Futility Closet An idler's miscellany of compendious amusements

“The pointing of the words is the solution, as follows: Thou shalt goe thither well and safely, and from thence come home alive againe never: at that field shalt thou be slaine.”

See “Ambiguous Lines.”

Black’s pawns have made 14 captures altogether, which accounts for every one of the missing white pieces. So the missing piece cannot be white. Both kings are in check, which is illegal, so the missing black piece must be on a2, blocking the rook’s check. The missing piece cannot be a queen or rook, as this would put the white king in an illegal double check. So it’s a black knight or a black bishop. And it can’t be a bishop — Black’s light-squared bishop never left its home square (the pawns on b7 and d7 have not moved), and all his pawns are still on the board, so Black has made no promotions. So the missing piece is a black knight on a2.

From Schachmatnaja komposizija, 2007.

If a and b are the first and nth terms of the progression, then the sum of the first n terms is S = (a + b)n/2. So 2S is divisible by n, and since 2S is a power of 2, so is n.

Let x be the number of steps on the escalator. I climb x – 20 steps in 60 seconds, and my wife climbs x – 16 steps in 72 seconds. This means the escalator ascends at a rate of 4 steps every 12 seconds, or 20 steps in 60 seconds. Its length is the sum of these 20 steps and the 20 steps I climb, or 40 steps.

1. Qg8! and the queen or rook will mate.

From Österreichische Lesehalle, June 1881.

Consider them in turn. A can’t be true because some of the other statements contradict one another (for example, C and D). B can’t be true because it implies that C is also true. Since A and B are false, C is also false, and likewise D. But E is true, and this makes F false. So the answer is E.

The number on the first milestone can be expressed as 10A + B, and the number on the second milestone is 10B + A. The number on the third milestone is either 100A + B or 100B + A.

Caroline’s speed is constant, so the distances between the milestones are equal. What’s the greatest this distance could be? Well, setting the two digits as far apart as possible would mean that one digit is 1 and the other is 9; then the first milestone would be at 19, the second at 91, and the third at 163. This doesn’t satisfy the puzzle, but it tells us that the number in the hundreds place must be 1 — Caroline doesn’t get as far as the 200-mile mark.

That means that either 100A or 100B must equal 100. Which is it? It must be 100A, since the number on the first milestone, where A stands for tens, is smaller than the number on the second milestone, where B stands for tens. So A is 1, the first milestone is 10 + B, the second milestone is 10B + 1, and the third milestone is 100 + B. Since the distances between milestones are equal, we have:

(10B + 1) – (10 + B) = (100 + B) – (10B + 1)
18B = 108
B = 6

A = 1 and B = 6, so the milestones carry the numbers 16, 61, and 106. Caroline’s speed is 45 mph.

(From Berloquin’s 1976 book 100 Numerical Games.)

1. No: (5/7) × (4/6) × (3/5) = 0.28571428571. The odds are slightly against you even if you draw only two olives.

From John Fisher, Never Give a Sucker an Even Break, 1976.

2. One is black and six are green. You can work this out mathematically as above, or make an observation: If there’s a single black olive, it has an equal chance of lying among the first seven olives or the second seven.

From Chris Maslanka, “A Bouquet of Brainteasers,” in Barry Cipra’s Tribute to a Mathemagician, 2005.

Penrose and his father Lionel have devised several such mazes — the Wolfram Demonstrations Project has a selection.

1. … b1=Q+! 2. Kxb1 Kd3 3. Ka1 Kc2 4. d4 (or d3) 5. Bb2#

Markham was frowning in deep perplexity.

‘You say it’s unusual for a bishop alone to mate?’ he asked Arnesson.

‘Never happens — almost unique situation. And that it should happen to Pardee of all people! Incomprehensible!’ he gave a short ironic laugh. ‘Inclines one to believe in a nemesis. You know, the bishop has been Pardee’s bête noir for twenty years — it’s ruined his life. Poor beggar! The black bishop is the symbol of his sorrow. Fate, by Gad! It’s the one chessman that defeated the Pardee gambit. Bishop-to-Knight-5 always broke up his calculations — disqualified his pet theory — made a hissing and a mocking of his life’s work. And now, with a chance to break even with the great Rubinstein, the bishop crops up again and drives him back into obscurity.’

(Thanks, Ray.)

1. Qf6! forces the knight to move, permitting 2. Qg7#.

From The Chess Amateur, 1921.

1. Qd1! and the queen will mate.

From The Dubuque Chess Journal, 1872.

1. Nb5! Kxb5 2. Qa4#. If 1. … Kd5 then 2. Qe6#.

From Mathematics and Chess, 1997.

The quiet 1. Kg5! forces Black to move a knight, permitting White to mate from e6 or g6. (Note that 1. Ke5 won’t work because of 1. … Nc6+!)

From Canadian Illustrated News, 1880.

Typically for Loyd, the answer is the least likely move on the board:

1. Nd2! (threatening 2. Rxe2#)

If 1…Kxf2 then 2.Qg3#
If 1…Kxd2 then 2.Qc3#
If 1…Rxe3 then 2.Qxe3#

Suppose it’s rational. Then log₁₀ 5 = a/b, where a and b are positive integers. Then 10^a/b = 5 and 10^a = 5^b. But these two values can never be equal — any positive integral power of 10 will end in 0, and any such power of 5 will end in 5. So log₁₀ 5 cannot be rational.

1. Qh2! threatens 2. Nf5#. If 1. … Kf4 then 2. Ne4#, and if 1. … Kd4 then the queen mates from h8.

From The Chess Players’ Chronicle, 1874.

Yes. Imagine that the king is on the lower left square and that on each move he takes a step along the main diagonal toward the upper right. After his first move and Black’s response, there must be no rooks on the lowest three ranks or the leftmost three files, or the king could immediately reach a threatened square. After his 998th move, the king arrives at a similar situation in the upper right: At this point there must be no rooks on the uppermost three ranks or the rightmost three files, for the same reason. This means that when the king begins his journey, all the rooks must be northeast of him, and when he finishes, all must be southwest. During the trip, then, each of Black’s 499 rooks must change both its rank and its file, in order to keep out of his way. This requires 499 x 2 = 998 moves. So, at the latest, Black will run out of time just a half-move too soon: White will squeeze Black’s maneuvering room down to zero on his own 998th move, just before Black evacuates the last rook.

From Miodrag Petkovic, Mathematics and Chess, 1997.