BIO
Michael Burke is a consultant with The MathWorks and former coordinator for the MathWorks Automotive Advisory Board (MAAB). I currently focus on Model-Based Design Process Adoption and Establishment projects. Views expressed in this article do not represent the views of The MathWorks.

Handing a model off between developers, or from developer to user, is one most common tasks in Model-Based Design. So what steps should you follow to insure that the hand-off is successful?

Step 0: Agree upon the requirements

A few weeks ago I made muffins, lemon poppy-seed; while my wife was happy to receive the muffins she had requested chocolate-chip muffins, a classic requirement error.

In the much simpler world of model hand off the following items need to be defined

The functional interface: inputs, outputs and rate of execution

Behavioral characteristics: what behaviors does the model cover; what are the “corner cases” that it does not cover.

Supporting files: most models require models, libraries and data. For parameterized models the same “model” will act differently with different data.

Acceptance criteria: a set of defined metrics that define what is required; these should be derived from the behavioral characteristics.

Step 1: Model validation

Assuming you have acceptance criteria the model validation is the process of validating the model against the criteria. Ideally the methods for validating the model are established at the start of your project and are run routinely as the model is developed.

Step 2: Wrap it up!

Delivery of the model is important, there is nothing more frustrating then getting your shinny new model only to find out you are missing a library or a data file. There are several methods for addressing this

Version control software: If the model is checked in as part of a project the end user can check out the full repository (note: this can result in file bloat)

Use of Simulink Projects:A tool from the MathWorks that allows for the definition of model projects. It will analyze the required files for you and create a package for distribution.

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If you work in the controls design space then the PID (Proportional, Integral, Derivative) control element is an old friend. For those of you who do not work in the domain here is a quick overview.

Observe and correct errors

A PID controller can be viewed as an optimization function with three terms. The system attempts to minimize the error between the observed and desired values.

P term: The greater the relative error the stronger the command

I term: The longer the error goes on the stronger the command

D term: The greater the change in the error the more the command changes

All wound upI

Integral windup refers to the situation in a PID feedback controller where a large change in setpoint occurs (say a positive change) and the integral terms accumulates a significant error during the rise. This results in overshooting the target. Over time the error (now negative) will drive the integral to zero however this will result in an extended period of time in error. There are several solution, including this one as documented by The MathWorks

Derivative work

The derivative term in the PID control “dampens” the rate of change of the error term. However, due to difficulties in tuning systems with derivative terms this is often left out of the control algorithm

Overview of all terms

Rise time: How long it takes the system to reach the target value

Overshoot: How much the model goes “past” the target value”

Settling time: How long it takes the system to zero out the error

Steady state error: What is the final error (can it reach zero?)

Stability: Effect of noise on the system

As you increase value the term…

Parameter

Rise time

Over shoot

Settling time

Steady state error

Stability

P

Decrease

Increase

Small change

Decrease

Degrade

I

Decrease

Increase

Increase

Eliminate

Degrade

D

Minor change

Decrease

Decrease

No effect

Improve if D is small

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Recently I was talking with a co-worker about an image detection model and they mentioned the now “classic” question of how do you deal with weather obfuscation of data.

We quickly moved from static obstruction (the snow covered stop sign) to the dynamic obstruction of rain and snow.

Starting from first principals you can quickly out line the factors that contribute to the model

Rain / Snow density (drops / flakes per m^3): This is a measure of storm “intensity”

Size: How large are the snow flakes / rain drops

Wind speed: This effects how the flakes / drops move, it is complicated by wind gusts.

Camera velocity: Is your camera moving?

Depth: How far away is the object that you are viewing

There already exist a number of interesting papers that examine these parameters in full. My real question is “Do I want to model the rain or the effect of the rain on my algorithms”?.

In some cases it may be necessary to fully model a the behavior. In others a simplified characteristic model can be used. Let us look at what we determined was important.

What really matters…

Given that objects, in general, don’t change their shape(1) it is possible to filter out the noise of rain or snow. What we need to understand is how rain or snow obscure objects.

