Is there a way to concatenate two arrays in Excel without VBA?

I am trying to create a formula that returns the concatenation of two arrays of different lengths. I need this concatenation for part of another formula and I would like to avoid "helper" rows, if possible.

See below for example data. The goal is to have the output be `{10;11;12;13;20;21;22}`. Of course, this can easily be hardcoded into the formula but these values are dynamic so that is not an option.

I tried the following:

``````{A1:A4;B1:B3}
``````

but this is apparently not valid Excel syntax.

Is there a solution?

Excel cannot directly concatenate arrays in the way you describe (i.e. simply combining them back to back.) However, there is a (complicated) solution to this problem without using helper functions.

Essentially what you need to do is convert `{10;11;12;13}` to `{10;11;12;13;0;0;0}` and convert `{20;21;22}` to `{0;0;0;0;20;21;22}`. Once you have that result, you can add the two arrays of length 7 together to get the desired result.

So how do you add zeros to the beginning or end of an array?

The answer is to use matrix multiplication (`MMULT` Excel built-in function) in a clever way.

I won't explain all of the mathematics as to why this is the result because I think it gets too off-topic from programming but ultimately the following matrix multiplication equation gives you the desired result:

``````[1 0 0 0]      
[0 1 0 0] *  = 
[0 0 1 0]      
[0 0 0 1]      
[0 0 0 0]          [ 0]
[0 0 0 0]          [ 0]
[0 0 0 0]          [ 0]
``````

Or in Excel, you can type this to get you the result: (I added line breaks for increased readability.)

``````= MMULT({1,0,0,0;
0,1,0,0;
0,0,1,0;
0,0,0,1;
0,0,0,0;
0,0,0,0;
0,0,0,0},A1:A4)
``````

If you highlight this formula in the cell and press the F9 key, you should notice it will give you the desired result of `{10;11;12;13;0;0;0}`.

Similarly, the following formula will get you the desired result of `{0;0;0;0;20;21;22}`:

``````= MMULT({0,0,0;
0,0,0;
0,0,0;
0,0,0;
1,0,0;
0,1,0;
0,0,1},B1:B3)
``````

Summing these two values together will get the desired final result which is `{10;11;12;13;20;21;22}`.

NOTE

At this point, this might be enough information for your wants/needs. However, for large arrays, it may be too cumbersome to hard-code these matrices of 1's and 0's into your formula. If this is the case, continue reading which tells you how to generate these matrices of 1's and 0's automatically rather than hard-coding them.

How do we generate these large matrices of 1's and 0's shown above automatically?

Again without explaining much of the "why" because I think the discussion will get too long and off-topic, here is a formula that generates the first matrix of 1's and 0's above:

``````= (ROW(INDIRECT(ADDRESS(1,1)&":"&ADDRESS(ROWS(A1:A4)+ROWS(B1:B3),1)))
``````

The formula for the 2nd matrix of 1's and 0's is slightly different:

``````= (ROW(INDIRECT(ADDRESS(1,1)&":"&ADDRESS(ROWS(A1:A4)+ROWS(B1:B3),1)))
``````

FINAL FORMULA

The final formula to concatenate two (vertical) arrays is the following: (Several line breaks added for increased readability)

``````= MMULT(
A1:A4)
+MMULT(
B1:B3)
``````

FINAL NOTES/THOUGHTS

The advantage to using this formula is that it allows arrays to be concatenated without using VBA. The disadvantage is that this method for concatenating arrays only works with numbers, not text. (This is because `MMULT` requires numbers.)

• Without the Volatile formulas: `=MMULT( (ROW(\$A\$1:INDEX(\$A:\$A,ROWS(\$A\$1:\$A\$4)+ROWS(\$B\$1:\$B\$3))) =COLUMN(\$A\$1:INDEX(\$1:\$1,ROWS(\$A\$1:\$A\$4))))+0, \$A\$1:\$A\$4) +MMULT( (ROW(\$A\$1:INDEX(\$A:\$A,ROWS(\$A\$1:\$A\$4)+ROWS(\$B\$1:\$B\$3))) =(COLUMN(\$A\$1:INDEX(\$1:\$1,ROWS(\$B\$1:\$B\$3))))+ROWS(\$A\$1:\$A\$4))+0, \$B\$1:\$B\$3)` – Scott Craner Sep 12 '17 at 18:42
• Thanks Scott. I always wondered if there was a way around using `INDIRECT(ADDRESS(...`. But I typically avoid checking entire rows/columns (e.g. `A:A`) in formulas because it seems to me like that would slow things down considering a spreadsheet contains literally over a million rows. Is using your method more efficient than `INDIRECT`? – ImaginaryHuman072889 Sep 12 '17 at 19:14
• There is no detriment in INDEX to full column/rows as it only sets the range in which to look, it does not actually load the whole range into memory. It does not use any more memory than `\$A\$7` – Scott Craner Sep 12 '17 at 19:16
• Thanks Scott, this is good to know for future use, as I often find myself using `INDIRECT(ADDRESS(...` – ImaginaryHuman072889 Sep 12 '17 at 19:20

