The flag measures 4 feet by 3 feet, so its diagonal is 5 feet. “All you need to do is to deduct half the length of this diagonal (2 1/2 feet) from a quarter of the distance all round the edge of the flag (3 1/2 feet) — a quarter of 14 feet. The difference (1 ft.) is the required width of the arm of the red cross.”

Proof:

If the flag measures 4 feet by 3 feet, the red area is given by

4x + 3x – x² = 6,

so

x² – 7x + 6 = 0.

Solving the quadratic equation gives x – 3.5 = ± 2.5, and as x can’t be 6, the answer must be 1 foot.

From Dudeney’s Amusements in Mathematics, via Erwin Brecher’s Ultimate Book of Puzzles, Mathematical Diversions, and Brainteasers (1996).

04/18/2025 UPDATE: Reader Catalin Voinescu has a simpler solution:

“Consider: the banner has the same areas of red and white as a banner of the same size with a red L of the same thickness as the cross along two of the edges. (Cut the original banner in four and rearrange the fragments.) In this case, the white area is a rectangle. The problem states that it must be half of the area of the flag, that is, 6 sq ft. Its sides are shorter than the sides of the banner by the same amount each, namely, the thickness of the red L. Without any equation, one immediately notices that 3 by 2 gives 6, and that’s 1 less than 4 by 3. So the red part is 1 ft wide.”

(Thanks, Catalin.)

In place of each decagon, consider a circle whose circumference is 99 units long and divided into segments whose length corresponds to the vertex integers, in order. So if the first few vertices around one decagon bear the integers 14, 9, 30, then the corresponding segments of that circle will have those lengths.

Now superimpose the two circles and rotate one of them. If at any point two pairs of segment endpoints coincide simultaneously, then we have our solution — these endpoints identify two sets of successive vertices on the two decagons that produce the same sum.

What if we never get two simultaneous coincidences? Well, that’s impossible: During a full rotation, each endpoint on the first circle must encounter 10 endpoints on the other circle, so there are 100 coincidences altogether. These must occur over the course of 99 discrete opportunities (the lengths of the two circles’ circumferences), so some two coincidences must occur together.

From the January-February 1995 issue of Quantum.

OILILY and BAILIWICK.

See Pillow Talk.

Insert a C before each capitalized word (except those that begin sentences):

“The Coptic creed has a chaste charm. It chose, one assumes, not to be clever; it neither cheats the cripple, nor chides the crazed sinner for his crude crime; it is not cold. Then cleave to it; ere thy grave closes, thou mayst find here the chart to the crest thou cravest to climb.”

From The Game of Words, 1987.

No. Call the current six numbers a₁ … a₆. Now I = a₁ – a₂ + a₃ – a₄ + a₅ – a₆ is initially 2, and I will remain unchanged no matter what we do. So there’s no way to reach I = 0.

Via Arthur Engel, Problem-Solving Strategies, 1999.

Yes.

(From Quantum, November-December 1994.)

Henle’s solution:

The black king is in check, and the check must have been discovered when the white king moved from f3 to e2. But how is this possible? The white king would itself have been in check in two different ways on f3. How could Black have inflicted two checks at once?

The answer is that a black pawn must have stood on f2, blocking the rook’s check. This pawn then captured some white piece on e1, promoting to a knight and inflicting a double check. So, from this position:

1. … fxe1=N+ 2. Ke2+.

(Jim Henle, “The Entertainer,” Mathematical Intelligencer 40:2 [June 2018], 76-80.)

If one of the men is unacquainted with four of the others, then those four know one another and we’re done.

If not, then this means that each man is mutually acquainted with at least five of the others. It can’t be exactly five in every case, because the total number of acquaintances in the room must be an even number. Hence someone is acquainted with at least six men.

Among those six, three know one another, and they together with the man himself make four.