"In a *regression* problem, we aim to predict the output of a continous value, like a price or a probability. Contrast this with a *classification* problem, where we aim to predict a discrete label (for example, where a picture contains an apple or an orange). \n",
"In a *regression* problem, we aim to predict the output of a continuous value, like a price or a probability. Contrast this with a *classification* problem, where we aim to predict a discrete label (for example, where a picture contains an apple or an orange). \n",
"\n",
"\n",
"This notebook builds a model to predict the median price of homes in a Boston suburb during the mid-1970s. To do this, we'll provide the model with some data points about the suburb, such as the crime rate and the local property tax rate.\n",
"This notebook builds a model to predict the median price of homes in a Boston suburb during the mid-1970s. To do this, we'll provide the model with some data points about the suburb, such as the crime rate and the local property tax rate.\n",
"\n",
"\n",
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@@ -342,7 +342,7 @@
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@@ -342,7 +342,7 @@
"source": [
"source": [
"## Create the model\n",
"## Create the model\n",
"\n",
"\n",
"Let's build our model. Here, we'll use a `Sequential` model with two densely connected hidden layers, and an output later that returns a single, continous value. The model building steps are wrapped in a function, `build_model`, since we'll create a second model, later on."
"Let's build our model. Here, we'll use a `Sequential` model with two densely connected hidden layers, and an output later that returns a single, continuous value. The model building steps are wrapped in a function, `build_model`, since we'll create a second model, later on."
