It's not us; it's the weather

If you are a frequent flier, you already know the gist of this nice article by the BBC: that airlines are allowed to sandbag the flight durations. A flight that takes 60 minutes will be portrayed to fliers as taking twice as long, if not longer.

The airlines are even allowed to lie about this practice. When your flight is delayed taking off, the captain claims that s/he will “make up for the delay,” as if the plane could be driven faster on command. (Were they deliberately going slower before?) The truth is that the schedule is padded, so that it can absorb a limited amount of delay.

This quote sums the situation up: “By padding, airlines are gaming the system to fool you.”

At the very bottom of the article, you’d find the potential motivation – to avoid compensating travelers for long delays, as required by law in some countries.

***

The situation here is similar to the road congestion problem discussed in Chapter 1 of Numbers Rule Your World (link). Managing perceived time is as important as managing actual time experienced by the traveler. Of course, reducing actual wasted time is preferred, especially to scientists working on the problem, but when the road/sky capacity is fixed and over-subscribed, it’s almost impossible to attain. The second half of the article addresses “why don’t the airlines work on efficiency instead of lengthening flight times?”

***

Another quote reveals: “Over 30% of all flights arrive more than 15 minutes late every day despite padding.”

The “on-time arrival rate” blessed by the Department of Transportation (DoT) is not what you think it is.

Let’s take a random flight that takes 60 minutes. This flight schedule might be padded and advertised as departing at 2 pm and arriving at 4 pm.

If the flight departs at 2 pm and takes 60 minutes, then you’d think on-time arrival is defined as arriving at 3 pm. You might agree to allow for some slack, say, 15 minutes. In this case, on-time arrival is arriving before 3:15 pm.

Given the discussion, you now know that on-time arrival is actually arriving before 4 pm since the schedule is padded not by 15 minutes but by 60 minutes.

And then you’d be wrong! Because there is padding upon padding. Airlines are allowed to claim “on-time arrival” if the flights arrive within 15 minutes of the scheduled arrival time, which in our example, has been padded by 60 minutes. So any flight arriving before 4:15 pm is counted as “on-time.”

***

Padding is not purely a bad thing. A certain amount of padding is necessary because lots of flights are vying for a limited amount of airport and air space. A padded schedule is a more accurate schedule. It acknowledges other factors that cause delays in arrival.

The gaming of the padded metric is what works people up. Gaming is possible because padding inserts subjectivity into the measurement. So long as subjectivity cannot be avoided, gaming is here to stay.

***

The reporter said airlines have spent billions on technologies to improve efficiency, i.e., managing actual experienced time. But, “this has not moved the needle on delays, which are stubbornly stuck at 30%.”

Now square that statement with this one: “Billions of dollars in investment [in modernising air traffic control] have in fact halved air traffic control-caused delays since 2007 while airline-caused delays have soared.”

Does this sound like the new technologies have successfully reclassified delays from air traffic control caused to airline caused? Passing the buck?

The next time your flight is delayed, the airlines will likely tell you, “it’s not us, it’s the weather.”

 

 

How to use Kahneman-Tversky research from 1970s in the big data era

Just finished reading The Undoing Project by Michael Lewis, his bio of the Kahneman and Tversky duo who made many of the seminal discoveries in behavioral economics.

In Chapter 7, Lewis recounts one of their most celebrated experiments which demonstrated the “base rate fallacy.”

Here is one version of the experiment. The test subjects are asked to make judgments based on a vignette.

Psychologists have administered tests to 100 people, 70 of whom are lawyers and 30 are engineers.

(A) If one person is selected at random from this group, what is the chance that the selected person is a lawyer?

(B) Dick is selected at random from this group. Here is a description of him: “Dick is a 30 year old man. He is married with no children. A man of high ability and high motivation, he promises to be quite successful in his field. He is well liked by his colleagues.” What is the chance that Dick is a lawyer?

 

Those subjects who answered (A) made the right judgment, in accordance with the base rate of 70 percent.

The answer to (B) should be the same, since it shouldn't matter whether the random person is named Dick or not, and the generic description provides no useful information to determine Dick’s occupation. However, those subjects who answered (B) edited the chance down to about 50-50. The experiment showed that access to Dick’s description led people astray – to ignore the base rate. Note that the base rate here is the prior probability.

***

What are the practical applications of the KT experiment for business data analysts?

tl;dr

Before throwing the kitchen sink of variables (features) into your statistical (machine learning) models, review the literature on the base rate fallacy starting with Kahneman-Tversky experiments.

 

1. Adding more variables can make your predictions worse

Let's start with what kind of additional information is provided by Dick’s description. The sample size has not changed – it’s still one. The data expanded only in the number of variables (or features). Specifically, these eight additional variables:

X1 = age

X2 = gender

X3 = martial status

X4 = number of children

X5 = ability level

X6 = motivation level

X7 = expected level of success in field

X8 = popularity among colleagues

In today’s age of surveillance data, it is all too easy for any analyst to assemble more variables. The KT experiment shows that having more variables does not imply you have more useful information. Worse, those extra variables may distract you from the base rate, leading to worse predictions.

 

2. Machines are even more susceptible than humans

If humans are prone to such mistakes, should we use machines instead? Sadly, machines will perform worse.

Machines allow us to process even more variables at even greater efficiency. Instead of eight useless variables, you can now add 800 or even 8,000 useless variables about Dick. The machines will then inform you which subset of these variables “pop.” The more useless data you add in, the higher the chance you will encounter an accidental correlation.

