https://blog.tensorflow.org/2018/10/industrial-ai-bhges-physics-based.html?hl=es_419

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octubre 11, 2018 —
*By Arun Subramaniyan, VP Data Science & Analytics at BHGE Digital*

Baker Hughes, a GE Company (BHGE), is the world’s leading fullstream oil and gas company with a mission to find better ways to deliver energy to the world. The BHGE Digital team develops enterprise grade, AI-driven, SaaS solutions to improve efficiency and reduce non-productive time for the oil and gas industry. Consider missio…

Industrial AI: BHGE’s Physics-based, Probabilistic Deep Learning Using TensorFlow Probability — Part 1

Baker Hughes, a GE Company (BHGE), is the world’s leading fullstream oil and gas company with a mission to find better ways to deliver energy to the world. The BHGE Digital team develops enterprise grade, AI-driven, SaaS solutions to improve efficiency and reduce non-productive time for the oil and gas industry. Consider mission-critical issues such as predicting the failure of a gas turbine or optimizing a large system like a petrochemical plant; these issues require building and maintaining sophisticated analytics at scale. We have developed an analytics-driven strategy to enable company-wide digital transformation for our customers.

Through years of solving the hardest problems facing the industrial world, we have learned that the most elegant and enduring solutions lie at the intersection of:

- domain knowledge
- traditional machine learning (ML)
- probabilistic techniques
- deep learning

Classes of problems that were previously intractable are now solvable by combining seemingly unrelated techniques and deploying them with modern scalable software and hardware. Our collaboration with the TensorFlow Probability (TFP) team and the Cloud ML teams at Google has accelerated our journey to develop and deploy these techniques at scale.

We intend to showcase the innovations occurring at these intersections with this series of blogs and hope to motivate a Cambrian explosion in industrial applications of probabilistic deep learning techniques. An example set of these applications that we showcased at Google Next 2018 can be viewed here.

For example, take the “simple” case of a projectile’s trajectory. To predict the location where a projectile would land, the only observation (“data”) required to make an accurate prediction is the velocity (speed and angle) with which the projectile is thrown. However, adding a small uncertainty (~5%) in the initial angle and wind speed introduces a large uncertainty (~200%) to where the projectile will land, as shown in the figure below.

- Domain expertise (i.e., physics) combined with traditional ML allows us to solve known problems precisely, a.k.a
. By**known knowns***traditional ML*, we are referring to techniques such as polynomial regression, kernel density methods, and state-space estimation methods (e.g. Kalman filters). Predicting the length of a crack in a component under various thermo-mechanical loads is an example of domain expertise: it requires a thorough understanding of the physics of the problem combined with knowledge of the boundary conditions such as temperature and pressure. Even when the phenomenon is well understood, there are several traditional ML techniques that are required to compute coefficients that are specific to the problem (e.g. material properties). - Probabilistic inference provides a systematic way to quantify uncertainty, a.k.a.
. In the example above, in addition to understanding the phenomena, we also need to account for uncertainty in measurements and un-modeled factors like manufacturing variability. It is well known that there are variabilities (uncertainty) in the system that will affect the crack growth. Predicting crack length then becomes an uncertainty quantification exercise. More specifically, the material property calibration becomes a probabilistic inference problem when we add uncertainty to the measurements.**known unknowns** - Deep learning and modern ML have the potential to identify and predict unknown patterns and behavior, a.k.a
. In the crack propagation example, even with probabilistic inference coupled with domain models, we can predict the crack propagating only under a particular set of loading conditions with known uncertainties. Consider an anomaly detection model based on an auto-encoder that monitors the loading conditions along with a variety of other conditions on the equipment. This deep learning model can catch anomalous conditions that the physics-based model would not pick up. The reason we denote this prediction as an**unknown unknowns***unknown unknow*n is because we don’t have any data on the anomaly to train the model. Though the deep learning model trains on data from normal operation (and some abnormalities for validation), it catches any deviation from the normal behavior that was previously not observed. This is one of many examples where deep learning models come in handy. One can argue that in some cases, a simple anomaly detection model based on traditional techniques such as a PCA reconstruction error can also do the trick. In our experience, simpler techniques can provide similar or sometimes better performance than deep learning models when known process characteristics align with the simplifying assumptions of these methods, leading to known anomalies. Deep learning models really shine when the anomalies are not known a priori — when you’ve not seen a particular failure mode before.

