I'm trying to learn more about pyhf and my understanding of what the goals are might be limited. I would love to fit my HEP data outside of ROOT, but I could be imposing expectations on pyhf which are not what the authors intended for it's use.

I'd like to write myself a hello-world example, but I might just not know what I'm doing. My misunderstanding could also be gaps in my statistical knowledge.

With that preface, let me explain what I'm trying to explore.

I have some observed set of events for which I calculate some observable and make a binned histogram of that data. I hypothesize that there are two contributing physics processes, which I call signal and background. I generate some Monte Carlo samples for these processes and the theorized total number of events is close to, but not exactly what I observe.

I would like to:

- Fit the data to this two process hypothesis
- Get from the fit the optimal values for the number of events for each process
- Get the uncertainties on these fitted values
- If appropriate, calculate an upper limit on the number of signal events.

My starter code is below, where all I'm doing is an ML fit but I'm not sure where to go. I know it's not set up to do what I want, but I'm getting lost in the examples I find on RTD. I'm sure it's me, this is not a criticism of the documentation.

```
import pyhf
import numpy as np
import matplotlib.pyplot as plt
nbins = 15
# Generate a background and signal MC sample`
MC_signal_events = np.random.normal(5,1.0,200)
MC_background_events = 10*np.random.random(1000)
signal_data = np.histogram(MC_signal_events,bins=nbins)[0]
bkg_data = np.histogram(MC_background_events,bins=nbins)[0]
# Generate an observed dataset with a slightly different
# number of events
signal_events = np.random.normal(5,1.0,180)
background_events = 10*np.random.random(1050)
observed_events = np.array(signal_events.tolist() + background_events.tolist())
observed_sample = np.histogram(observed_events,bins=nbins)[0]
# Plot these samples, if you like
plt.figure(figsize=(12,4))
plt.subplot(1,3,1)
plt.hist(observed_events,bins=nbins,label='Observations')
plt.legend()
plt.subplot(1,3,2)
plt.hist(MC_signal_events,bins=nbins,label='MC signal')
plt.legend()
plt.subplot(1,3,3)
plt.hist(MC_background_events,bins=nbins,label='MC background')
plt.legend()
# Use a very naive estimate of the background
# uncertainties
bkg_uncerts = np.sqrt(bkg_data)
print("Defining the PDF.......")
pdf = pyhf.simplemodels.hepdata_like(signal_data=signal_data.tolist(), \
bkg_data=bkg_data.tolist(), \
bkg_uncerts=bkg_uncerts.tolist())
print("Fit.......")
data = pyhf.tensorlib.astensor(observed_sample.tolist() + pdf.config.auxdata)
bestfit_pars, twice_nll = pyhf.infer.mle.fit(data, pdf, return_fitted_val=True)
print(bestfit_pars)
print(twice_nll)
plt.show()
```

EDITED ------------------------

ADDED FOLLOWING IN RESPONSE TO ANSWER ---------

OK, I guess I can't make a significant comment to your response without editing my original question. Sorry if this all gets confusing.

I'm going to start with Matthew's `anwser.py`

code and make a minor modification. I want to see the results of the fit, so I add some code to weight the original templates by the fit results and replot it with the overlays. The code I added is included below, along with the original code just before it for reference.

```
# Perform inference
fit_result = pyhf.infer.mle.fit(data, model, return_uncertainties=True)
bestfit_pars, par_uncerts = fit_result.T
print(
f"best fit parameters:\
\n * signal strength: {bestfit_pars[0]} +/- {par_uncerts[0]}\
\n * nuisance parameters: {bestfit_pars[1:]}\
\n * nuisance parameter uncertainties: {par_uncerts[1:]}"
)
# Visualize the results
fit_bkg_sample = []
for w,b in zip(bestfit_pars[1:],bkg_sample):
fit_bkg_sample.append(w*b)
fit_signal_sample = bestfit_pars[0]*np.array(signal_sample)
fig, ax = plt.subplots()
fig.set_size_inches(7, 5)
plot_hist(ax, _bins, fit_bkg_sample, label="Background")
plot_hist(ax, _bins, fit_signal_sample, bottom=fit_bkg_sample, label="Signal")
plot_data(ax, _bins, observed_sample)
ax.legend(loc="best")
ax.set_ylim(top=np.max(observed_sample) * 1.4)
ax.set_xlabel("Observable")
ax.set_ylabel("Count")
fig.savefig("components_after_fi.png")
```

Otherwise everything is the same. When I run it, I get the following, where I've also included the original observations/simulation for comparison.

So this all looks good and I think I understand what his happening.

But this leads me to another question, which is better illustrated with a slight variation on your example. If you think this should be another thread question, I can do that.

I'm going to modify the generated simulations and observations such that there are a different number of background events in the simulations and samples. I'm also making the signal more significant. This would be an example where I've not been able to get a good estimation of the background contribution(s).

```
n_bkg = 2000
n_signal = 200
# Generate simulation
bkg_simulation = 10 * np.random.random(n_bkg)
signal_simulation = np.random.normal(5, 1.0, n_signal)
bkg_sample, _ = np.histogram(bkg_simulation, bins=_bins)
signal_sample, _ = np.histogram(signal_simulation, bins=_bins)
# Generate observations
signal_events = np.random.normal(5, 1.0, int(n_signal * 0.8))
bkg_events = 10 * np.random.random(n_bkg - 300)
```

The fit isn't great, and I wouldn't expect it to be since I locked down the number of background events, modulo the Poisson fluctuations in each bin. The relevant plots (before/after fit) are shown here.

I might have thought another way to approach this would be to add another non-nuisance, floating parameter that represents the background strength, while still letting the individual bins vary within Poisson fluctuations. For that matter, couldn't (shouldn't?) the signal bins fluctuate as well?

In that case, I could start with my simulated samples having a vastly larger number of events to get the more "true" (I know that's not rigorous) distribution. Once the fit drives the number of signal/background events down, Poisson fluctuations become more significant.

I'm sure the optimization/minimization of the likelihood function becomes much more difficult but it also feels like we're constraining the fit too early if we lock down the bulk background normalization. Or maybe I'm missing something?

Thanks as always for your help and response!