Redes Neuronales
Genaro Rodríguez Alcántara - A00833172
2024-02-22
Teoría
Una red Neuroanl Artificial (ANN) modela la relación entre un conjunto de entradas y una salida, resolviendo un problema de aprendizaje.
Algunos ejemplos de aplicación de ANN son:
- La recomendación de contenido de Netflix.
- El feed de Instagram.
- Determinar el número escrito a mano.
Ejercicio 1. ¿Pasé la materia?
1. Instalar paquetes y llamar librería
#install.packages("neuralnet")
library(neuralnet)2. Obtener datos
examen <- c(20,10,30,20,80,30)
proyecto <- c(90,20,40,50,50,80)
estatus <- c(1,0,0,0,0,1)
df1 <- data.frame(examen, proyecto, estatus)3. Generar la Red Neuroanl
rn1 <- neuralnet(estatus~., data = df1)
plot(rn1, rep = "best")
4. Predecir Resultados
prueba_examen <- c(30,40,85)
prueba_proyecto <- c(85,50,40)
prueba1 <- data.frame(prueba_examen, prueba_proyecto)
prediccion <- compute(rn1,prueba1)
prediccion$net.result## [,1]
## [1,] 0.4006943
## [2,] 0.4006943
## [3,] -0.3503815probabilidad <- prediccion$net.result
resultado <- ifelse(probabilidad>0.5,1,0)
resultado## [,1]
## [1,] 0
## [2,] 0
## [3,] 0Ejercicio 2. Cáncer de mama
A. Obtener Datos
canmama <- read.csv("/Users/genarorodriguezalcantara/Desktop/Tec/AI - Concentración/Módulo 2 - Machine Learning/BD/cancer_de_mama.csv")
