Models Of Reality

For those who want to play around with the falling ball experiment and fit their own models or reproduce mine, here is the Ball Analysis R code, with some comments, to analyze the drops and balls data I posted earlier. WordPress won't let me upload a file with extension ".R" so I changed it to ".txt" just rename the file when you download it.  (note, I know I can edit the wordpress installation to allow ".R" but I'm lazy)

Measured and imputed fall times from Bayesian model and predictions via ODE with drag

Well, the results are in, and we have a nice set of preliminary predictions for the falling ball problem (a more massive MCMC run would be in order next). They also show some very nice advantages to a Bayesian analysis of the problem. In the above graph are measured fall times (black points) predicted fall times without drag (black curve), a linear fit to the raw data (grey line/area), corrected fall times including imputed timing bias (red points) and predicted fall times from the ODE model for the initial conditions and the aerodynamic radius. Bayesian uncertainty not shown (I used the mean values from the MCMC runs).

One of the nice aspects of this analysis is how prior information helped determine which sources of uncertainty were important. For example, we could obviously fit the original data pretty well if we had no drag and a little extra gravity (imagine the black curve a little lower). In fact fitting the model

> linmod1 <- lm(ts ~ 0+I(sqrt(2*h0cm/100)),data=drops);
> 1/coef(linmod1)^2
I(sqrt(2 * h0cm/100)) 
 12.15669

But gravitational acceleration of 12.2 m/s^2 is completely out of the question, we know thanks to others work that g in LA is within about 0.01 of 9.796 and we know from dropping something denser than a paper ball that the paper ball takes longer due to drag, maybe around .1 or .2 seconds longer for these heights. We could include this timing bias into the model easily:

> linmod2 <- lm(ts ~ I(sqrt(2*h0cm/100)),data=drops);
> 1/coef(linmod2)[2]^2;
I(sqrt(2 * h0cm/100)) 
 7.101245
> coef(linmod2)[1]
(Intercept)
 -0.1371857

But although a timing bias of 0.14 seconds is not unreasonable (the Bayesian method predicts 0.275 s), g=7.1 is also completely out of the question. This reflects the fact that the shape of the point cloud isn't like a $\sqrt{2h_0/g}$ curve because of drag (it's more linear because we're transitioning to a constant terminal velocity by the time we hit the ground).

To include the ODE predictions in the least squares type model we need to first run the ODE predictor for each drop. To do that, we need some value for the aerodynamic radius, and we need to know the initial conditions, neither of which do we actually know. Oh sure, we could assume $r$ is pretty close to half the average measured diameter for example, but the linear model needs just one r value and we are not comfortable saying that r is any definite quantity based on the variability in size and shape, so we're going to need to do "sensitivity analysis" on r. Also, we know that there's some kind of uncertainty in the initial height, oh sure I tried to hold it very close to the height requested, but the shape isn't a sphere with a precisely defined edge, it's a crumpled ball of paper. Plus there's the $\rho$ and $\mu$ values for air, fixed during the experiments, but not known exactly due to temperature and humidity and soforth. So again, we are going to have to run "sensitivity" analysis on all of these things. How will we choose the heights and radii (and air properties) to use in our analysis? Will we, as Gelman rails against, invert a hypothesis test, and accept any r,h pair which we can not reject? That will probably be a pretty big range considering that our above analysis is willing to put g between 7.1 and 12!

The Bayesian analysis goes one step further than the frequentist analysis in allowing us to specify that some values are more reasonable than others, namely g tightly coupled around 9.796 and $\mu,\rho$ somewhat less tightly coupled around their nominal values, so that we expect more uncertainty in $r,h$. Furthermore, if we like we could couple these values together. A ball with a more irregular shape will be harder to hold at an exact height for example.

So how about calibration? One of the complaints from Frequentists is that predictions from Bayesian analysis do not necessarily have well calibrated probabilities for reproducible experiments. For example if I took my fitted model and predicted fall times for each ball for a new fall height, and then ran the new experiment a bunch of times to get a lot of data, would the distribution of measured values be pretty close to the distribution of predictions from the Bayesian model? Well, it's hard to say without running the experiment. But my intuition says that after all the sensitivity analysis and inversion of hypothesis tests and soforth, any Frequentist confidence intervals would be pretty large, what with having to include different g values and r  values and soforth. And if you are including different values for $g,r,h_0$ but not assigning them prior probabilities, what do you do for confidence intervals? You'll get one for every different value of $g,r,h_0$ so it's not clear which one to evaluate for advertised coverage.

All this is to say, I use Bayesian methods because they answer the question that I tend to want answered. Namely, if I can make some reasonable assumption (to me based on my general knowledge) then Bayes theorem will give me the resulting weights to be placed on different values for quantities that I do not know exactly (things like aerodynamic radius, fall height, air density, timing bias, timing variance etc).

One question that I don't know how to answer is how to deal with calibration issues in the absence of an enormous validation sample. But this is a problem I have no matter what. When the sample size is enormous we can be pretty sure about our predictions. When I have 30 drops for 10 balls and I predict the future from that, I'm only going to know how well calibrated my predicted fall time distribution is after I go and do a whole bunch more drops. Of course then I'd want to update my model with those additional data points, and I'd have to collect even more data to see how calibrated I am... ad nauseum.

Above is a plot of the height vs time for a sphere falling through air both predicted (black) and drag free (red). As you can see by drawing a horizontal line at h = 0.0 there should be a significant effect, 50% longer fall time or so. t=1 corresponds to 0.534 seconds (shown in the title). On the other hand, the actual data shows nothing like these fall times. In fact thae data shows t' values < 1 which suggests maybe the Android based stopwatch + user reaction time / anticipation is a big issue. Uncertainty abounds, but it's not really that interesting uncertainty (we know the time measurement method is crude). If we want to find out about drag we may very well need much more accurate time measurements, or drops from higher heights.

