Machine Learning Engineer Nanodegree

Model Evaluation & Validation

Project: Predicting Boston Housing Prices

Welcome to the first project of the Machine Learning Engineer Nanodegree! In this notebook, some template code has already been provided for you, and you will need to implement additional functionality to successfully complete this project. You will not need to modify the included code beyond what is requested. Sections that begin with 'Implementation' in the header indicate that the following block of code will require additional functionality which you must provide. Instructions will be provided for each section and the specifics of the implementation are marked in the code block with a 'TODO' statement. Please be sure to read the instructions carefully!

In addition to implementing code, there will be questions that you must answer which relate to the project and your implementation. Each section where you will answer a question is preceded by a 'Question X' header. Carefully read each question and provide thorough answers in the following text boxes that begin with 'Answer:'. Your project submission will be evaluated based on your answers to each of the questions and the implementation you provide.

Note: Code and Markdown cells can be executed using the Shift + Enter keyboard shortcut. In addition, Markdown cells can be edited by typically double-clicking the cell to enter edit mode.

Getting Started

In this project, you will evaluate the performance and predictive power of a model that has been trained and tested on data collected from homes in suburbs of Boston, Massachusetts. A model trained on this data that is seen as a good fit could then be used to make certain predictions about a home — in particular, its monetary value. This model would prove to be invaluable for someone like a real estate agent who could make use of such information on a daily basis.

The dataset for this project originates from the UCI Machine Learning Repository. The Boston housing data was collected in 1978 and each of the 506 entries represent aggregated data about 14 features for homes from various suburbs in Boston, Massachusetts. For the purposes of this project, the following preprocessing steps have been made to the dataset:

16 data points have an 'MEDV' value of 50.0. These data points likely contain missing or censored values and have been removed.
1 data point has an 'RM' value of 8.78. This data point can be considered an outlier and has been removed.
The features 'RM', 'LSTAT', 'PTRATIO', and 'MEDV' are essential. The remaining non-relevant features have been excluded.
The feature 'MEDV' has been multiplicatively scaled to account for 35 years of market inflation.

Run the code cell below to load the Boston housing dataset, along with a few of the necessary Python libraries required for this project. You will know the dataset loaded successfully if the size of the dataset is reported.



In [1]:

    
# Import libraries necessary for this project
import numpy as np
import pandas as pd
from sklearn.model_selection import ShuffleSplit

# Import supplementary visualizations code visuals.py
import visuals as vs

# Pretty display for notebooks
%matplotlib inline

# Load the Boston housing dataset
data = pd.read_csv('housing.csv')
prices = data['MEDV']
features = data.drop('MEDV', axis = 1)
    
# Success
print("Boston housing dataset has {} data points with {} variables each.".format(*data.shape))









    



Boston housing dataset has 489 data points with 4 variables each.

Data Exploration

In this first section of this project, you will make a cursory investigation about the Boston housing data and provide your observations. Familiarizing yourself with the data through an explorative process is a fundamental practice to help you better understand and justify your results.

Since the main goal of this project is to construct a working model which has the capability of predicting the value of houses, we will need to separate the dataset into features and the target variable. The features, 'RM', 'LSTAT', and 'PTRATIO', give us quantitative information about each data point. The target variable, 'MEDV', will be the variable we seek to predict. These are stored in features and prices, respectively.

Implementation: Calculate Statistics

For your very first coding implementation, you will calculate descriptive statistics about the Boston housing prices. Since numpy has already been imported for you, use this library to perform the necessary calculations. These statistics will be extremely important later on to analyze various prediction results from the constructed model.

In the code cell below, you will need to implement the following:

Calculate the minimum, maximum, mean, median, and standard deviation of 'MEDV', which is stored in prices.
- Store each calculation in their respective variable.