Interposition: Every drop of rain and every flake of snow acts as a “point barrier” between the camera and the object.

Take the simple example: for an object 10 meters away the extent of “obscuring” is a function of the rain density and the droplet size; further the distance between the camera and the object (depth) determines the extend of the obstruction. What then should we do with with the wind? How should we model the movement?

It turns out, not much. When I compared the effect of random movement of the patterns with the wind models the effect on obstruction there were negligible difference for the vision application.

The moral of the story…

Modeling systems is a question about what is required for your analysis. Knowing this I can create the minimal model that is required to perform my tests.

Developing simplified models start with an understanding of the “real” system

Footnote: 1: The profile of the object may change as the relative angle is changed.

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For most of the last 25 years I have worked in a consultative capacity; during that time I have come to a set of principals that define what I consider an ethical frame work as a consultant.

Honesty: Time, Talent and Tools

In all interactions with a client honesty is the foremost byword. This shows up in three areas.

Time: Projects take time. Estimating how long a project takes is a skill that develops with experience. When providing an estimate to a client always use your best judgement as to how long the project will take enumerating the tasks to be completed and the potential unknowns. If an accurate estimate is not possible due to a lack of understanding you should consider if this is the correct type of project for you to be working on.

Talent: When I speak about talent I am thinking about the sum of the things that you or people you work with have a strong understanding of. When starting a project my rule of thumb is that my team should understand at least 80% of the project scope. Why 80% though and not 100%? My assumption is that for any project, outside of turn key implementations, there is project specific knowledge that my customer has that my group will need to learn to best help out. A critical early part of any project is coming to terms with that unknown 20%.

Tools: There an old saying “when all you have is a hammer, everything looks like a nail”. Selecting the correct tool for any job is important. Not forcing a tool because you work for a company or it is something you are familiar with is ethical. In the end select tools being aware of the cost (both of the tool and in time spent to work with the tool) versus the functionality (what percentage of the issue does the tool address.

Understand what customer needs…

A story I have often told is about the first consulting contract I worked on over 20 years ago. The customer requirements were well written, scoping things out fully. I had the required skill set to implement what they requested and the tools were available “in-house” for the customer. After 200 hours of work (out of an estimated 220) I handed over the finished product and the customer went away happily. However, in hindsight what the customer asked me to do wasn’t what they needed me to do; I solved the symptom, not the problem.

There are two things to take from this, first during the initial interview it is critical to get to a solid understanding of what the root issue the customer is trying to solve. Second it is important to be able to convey to the customer why a proposed solution may not address the underlying problem. (If you already know how to solve the problem then you are hiring a temporary employee, not a consultant).

Stand behind what you deliver

For most consulting projects the works is completed within a handful of months. The customer will continue to use what you to taught them and delivered to them for years. In the 25 years I have been working I have always been ready to speak with old customers about what I did to help them with the unexpected curves they hit.

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A few months ago there was an interesting article about AlphaGo and deep learning. What made the solution interesting is that AlphaGo determined a new strategy for playing Go, e.g. it wasn’t just replicating the best of current players, it was creating something new.

So this got me thinking about sensor placement. Let’s say you are building an autonomous vehicle; you give it radar, LIDAR, cameras, heck even a person walking 5 feet in front of the car with a red flag. But how do you know what the best configuration of those sensor is? This is where math and deep learning can come to the rescue.

It’s research, dam the budget!

With research vehicles it is common to go high end with the sensors and processors. Often the number of sensors are far in excess of what the final vehicle will have; the question then becomes “If you train your controller using 10 sensor and the final vehicle will only have 3 do you have to retrain?”

So here is the insight, in regression there is the concept of a synthetic variable. E.g. you can take the raw data X and put X^2 into the equation. What if, for sensor data, you optimize for sensor position?

Step 1: Train your model using the full set of sensors. Train it until you reach the highest confidence level you can.

