As a Tetris player, it’s 2 T-pieces and a line-piece. Each Tetris piece is 4 squares (Tetris = tetra (meaning 4) + Tennis). 3 Tetris pieces times 4 squares each = 12 tiles
But isn’t that how many imaginary tiles there are? Thats not counting the tiles that aren’t there. You’re just deciding the number of imaginary tiles is the same as the missing tiles.
You can see that there are 4 rows where tiles are missing, and you can use the minimum and maximum size of the adjacent tiles in a row to assume how many can fit in each row, because the lines formed by edges WILL all line up. It’s all about deciding where the boundaries are.
12, right?
For anyone having trouble visualizing it…
Ty; the weird angle was messing with my brain.
As a Tetris player, it’s 2 T-pieces and a line-piece. Each Tetris piece is 4 squares (Tetris = tetra (meaning 4) + Tennis). 3 Tetris pieces times 4 squares each = 12 tiles
Or 3 Z pieces…
As a Minecraft player, this checks out,
Assuming they are square tiles, yes. It’s also possible to tile the area with 6 2x1 tiles.
But all the tiles around the hole are squares
Not necessarily, they could be 2x1 rectangles, half dark and half light
Fair enough
More like 4 2×1 tiles:
Those are not 2x1 tiles.
My bad.
https://www.youtube.com/watch?v=pN5CtyAhnlc
Yes. That’s how many I counted.
How can you count something that isn’t there?
Just keep imagining another tile until you can’t anymore.
But isn’t that how many imaginary tiles there are? Thats not counting the tiles that aren’t there. You’re just deciding the number of imaginary tiles is the same as the missing tiles.
I stand by my decision.
respect
Behold! The invention of negative numbers.
You can see that there are 4 rows where tiles are missing, and you can use the minimum and maximum size of the adjacent tiles in a row to assume how many can fit in each row, because the lines formed by edges WILL all line up. It’s all about deciding where the boundaries are.
Yes