For numeric arrays:

``````=SMALL((A1:A4,B1:B4),ROW(INDIRECT("1:"&COUNT(A1:A4)+COUNT(B1:B4))))
``````

or

``````=SMALL((A1:A4,B1:B4),ROW(INDEX(A:A,1):INDEX(A:A,COUNT(A1:A4)+COUNT(B1:B4))))
``````
• Can you please explain how these formulas solve the question? – Dominique Dec 10 '18 at 11:28
• The formula gives set of all values of the combined range (A1:A4,B1:B4) ordered from a smallest one (Nr = 1) to a largest one (Nr = COUNT(A1:A4)+COUNT(B1:B4) = members quantity). This way of combination of arrays via brackets (arr1,arr2,...) probably works only with functions SMALL() and LARGE(). Any way the formula works and it is simple )) – 4udoudo Dec 10 '18 at 12:56
• @4udoudo Interesting formula, doesn't answer the question though. The question is how to concatenate two arrays. Your answer concatenates two arrays and sorts them. – ImaginaryHuman072889 Dec 10 '18 at 21:50
• Sorry, but in the start task is written "The goal is to have the output be {10;11;12;13;20;21;22}" and nothing is said about sorting. With the formula I proposed the goal is reached. – 4udoudo Dec 11 '18 at 7:55
• @4udoudo The question states that the desired output should be `{A1:A4;B1:B3}`. This is not the output of your formula. The fact that the example input data is sorted is just a coincidence. By the way, I think your formula is clever, just saying it doesn't answer the question. – ImaginaryHuman072889 Dec 12 '18 at 12:01

For what it's worth, here is a solution that concatenates two any two vertical arrays (without the limitation that the data must be numbers).

Here is the array formula: (e.g. combining `A1:A4` and `C7:C9`)

``````= INDEX(CHOOSE({1,2},A1:A4,C7:C9),
N(IF({1},ROW(INDEX(\$A:\$A,1):INDEX(\$A:\$A,ROWS(A1:A4)+ROWS(C7:C9)))-IF(
ROW(INDEX(\$A:\$A,1):INDEX(\$A:\$A,ROWS(A1:A4)+ROWS(C7:C9)))<=ROWS(A1:A4),0,ROWS(A1:A4)))),
N(IF({1},2-(ROW(INDEX(\$A:\$A,1):INDEX(\$A:\$A,ROWS(A1:A4)+ROWS(C7:C9)))<=ROWS(A1:A4)))))
``````

And here is the array formula to combine two horizontal arrays (e.g. `A1:D1` and `C3:E3`)

``````= INDEX(CHOOSE({1;2},A1:D1,C3:E3),
N(IF({1},2-(COLUMN(INDEX(\$1:\$1,1):INDEX(\$1:\$1,COLUMNS(A1:D1)+COLUMNS(C3:E3)))
<=COLUMNS(A1:D1)))),N(IF({1},COLUMN(INDEX(\$1:\$1,1):INDEX(\$1:\$1,COLUMNS(A1:D1)+
COLUMNS(C3:E3)))-IF(COLUMN(INDEX(\$1:\$1,1):INDEX(\$1:\$1,COLUMNS(A1:D1)+COLUMNS(C3:E3)))
<=COLUMNS(A1:D1),0,COLUMNS(A1:D1)))))
``````

TLDR and self guided - Here's the example workbook.

Yes, there is a way to join arrays in pre-office 2016. I know this has been answered by ImaginaryHuman above, but I have another way, it returns an array, and it's a little easier to read (IMHO). I'm going to break out evolutions of the formula so that you can find one that fits your use case. I've highlighted the use cases in bold so you can find yours quickly. I know this is rather verbose, but I am the kind of person who likes to know how a solution works, so I'm going to try to give you the same courtesy.

The formula relies on nested `IF` statements and `INDEX`/`CHOOSE` structures. It works with ranges, named ranges, and even table columns. All of my examples show four ranges, hence three `IF` statements, but this can be strung up to (I think) 64 ranges if you care for that many nested `IF` statements.

For these examples, the data ranges are `A3:B6`, `A9:B11`, `A14:B19`, and `A22:B32`. The resulting array formula is put in the range `E3:E26` and finished with a `Ctrl+Shift+Enter` to make it an array formula. Your data can go wherever you like - you are not tied to these ranges - just substitute your ranges appropriately.