 

Before throwing the kitchen sink of variables (features) into your statistical (machine learning) models, review the literature on the base rate fallacy starting with ground-breaking Kahneman-Tversky experiments.

 

 

Going bananas over this Seamless ad

Seamless, the online restaurant delivery service, has been running a series of fun ads on the New York subway that has a statistics theme. Here is a snapshot of one of them:

The text on the ad says:

The Most Potassium-Rich Neighborhood

MURRAY HILL

Based on the Number of Banana Orders

No One’s Cramping Here

***

This ad is tongue-in-cheek. But it's making a data-driven argument. So I started unpacking it.

The conclusion is “No one’s cramping here (in Murray Hill).” It’s an exaggeration so I’m going to read this as “Most people don’t cramp here in Murray Hill.”

The data behind this conclusion is much harder to nail down. One would think it should be the proportion of orders containing bananas in Murray Hill relative to the same in other neighborhoods. The ad uses the phrase “number of banana orders.” What does that mean? Is it “orders with at least one banana”? Or “orders of bananas only”? Or “total number of bananas ordered (across all orders)”?

Between the data and the conclusion is a long, windy path. Let me draw this out:

Assumption 1
All the neighborhoods have similar total populations so that by proportion of banana orders, Murray Hill also ranks #1.

Assumption 2
“Banana orders” is defined meaningfully. For the sake of argument, we’ll assume a banana order is an order that contains at least one banana.

Assumption 3
The data analyst used the appropriate address data. For the sake of argument, we'll assume that the delivery address is the source of the neighborhood data.

Assumption 4
Everyone who has a “banana order” through Seamless lives in the neighborhood to which the banana(s) were delivered. This further requires

Assumption 5
Everyone who has a “banana order” through Seamless works in the same neighborhood as they live. This distinction is important for daytime orders.

Assumption 6
Murray Hill residents who has a “banana order” through Seamless are just like other Murray Hill residents

Assumption 7
The name on each “banana order” is the one person who consumes the banana(s). No dogs ate the bananas, nor did a co-worker, family member, or anyone else not known to Seamless

Assumption 8
Eating bananas prevents or massively reduces cramping. The health effect of bananas requires

Assumption 9
Published scientific reports reach a strong consensus on the effect of bananas on cramping (highly unlikely); or, Seamless data show that those with a “banana order” report the absence of cramps (which requires primary research). The causal interpretation further requires

Assumption 10
Knowing that the people who made “banana orders” through Seamless would have suffered cramps had they not ordered and consumed those bananas. This counterfactual scenario is never observed, so instead, we accept

Assumption 10b
Knowing that the people who did not make a “banana order” through Seamless did suffer cramps. This requires

Assumption 11
The people who live in Murray Hill and did not make a “banana order” through Seamless also did not order bananas from a different shop, or otherwise consume bananas. In addition, we require

Assumption 12
No one who is part of this analysis benefited from any other anti-cramping remedy; or at the minimum,

Assumption 13
That people who have “banana orders” through Seamless, and those who don’t, are equally likely to have used other forms of anti-cramping remedy

Assumption 14
One banana is effective at stopping cramps, meaning there is no dose-response effect, the presence of which would require us to define “banana order” differently under Assumption 2.

The above assumptions fall into three groups: obviously false (e.g. Assumption 1); possibly true; and most likely true. The probability of the conclusion depends on the probabilities of these individual assumptions.

***

tl;dr

Most data-driven arguments consist of one part data, and many parts assumptions. An analyst should not fear making assumptions. Assumptions should be supported as much as possible.

 

 

Do wearable healthcare devices work?

A report came out from Stanford School of Medicine about a study of Apple Watch's health monitoring features. Some headline writers are proclaiming that "finally, there is proof that these watches benefit our health!" For example, Apple Watch Stanford Study Shows How It Can Save Lives (link).

When you read the official story, you will learn the following facts about the study:

• The research is funded by Apple
• It was a purely observational study in which they follow (400,000) people who wear Apple Watches
• Participants must own both an Apple Watch and an iPhone to be eligible (plus meeting other criteria)
• There was no "control" group - they did not follow anyone who did not use Apple Watch or use any other health monitoring wearables
• Every participant is self-selected
• The device issued warnings to only 0.5 percent of the participants (~ 2,160)
• Those who received a warning were directed to a video consultation; and the doctor decided whether or not to send the participant an ECG patch, which is used to establish the "ground truth". Only about 30 percent were sent patches, and of those, 70 percent (450) returned the patches for analysis.
• Only those who had ECG data were analyzed. One third of these were shown to have experienced "atrial fibrillation" (irregular heartbeat). This means that two-thirds got false alarms. But if we include the 70% who were not sent patches after the video consultation as false alarms as well, then out of every 100 warnings, only 7 were validated.
• There is no discussion of false negatives: did any of the 99.5 percent who did not receive warnings experienced irregular heartbeats?
• We do know that if there were significant false negatives, then more warnings would have to be sent, which pushes up false alarms.
• Despite the headlines, any lives saved were extrapolated.

There are some major methodological limitations about this study.

Firstly, the study design prevents drawing conclusions of the type "People wearing Apple Watches .... compared to those who did not wear Apple Watches." It does not include anyone not wearing Apple Watches.

Secondly, it's difficult to interpret the accuracy metrics. Is 20 percent false alarms a good or bad number? Is 0.5 percent receiving warnings a reasonable proportion given the demographic and health characteristics of the study population?

Hopefully, this study is just the beginning, and more rigorous studies are being planned.