In this article, we will focus on probabilistic inference with domain models for predicting

Probabilistic deep learning allows us to leverage all of the capabilities highlighted above in a “self-learning” package. We will address probabilistic deep learning with TFP in our subsequent blogs, which will cover model discrepancy, anomaly detection, missing data estimation and time series forecasting.

The phenomenon of fatigue crack propagation can be modeled with Paris’ law. Paris’ law relates the rate of crack growth (da/dN) to the stress intensity factor (ΔK=Δσ√𝜋a) through the equation below:

where

Integrating Paris’ law for a specific geometry and loading configuration, we arrive at the analytical formulation for the size of a crack as a function of the loading cycle as shown below:

where

The parameters

In this example, we will use the sample dataset from the PHM book by Kim, An and Choi, demonstrating a probabilistic calibration of

Pictured in the diagram below, we have the dataset provided in the Table 4.2 of the PHM book by Kim, An and Choi. As is typical for most crack propagation datasets, the underlying trends are not quite obvious from the observed data points.

For Bayesian calibration, we need to define the prior distributions for the calibration variables. In a real application, these priors can be informed by a subject matter expert. For this example, we will assume that both

In TFP, we can encode this information as follows:

```
prio_par_logC = [-23., 1.1] # [location, scale] for Normal Prior
prio_par_m = [4., 0.2] # [location, scale] for Normal Prior
rv_logC = tfd.Normal(loc=0., scale=1., name='logC_norm')
rv_m = tfd.Normal(loc=0., scale=1., name='m_norm')
```

We have defined external parameters and standard Normal distributions for both variables, just to sample from a normalized space. Therefore, we will need to de-normalize both random variables when computing the crack model.Now we define the joint log probability for the random variables being calibrated and the associated crack model defined by Equation 2:

```
def joint_log_prob(cycles, observations, y0, logC_norm, m_norm):
# Joint logProbability function for both random variables and observations.
# Some constants
dsig = 75.
B = tf.constant(dsig * np.pi**0.5, tf.float32)
# Computing m and logC on original space
logC = logC_norm * prio_par_logC[1]**0.5+ prio_par_logC[0] #
m = m_norm * prio_par_m[1]**0.5 + prio_par_m[0]
# Crack Propagation model
crack_model =(cycles * tf.exp(logC) * (1 - m / 2.) * B**m + y0**(1-m / 2.))**(2. / (2. - m))
y_model = observations - crack_model
# Defining child model random variable
rv_model = tfd.Independent(
tfd.Normal(loc=tf.zeros(observations.shape), scale=0.001),
reinterpreted_batch_ndims=1, name = 'model')
# Sum of logProbabilities
return rv_logC.log_prob(logC_norm) + rv_m.log_prob(m_norm) + rv_model.log_prob(y_model)
```