If your data is in contiguous ranges:

``````=IF(ROW()-ROW(E3)<ROWS(A3:A6),INDEX(A3:B6,ROW()-ROW(E3)+1,COLUMN()-COLUMN(E3)+1),
IF(ROW()-ROW(E3)<ROWS(A3:A6)+ROWS(A9:A11),INDEX(A9:B11,ROW()-ROW(E3)-ROWS(A9:A11),COLUMN()-COLUMN(E3)+1),
IF(ROW()-ROW(E3)<ROWS(A3:A6)+ROWS(A9:A11)+ROWS(A14:A19),INDEX(A14:B19,ROW()-ROW(E3)-ROWS(A3:A6)-ROWS(A9:A11)+1,COLUMN()-COLUMN(E3)+1),
INDEX(A22:B32,ROW()-ROW(E3)-ROWS(A3:A6)-ROWS(A9:A11)-ROWS(A14:A19)+1,COLUMN()-COLUMN(E3)+1))))
``````

How it works:

1. The `IF` statement makes sure that we are in the first range by subtracting the current row from the top of the output range in cell `E3` and comparing it to the number of cells in the first input range of `A3:B6`.
2. The INDEX statement chooses an item from the first input range of `A3:B6`, given a row and column offset calculated from cell `E3`.
3. If the row is not in the first range it moves on to the next `IF` statement, which repeats the process but compares the current row of the array to the length of the first two ranges. The process repeats for any further nested `IF` statements.

If your data is not in contiguous ranges, you need a column showing what range the data originally came from, or both:

``````=IF(ROW()-ROW(E3)<ROWS(A3:A6),INDEX(CHOOSE({1,2,3},{1},A3:A6,B3:B6),ROW()-ROW(E3)+1,COLUMN()-COLUMN(E3)+1),
IF(ROW()-ROW(E3)<ROWS(A3:A6)+ROWS(A9:A11),INDEX(CHOOSE({1,2,3},{2},A9:A11,B9:B11),ROW()-ROW(E3)-ROWS(A3:A6)+1,COLUMN()-COLUMN(E3)+1),
IF(ROW()-ROW(E3)<ROWS(A3:A6)+ROWS(A9:A11)+ROWS(A14:A19),INDEX(CHOOSE({1,2,3},{3},A14:A19,B14:B19),ROW()-ROW(E3)-ROWS(A3:A6)-ROWS(A9:A11)+1,COLUMN()-COLUMN(E3)+1),
INDEX(CHOOSE({1,2,3},{4},A22:A32,B22:B32),ROW()-ROW(E3)-ROWS(A3:A6)-ROWS(A9:A11)-ROWS(A14:A19)+1,COLUMN()-COLUMN(E3)+1))))
``````

How it works:

1. All the principles for the `IF` and `INDEX` statements remain the same as above.
2. A `CHOOSE` statement is added which allows you to select non-contiguous columns of data or a static array with whatever identifier you want for each range. In this case, I went with numbers (1,2,3,4).
3. The `CHOOSE` statement can have as many columns as you like - just change the first argument to `{1,2,3,4}` for four columns and add your fourth column as the last argument. Do the same for any subsequent columns (i.e. `{1,2,3,4,5}` and add your fifth column as the last argument.

If you have horizontal data instead of vertical data, you can use `TRANSPOSE` to make the previous example work. Just nest the `TRANSPOSE` function inside the `CHOOSE` function like this:

``````CHOOSE({1,2,3},{1},TRANSPOSE(A3:C3),TRANSPOSE(A4:C4)
``````

You can clean up the formula significantly with named ranges or tables. This example builds on the previous one allowing data not in contiguous ranges and provides an identifier column showing where the data came from:

``````=IF(ROW()-ROW(E3)<ROWS(Table1),INDEX(CHOOSE({1,2,3},{1},Table1[Column1],Table1[Column2]),ROW()-ROW(E3)+1,COLUMN()-COLUMN(E3)+1),
IF(ROW()-ROW(E3)<ROWS(Table1)+ROWS(Table2),INDEX(CHOOSE({1,2,3},{2},Table2[Column1],Table2[Column2]),ROW()-ROW(E3)-ROWS(Table1)+1,COLUMN()-COLUMN(E3)+1),
IF(ROW()-ROW(E3)<ROWS(Table1)+ROWS(Table2)+ROWS(Table3),INDEX(CHOOSE({1,2,3},{3},Table3[Column1],Table3[Column2]),ROW()-ROW(E3)-ROWS(Table1)-ROWS(Table2)+1,COLUMN()-COLUMN(E3)+1),
INDEX(CHOOSE({1,2,3},{4},Table4[Column1],Table4[Column2]),ROW()-ROW(E3)-ROWS(Table1)-ROWS(Table2)-ROWS(Table3)+1,COLUMN()-COLUMN(E3)+1))))
``````