In [2]:

    
# TODO: Minimum price of the data
minimum_price = np.min(prices)

# TODO: Maximum price of the data
maximum_price = np.max(prices)

# TODO: Mean price of the data
mean_price = np.mean(prices)

# TODO: Median price of the data
median_price = np.median(prices)

# TODO: Standard deviation of prices of the data
std_price = np.std(prices)

# Show the calculated statistics
print("Statistics for Boston housing dataset:\n")
print("Minimum price: ${}".format(minimum_price)) 
print("Maximum price: ${}".format(maximum_price))
print("Mean price: ${}".format(mean_price))
print("Median price ${}".format(median_price))
print("Standard deviation of prices: ${}".format(std_price))









    



Statistics for Boston housing dataset:

Minimum price: $105000.0
Maximum price: $1024800.0
Mean price: $454342.9447852761
Median price $438900.0
Standard deviation of prices: $165171.13154429474

Question 1 - Feature Observation

As a reminder, we are using three features from the Boston housing dataset: 'RM', 'LSTAT', and 'PTRATIO'. For each data point (neighborhood):

'RM' is the average number of rooms among homes in the neighborhood.
'LSTAT' is the percentage of homeowners in the neighborhood considered "lower class" (working poor).
'PTRATIO' is the ratio of students to teachers in primary and secondary schools in the neighborhood.

Using your intuition, for each of the three features above, do you think that an increase in the value of that feature would lead to an increase in the value of 'MEDV' or a decrease in the value of 'MEDV'? Justify your answer for each.

Hint: This problem can phrased using examples like below.

Would you expect a home that has an 'RM' value(number of rooms) of 6 be worth more or less than a home that has an 'RM' value of 7?
Would you expect a neighborhood that has an 'LSTAT' value(percent of lower class workers) of 15 have home prices be worth more or less than a neighborhood that has an 'LSTAT' value of 20?
Would you expect a neighborhood that has an 'PTRATIO' value(ratio of students to teachers) of 10 have home prices be worth more or less than a neighborhood that has an 'PTRATIO' value of 15?

Answer:

I expect a home that has an 'RM' value(number of rooms) of 6 to be worth more than a home that has an 'RM' value of 7, because generally more rooms means higher square footage and higher construction expenditure.
I expect a neighborhood that has an 'LSTAT' value(percent of lower class workers) of 15 to have their home prices worth more than a neighborhood that has an 'LSTAT' value of 20, because higher income people generally prefer to stay in a neighborhood of higher income people and houses bought by higher income people will be generally more expensive as they can afford more.
I expect a neighborhood that has an 'PTRATIO' value(ratio of students to teachers) of 10 to have home prices be worth more than a neighborhood that has an 'PTRATIO' value of 15, because education will generally be better in a place with 10 students per teacher than in a place with 15 students per teacher and thus accomodation in such a place can command a premium.

Developing a Model

In this second section of the project, you will develop the tools and techniques necessary for a model to make a prediction. Being able to make accurate evaluations of each model's performance through the use of these tools and techniques helps to greatly reinforce the confidence in your predictions.

Implementation: Define a Performance Metric

It is difficult to measure the quality of a given model without quantifying its performance over training and testing. This is typically done using some type of performance metric, whether it is through calculating some type of error, the goodness of fit, or some other useful measurement. For this project, you will be calculating the coefficient of determination, R², to quantify your model's performance. The coefficient of determination for a model is a useful statistic in regression analysis, as it often describes how "good" that model is at making predictions.

The values for R² range from 0 to 1, which captures the percentage of squared correlation between the predicted and actual values of the target variable. A model with an R² of 0 is no better than a model that always predicts the mean of the target variable, whereas a model with an R² of 1 perfectly predicts the target variable. Any value between 0 and 1 indicates what percentage of the target variable, using this model, can be explained by the features. A model can be given a negative R² as well, which indicates that the model is arbitrarily worse than one that always predicts the mean of the target variable.