Step 2: Define the set of equations that will take your original sensor data and use them to create “artificial” sensor at arbitrary locations. E.g. if you have 10 LIDAR sensors, then it could be that AS_1 = func(X1,Y1,Z1) = func(L1,L2,L4,L6) AS_2 = func(X2,Y2,Z2) = func(L3,L4,L7) AS_3 = func(X3,Y3,Z3) = func(L2,L6,L9,L10)

Step 3: Using the already trained data train the new sensor array

Step 4: Optimize the models as a function of the sensor placement and number of sensors

Sensor fusion before the sensors…

I think of this approach as “sensor fusion before the sensors”. What is interesting about this approach is that it is possible that we could discover a combination of sensors (and yes this should be done with multiple sensors) that has a higher accuracy and lower costs than we expect.

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Welcome to the year 2019, the first post of the year (or last post of the year) generally are places for retrospectives/forward looking visions. I shall keep to the form.

Excited: 2018

There are multiple things to be excited about this year, the following are what I a found most exciting

. Simplified methods for integrating C with models: MATLAB and Simulink added new functionality to improve the integration of C code and Models, either by including code in the model (C-Caller block) or by simplifying the function interface definition.

Projects, data dictionaries and testing: MathWorks continues to work on the integration between Simulink Projects and the supporting tool chain, these improvements coupled with version control software integration make the tool powerful for team based development

String support: For better or for worse, strings are a part of control systems, after many years Simulink has native support.

Looking forward: 2019

Machine learning: Ok, sure I just got started but already there are a number of interesting question (and lovely math) that I am enjoying.

Systems of systems: The scope of Model-Based Design projects continues to expand, the analysis of system of systems is an area I’m excited to move into.

Statistical validation: As our systems become more complex statistical analysis (DOE) becomes more and more important

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There is an old saying that “You can’t compare apples to oranges”; but frequently as an engineer, one of our jobs is to compare apples to oranges. Why and what does that mean?

Frequently, when systems are built the actual system does not yet exist. As a result, we need to draw analogies between the two items. So if we are going to compare apples and oranges how do we “juice” them for the correct data?

The mapping between objects: first principals

One objective with these mappings is to reduce the volume of first principals modeling that needs to be done; e.g. instead of building up a complex system of equations, use a modified data reduction of an existing system modified for the new system. However, to do that, we must first validate that the fundamental behavior of the systems scale between each other. For example, scaling a 4 cylinder 1.8L engine to a 2.1L engine is straight forward. To go from a 4 cylinder to an 8 cylinder is also straightforward if a slightly different problem.

What is the same? What is different?

You selected the reference model because there are things that they share in common. At the same time, there will be things that are different. In our example of the 4 cylinder to the 8 cylinder engine, there are differences in total displacement (an easy mapping) torque output excetra. The thing that may not be easy to map is the change to the in the vibrational aspects of the engine. The questions to ask are

What physical aspects of the system am I concerned with?

Torque

Fuel consumption

Max rpm

…

What aspects am I not concerned with?

Vibration

Heat transfer

….

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So my first step into machine learning is examining supervised learning and my old friend curve fitting. This was a fun trip down memory lane as my numerical mathematics background had me well prepared for this topic. Further, in the 25 years since I graduated, the basic tools for performing regression analysis have greatly improved, I was able to use the built-in curve fitting tool in MATLAB to perform these operations directly. At the same time, I quickly remembered the “gotchas” about regression…

Starting points

As a starting point, I thought I would see how well the tool would do with a known polynomial equation. I defined a simple 3rd order equation and added some noise into the signal. I then ran the results through the curve fitting toolbox…

As a sanity check, I first tried it out using the “real” X and Y data. As would be expected the tool spits back out the coefficients that I expected. When I ran it with the noise (and telling it to use a 3rd order polynomial) it returned coefficients fairly close to the “real” things.