canmama_filtrado <- canmama[19:23,]B. Entender la base de datos
summary(canmama)## diagnosis radius_mean texture_mean perimeter_mean
## Length:569 Min. : 6.981 Min. : 9.71 Min. : 43.79
## Class :character 1st Qu.:11.700 1st Qu.:16.17 1st Qu.: 75.17
## Mode :character Median :13.370 Median :18.84 Median : 86.24
## Mean :14.127 Mean :19.29 Mean : 91.97
## 3rd Qu.:15.780 3rd Qu.:21.80 3rd Qu.:104.10
## Max. :28.110 Max. :39.28 Max. :188.50
## area_mean smoothness_mean compactness_mean concavity_mean
## Min. : 143.5 Min. :0.05263 Min. :0.01938 Min. :0.00000
## 1st Qu.: 420.3 1st Qu.:0.08637 1st Qu.:0.06492 1st Qu.:0.02956
## Median : 551.1 Median :0.09587 Median :0.09263 Median :0.06154
## Mean : 654.9 Mean :0.09636 Mean :0.10434 Mean :0.08880
## 3rd Qu.: 782.7 3rd Qu.:0.10530 3rd Qu.:0.13040 3rd Qu.:0.13070
## Max. :2501.0 Max. :0.16340 Max. :0.34540 Max. :0.42680
## concave.points_mean symmetry_mean fractal_dimension_mean radius_se
## Min. :0.00000 Min. :0.1060 Min. :0.04996 Min. :0.1115
## 1st Qu.:0.02031 1st Qu.:0.1619 1st Qu.:0.05770 1st Qu.:0.2324
## Median :0.03350 Median :0.1792 Median :0.06154 Median :0.3242
## Mean :0.04892 Mean :0.1812 Mean :0.06280 Mean :0.4052
## 3rd Qu.:0.07400 3rd Qu.:0.1957 3rd Qu.:0.06612 3rd Qu.:0.4789
## Max. :0.20120 Max. :0.3040 Max. :0.09744 Max. :2.8730
## texture_se perimeter_se area_se smoothness_se
## Min. :0.3602 Min. : 0.757 Min. : 6.802 Min. :0.001713
## 1st Qu.:0.8339 1st Qu.: 1.606 1st Qu.: 17.850 1st Qu.:0.005169
## Median :1.1080 Median : 2.287 Median : 24.530 Median :0.006380
## Mean :1.2169 Mean : 2.866 Mean : 40.337 Mean :0.007041
## 3rd Qu.:1.4740 3rd Qu.: 3.357 3rd Qu.: 45.190 3rd Qu.:0.008146
## Max. :4.8850 Max. :21.980 Max. :542.200 Max. :0.031130
## compactness_se concavity_se concave.points_se symmetry_se
## Min. :0.002252 Min. :0.00000 Min. :0.000000 Min. :0.007882
## 1st Qu.:0.013080 1st Qu.:0.01509 1st Qu.:0.007638 1st Qu.:0.015160
## Median :0.020450 Median :0.02589 Median :0.010930 Median :0.018730
## Mean :0.025478 Mean :0.03189 Mean :0.011796 Mean :0.020542
## 3rd Qu.:0.032450 3rd Qu.:0.04205 3rd Qu.:0.014710 3rd Qu.:0.023480
## Max. :0.135400 Max. :0.39600 Max. :0.052790 Max. :0.078950
## fractal_dimension_se radius_worst texture_worst perimeter_worst
## Min. :0.0008948 Min. : 7.93 Min. :12.02 Min. : 50.41
## 1st Qu.:0.0022480 1st Qu.:13.01 1st Qu.:21.08 1st Qu.: 84.11
## Median :0.0031870 Median :14.97 Median :25.41 Median : 97.66
## Mean :0.0037949 Mean :16.27 Mean :25.68 Mean :107.26
## 3rd Qu.:0.0045580 3rd Qu.:18.79 3rd Qu.:29.72 3rd Qu.:125.40
## Max. :0.0298400 Max. :36.04 Max. :49.54 Max. :251.20
## area_worst smoothness_worst compactness_worst concavity_worst
## Min. : 185.2 Min. :0.07117 Min. :0.02729 Min. :0.0000
## 1st Qu.: 515.3 1st Qu.:0.11660 1st Qu.:0.14720 1st Qu.:0.1145
## Median : 686.5 Median :0.13130 Median :0.21190 Median :0.2267
## Mean : 880.6 Mean :0.13237 Mean :0.25427 Mean :0.2722
## 3rd Qu.:1084.0 3rd Qu.:0.14600 3rd Qu.:0.33910 3rd Qu.:0.3829
## Max. :4254.0 Max. :0.22260 Max. :1.05800 Max. :1.2520
## concave.points_worst symmetry_worst fractal_dimension_worst
## Min. :0.00000 Min. :0.1565 Min. :0.05504
## 1st Qu.:0.06493 1st Qu.:0.2504 1st Qu.:0.07146
## Median :0.09993 Median :0.2822 Median :0.08004
## Mean :0.11461 Mean :0.2901 Mean :0.08395
## 3rd Qu.:0.16140 3rd Qu.:0.3179 3rd Qu.:0.09208
## Max. :0.29100 Max. :0.6638 Max. :0.20750str(canmama)## 'data.frame': 569 obs. of 31 variables:
## $ diagnosis : chr "M" "M" "M" "M" ...
