Call the original table A and represent it as the sum of two tables B and C:

Now if we assign minus signs correspondingly to all three tables as described in the problem, then the sum of each row in Table B and each column in Table C will be zero. It follows that the sum of all the numbers in Tables B and C combined, and hence in Table A, is zero.

This solution is by Eric Zhang. If 10a + b is a multiple of 7, then 10a + b = 7n, where n is an integer. Rearrange that as b = 7n – 10a and substitute it into a – 2b and you get

a – 2b = a – 2(7n – 10a) = 21a – 14n,

which is a multiple of 7.

They’re the same as the numbers in the first row. Added colors make it easier to see that each number in row n counts how many segments of each type (color) occur in row n – 1. Remarkably, the loop closes after four cycles. (Thanks, Lee.)

This solution is by Geneviève Lalonde. Call a committee an even committee if it has an even number of members and an odd committee if it has an odd number of members.

If the total number of people in the group is odd, then for each even committee the total number of remaining people is odd (and thus constitutes an odd committee). And vice versa: For each odd committee, the number of people who aren’t in that committee is even and constitutes an even committee. So there’s a one-to-one correspondence between the even and odd committees, and their numbers must be equal.

If the total number of people in the group is even, then consider one person (call him John). For each even committee C that doesn’t contain John, there’s a corresponding odd committee made up of everyone who’s not in C except for John. And for each even committee C that contains John, there’s a corresponding odd committee made up of John plus everyone who’s not in C. So again there’s a one-to-one correspondence between the even and odd committees, and we conclude that their numbers are equal.

1. Be4! and mate must follow.

From Elementary Chess Problems, 1880.

Call one of the 10-gallon cans A and the other B.

Fill the 5-quart pail from can A.

Pour the 5-quart pail into the 4-quart pail.

Empty the 4-quart pail into can A.

Pour the 5-quart pail into the 4-quart pail.

Fill the 5-quart pail from can A.

Fill the 4-quart pail from the 5-quart pail.

Empty the 4-quart pail into can A.

Fill the 4-quart pail from can B.

Pour the 4-quart pail into can A.

This fills can A and leaves 2 quarts in the 4-quart pail. “Thus the milkman has supplied each of his customers with exactly two quarts of milk and solved his perplexing problem.”

From Loyd’s Cyclopedia of Puzzles, 1914. See also Well Done.

(From the Eureka Digital Archive, published under a Creative Commons license.)

The key is to notice that if all the liars were changed to truth-tellers and vice versa, none of the answers would change. So if the fraction x can be determined, it must have the property that x = 1 – x, and x must be 1/2.

Divide the coins arbitrarily into piles of 30, 30, and 41 coins, calling these respectively A, B, and C. Now weigh A against B. If these balance, then X must be in C; combine A and B and weigh 41 of these coins against the 41 coins in C and you’ll find out whether X is heavy or light.

If A and B don’t balance, then one of those groups contains the bad coin. For definiteness, suppose that A goes down in the weighing. That means either that A contains the bad coin and it’s heavy or that B contains the bad coin and it’s light. So determining where X is will also tell us its relative weight.

Divide A in half and weigh these halves against each other. If they balance then the coins are all good and X must be in B. If they don’t balance then X is in A.

(Obviously the same plan will work with certain pile sizes other than 30, 30, and 41, but that arrangement will do the job.)