I've been trying to implement **Bayesian Linear Regression** models using `PyMC3`

with *REAL DATA* (i.e. not from linear function + gaussian noise) from the datasets in `sklearn.datasets`

. I chose the regression dataset with the smallest number of attributes (i.e. `load_diabetes()`

) whose shape is `(442, 10)`

; that is, `442 samples`

and `10 attributes`

.

I believe I got the model working, the posteriors look decent enough to try and predict with to figure out how this stuff works but...I realized I have no idea how to predict with these Bayesian Models! I'm trying to avoid using the `glm`

and `patsy`

notation because it's difficult for me to understand what is actually going on when using that.

I tried following: Generating predictions from inferred parameters in pymc3 and also http://pymc-devs.github.io/pymc3/posterior_predictive/ but my model is either extremely terrible at predicting or I'm doing it wrong.

If I actually am doing the prediction correctly (which I'm probably not) then can anyone help me *optimize* my model. I don't know if least `mean squared error`

, `absolute error`

, or anything like that works in Bayesian frameworks. Ideally, I would like to get an array of number_of_rows = the amount of rows in my `X_te`

attribute/data test set, and the number of columns to be samples from the posterior distribution.

```
import pymc3 as pm
import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
import seaborn as sns; sns.set()
from scipy import stats, optimize
from sklearn.datasets import load_diabetes
from sklearn.cross_validation import train_test_split
from theano import shared
np.random.seed(9)
%matplotlib inline
#Load the Data
diabetes_data = load_diabetes()
X, y_ = diabetes_data.data, diabetes_data.target
#Split Data
X_tr, X_te, y_tr, y_te = train_test_split(X,y_,test_size=0.25, random_state=0)
#Shapes
X.shape, y_.shape, X_tr.shape, X_te.shape
#((442, 10), (442,), (331, 10), (111, 10))
#Preprocess data for Modeling
shA_X = shared(X_tr)
#Generate Model
linear_model = pm.Model()
with linear_model:
# Priors for unknown model parameters
alpha = pm.Normal("alpha", mu=0,sd=10)
betas = pm.Normal("betas", mu=0,#X_tr.mean(),
sd=10,
shape=X.shape[1])
sigma = pm.HalfNormal("sigma", sd=1)
# Expected value of outcome
mu = alpha + np.array([betas[j]*shA_X[:,j] for j in range(X.shape[1])]).sum()
# Likelihood (sampling distribution of observations)
likelihood = pm.Normal("likelihood", mu=mu, sd=sigma, observed=y_tr)
# Obtain starting values via Maximum A Posteriori Estimate
map_estimate = pm.find_MAP(model=linear_model, fmin=optimize.fmin_powell)
# Instantiate Sampler
step = pm.NUTS(scaling=map_estimate)
# MCMC
trace = pm.sample(1000, step, start=map_estimate, progressbar=True, njobs=1)
#Traceplot
pm.traceplot(trace)
```

```
# Prediction
shA_X.set_value(X_te)
ppc = pm.sample_ppc(trace, model=linear_model, samples=1000)
#What's the shape of this?
list(ppc.items())[0][1].shape #(1000, 111) it looks like 1000 posterior samples for the 111 test samples (X_te) I gave it
#Looks like I need to transpose it to get `X_te` samples on rows and posterior distribution samples on cols
for idx in [0,1,2,3,4,5]:
predicted_yi = list(ppc.items())[0][1].T[idx].mean()
actual_yi = y_te[idx]
print(predicted_yi, actual_yi)
# 158.646772735 321.0
# 160.054730647 215.0
# 149.457889418 127.0
# 139.875149489 64.0
# 146.75090354 175.0
# 156.124314452 275.0
```