For the performance_metric function in the code cell below, you will need to implement the following:

Use r2_score from sklearn.metrics to perform a performance calculation between y_true and y_predict.
Assign the performance score to the score variable.



In [3]:

    
from sklearn.metrics import r2_score

def performance_metric(y_true, y_predict):
    """ Calculates and returns the performance score between 
        true and predicted values based on the metric chosen. """
    
    # Calculate the performance score between 'y_true' and 'y_predict'
    score = r2_score(y_true, y_predict)
    
    # Return the score
    return score

Question 2 - Goodness of Fit

Assume that a dataset contains five data points and a model made the following predictions for the target variable:

True Value	Prediction
3.0	2.5
-0.5	0.0
2.0	2.1
7.0	7.8
4.2	5.3

Run the code cell below to use the performance_metric function and calculate this model's coefficient of determination.



In [4]:

    
# Calculate the performance of this model
score = performance_metric([3, -0.5, 2, 7, 4.2], [2.5, 0.0, 2.1, 7.8, 5.3])
print("Model has a coefficient of determination, R^2, of {:.3f}.".format(score))









    



Model has a coefficient of determination, R^2, of 0.923.

Would you consider this model to have successfully captured the variation of the target variable?
Why or why not?

Hint: The R2 score is the proportion of the variance in the dependent variable that is predictable from the independent variable. In other words:

R2 score of 0 means that the dependent variable cannot be predicted from the independent variable.
R2 score of 1 means the dependent variable can be predicted from the independent variable.
R2 score between 0 and 1 indicates the extent to which the dependent variable is predictable. An
R2 score of 0.40 means that 40 percent of the variance in Y is predictable from X.

Answer: A R2 score of 0.923 means that 92.3 percent pf the variance is predictable from X. So the model has done a good job of successfully capturing the varaiation of the target variable. There may still be some room to improve the model but so far it is doing a very good job.

Implementation: Shuffle and Split Data

Your next implementation requires that you take the Boston housing dataset and split the data into training and testing subsets. Typically, the data is also shuffled into a random order when creating the training and testing subsets to remove any bias in the ordering of the dataset.

For the code cell below, you will need to implement the following:

Use train_test_split from sklearn.model_selection to shuffle and split the features and prices data into training and testing sets.
- Split the data into 80% training and 20% testing.
- Set the random_state for train_test_split to a value of your choice. This ensures results are consistent.
Assign the train and testing splits to X_train, X_test, y_train, and y_test.



In [5]:

    
from sklearn.model_selection import train_test_split

# TODO: Shuffle and split the data into training and testing subsets
X_train, X_test, y_train, y_test = train_test_split(features, 
                                                    prices, 
                                                    test_size=0.2, 
                                                    random_state=7)

# Success
print("Training and testing split was successful.")









    



Training and testing split was successful.

Question 3 - Training and Testing

What is the benefit to splitting a dataset into some ratio of training and testing subsets for a learning algorithm?

Hint: Think about how overfitting or underfitting is contingent upon how splits on data is done.

Answer: Our goal is to create a model that generalizes well to new data. Our test set serves as a representation of new data for testing generalization of model.

The test data is kept completely apart while training so that the model has never 'seen' the test data while training. If the model performs as well on the test data as on the train data then we know the model has not overfit to the training data, and can be expected to perform as well on new data.

If we don't test using a separate test set and only train on only one set to the best performance possible the model will overfit to the training data (like rote learning) and will perform poorly on any new data as the model has only learnt to do best on the train set and not learned to generalize to the behaviour of the whole population.

If a model is underfit, then improving it will imrpove performance on both training set as well as test set.

Analyzing Model Performance

In this third section of the project, you'll take a look at several models' learning and testing performances on various subsets of training data. Additionally, you'll investigate one particular algorithm with an increasing 'max_depth' parameter on the full training set to observe how model complexity affects performance. Graphing your model's performance based on varying criteria can be beneficial in the analysis process, such as visualizing behavior that may not have been apparent from the results alone.