Finally, it is time to set up the sampler and run a TensorFlow session:```
# This cell can take 12 minutes to run in Graph mode
# Number of samples and burnin for the MCMC sampler
samples = 10000
burnin = 10000
# Initial state for the HMC
initial_state = [0., 0.]
# Converting the data into tensors
cycles = tf.convert_to_tensor(t_,tf.float32)
observations = tf.convert_to_tensor(y_,tf.float32)
y0 = tf.convert_to_tensor(y_[0], tf.float32)
# Setting up a target posterior for our joint logprobability
unormalized_target_posterior= lambda *args: joint_log_prob(cycles, observations, y0, *args)
# And finally setting up the mcmc sampler
[logC_samples, m_samples], kernel_results = tfp.mcmc.sample_chain(
num_results= samples,
num_burnin_steps= burnin,
current_state=initial_state,
kernel= tfp.mcmc.HamiltonianMonteCarlo(
target_log_prob_fn=unormalized_target_posterior,
step_size = 0.045,
num_leapfrog_steps=6))
# Tracking the acceptance rate for the sampled chain
acceptance_rate = tf.reduce_mean(tf.to_float(kernel_results.is_accepted))
# Actually running the sampler
# The evaluate() function, defined at the top of this notebook, runs `sess.run()`
# in graph mode and allows code to be executed eagerly when Eager mode is enabled
[logC_samples_, m_samples_, acceptance_rate_] = evaluate([
logC_samples, m_samples, acceptance_rate])
# Some initial results
print('acceptance_rate:', acceptance_rate_)
```

The damage (in this case crack length) is known to be skewed, thus log normal or Gumbel distributions are commonly used to model damage. Expressing the model in TFP looks like this:

```
def posterior(logC_samples, m_samples, time):
n_s = len(logC_samples)
n_inputs = len(time)
# Some Constants
dsig = 75.
B = tf.constant(dsig * np.pi**0.5, tf.float32)
# Crack Propagation model - compute in the log space
y_model =(
time[:,None] *
tf.exp(logC_samples[None,:])*
(1-m_samples[None,:]/2.0) *B**m_samples[None,:] +y0** (1-m_samples[None,:]/2.0))**(2. / (2. - m_samples[None,:]))
noise = tfd.Normal(loc=0., scale=0.001)
samples = y_model + noise.sample(n_s)[tf.newaxis,:]
# The evaluate() function, defined at the top of this notebook, runs `sess.run()`
# in graph mode and allows code to be executed eagerly when Eager mode is enabled
samples_ = evaluate(samples)
return samples_
# Predict for a range of cycles
time = np.arange(0, 3000, 100)
y_samples = posterior(logC_samples_scale, m_samples_scale, time)
print(y_samples.shape)
```

The predicted mean with the 95% uncertainty bounds of crack length using the hybrid-physics-probabilistic model is shown below. Clearly, the model captures not only the mean behavior but also an estimate of uncertainty of the model predictions for every time point. As we move away from the observations, the uncertainty in the model predictions increases exponentially.Another subtle point is the way the likelihood is defined. We have chosen to define it on the prediction errors rather than the predicted value directly. Note that the individual blue lines depicted below in “Likelihood based on prediction error” are samples of the model prediction errors. Changing the formulation to model predictions directly — instead of the prediction errors — produces non-monotonic, non-physical results as shown in “Likelihood based on actual predictions”. We call these results non-physical because crack lengths cannot decrease over time. If we were to look at just the “smeared” percentile view shown above, we might not notice the subtle difference in model formulations that could lead to large prediction errors. We will address some of these more practical challenges and their mitigation in the next blogs.

This is the first of a series of blogs aimed at expanding the use of probabilistic and deep learning techniques for industrial applications with TFP. We (@sarunkarthi) would love to hear about your applications and look forward to seeing these methods used in unique ways. Stay tuned to this blog feed for more updates and examples on anomaly detection, missing data estimation, and forecasting with variational inference.

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Industrial AI: BHGE’s Physics-based, Probabilistic Deep Learning Using TensorFlow Probability — Part 1

octubre 11, 2018
—
*By Arun Subramaniyan, VP Data Science & Analytics at BHGE Digital*

Baker Hughes, a GE Company (BHGE), is the world’s leading fullstream oil and gas company with a mission to find better ways to deliver energy to the world. The BHGE Digital team develops enterprise grade, AI-driven, SaaS solutions to improve efficiency and reduce non-productive time for the oil and gas industry. Consider missio…

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