HomeiOS DevelopmentSome Statistics for Starters | Cocoanetics

Some Statistics for Starters | Cocoanetics

As a interest, I’m engaged on a SwiftUI app on the aspect. It permits me to maintain monitor of peak and weight of my daughters and plot them on charts that enable me to see how “regular” my offspring are creating.

I’ve shied away from statistics at college, so it took me so time to analysis a couple of issues to unravel a problem I used to be having. Let me share how I labored in the direction of an answer to this statistical downside. Could you discover it as instructive as I did.

Notice: Should you discover any error of thought or truth on this article, please let me know on Twitter, in order that I can perceive what brought about it.

Let me first provide you with some background as to what I’ve achieved earlier than at this time, so that you just perceive my statistical query.


The World Well being Group publishes tables that give the percentiles for size/peak from delivery to 2 years, to 5 years and to 19 years. Till two years of age the measurement is to be carried out with the toddler on its again, and known as “size”. Past two years we measure standing up after which it’s known as “peak”. That’s why there’s a slight break within the printed values at two years.

I additionally compiled my women heights in a Numbers sheet which I fed from paediatrician visits initially and later by sometimes marking their peak on a poster in the back of their bed room door.

To get began I hard-coded the heights such:

import Basis

struct ChildData
   let days: Int
   let peak: Double

let elise = [ChildData(days: 0, height: 50),
	     ChildData(days: 6, height: 50),
	     ChildData(days: 49, height: 60),
	     ChildData(days: 97, height: 64),
	     ChildData(days: 244, height: 73.5),
	     ChildData(days: 370, height: 78.5),
	     ChildData(days: 779, height: 87.7),
	     ChildData(days: 851, height: 90),
	     ChildData(days: 997, height: 95),
	     ChildData(days: 1178, height: 97.5),
	     ChildData(days: 1339, height: 100),
	     ChildData(days: 1367, height: 101),
	     ChildData(days: 1464, height: 103.0),
	     ChildData(days: 1472, height: 103.4),
	     ChildData(days: 1544, height: 105),
	     ChildData(days: 1562, height: 105.2)

let erika = [ChildData(days: 0, height: 47),
	     ChildData(days: 7, height: 48),
	     ChildData(days: 44, height: 54),
	     ChildData(days: 119, height: 60.5),
	     ChildData(days: 256, height: 68.5),
	     ChildData(days: 368, height: 72.5),
	     ChildData(days: 529, height: 80),
	     ChildData(days: 662, height: 82),
	     ChildData(days: 704, height: 84),
	     ChildData(days: 734, height: 85),
	     ChildData(days: 752, height: 86),

The WHO outlined one month as 30.4375 days and so I used to be capable of have these values be plotted on a SwiftUI chart. The vertical strains you see on the chart are months with bolder strains representing full years. You can even discover the small step on the second 12 months finish.

It’s nonetheless lacking some type of labelling, however you’ll be able to already see that my older daughter Elise (blue) was on the taller aspect throughout her first two years, whereas the second-born Erika (purple) was fairly near the “center of the street”.

This chart offers you an eye-eye overview of the place on the street my daughters are, however I wished to have the ability to put your finger down on each place and have a pop up let you know the precise percentile worth.

The Information Dilemma

A percentile worth is principally giving the knowledge what number of p.c of kids are shorter than your youngster. So in case your child is on the seventy fifth percentile, then seventy fifth of kids are shorter than it. The shades of inexperienced on the chart symbolize the steps within the uncooked knowledge supplied by the WHO.

Thery provide you with P01, P1, P3, P5, P10, P15, P25, P50, P75, P85, P90, P95, P97, P99, P999. P01 is the 0.1th percentile, P999 is the 99.ninth percentile. On the extremes the percentiles are very shut collectively, however within the center there’s a enormous bounce from 25 to 50 to 75.

I wished to point out percentile values at these arbitrary occasions which can be no less than full integers. i.e. say forty seventh percentile as a substitute of “between 25 and 50” and doubtless present this place with a coloured line on the distribution curve these percentile values symbolize.

It seems, these peak values are “usually distributed”, on a curve that appears a bit like a bell, thus the time period “bell curve”. To me as a programmer, I might say that I perceive {that a} a kind a knowledge compression the place you solely have to to know the imply worth and the usual deviation and from you can draw the curve, versus interpolating between the person percentile values.