Learning Curves

The following code cell produces four graphs for a decision tree model with different maximum depths. Each graph visualizes the learning curves of the model for both training and testing as the size of the training set is increased. Note that the shaded region of a learning curve denotes the uncertainty of that curve (measured as the standard deviation). The model is scored on both the training and testing sets using R², the coefficient of determination.

Run the code cell below and use these graphs to answer the following question.



In [8]:

    
# Produce learning curves for varying training set sizes and maximum depths
vs.ModelLearning(features, prices)

Question 4 - Learning the Data

Choose one of the graphs above and state the maximum depth for the model.
What happens to the score of the training curve as more training points are added? What about the testing curve?
Would having more training points benefit the model?

Hint: Are the learning curves converging to particular scores? Generally speaking, the more data you have, the better. But if your training and testing curves are converging with a score above your benchmark threshold, would this be necessary? Think about the pros and cons of adding more training points based on if the training and testing curves are converging.

Answer:

max_depth = 3:
- This is the ideal balanced scenario, when the model generalizes well and doesn't have high bias or high variance.
- Training score descreases slightly as more training points are added as the model generalizes better and the overfitting decreases.
  - It plateaus at a high value of about ~0.8, which is a good model performance
  - After plateauing, adding more data may not further improve the training score significantly
- Testing score improves a lot as more training points are added as the model generalizes better with more examples.
  - It plateaus at a high value of about ~0.8, which is a good model performance
  - After plateauing, adding more data may not further improve the testing score significantly
  - The model performs as well on the test data as on the train data, which is the ideal balance
- Having more data increases the performance of the model, but after a certain amount of data the performance plateaus and adding more data may not further improve the performance significantly.

Complexity Curves

The following code cell produces a graph for a decision tree model that has been trained and validated on the training data using different maximum depths. The graph produces two complexity curves — one for training and one for validation. Similar to the learning curves, the shaded regions of both the complexity curves denote the uncertainty in those curves, and the model is scored on both the training and validation sets using the performance_metric function.

Run the code cell below and use this graph to answer the following two questions Q5 and Q6.



In [9]:

    
vs.ModelComplexity(X_train, y_train)

Question 5 - Bias-Variance Tradeoff

When the model is trained with a maximum depth of 1, does the model suffer from high bias or from high variance?
How about when the model is trained with a maximum depth of 10? What visual cues in the graph justify your conclusions?

Hint: High bias is a sign of underfitting(model is not complex enough to pick up the nuances in the data) and high variance is a sign of overfitting(model is by-hearting the data and cannot generalize well). Think about which model(depth 1 or 10) aligns with which part of the tradeoff.

Answer:

When the model is trained with a maximum depth of 1, the model suffers from high bias. In this case, both training score and validation score are similar but very low, infact both are below 0.5, so arbitralily worse than simple average. So this is a case where the model is not complex enough to picl up the nuances in the data.
The model is trained with a maximum depth of 10, the model suffers from high variance. In this case, training score is very high and testing score is low. Thus the model is overfitting to the training data and by-hearting it and cannot generalize well.

Question 6 - Best-Guess Optimal Model

Which maximum depth do you think results in a model that best generalizes to unseen data?
What intuition lead you to this answer?

Hint: Look at the graph above Question 5 and see where the validation scores lie for the various depths that have been assigned to the model. Does it get better with increased depth? At what point do we get our best validation score without overcomplicating our model? And remember, Occams Razor states "Among competing hypotheses, the one with the fewest assumptions should be selected."

Answer: The maximum depth of 4

This is where the validation score is maximum, so it seems to be the point where model has reached it's best generalization ability.
At max depth 4, the model is not too complex.
Though the difference between training and testing performance increases, the difference is not high and the model doesn't seem to be suffering from high variance scenario.

Evaluating Model Performance

In this final section of the project, you will construct a model and make a prediction on the client's feature set using an optimized model from fit_model.

