% disp(['Scenario 4 IRR = ',num2str(round(Scen4.IRR*1e2,4)),' %'])
% disp(['Scenario 4 Arbitrage profit = ',num2str(round(Scen4.arbprof,4)),' EUR'])

%% Plots 

% Scenario parameters
%%%%%%%%%%%%%%%%%%%%%

% plotScenParam(inputs.DAM, inputs.vw) 

% AWE performance
%%%%%%%%%%%%%%%%%

Scen1.P_m = [0,200.000000000000,200.000000000000,0,-30.8149680256871,5.45696821063757e-14,0];
Scen1.P_m_avg = 148250.920152283/1e3;

plotAWEperf(Scen1.P, [0	0	0 0 6823.05494180757	20750.8552913604	40035.5511607199	63415.6188669052	85700.7504181529	99999.9999634139	99999.9999993995	100000.000000000	99999.9999612856	99999.9999939655	99999.9999993012	99999.9999999965	100000.000000000	100000.000000000	100000.000000000	100000	100000.000000000]'...
               , inputs.vw, [0,137.381331953625,137.209204335937,0,-39.7295922699621,7.03564325810917e-14,0])



% Storage performance
%%%%%%%%%%%%%%%%%%%%%

% plotStorperf( Scen1, Scen2, Scen4)

% Arbitrage operation
%%%%%%%%%%%%%%%%%%%%%

% plotArbOpp(inputs, Scen1,Scen2, Scen3, Scen4)

% Plots Scenario 1
%%%%%%%%%%%%%%%%%%
% Scen1.SoC = zeros(8760,1);
% plotScenario(5950, inputs, Scen1, Scen1, Scen1.E_UC_req, inputs.N_UC_cycles)

% Plots Scenario 2
%%%%%%%%%%%%%%%%%%

% plotScenario(5950, inputs, Scen1, Scen2, Scen2.E_batt_req, inputs.N_li_cycles)

% Plots Scenario 3
%%%%%%%%%%%%%%%%%%
% Scen3.E_res = zeros(8760,1);
% Scen3.E_sm = zeros(8760,1);
% Scen3.P_sm = zeros(8760,1);
% plotScenario(5950, inputs, Scen3, Scen3, Scen2.E_batt_req, inputs.N_li_cycles)

% Plots Scenario 4
%%%%%%%%%%%%%%%%%%

% plotScenario(5950, inputs, Scen1, Scen4, Scen2.E_batt_req, inputs.N_li_cycles)

% Discussion
%%%%%%%%%%%%

% plotDiscuss(inputs, Scen1, Scen2, Scen3, Scen4)