Squares have four sides of equal length. In rectangles, the opposite sides are equal to one another. In both shapes, the internal angles are all 90°.
no, but a square is always a rectangle. You see, squares have 4 equal sides. Rectangles don't HAVE to have 4 equal sides, but one side is equal to the opposite. So, all squares are rectangles, but not are rectangles are squares.
Noo... it equals one rectangle
Parallelograms (including rectangles and squares)
Using all 13 squares, and not counting different orientations, only one.
Squares have four sides of equal length. In rectangles, the opposite sides are equal to one another. In both shapes, the internal angles are all 90°.
9 (six rectangles = three squares)
One of the properties of squares is four equal sides. Rectangles don't have equal sides
no, but a square is always a rectangle. You see, squares have 4 equal sides. Rectangles don't HAVE to have 4 equal sides, but one side is equal to the opposite. So, all squares are rectangles, but not are rectangles are squares.
Noo... it equals one rectangle
Parallelograms (including rectangles and squares)
All rectangles contain a square in which all four sides of the square are the same as one of the short sides of the rectangle. All squares are special types of rectangles.
There is only one rectangle containing exactly 11 squares.
Using all 13 squares, and not counting different orientations, only one.
The above statement is not true since some rectangles ARE squares. Squares are a special type of a rectangle - one in which all sides are of equal length. In other words, the set of all squares is a subset of the set of all rectangles.
A reversible statement is one where the truth of the statement would still hold if the subject and predicate were reversed. For example, "All squares are rectangles" is reversible because it is also true that "All rectangles are squares."
No indeed, but every square is a rectangle. Rectangles have four sides like squares, but they don't have all sides congruent to one another. All rectangles do not possess the same symmetrical lines as squares.