# Finding the First and Third Quartiles

What i want to do is get the middle of each half of my number. So what i have already created is a way to get the middle of the number (The medium in math terms) here;

``````    public static String Find_Medium()
{
double Size = list.Count;
double Final_Number = 0;
if (Size % 2 == 0)
{
int HalfWay = list.Count / 2;
double Value1 = Convert.ToDouble(list[HalfWay - 1].ToString());
double Value2 = Convert.ToDouble(list[HalfWay - 1 + 1].ToString());
double Number = Value1 + Value2;
Final_Number = Number / 2;
}
else
{
int HalfWay = list.Count / 2;
double Value1 = Convert.ToDouble(list[HalfWay].ToString());
Final_Number = Value1;
}
return Convert.ToString(Final_Number);
}
``````

That gets the exact middle number of all the numbers in the list, even if its got to middle it does that math also. I want to do that on both sides; heres an exmaple;

``````3 2 1 4 5 6
``````

The middle(Medium) of that list is 3.5. I want use math to find 2, which is between the start and the middle of the equation. also known as Q1 in the IQR. I also want to know how i can find the middle number between the medium(middle) and the end, which is 5.

I.E. So i can find 70,80 and 90 with code.

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What should the answer be for the list `4 3 2 1`? – SWeko Feb 4 '13 at 9:10
`list[list.Count/2]`, `list[list.Count/4]`, `list[3*list.Count/4]`, is that what you want? – Nolonar Feb 4 '13 at 9:12
@SWeko Not sure how to get the first and thired from such a small pool of numbers, but in math the numbers lists are always larger then 4. – Metab Feb 4 '13 at 9:12
Why not just split this list into two more lists and use the same method? `list1 = list.Where(x => x < Final_Number)`, `list2 = list.Where(x => x > Final_Number)` – E.T. Feb 4 '13 at 9:12
I'm not sure how to correctly do that, hence why i am needing some help :3 – Metab Feb 4 '13 at 9:13

Run the same metod on the following lists:

``````list1 = list.Where(x => x < Median)
list2 = list.Where(x => x > Median)
``````

`Find_Medium(list1)` will return first Quartile, `Find_Medium(list2)` will return third Quartile

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What's 'X'? (The total numbers?) – Metab Feb 4 '13 at 9:29
That's the syntax for a Lambda expression. msdn.microsoft.com/en-us/library/bb397687.aspx – E.T. Feb 4 '13 at 9:31

I just ran into the same issue, and checking the wikipedia entry for Quartile, it's a bit more complex than it first appears.

My approach was as follows: (which seems to work pretty well for all cases, N=1 on up)...

`````` /// <summary>
/// Return the quartile values of an ordered set of doubles
///   assume the sorting has already been done.
///
/// This actually turns out to be a bit of a PITA, because there is no universal agreement
///   on choosing the quartile values. In the case of odd values, some count the median value
///   in finding the 1st and 3rd quartile and some discard the median value.
///   the two different methods result in two different answers.
///   The below method produces the arithmatic mean of the two methods, and insures the median
///   is given it's correct weight so that the median changes as smoothly as possible as
///   more data ppints are added.
///
/// This method uses the following logic:
///
/// ===If there are an even number of data points:
///    Use the median to divide the ordered data set into two halves.
///    The lower quartile value is the median of the lower half of the data.
///    The upper quartile value is the median of the upper half of the data.
///
/// ===If there are (4n+1) data points:
///    The lower quartile is 25% of the nth data value plus 75% of the (n+1)th data value.
///    The upper quartile is 75% of the (3n+1)th data point plus 25% of the (3n+2)th data point.
///
///===If there are (4n+3) data points:
///   The lower quartile is 75% of the (n+1)th data value plus 25% of the (n+2)th data value.
///   The upper quartile is 25% of the (3n+2)th data point plus 75% of the (3n+3)th data point.
///
/// </summary>
internal Tuple<double, double, double> Quartiles(double[] afVal)
{
int iSize = afVal.Length;
int iMid = iSize / 2; //this is the mid from a zero based index, eg mid of 7 = 3;

double fQ1 = 0;
double fQ2 = 0;
double fQ3 = 0;

if (iSize % 2 == 0)
{
//================ EVEN NUMBER OF POINTS: =====================
//even between low and high point
fQ2 = (afVal[iMid - 1] + afVal[iMid]) / 2;

int iMidMid = iMid / 2;

//easy split
if (iMid % 2 == 0)
{
fQ1 = (afVal[iMidMid - 1] + afVal[iMidMid]) / 2;
fQ3 = (afVal[iMid + iMidMid - 1] + afVal[iMid + iMidMid]) / 2;
}
else
{
fQ1 = afVal[iMidMid];
fQ3 = afVal[iMidMid + iMid];
}
}
else if (iSize == 1)
{
//================= special case, sorry ================
fQ1 = afVal[0];
fQ2 = afVal[0];
fQ3 = afVal[0];
}
else
{
//odd number so the median is just the midpoint in the array.
fQ2 = afVal[iMid];

if ((iSize - 1) % 4 == 0)
{
//======================(4n-1) POINTS =========================
int n = (iSize - 1) / 4;
fQ1 = (afVal[n - 1] * .25) + (afVal[n] * .75);
fQ3 = (afVal[3 * n] * .75) + (afVal[3 * n + 1] * .25);
}
else if ((iSize - 3) % 4 == 0)
{
//======================(4n-3) POINTS =========================
int n = (iSize - 3) / 4;

fQ1 = (afVal[n] * .75) + (afVal[n + 1] * .25);
fQ3 = (afVal[3 * n + 1] * .25) + (afVal[3 * n + 2] * .75);
}
}

return new Tuple<double, double, double>(fQ1, fQ2, fQ3);
}
``````
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