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# Getting the statistics of deterministic variables in PyMC

Say I have a random collection of (X,Y) points:

``````import pymc as pm
import numpy as np
import matplotlib.pyplot as plt
import scipy

x = np.array(range(0,50))
y = np.random.uniform(low=0.0, high=40.0, size=200)
y = map((lambda a: a[0] + a[1]), zip(x,y))

plt.scatter(x,y)
``````

and that I fit simple linear regression:

``````std = 20.
tau=1/(std**2)
alpha = pm.Normal('alpha', mu=0, tau=tau)
beta  = pm.Normal('beta', mu=0, tau=tau)
sigma = pm.Uniform('sigma', lower=0, upper=20)

y_est = alpha + beta * x

likelihood = pm.Normal('y', mu=y_est, tau=1/(sigma**2), observed=True, value=y)

model = pm.Model([likelihood, alpha, beta, sigma, y_est])
mcmc  = pm.MCMC(model)
mcmc.sample(40000, 15000)
``````

How can I get the distribution or the statistics of `y_est[0]`, `y_est[1]`, `y_est[2]`.. (note that these variables correspond to the `y` values estimated for each input `x` value.

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## migrated from stats.stackexchange.comMar 5 '14 at 2:36

This question came from our site for people interested in statistics, machine learning, data analysis, data mining, and data visualization.

In PyMC 2, if you are interested in the trace of a deterministic, you should wrap the deterministic in a `Lambda` object (or decorate a function with `@deterministic`). In your case, this would be:

``````y_est = Lambda('y_est', lambda a=alpha, b=beta: a + b * x)
``````

You should then be able to call the `summary` method or plot the node, just like a Stochastic.

BTW, you do not need to instantiate a `Model` object, as `MCMC` already does that for you. All you need is:

``````mcmc = pm.MCMC([likelihood, alpha, beta, sigma, y_est])
``````

or even more concisely:

``````mcmc = pm.MCMC(vars())
``````
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Thanks Chris - I almost got it to work following your suggestions, but still no luck. I have updated the OP (I must be very close) – Amelio Vazquez-Reina Mar 6 '14 at 0:34

Following @Chris' advice, the following works:

``````x     = pm.Uniform('x', lower=xmin, upper=xmax)
alpha = pm.Normal('alpha', mu=0, tau=tau)
beta  = pm.Normal('beta', mu=0, tau=tau)
sigma = pm.Uniform('sigma', lower=0, upper=20)

# The deterministic:
y_gen = pm.Lambda('y_gen', lambda a=alpha, x=x, b=beta: a + b * x)
``````

And then draw samples from it as follows:

``````mcmc = pm.MCMC([x, y_gen])
mcmc.sample(n_total_samples, n_burn_in)

x_trace = mcmc.trace('x')[:]
y_trace = mcmc.trace('y_gen')[:]
``````
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