Question 7 - Grid Search

What is the grid search technique?
How it can be applied to optimize a learning algorithm?

Hint: When explaining the Grid Search technique, be sure to touch upon why it is used, what the 'grid' entails and what the end goal of this method is. To solidify your answer, you can also give an example of a parameter in a model that can be optimized using this approach.

Answer:

The grid search technique exhaustively tries every possible combination of provided hyper-paramter values in order to determine the hyperparameter set that yields the best generalized performance from the model for the given data. The performance for each hyperparameter set is calculated on cross-validation training.
The 'grid' here refers to all possible permuations of all values given for a set of hyperparameters.
If for a particular machine learning technique, I want to choose the ideal model complexity, so that my model generalizes well, performance is the best value that can be achieved with said technique without increasing the model complexity too much, I would run a grid search on the model hyperparameters to decide on the ideal model complexity.
For example, in the given sample model above, running a grid search on many values of max_depth gives us the change in model performance according to changing max depth. With this information we can make a decision on which model complexity to use to get the best results.

Question 8 - Cross-Validation

What is the k-fold cross-validation training technique?
What benefit does this technique provide for grid search when optimizing a model?

Hint: When explaining the k-fold cross validation technique, be sure to touch upon what 'k' is, how the dataset is split into different parts for training and testing and the number of times it is run based on the 'k' value.

When thinking about how k-fold cross validation helps grid search, think about the main drawbacks of grid search which are hinged upon using a particular subset of data for training or testing and how k-fold cv could help alleviate that. You can refer to the docs for your answer.

Answer: K-fold cross validation:

Dataset is devided into k subsets of equal size
K iterations of traning & testing are run, where in each iteration a new subset is kept as the testing set and the remaining k-1 subsets form the training set. So, each subset acts as the testing set 1 time, and acts as the training set K-1 times.
Average testing performance is used as the estimate of out-of-sample(forecasting for an observation that was not part of the training sample) performance, also known as cross-validated performance.

Benefits in grid search:

Evaluating different hyperparameters for a model can still a risk of overfitting on the test set because the parameters can be tweaked until the estimator performs optimally.
- This way, knowledge about the test set can “leak” into the model.
- This can be solved by partioning data into 3 sets: training set, validation set and test set. After doing all training and testing on the training set and validation sets respectively, final evaluation can be done on test set which wasn't touched before this.
- However, partitioning the data into three sets drastically reduces the number of samples which can be used for learning the model, and the results can depend on a particular random choice for the pair of (train, validation) sets.
Cross-validation solves this as a test set is still held out for final evaluation, but the validation set is no longer needed when doing CV.
CV can be computationally expensive, but does not waste too much data, as the training set is fully utilized for training without overfitting on it by training and validating on a different slice of the training data in each iteration and averaging the results.

Implementation: Fitting a Model

Your final implementation requires that you bring everything together and train a model using the decision tree algorithm. To ensure that you are producing an optimized model, you will train the model using the grid search technique to optimize the 'max_depth' parameter for the decision tree. The 'max_depth' parameter can be thought of as how many questions the decision tree algorithm is allowed to ask about the data before making a prediction. Decision trees are part of a class of algorithms called supervised learning algorithms.

In addition, you will find your implementation is using ShuffleSplit() for an alternative form of cross-validation (see the 'cv_sets' variable). While it is not the K-Fold cross-validation technique you describe in Question 8, this type of cross-validation technique is just as useful!. The ShuffleSplit() implementation below will create 10 ('n_splits') shuffled sets, and for each shuffle, 20% ('test_size') of the data will be used as the validation set. While you're working on your implementation, think about the contrasts and similarities it has to the K-fold cross-validation technique.