Coefficient

Original

Regressed “Real”

Regressed “Noise”

P4

0.0

-3.79e-14

-0.745

P3

1.5

1.5

3.05

P2

1.2

1.2

0.8709

P1

-0.5

-0.5

-0.522

R-Square

NA

1.0

0.9939

Within the defined range we have an R-squared value of 0.9925, pretty darn good. But, the question quickly becomes, how does it hold up outside of the known range?

So depending on how you want to look at it, as an absolute error or a percentage error you may be doing “O.k.” or not. But what if I didn’t know what the underlying equation was? A power function would seem like a reasonable. If I try a first order power equation

y = a * exp(b * x) or second y = a * exp(b * x) + c * exp(d * x);

Order

R-square

1st

0.9852

2nd

.9961

Within the original bounds, the R-Squared value is close to the actual polynomial. If we used the 1st order equation just in that region it executes faster then the 3rd order polynomial so we may want to go with a “fake fast fit”. (say that three times fast).

Why do we try to “fit-in”?

There are several reasons why regression is performed. Sometimes it is because the underlying equations are unknown, are too computationally expensive, there isn’t an equation. Regardless of the reason when I am trying to perform a regression I perform the following steps

What are the fundamental physics: Use this to pick out which terms and functions to use. (Note: The curve fitting toolbox has an wonderful “custom equation” option that let’s you try these equation based approaches out)

Boundaries? I try to understand how the data outside of the known data set? In my example the exponential function does not perform well much outside of my known data.

Disclaimer:

Roughly 30 minutes after I finished writing this blog post I stumbled across this post “Explore Runge’s Polynomial Interpolation Phenomenon” by Cleve Moler. I would be amiss to not include this link for three reasons

Cleve’s post clearly articulates the mathematical underpinnings of interpolation

As the creator of MATLAB, his work is why things are “greatly improved”.

It’s a post about Runge, and since I had a cat named Runga-Kutta (RK) back in college well…

Warning: Bad aerospace engineering pun follows:

When I was in grad school and had that cute cat I was working on a simple project, a device to determine the terminal angle (stall) for a kite. For the most part, I worked on this project in my apartment, and Runga loved to attack the kite’s tail, jumping at it attacking it. That was well and good in the apartment.

Well at the early testing stages I was flying the kite off of my back deck. One day while flying RK managed to get out. In a leap of excitement she jumped onto the kite’s tail (knowing from experience she would land happily on the carpet). Except, this time, the kite was 8 feet off the ground. Needless to say, both the cat and the kite crashed to the ground proving that for this case the Kutta condition did not hold.

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For the last two years, I have written about Model-Based Design in the context of classical control algorithms and software verification processes. Over the next year, I am broadening the scope of this blog as I investigate how machine learning can be applied to MBD in the context of safety critical systems.

My questions

What is the current state of the art in Machine learning?

How can it be used for controls problems?

When should it be used? When should it not be used?

Where is it the only solution?

What are building blocks of machine learning?

Starting small, what are the easy things to do?

Hitting the middle, what is a “real” project?

Common “starting” pitfalls

Testing and verification

Can you do black box testing?

How do you test an “open world” model?

So join me on this trip…

I will share my insights, my mistakes and look forward to hearing from you…

In English, there is a saying, where there is smoke there is fire. It is an interesting saying which you could take to mean multiple things

Smoke will let you find problems from a distance

Smoke will show up before the fire

…

At The MathWorks, we call our most primitive tests “smoke tests”. A smoke test is a basic “does it turn on test”. The idea behind smoke tests is to validate that the unit under test performs in the most basic fashion, therefore, is ready to run longer more complex tests. For example, a set of smoke tests for a Model would look like this

Perform an update diagram (Order of a minute)
if pass then…

Check the model configuration parameters (Order of a minute)
if pass then…

Check model for unallowed blocks (Simulink Check) (Order of a minute)
if pass then…

Run your complex test suite… (Order of a ???)

Why?

For large, more complex tests, the setup, execution and evaluation time of the tests can be on the order of hours for a complex set of tests. The ability to “abort” running these longer tests is important as your test suite grows. You don’t want to take up time on your CI system running tests on models that are not in the correct state.

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