## $ radius_mean : num 18 20.6 19.7 11.4 20.3 ...
## $ texture_mean : num 10.4 17.8 21.2 20.4 14.3 ...
## $ perimeter_mean : num 122.8 132.9 130 77.6 135.1 ...
## $ area_mean : num 1001 1326 1203 386 1297 ...
## $ smoothness_mean : num 0.1184 0.0847 0.1096 0.1425 0.1003 ...
## $ compactness_mean : num 0.2776 0.0786 0.1599 0.2839 0.1328 ...
## $ concavity_mean : num 0.3001 0.0869 0.1974 0.2414 0.198 ...
## $ concave.points_mean : num 0.1471 0.0702 0.1279 0.1052 0.1043 ...
## $ symmetry_mean : num 0.242 0.181 0.207 0.26 0.181 ...
## $ fractal_dimension_mean : num 0.0787 0.0567 0.06 0.0974 0.0588 ...
## $ radius_se : num 1.095 0.543 0.746 0.496 0.757 ...
## $ texture_se : num 0.905 0.734 0.787 1.156 0.781 ...
## $ perimeter_se : num 8.59 3.4 4.58 3.44 5.44 ...
## $ area_se : num 153.4 74.1 94 27.2 94.4 ...
## $ smoothness_se : num 0.0064 0.00522 0.00615 0.00911 0.01149 ...
## $ compactness_se : num 0.049 0.0131 0.0401 0.0746 0.0246 ...
## $ concavity_se : num 0.0537 0.0186 0.0383 0.0566 0.0569 ...
## $ concave.points_se : num 0.0159 0.0134 0.0206 0.0187 0.0188 ...
## $ symmetry_se : num 0.03 0.0139 0.0225 0.0596 0.0176 ...
## $ fractal_dimension_se : num 0.00619 0.00353 0.00457 0.00921 0.00511 ...
## $ radius_worst : num 25.4 25 23.6 14.9 22.5 ...
## $ texture_worst : num 17.3 23.4 25.5 26.5 16.7 ...
## $ perimeter_worst : num 184.6 158.8 152.5 98.9 152.2 ...
## $ area_worst : num 2019 1956 1709 568 1575 ...
## $ smoothness_worst : num 0.162 0.124 0.144 0.21 0.137 ...
## $ compactness_worst : num 0.666 0.187 0.424 0.866 0.205 ...
## $ concavity_worst : num 0.712 0.242 0.45 0.687 0.4 ...
## $ concave.points_worst : num 0.265 0.186 0.243 0.258 0.163 ...
## $ symmetry_worst : num 0.46 0.275 0.361 0.664 0.236 ...
## $ fractal_dimension_worst: num 0.1189 0.089 0.0876 0.173 0.0768 ...C. Generar Arbol de Decisión
# install.packages("rpart")
library(rpart)
arbol <- rpart(formula=diagnosis ~ ., data = canmama)
arbol## n= 569
##
## node), split, n, loss, yval, (yprob)
## * denotes terminal node
##
## 1) root 569 212 B (0.62741652 0.37258348)
## 2) radius_worst< 16.795 379 33 B (0.91292876 0.08707124)
## 4) concave.points_worst< 0.1358 333 5 B (0.98498498 0.01501502) *
## 5) concave.points_worst>=0.1358 46 18 M (0.39130435 0.60869565)
## 10) texture_worst< 25.67 19 4 B (0.78947368 0.21052632) *
## 11) texture_worst>=25.67 27 3 M (0.11111111 0.88888889) *
## 3) radius_worst>=16.795 190 11 M (0.05789474 0.94210526) *# install.packages("rpart.plot")
library(rpart.plot)
rpart.plot(arbol)
prp(arbol,extra = 7,prefix = "fraccion")
D. Generar Red Neuronal
set.seed(123)
rnmama <- neuralnet(diagnosis ~.,data = canmama_filtrado)
plot(rnmama, rep = "best")
E. Predicción de Resultados
prediccionmama <- neuralnet::compute(rnmama,canmama_filtrado)
prediccionmama$net.result## [,1] [,2]
## 19 0.6016767 0.3988474
## 20 0.6016767 0.3988474
## 21 0.6016767 0.3988474
## 22 0.6016767 0.3988474
## 23 0.6016767 0.3988474probabilidad_bm <- prediccionmama$net.result
resultado <- ifelse(probabilidad_bm>0.5,1,0)
resultado## [,1] [,2]
## 19 1 0
## 20 1 0
## 21 1 0
## 22 1 0
## 23 1 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