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- import glob
- import os
- import pandas as pd
- import matplotlib.pyplot as plt
- import time
- import numpy as np
- import seaborn as sns
- import math
- path = os.getcwd()
- def get_average(records):
- return sum(records) / len(records)
- def get_variance(records):
- average = get_average(records)
- return sum([(x - average) ** 2 for x in records]) / len(records)
- def get_standard_deviation(records):
- variance = get_variance(records)
- return math.sqrt(variance)
- def get_rms(records):
- return math.sqrt(sum([x ** 2 for x in records]) / len(records))
- def get_mse(records_real, records_predict):
- if len(records_real) == len(records_predict):
- return sum([(x - y) ** 2 for x, y in zip(records_real, records_predict)]) / len(records_real)
- else:
- return None
- def get_rmse(records_real, records_predict):
- mse = get_mse(records_real, records_predict)
- if mse:
- return math.sqrt(mse)
- else:
- return None
- def get_mae(records_real, records_predict):
- if len(records_real) == len(records_predict):
- return sum([abs(x - y) for x, y in zip(records_real, records_predict)]) / len(records_real)
- else:
- return None
- def writeSDCSV(filename):
- file = pd.read_csv("Mean.csv")
- conditions = file['condition']
-
- dict = {}
- dict['conditon'] = conditions
- for scale in scales:
- temp = []
- for condition in conditions:
- col = df_merged.groupby('condition').get_group(condition)
- col = col[scale]
- temp.append(get_standard_deviation(col))
- dict[scale] = temp
- df = pd.DataFrame(dict)
- df.to_csv(filename)
- def draw(filename):
- conditions = file['condition']
- result = file[filename]
- plt.figure(figsize=(9, 6), dpi=100)
- plt.bar(conditions, result, width=0.35, color=colors,alpha=a)
- plt.title(filename,fontsize=20)
- plt.ylabel('score')
- plt.grid(alpha=0, linestyle=':')
- plt.savefig(filename + ".jpg", dpi=300)
- #plt.show()
- def drawRobotPerformance():
- plt.figure(figsize=(20,8))
- conditions = file['condition']
-
- sd = pd.read_csv(SD)
-
- error_params=dict(elinewidth=1,ecolor='black',capsize=5)
-
- plt.suptitle("Robot Performance",fontsize=20)
- plt.subplot(221)
- plt.title("Collision",fontsize=15)
- std_err = sd["Collision"]
- plt.ylabel('Times')
- plt.bar(conditions, file["Collision"], width=0.35, color=colors,alpha=a,yerr=std_err,error_kw=error_params)
-
- plt.subplot(222)
- plt.title("Drive Distance",fontsize=15)
- std_err = sd["Drive Distance"]
- plt.ylabel('Distance(m)')
- plt.bar(conditions, file["Drive Distance"], width=0.35, color=colors,alpha=a,yerr=std_err,error_kw=error_params)
-
- plt.subplot(223)
- plt.title("Total driving time",fontsize=15)
- std_err = sd["Total driving time"]
- plt.ylabel('Time(s)')
- plt.bar(conditions, file["Total driving time"], width=0.35, color=colors,alpha=a,yerr=std_err,error_kw=error_params)
- plt.subplot(224)
- plt.title("Adverage speed",fontsize=15)
- std_err = sd["Adverage speed"]
- plt.ylabel('Speed(m/s)')
- plt.bar(conditions, file["Adverage speed"], width=0.35, color=colors,alpha=a,yerr=std_err,error_kw=error_params)
-
- plt.savefig("Robot Performance",dpi=300)
- def drawRescue():
- plt.figure(figsize =(15,7))
- x = np.arange(len(scales))
- total_width, n = 0.8, 4
- width = total_width / n
- sd = pd.read_csv(SD)
- error_params=dict(elinewidth=1,ecolor='black',capsize=5)
- # set range
- plt.ylim(0, 10)
- for i in range(0,4):
- result = []
- std_err = []
- for scale in scales:
- result.append(file.iloc[i][scale])
- std_err.append(sd.iloc[i][scale])
- plt.bar(x+width*(i-1),result,width=width,color=colors[i],label=file.iloc[i]["condition"],alpha=a,yerr=std_err,error_kw=error_params)
- plt.legend()
- plt.title("Rescue situation",fontsize=15)
- plt.xticks(x+width/2,scales)
- plt.ylabel('Person')
- #plt.show()
-
- plt.savefig("Rescue situation",dpi=300)
- # Merge all the .csv file
- all_files = glob.glob(os.path.join(path, "*.csv"))
- df_from_each_file = (pd.read_csv(f, sep=',') for f in all_files)
- df_merged = pd.concat(df_from_each_file, ignore_index=True)
- # Save the file to Merged.csv in the same folder
- # df_merged.to_csv( "Merged.csv")
- # save the results in csv
- file = df_merged.groupby(["condition"]).mean()
- file.to_csv( "Mean.csv")
- scales = ["Collision","Drive Distance","Total driving time","Adverage speed","Rescued Target", "Remained Visible Target","Remained Unvisible Target"]
- SD = "standard_deviation.csv"
- writeSDCSV(SD)
- file = pd.read_csv("Mean.csv")
- colors = sns.color_palette()
- a = 0.6
- # for scale in scales:
- # draw(scale)
- scales = ["Rescued Target", "Remained Visible Target","Remained Unvisible Target"]
- drawRescue()
- scales = ["Collision","Drive Distance","Total driving time","Adverage speed"]
- drawRobotPerformance()
- os.remove("Mean.csv")
- os.remove(SD)
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