diff --git a/docs/src/examples.md b/docs/src/examples.md index 9adc8e2..ba1d16d 100644 --- a/docs/src/examples.md +++ b/docs/src/examples.md @@ -51,7 +51,7 @@ fit!(model; penalize_initial_states=false) simulation = StateSpaceLearning.simulate(model, steps_ahead, 100) #Gets a 12 steps ahead prediction plot_scenarios(y, simulation) ``` -![solar_sim_raw](assets/solar_sim_raw.PNG) +![solar_sim_raw](assets/solar_sim_raw.png) Now we present the results by setting the ``seasonal\_innovation\_simulation`` hyperparameter to 24 (given that it is a solar hourly time series). @@ -68,7 +68,7 @@ fit!(model; penalize_initial_states=false) simulation = StateSpaceLearning.simulate(model, steps_ahead, 100; seasonal_innovation_simulation=24) #Gets a 12 steps ahead prediction plot_scenarios(y, simulation) ``` -![solar_sim_treated](assets/solar_sim_treated.PNG) +![solar_sim_treated](assets/solar_sim_treated.png) Thus, the model has demonstrated its capability to effectively capture the intermittent nature of the solar time series, providing a more accurate representation of its underlying characteristics. @@ -92,7 +92,7 @@ prediction = StateSpaceLearning.forecast(model, steps_ahead) # arguments are the plot_point_forecast(y, prediction) ``` -![one_seas](assets/one_seas.PNG) +![one_seas](assets/one_seas.png) Note that the model successfully captured the daily seasonality but, as expected, was unable to capture the weekly seasonality. We now present the results after setting the `freq\_seasonal` hyperparameter to [24, 168], accounting for both daily and weekly seasonalities. @@ -112,6 +112,6 @@ prediction = StateSpaceLearning.forecast(model, steps_ahead) # arguments are the plot_point_forecast(y, prediction) ``` -![two_seas](assets/two_seas.PNG) +![two_seas](assets/two_seas.png) Note that the model was able to capture both seasonalities in this case. \ No newline at end of file