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opensci:2025:rafael:art2 [2025/04/01 23:26] – criada rafaelopensci:2025:rafael:art2 [2025/04/07 23:39] (atual) rafael
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-====== Time Series Analysis and Projection of Climate of Variables of Piracicaba, SP ======+====== Time Series Analysis and Projection of Climate Variables of Piracicaba, SP ======
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 **Author**: [[opensci:2025:rafael|Cassio Rafael C. dos Santos]] **Author**: [[opensci:2025:rafael|Cassio Rafael C. dos Santos]]
  
-**Overview**: [[https://figshare.com/account/home|FigShare]] FALAR DA SÉRIE HISTÓRICA CLIMÁTICA DE PIRA.+**Overview**: In this task, we used the long timeseries of climatic attributes, from Piracicaba [[http://www.leb.esalq.usp.br/posto/|Weather Station]]. This timeseries data started to be recorded in 1905, gathering more than a century of climate information. The spreadsheet with these data contains attributes such as Temperature (maximum, minimum and average), Air Relative Humidity, Precipitation and Global Radiation.  
  
 +**Questions**: Using these climate data, we formulated the following scientific questions: 1-Is Piracicaba climate getting warmer, dryer and more rainless? 2-The tendency of increasing temperatures and decreasing relative humidities and precipitation will continue 100 years ahead?
  
-**Questions**: DESTACAR AQUI AS QUESTÕES DEPOIS.+**Procedures Description**: From Piracicaba Climate Spreadsheet, we extracted Mean, Minimum and Maximum Temperature, Relative Humidity and Precipitation data. Using dynamic tables in the Spreadsheet, we organized these daily data, turning them into average annual data and then into average decade data. With these decade data, we performed a polinomial quadractic modelling, aiming to predict these climate attributes (response variables), using the decade as the predictor variable. Thereafter, we used the fitted equations to perform a projection of the climate variables 100 years ahead (until 2120) to assess the tendency of these attributes over a century
  
-**A Different Approach Proposal**:  Although they have found some interesting outcomeswe believe the raw data were underutilizedespecially by shrinking the AFS groups into only one group. Thereforewe tried to propose an alternative assessment approach using the raw data of this paper, for the following soil variables: C and N concentration and stockC/N ratiosoil bulk density and soil pHBy performing this new assessmentwe found significant differences between the different AFSdenoting these systems need to be evaluated differently +**Results Interpretation**: Firstly, the increasing behavior of temperatures (minimummaximum and mean) and decreasing behavior of Relative Humidity and Precipitation were confirmed by the tendency curves fitted by the polynomial modelfrom 1920 to 2025. These outcomes answer positively the first scientific question, denoting the possible effects of climate changes on Piracicaba climate. Additionallythe projection for the future decades until 2120 shows that this tendency continues over these decadesresponding positively the second scientific question. For temperaturesfrom 2025 to 2125, the tendency curves denote an increase of 23,3 % for Mean Temperature, 68,4 % for Minimum Temperature and 24,7 % for Maximum TemperatureFor Relative Humidity and Precipitation, from 2025 to 2125, the tendency curves denote an decrease of 46,7 % for Relative Humidity and 54,5 % for Precipitation
  
  
 **Raw Data and Code used** **Raw Data and Code used**
  
-  *[[LINK|RCloud Code to Data Analysis]]  +  *[[https://posit.cloud/content/9957157|RCloud Code to Data Analysis]]  
-  *[[LINK|Raw Data in GitHub]] +  *[[https://github.com/RafaSantos71/Piracicaba_Climate_Data/blob/main/Clima_Pira_Comparison.xlsx|Raw Data in GitHub]] 
  
 **Plots Generated** **Plots Generated**
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 {{:opensci:2025:rafael:projection_tmin.png?300|}} {{:opensci:2025:rafael:projection_tmin.png?300|}}
 {{:opensci:2025:rafael:ajuste_do_modelo_para_tmin.jpg?250|}} {{:opensci:2025:rafael:ajuste_do_modelo_para_tmin.jpg?250|}}
 +
 +Figure 1. Modelling of Minimum Temperature using 1920-2025 data and its projection to 2120.
  
 {{:opensci:2025:rafael:projection_tmed.png?300|}} {{:opensci:2025:rafael:projection_tmed.png?300|}}
 {{:opensci:2025:rafael:ajuste_do_modelo_para_tmed.jpg?250|}} {{:opensci:2025:rafael:ajuste_do_modelo_para_tmed.jpg?250|}}
 +
 +Figure 2. Modelling of Average Temperature using 1920-2025 data and its projection to 2120.
  
 {{:opensci:2025:rafael:projection_tmax.png?300|}} {{:opensci:2025:rafael:projection_tmax.png?300|}}
 {{:opensci:2025:rafael:ajuste_do_modelo_para_tmax.jpg?250|}} {{:opensci:2025:rafael:ajuste_do_modelo_para_tmax.jpg?250|}}
 +
 +Figure 3. Modelling of Maximum Temperature using 1920-2025 data and its projection to 2120.
  
 {{:opensci:2025:rafael:projection_precipitation.png?300|}} {{:opensci:2025:rafael:projection_precipitation.png?300|}}
 {{:opensci:2025:rafael:ajuste_do_modelo_para_precipitation.jpg?250|}} {{:opensci:2025:rafael:ajuste_do_modelo_para_precipitation.jpg?250|}}
 +
 +Figure 4. Modelling of Annual Average Precipitation using 1920-2025 data and its projection to 2120.
  
 {{:opensci:2025:rafael:projection_relhumid.png?300|}} {{:opensci:2025:rafael:projection_relhumid.png?300|}}
 {{:opensci:2025:rafael:ajuste_do_modelo_para_relhumidty.jpg?250|}} {{:opensci:2025:rafael:ajuste_do_modelo_para_relhumidty.jpg?250|}}
 +
 +Figure 5. Modelling of Air Relative Humidity using 1920-2025 data and its projection to 2120.
  
opensci/2025/rafael/art2.1743550000.txt.gz · Última modificação: 2025/04/01 23:26 por rafael