not sure it has a name; more formally stated, it would be:
|a-b| = 100
|c-b| = 20
|c-d| = 90
|a-d| = 170
|x| stands for the absolute value of x
As far as the generalized system goes, if you have N equations of this type with k unknowns, you have N choices of sign. Without loss of generality (because any solution yields a second solution with reversed ordering) you can choose a sign for the first equation, and a particular value for one of the unknowns (since the whole thing can slide left and right in position). Then you have 2N-1 possibilities for the remaining equations, and all you have to do is go through them to see which ones, if any, have solutions. Because the coefficients are all +/- 1 and each equation has 2 unknowns, you just go through them one by one:
Step 1: Without loss of generality,
choose a sign for one equation
and pick a value for one unknown:
a-b = 100, a = 0
Step 2: Choose signs for the remaining absolute values.
a = 0
a-b = 100
c-b = 20
c-d = 90
a-d = 170
Step 3: go through them one by one to solve / verify there aren't conflicts
(time = N steps).
0-b = 100 => b = -100
c-b = 20 => c = -80
c-d = 90 => d = -170
a-d = 170 => OK => (0,-100,-80,-170) is a solution
Step 4: if this doesn't work, go back through the possible choices of sign
and try again, starting at step 2.
Full set of solutions is (0,-100,-80,-170)
and its negation (0,100,80,170) and any number x<sub>0</sub> added to all terms.
So an upper bound for the runtime is O(N * 2N-1) ≡ O(N * 2N).
I suppose there could be a shortcut but no obvious one comes to mind.