# Linear regression with pymc3 and belief

I am trying to grasp Bayesain statistics with `pymc3`

I ran this code for a simple linear regression

``````#Generating data y=a+bx
import pymc3
import numpy as np
N=1000
alpha,beta, sigma = 2.0, 0.5, 1.0
np.random.seed(47)
X = np.linspace(0, 1, N)
Y = alpha + beta*X + np.random.randn(N)*sigma

#Fitting
linear_model = pymc3.Model()
with linear_model:
alpha = pymc3.Normal('alpha', mu=0, sd=10)
beta = pymc3.Normal('beta', mu=0, sd=10)
sigma = pymc3.HalfNormal('sigma', sd=1)
mu = alpha + beta*X
Y_obs = pymc3.Normal('Y_obs', mu=mu, sd=sigma, observed=Y)

start = pymc3.find_MAP(fmin=optimize.fmin_powell)
step = pymc3.NUTS(scaling=start)
trace = pymc3.sample(500, step, start=start)
``````

I dont understand what does the trace stand for

If I understand the Bayesian theory well enough, there supposed to be a `belief` function that gets `alpha`,`beta` and `sigma` and outputs the probability of their combination.

How can I get this `belief` structure out of the `trace` variables ?

The `trace` is the output of the Markov Chain Monte Carlo (MCMC) process. It converges to a distribution (e.g., belief) of your parameters, given the data.

You can view the trace using:

``````pymc3.traceplot(trace, vars=['alpha', 'beta', 'sigma'])
``````

If you would like to see the individual realizations of your regression along each point of the trace, you can do something like this:

``````import matplotlib.pyplot as plt

a = trace['alpha']
b = trace['beta']
x = np.linspace(0,1,N)

fig = plt.figure(figsize=(12,4))

plt.scatter(X,Y, color='g', alpha=0.3)
for i in xrange(500):
y = a[i] + b[i] * x
plt.plot(x, y, 'b', alpha=0.02)

Note: It appears that your code is missing the line: `from scipy import optimize`