For the fit_model function in the code cell below, you will need to implement the following:

Use DecisionTreeRegressor from sklearn.tree to create a decision tree regressor object.
- Assign this object to the 'regressor' variable.
Create a dictionary for 'max_depth' with the values from 1 to 10, and assign this to the 'params' variable.
Use make_scorer from sklearn.metrics to create a scoring function object.
- Pass the performance_metric function as a parameter to the object.
- Assign this scoring function to the 'scoring_fnc' variable.
Use GridSearchCV from sklearn.model_selection to create a grid search object.
- Pass the variables 'regressor', 'params', 'scoring_fnc', and 'cv_sets' as parameters to the object.
- Assign the GridSearchCV object to the 'grid' variable.



In [10]:

    
from sklearn.tree import DecisionTreeRegressor
from sklearn.metrics import make_scorer
from sklearn.model_selection import GridSearchCV

def fit_model(X, y):
    """ Performs grid search over the 'max_depth' parameter for a 
        decision tree regressor trained on the input data [X, y]. """
    
    # Create cross-validation sets from the training data
    cv_sets = ShuffleSplit(n_splits = 10, test_size = 0.20, random_state = 7)

    # TODO: Create a decision tree regressor object
    regressor = DecisionTreeRegressor()

    # TODO: Create a dictionary for the parameter 'max_depth' with a range from 1 to 10
    params = {'max_depth': range(1,11)}

    # TODO: Transform 'performance_metric' into a scoring function using 'make_scorer' 
    scoring_fnc = make_scorer(performance_metric)

    # TODO: Create the grid search cv object --> GridSearchCV()
    # Make sure to include the right parameters in the object:
    # (estimator, param_grid, scoring, cv) which have values 'regressor', 'params', 'scoring_fnc', and 'cv_sets' respectively.
    grid = GridSearchCV(regressor, params, scoring=scoring_fnc, cv=cv_sets)

    # Fit the grid search object to the data to compute the optimal model
    grid = grid.fit(X, y)

    # Return the optimal model after fitting the data
    return grid.best_estimator_

Making Predictions

Once a model has been trained on a given set of data, it can now be used to make predictions on new sets of input data. In the case of a decision tree regressor, the model has learned what the best questions to ask about the input data are, and can respond with a prediction for the target variable. You can use these predictions to gain information about data where the value of the target variable is unknown — such as data the model was not trained on.

Question 9 - Optimal Model

What maximum depth does the optimal model have? How does this result compare to your guess in Question 6?

Run the code block below to fit the decision tree regressor to the training data and produce an optimal model.



In [11]:

    
# Fit the training data to the model using grid search
reg = fit_model(X_train, y_train)

# Produce the value for 'max_depth'
print("Parameter 'max_depth' is {} for the optimal model.".format(reg.get_params()['max_depth']))









    



Parameter 'max_depth' is 4 for the optimal model.

Hint: The answer comes from the output of the code snipped above.

Answer: The optimal model has maximum depth of 4, which corresponds to my guess in Question 6

Question 10 - Predicting Selling Prices

Imagine that you were a real estate agent in the Boston area looking to use this model to help price homes owned by your clients that they wish to sell. You have collected the following information from three of your clients:

Feature	Client 1	Client 2	Client 3
Total number of rooms in home	5 rooms	4 rooms	8 rooms
Neighborhood poverty level (as %)	17%	32%	3%
Student-teacher ratio of nearby schools	15-to-1	22-to-1	12-to-1

What price would you recommend each client sell his/her home at?
Do these prices seem reasonable given the values for the respective features?

Hint: Use the statistics you calculated in the Data Exploration section to help justify your response. Of the three clients, client 3 has has the biggest house, in the best public school neighborhood with the lowest poverty level; while client 2 has the smallest house, in a neighborhood with a relatively high poverty rate and not the best public schools.

Run the code block below to have your optimized model make predictions for each client's home.