Rama suggested using an x-box kinect sensor to get fairly precise distance vs time data which would help you because velocity is more strongly affected. In any case I will reconsider the experiment a little. The results as-is are still interesting when it comes to philosophical aspects of uncertainty. For example, $t/\sqrt{2h_0/g_n}$ is less than 1 for most experiments. This either means that $g$ was significantly less than $g_n$, that $h > h_0$ or that there was a bias towards stopping the stopwatch earlier. Bayesians will have no trouble putting prior distributions over the various options. Since the tape measure and gravitational constant are relatively well calibrated, I certainly suspect that the timer was biased low. This might be caused by the timer program itself (attempting to account for a delay in response it might subtract a fixed delay estimate for example), or by the experimenter pressing the start button late or the stop button early or both.

So, we'll have to see what happens with this data. perhaps it's overwhelmed by time measurement noise, or perhaps we can discover some effective radii even with the measurement noise.

Attached data: drops and balls which contain the timing data for 30 drops, and the mass and size data for 10 balls.

From my previous article proposing a simple experiment of dropping a ball that will experience drag and then doing inference about the unknown quantities based on a mechanical model that will induce a likelihood: Here's an update on the model and experimental protocol. I ran the experiment today and the data is posted as text files above.

We started with Newton's Laws for a falling sphere with drag:

$$ma = -mg + c(\rho v r / \mu) \rho A(r) \frac{v^2}{2}$$

$$v = \frac{dh}{dt}$$

and the initial conditions $v(0)=0, h(0)=h_0+\epsilon_h$ where $h_0$ is the measured initial height and $\epsilon_h$ accounts for the difference between measured and actual.

It makes sense to nondimensionalize every physical equation. We will define new variables: $a'=a/g_n, v'=v/(h_0/\sqrt{2h_0/g_n}), h' = h/h_0, t'=t/\sqrt{2h_0/g_n}$ where $g_n$ is the nominal "standard" value for g, defined as $g_n=9.80665 {\rm m/s^2}$. Substituting for the variables $a,v,h,t$ and solving for the new equations in $a',v',h',t'$ gives us:

$$a' = -\frac{g}{g_n} + c\left (\frac{v'r\rho \sqrt{g_nh_0/2}}{\mu}\right ) \frac{h_0A(r)\rho}{4m} {v'}^2$$

$$v' = \frac{dh'}{dt'}$$

These are dimensionless equations (choose a system of units, such as SI, and calculate the units of any term, and you will see they all cancel) and it emphasizes that we don't need to know exactly each constant. Ultimately we need 3 dimensionless ratios, some of which are exact and for a frequentist are not random variables at all (they are fixed in every experiment): $g/g_n, \rho r \sqrt{g_n h_0/2}/\mu, \rho Ah_0/(4m)$. We are modeling $A$ as $\pi r^2$ and we have that $v'$ is a dynamic variable that our deterministic model will predict. The uncertainty comes in the variables $r, m, g, \rho, \mu, \epsilon_h$ which is 6 unknown variables, however we only need to infer 4 quantities thanks to our nondimensionalization $g, r/\nu, \rho/m, \epsilon_h/h_0$ where $\nu = \mu/\rho$ is called the "kinematic viscosity".

Next, we need to consider the differences between our predictions from the ODE model and the measured fall times. From the ODE model we have that the fall time is $t:h(t)=0$ and given values for the constants, we can estimate this essentially exactly (ie. 8 or 10 decimal places, which is enormously precise compared to other aspects of our problem). However our measured time will definitely be different from this predicted time. The dimensionless version of the measured time $t_m' = t_m/\sqrt{2h_0/g_n}$ will differ from the predicted amount by a "reaction time" error $t_r'$. If an experimenter flubs the measurement entirely (forgets to press start, misses the end time and lets the timer run for several extra seconds, etc), they will redo the experiment rather than recording it, so they will only accept values that are reasonably tightly clustered around something "true" and hence a normal random variable is a reasonable model for $t_m$. Alternatively if they might record several minutes of fall time due to letting the stopwatch go on accidentally, we might prefer to use a complicated mixture model or something with fat tails, like a t distribution. However even if we use the normal model, the bias and variance in this procedure are unknown. Having approximated the experiment a few times we know that the fall time will be on the order of 0.5 seconds, and that the fastest we can double-click the stopwatch is on the order of 0.1 seconds, so we might expect that the bias is some number whose size is on the order of 0.1 seconds and might be either positive or negative, and the variance in the measurement error should be on the order of 0.2^2 or less. For a Bayesian, we can define hyperparameters $\mu$ and $\sigma$, and a reasonable prior for them is something like $N(0,0.1^2)$ and $\Gamma(2,0.1)$ where here the 0.1 in the Gamma distribution is the scale parameter of the Gamma, (sometimes people parameterize in terms of a rate = 1/scale).

Now for more specifics on the data collection: create two sheets of paper, one with headings:

Ball Mass D1 D2 D3

Where you record info about the balls, namely the ball number, the mass in g based on weighing on a scale, and three approximate diameters (lay it on top of your tape measure and read off something that seems reasonable, record it in cm).  On the other sheet of paper we have:

Ball h0 t

Where we record which ball we dropped, the nominal height we tried to drop it from (generated randomly in a range that you can easily read without standing on something or stretching too much). Record these values in cm and seconds. For analysis we'll convert distances to meters to get consistent units.

At the beginning of this post I have links to data files that I generated thanks to Rama and Evangelia for helping me collect the data. BTW the temperature in the room was about 72 C 72 F plus or minus a degree or so, that's useful for looking up the kinematic viscosity of air to get a prior for that parameter.