The second – smaller – difficulty is that WHO supplies knowledge for full months solely. To find out the traditional distribution curve for arbitrary occasions in between the months we have to interpolate between the month knowledge earlier than and after the arbitrary worth.

With these questions I turned to Stack Overflow and Math Stack Trade hoping that anyone may assist out me statistics noob. Right here’s what I posted…

The Downside

Given the size percentiles knowledge the WHO has printed for ladies. That’s size in cm at for sure months. e.g. at delivery the 50% percentile is 49.1 cm.

Month    L   M   S   SD  P01 P1  P3  P5  P10 P15 P25 P50 P75 P85 P90 P95 P97 P99 P999
0    1   49.1477 0.0379  1.8627  43.4    44.8    45.6    46.1    46.8    47.2    47.9    49.1    50.4    51.1    51.5    52.2    52.7    53.5    54.9
1    1   53.6872 0.0364  1.9542  47.6    49.1    50  50.5    51.2    51.7    52.4    53.7    55  55.7    56.2    56.9    57.4    58.2    59.7
2    1   57.0673 0.03568 2.0362  50.8    52.3    53.2    53.7    54.5    55  55.7    57.1    58.4    59.2    59.7    60.4    60.9    61.8    63.4
3    1   59.8029 0.0352  2.1051  53.3    54.9    55.8    56.3    57.1    57.6    58.4    59.8    61.2    62  62.5    63.3    63.8    64.7    66.3

P01 is the 0.1% percentile, P1 the 1% percentile and P50 is the 50% percentile.

Say, I’ve a sure (doubtlessly fractional) month, say 2.3 months. (a peak measurement could be performed at a sure variety of days after delivery and you’ll divide that by 30.4375 to get a fractional month)

How would I am going about approximating the percentile for a selected peak at a fraction month? i.e. as a substitute of simply seeing it “subsequent to P50”, to say, properly that’s about “P62”

One method I considered could be to do a linear interpolation, first between month 2 and month 3 between all mounted percentile values. After which do a linear interpolation between P50 and P75 (or these two percentiles for which there’s knowledge) values of these time-interpolated values.

What I worry is that as a result of it is a bell curve the linear values close to the center could be too far off to be helpful.

So I’m considering, is there some formulation, e.g. a quad curve that you possibly can use with the mounted percentile values after which get an actual worth on this curve for a given measurement?

This bell curve is a standard distribution, and I suppose there’s a formulation by which you will get values on the curve. The temporal interpolation can in all probability nonetheless be performed linear with out inflicting a lot distortion. 

My Answer

I did get some responses starting from ineffective to a degree the place they could be right, however to me as a math outsider they didn’t assist me obtain my purpose. So I got down to analysis learn how to obtain the outcome myself.

I labored via the query based mostly on two examples, specifically my two daughters.

ELISE at 49 days
divide by 30.4375 = 1.61 months
60 cm

In order that’s between month 1 and month 2:

Month  P01 P1  P3  P5  P10 P15 P25 P50 P75 P85 P90 P95 P97 P99 P999
1 47.6 49.1 50 50.5 51.2 51.7 52.4 53.7 55 55.7 56.2 56.9 57.4 58.2 59.7
2 50.8 52.3 53.2 53.7 54.5 55 55.7 57.1 58.4 59.2 59.7 60.4 60.9 61.8 63.4

Subtract the decrease month: 1.61 – 1 = 0.61. So the worth is 61% the way in which to month 2. I might get a percentile row for this by linear interpolation. For every percentile I can interpolate values from the month row earlier than and after it.

// e.g. for P01
p1 = 47.6
p2 = 50.8

p1 * (1.0 - 0.61) + p2 * (0.61) = 18.564 + 30.988 = 49.552  

I did that in Numbers to get the values for all percentile columns.

Month P01 P1 P3 P5 P10 P15 P25 P50 P75 P85 P90 P95 P97 P99 P999
1.6 49.552 51.052 51.952 52.452 53.213 53.713 54.413 55.774 57.074 57.835 58.335 59.035 59.535 60.396 61.957

First, I attempted the linear interpolation:

60 cm is between  59,535 (P97) and 60,396 (P99).
0.465 away from the decrease, 0.396 away from the upper worth. 
0.465 is 54% of the space between them (0,861)

(1-0.54) * 97 + 0.54 * 99 = 44.62 + 53.46 = 98,08
// rounded P98

Seems that it is a dangerous instance.

On the extremes the percentiles are very intently spaced in order that linear interpolation would give comparable outcomes. Linear interpolation within the center could be too inaccurate.