In [12]:

    
# Produce a matrix for client data
client_data = [[5, 17, 15], # Client 1
               [4, 32, 22], # Client 2
               [8, 3, 12]]  # Client 3

# Show predictions
for i, price in enumerate(reg.predict(client_data)):
    print("Predicted selling price for Client {}'s home: ${:,.2f}".format(i+1, price))









    



Predicted selling price for Client 1's home: $407,232.00
Predicted selling price for Client 2's home: $229,200.00
Predicted selling price for Client 3's home: $979,300.00

Answer: Prices to recommend:

Client 1: $407,300
Client 2: $229,200
Client 3: $979,300

Data exploration findings:

Minimum price: $105000.0

Maximum price: $1024800.0

Mean price: $454342.9447852761

Median price $438900.0

Standard deviation of prices: $165171.13154429474

The recommended prices have been cielinged to the next 100
Using the data exloration results, Client 2 and Client 1 are below the median house price, with Client 1 close to the median price and Client 2 closer to the minimum price. Client 3 house price is very high, close to the maximum price
For Client 1 this seems reasonable owing to not too high no. of rooms, average poverty level and student-to-teacher ratio.
For Client 1 this seems reasonable owing to lower no. of rooms, high poverty level and high student-to-teacher ratio.
For Client 1 this seems reasonable owing to high no. of rooms, very low poverty level and low student-to-teacher ratio.

Sensitivity

An optimal model is not necessarily a robust model. Sometimes, a model is either too complex or too simple to sufficiently generalize to new data. Sometimes, a model could use a learning algorithm that is not appropriate for the structure of the data given. Other times, the data itself could be too noisy or contain too few samples to allow a model to adequately capture the target variable — i.e., the model is underfitted.

Run the code cell below to run the fit_model function ten times with different training and testing sets to see how the prediction for a specific client changes with respect to the data it's trained on.



In [13]:

    
vs.PredictTrials(features, prices, fit_model, client_data)









    



Trial 1: $391,183.33
Trial 2: $411,417.39
Trial 3: $415,800.00
Trial 4: $420,622.22
Trial 5: $413,334.78
Trial 6: $411,931.58
Trial 7: $390,250.00
Trial 8: $407,232.00
Trial 9: $402,531.82
Trial 10: $413,700.00

Range in prices: $30,372.22

Question 11 - Applicability

In a few sentences, discuss whether the constructed model should or should not be used in a real-world setting.

Hint: Take a look at the range in prices as calculated in the code snippet above. Some questions to answering:

How relevant today is data that was collected from 1978? How important is inflation?
Are the features present in the data sufficient to describe a home? Do you think factors like quality of apppliances in the home, square feet of the plot area, presence of pool or not etc should factor in?
Is the model robust enough to make consistent predictions?
Would data collected in an urban city like Boston be applicable in a rural city?
Is it fair to judge the price of an individual home based on the characteristics of the entire neighborhood?

Answer:

Data collected from 1978 may not be higky relevant today as the demographics, people's taste in homes, societal norms have changed since then. Inflation is also important in prices as would be the state of the economy and income distribution of the populace.
The features present in the data are not sufficient to describe a home. Factors like quality of apppliances in the home, square feet of the plot area, presence of pool or not etc should factor in.
The model is somewhat robust, but not very consistent as section 1.7.7 showed there can be a difference in prediction for the same house using this model of as much as '$30,000' which is quite a significant amount.
Data collected in an urban city like Boston may not be applicable in a rural city as demographics, people's taste in homes, societal norms alongwith house structures and sizes and accompanying empty area, etc would all be different.
In a human society, people don't live in isolation. Characteristics of the entire neighborhood would have a significance impact on the quality of life in the house. Although isolation amongst individuals living near each other has increased a lot since 1978.

Note: Once you have completed all of the code implementations and successfully answered each question above, you may finalize your work by exporting the iPython Notebook as an HTML document. You can do this by using the menu above and navigating to
File -> Download as -> HTML (.html). Include the finished document along with this notebook as your submission.