2010 AMC 10B Problem 23

Below is the professionally curated solution for Problem 23 of the 2010 AMC 10B, from LIVE by Po-Shen Loh. You can also try the full timed exam, view all 2010 AMC 10B solutions, or check the answer key.

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Concepts:arrangements with restrictionscasework

Difficulty rating: 2030

23.

The entries in a 3×33 \times 3 array include all the digits from 11 through 9,9, arranged so that the entries in every row and column are in increasing order. How many such arrays are there?

1818

2424

3636

4242

6060

Solution:

Note that 11 and 99 must be in the top left and bottom right corners respectively. We must also have that 22 and 88 are next to these squares.

We can then case on the center square. Note that the only possible values are 4,4,5,5, or 6.6.

Case 1: the center is 44

The 33 is necessarily next to the 1,1, since there is no other option that is less than 4.4.

Any number can be in the square next to the 8,8, but the other two squares are then fixed. There are 223=12 2 \cdot 2 \cdot 3 = 12 cases (two places for the 2,2, two places for the 8,8, and three choices for the square adjacent to 88).

Case 2: the center is 55

We can case on the position of the 3.3. If the 33 is in the top right square, the 44 is necessarily next to the 1.1.

If the 88 is above the 9,9, then the other two squares are fixed. If it is to the left of the 9,9, the other two squares can be filled arbitrarily.

Now consider when the 33 is below the 1.1. There are two spots for the 8,8, and the square next to the 88 can be any number.

The other two squares are then fixed. This means that this case has a total of 2(1+2+23)=18. 2(1 + 2 + 2 \cdot 3) = 18. We multiply by two since the 22 can be either to the right of or below the 1.1.

Case 3: the center is 66

This is similar to case 11 since the 77 is fixed instead of the 3.3.

The total number of arrangements is then 12+18+12=42. 12 + 18 + 12 = 42.

Thus, D is the correct answer.

Problem 23 in Other Years