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@ -277,16 +277,20 @@ def get_ongoing_recession(n_runs, start_year, end_year, sea_level_rise,
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# Calculate total underlying recession
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# Calculate total underlying recession
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year_factor = np.arange(1, n_years + 1)[:, np.newaxis]
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year_factor = np.arange(1, n_years + 1)[:, np.newaxis]
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underlying_recession = underlying_recession_rate * year_factor
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underlying_recession = underlying_recession_rate * year_factor
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underlying_recession_rate = np.tile(underlying_recession_rate,
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[n_years, 1])
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# Remove probabilistic component from start year
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# Remove probabilistic component from start year
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slr[0, :] = slr[0, :].mean()
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slr[0, :] = slr[0, :].mean()
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underlying_recession[0, :] = underlying_recession[0, :].mean()
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underlying_recession[0, :] = underlying_recession[0, :].mean()
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bruun_factor[0, :] = bruun_factor[0, :].mean()
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bruun_factor[0, :] = bruun_factor[0, :].mean()
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underlying_recession_rate[0, :] = underlying_recession_rate[0, :].mean()
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# Calculate total ongoing recession (m)
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# Calculate total ongoing recession (m)
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ongoing_recession = slr * bruun_factor + underlying_recession
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ongoing_recession = slr * bruun_factor + underlying_recession
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return ongoing_recession, slr, bruun_factor, underlying_recession
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return (ongoing_recession, slr, bruun_factor, underlying_recession,
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underlying_recession_rate)
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def get_storm_demand_volume(ref_aep, ref_vol, n, mode='fit'):
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def get_storm_demand_volume(ref_aep, ref_vol, n, mode='fit'):
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@ -397,8 +401,9 @@ def process(beach_name, beach_scenario, n_runs, start_year, end_year,
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probabilistic = True
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probabilistic = True
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# Simulate ongoing shoreline recession
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# Simulate ongoing shoreline recession
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r, slr, bf, ur = get_ongoing_recession(n_runs, start_year, end_year,
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r, slr, bf, ur, ur_rate = get_ongoing_recession(n_runs, start_year,
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sea_level_rise, bruun_factor,
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end_year, sea_level_rise,
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bruun_factor,
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underlying_recession)
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underlying_recession)
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ongoing_recession = r.copy()
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ongoing_recession = r.copy()
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