I'm unable to replicate results from provided BUGS code using PyMC. The BUGS model is the Andersen-Gill multiplicative intensity Cox PH model.

```
model
{
# Set up data
for(i in 1:Nsubj) {
for(j in 1:T) {
# risk set = 1 if obs.t >= t
Y[i,j] <- step(obs.t[i] - t[j] + eps)
# counting process jump = 1 if obs.t in [ t[j], t[j+1] )
# i.e. if t[j] <= obs.t < t[j+1]
dN[i, j] <- Y[i, j] * step(t[j + 1] - obs.t[i] - eps) * FAIL[i]
}
Useless[i] <- pscenter[i] + hhcenter[i] + ncomact[i]
+ rleader[i] + dleader[i] + inter1[i] + inter2[i]
}
# Model
for(j in 1:T) {
for(i in 1:Nsubj) {
dN[i, j] ~ dpois(Idt[i, j]) # Likelihood
Idt[i, j] <- Y[i, j] * exp(beta[1]*pscenter[i] + beta[2]*
hhcenter[i] + beta[3]*ncomact[i] + beta[4]*rleader[i] + beta[5]*dleader[i] + beta[6]*inter1[i] + beta[7]*inter2[i]) * dL0[j] # Intensity
}
dL0[j] ~ dgamma(mu[j], c)
mu[j] <- dL0.star[j] * c # prior mean hazard
}
c ~ dgamma(0.0001, 0.00001)
r ~ dgamma(0.001, 0.0001)
for (j in 1 : T) { dL0.star[j] <- r * (t[j + 1] - t[j]) }
# next line indicates number of covariates and is for the corresponding betas
for(i in 1:7) {beta[i] ~ dnorm(0.0,0.00001)}
}
```

I use the following initial values

```
list(beta=c(-.36,-.26,-.29,-.22,-.61,-9.73,-.23), c=0.01, r=0.01, dL0=c(1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1))
```

I use a single chain (for now) and 5000 iterations for burn-in. I run the estimation for 10000 additional iterations and receive the same point estimates as reported in the paper. These are also close to earlier frequentist estimates.

```
OpenBUGS> samplesStats('beta')
mean sd MC_error val2.5pc median val97.5pcstart sample
beta[1] 3.466 0.8906 0.03592 1.696 3.48 5.175 501 9500
beta[2] -0.04155 0.06253 0.002487 -0.1609 -0.04355 0.08464 501 9500
beta[3] -0.009709 0.07353 0.002008 -0.1544 -0.01052 0.1365 501 9500
beta[4] 0.3535 0.1788 0.004184 -0.01523 0.3636 0.6724 501 9500
beta[5] 0.08454 0.1652 0.004261 -0.2464 0.08795 0.3964 501 9500
beta[6] -4.109 1.325 0.05224 -6.617 -4.132 -1.479 501 9500
beta[7] 0.1413 0.08594 0.003381 -0.03404 0.1423 0.3031 501 9500
OpenBUGS> samplesStats('c')
mean sd MC_error val2.5pc median val97.5pcstart sample
c 4.053 1.08 0.02896 2.202 3.974 6.373 1001 10000
OpenBUGS> samplesStats('r')
mean sd MC_error val2.5pc median val97.5pcstart sample
r 0.01162 0.002929 7.846E-5 0.007387 0.01119 0.01848 1001 10000
```

I tried to replicate this in PyMC 2.3.2 with the following code. Full replication code is available here

```
def cox_model(dta):
(t, obs_t, pscenter, hhcenter, ncomact, rleader,
dleader, inter1, inter2, fail) = load_data_cox()
T = len(t) - 1
nsubj = len(obs_t)
# risk set equals one if obs_t >= t
Y = np.array([[int(obs >= time) for time in t] for obs in obs_t])
# counting process. jump = 1 if obs_t \in [t[j], t[j+1])
dN = np.array([[Y[i,j]*int(t[j+1] >= obs_t[i])*fail[i] for i in range(nsubj)] for j in range(T)])
c = Gamma('c', .0001, .00001, value=.1)
r = Gamma('r', .001, .0001, value=.1)
dL0_star = r*np.array([t[j+1] - t[j] for j in range(T)])
mu = dL0_star * c # prior mean hazard
dL0 = Gamma('dL0', mu, c, value=np.ones(T))
beta = Normal('beta', np.zeros(7), np.ones(7)*.00001,
value=np.array([-.36, -.26, -.29, -.22, -.61, -9.73, -.23]))
@deterministic
def idt(b1=beta, dl0=dL0):
mu_ = [[Y[i,j] * np.exp(b1[0]*pscenter[i] + b1[1]*hhcenter[i] +
b1[2]*ncomact[i] + b1[3]*rleader[i] +
b1[4]*dleader[i] + b1[5]*inter1[i] +
b1[6]*inter2[i])*dl0[j] for i in range(nsubj)]
for j in range(T)] # intensity
return mu_
dn_like = Poisson('dn_like', idt, value=dN, observed=True)
return locals()
m = MCMC(cox_model())
m.sample(15000)
```

However, I do not come close to the same point estimates. I get something like

```
beta:
Mean SD MC Error 95% HPD interval
------------------------------------------------------------------
-0.537 1.094 0.099 [-2.549 1.492]
0.276 0.048 0.004 [ 0.184 0.36 ]
-1.092 0.385 0.038 [-1.559 -0.371]
-1.461 0.746 0.073 [-2.986 -0.496]
-1.865 0.382 0.038 [-2.471 -1.329]
3.778 1.539 0.133 [ 1.088 6.623]
-0.449 0.109 0.01 [-0.661 -0.26 ]
Posterior quantiles:
2.5 25 50 75 97.5
|---------------|===============|===============|---------------|
-2.892 -1.274 -0.385 0.268 1.253
0.191 0.244 0.278 0.305 0.374
-1.553 -1.434 -1.179 -0.793 -0.258
-3.132 -1.856 -1.196 -0.904 -0.526
-2.471 -2.199 -1.864 -1.632 -1.201
1.287 2.685 3.601 4.72 7.262
-0.714 -0.519 -0.445 -0.368 -0.273
```

Most worryingly, the signs are different. I thought maybe it was just a convergence issue, so I ran it overnight with 50,000 iterations without much change. Maybe there's some bug or difference in my PyMC model, particularly with the dL0 specification?

I've tried with different starting values. I've tried letting the model run for many iterations. I've centered the priors on the point estimates from BUGS.