Let’s do a greater instance. This time with my second daughter.

at 119 days
divide by 30.4375 = 3.91 months
60.5 cm

We interpolate between month 3 and month 4:

Month P01 P1 P3 P5 P10 P15 P25 P50 P75 P85 P90 P95 P97 P99 P999
3 53.3 54.9 55.8 56.3 57.1 57.6 58.4 59.8 61.2 62.0 62.5 63.3 63.8 64.7 66.3
4 55.4 57.1 58.0 58.5 59.3 59.8 60.6 62.1 63.5 64.3 64.9 65.7 66.2 67.1 68.8
3.91 55.211 56.902 57.802 58.302 59.102 59.602 60.402 61.893 63.293 64.093 64.684 65.484 65.984 66.884 68.575

Once more, let’s attempt with linear interpolation:

60.5 cm is between 60.402 (P25) and 61.893 (P50)
0.098 of the space 1.491 = 6.6%

P = 25 * (1-0.066) + 50 * 0.066 = 23.35 + 3.3 = 26.65 
// rounds to P27

To match that to approximating it on a bell curve, I used an on-line calculator/plotter. This wanted a imply and a typical deviation, which I feel I discovered on the percentile desk left-most columns. However I additionally have to interpolate these for month 3.91:

Month L M S SD
3 1.0 59.8029 0.0352 2.1051
4 1.0 62.0899 0.03486 2.1645
3.91 1.0 61.88407 0.0348906 2.159154

I don’t know what L and S imply, however M in all probability means MEAN and SD in all probability means Customary Deviation.

Plugging these into the net plotter…

μ = 61.88407
σ = 2.159154
x = 60.5

The net plotter offers me a results of P(X < x) = 0.26075, rounded P26

That is far sufficient from the P27 I arrived at by linear interpolation, warranting a extra correct method.

Z-Scores Tables

Looking out round, I discovered that in the event you can convert a size worth right into a z-score you’ll be able to then lookup the percentile in a desk. I additionally discovered this nice rationalization of Z-Scores.

Z-Rating is the variety of normal deviation from the imply {that a} sure knowledge level is. 

So I’m making an attempt to realize the identical outcome as above with the formulation:

(x - M) / SD
(60.5 - 61.88407) / 2.159154 = -0.651

Then I used to be capable of convert that right into a percentile by consulting a z-score desk.

Wanting up -0.6 on the left aspect vertically after which 0.05 horizontally I get to 0.25785 – In order that rounds to be additionally P26, though I get an uneasy feeling that it’s ever so barely lower than the worth spewed out from the calculator.

How to do this in Swift?

Granted that it might be easy sufficient to implement such a percentile lookup desk in Swift, however the feeling that I can get a extra correct outcome coupled with much less work pushed me to search around for a Swift package deal.

Certainly, Sigma Swift Statistics appears to supply the wanted statistics perform “regular distribution”, described as:

Returns the traditional distribution for the given values of x, μ and σ. The returned worth is the realm underneath the traditional curve to the left of the worth x.

I couldn’t discover something talked about percentile as outcome, however I added the Swift package deal and I attempted it out for the second instance, to see what outcome I might get for this worth between P25 and P50:

let y = Sigma.normalDistribution(x: 60, μ: 55.749061, σ: 2.00422)
// outcome 0.2607534748851712

That appears very shut sufficient to P26. It’s totally different than the worth from the z-tables, `0.25785` however it rounds to the identical integer percentile worth.

For the primary instance, between P97 and P99, we additionally get inside rounding distance of P98.

let y = Sigma.normalDistribution(x: 60, μ: 55.749061, σ: 2.00422)
// outcome 0.9830388548349042

As a aspect observe, I discovered it pleasant to see the usage of greek letters for the parameters, a function doable resulting from Swifts Unicode assist.


Math and statistics had been the rationale why I aborted my college diploma in laptop science. I couldn’t see how these would have benefitted me “in actual life” as a programmer.

Now – many a long time later – I sometimes discover {that a} bit extra information in these issues would enable me to know such uncommon eventualities extra shortly. Fortunately, my web looking abilities could make up for what I lack in tutorial information.

I appear to have the substances assembled to begin engaged on this regular distribution chart giving interpolated percentile values for particular days between the month boundaries. I’ll give an replace when I’ve constructed that, if you’re .

Additionally printed on Medium.

Classes: Administrative



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