If that isn't enough, you can do more housekeeping for readability by creating some named values. The first thing that can be done is to define at what row we start getting data from each table. For this example, I have named these `Table2_UL`, `Table3_UL`, and `Table4_UL`. Their code formula in the name manager looks like this:

1. `Table2_UL`: `=ROWS(Table1)`
2. `Table3_UL`: `=Table2_UL+ROWS(Table2)`
3. `Table4_UL`: `=Table3_UL+ROWS(Table3)`

As you can see, each one builds upon the last so its output is dynamic. We now have a much more readable formula:

``````=IF(ROW()-ROW(E3)<Table2_UL,INDEX(CHOOSE({1,2,3},{1},Table1[Column1],Table1[Column2]),ROW()-ROW(E3)+1,COLUMN()-COLUMN(E3)+1),
IF(ROW()-ROW(E3)<Table3_UL,INDEX(CHOOSE({1,2,3},{2},Table2[Column1],Table2[Column2]),ROW()-ROW(E3)-Table2_UL+1,COLUMN()-COLUMN(E3)+1),
IF(ROW()-ROW(E3)<Table4_UL,INDEX(CHOOSE({1,2,3},{3},Table3[Column1],Table3[Column2]),ROW()-ROW(E3)-Table3_UL+1,COLUMN()-COLUMN(E3)+1),
INDEX(CHOOSE({1,2,3},{4},Table4[Column1],Table4[Column2]),ROW()-ROW(E3)-Table4_UL+1,COLUMN()-COLUMN(E3)+1))))
``````

But that's not enough for me. I want to get rid of all those nasty references to `ROW()` and `COLUMN()`. We can do that by defining two more values in the name manager that keep track of our current row and column for us:

1. `Output_CC`: `=COLUMN()-COLUMN(Sheet1!E3)+1`
2. `Output_CR`: `=ROW()-ROW(Sheet1!E3)+1`

Finally, we have something that is near human readable:

``````=IF(Output_CR-1<Table2_UL,INDEX(CHOOSE({1,2,3},{1},Table1[Column1],Table1[Column2]),Output_CR,Output_CC),
IF(Output_CR-1<Table3_UL,INDEX(CHOOSE({1,2,3},{2},Table2[Column1],Table2[Column2]),Output_CR-Table2_UL,Output_CC),
IF(Output_CR-1<Table4_UL,INDEX(CHOOSE({1,2,3},{3},Table3[Column1],Table3[Column2]),Output_CR-Table3_UL,Output_CC),
INDEX(CHOOSE({1,2,3},{4},Table4[Column1],Table4[Column2]),Output_CR-Table4_UL,Output_CC))))
``````

If we really want to take it all the way, we can turn our `CHOOSE` statements into named values as well. Just do the following for each of your input tables in the Name Manager, making sure to give each a unique name:

`Table1_IN`: `=CHOOSE({1,2,3},{1},Table1[Column1],Table1[Column2])`

Now we can read the formula really easy:

``````=IF(Output_CR-1<Table2_UL,INDEX(Table1_IN,Output_CR,Output_CC),
IF(Output_CR-1<Table3_UL,INDEX(Table2_IN,Output_CR-Table2_UL,Output_CC),
IF(Output_CR-1<Table4_UL,INDEX(Table3_IN,Output_CR-Table3_UL,Output_CC),
INDEX(Table4_IN,Output_CR-Table4_UL,Output_CC))))
``````

Again, though, that is not enough because you cannot turn on the filter and sort arrays A-Z. You get the error "You can't change part of an array." There is a workaround, though! It requires a helper column and duplicating your output. It can be duplicated to a plain old range or into a table. To allow you to both sort and filter your data, create a helper column to the left of the array output, in this case, starting in `D3`. If your data does not need to be ranked (like all text columns), create static numbering (1, 2, 3, 4, etc). In this example, column `G` contains a number to be ranked. If it does need to be ranked enter the following formula in `D3` and drag it down:

``````=RANK.EQ(G3,G\$3:G\$26,0)+COUNTIF(G\$3:G3,G3)-1
``````

Change the final argument to `1` if you need an ascending ranking instead. You now have an out of order ranking if your data was ranked or an unsortable array with a static number next to it if not. Now we duplicate the data into a range or table. In column `I`, starting at `I3`, create static numbering as long as the dataset (ie 1, 2, 3, 4). Now to the right in cell `J3` enter a `VLOOKUP` that refers to the data in the source array:

``````=VLOOKUP(\$I3,\$D\$3:\$G\$26,COLUMNS(\$I\$3:J3),FALSE)
``````

Drag the formula down and then drag it right. You can now sort and filter your data just as if it was a normal range.