It seems that there are many useful applications for matrix math where not all entries in a given matrix share the same units. I want to look into type systems that could track these units and ensure we don't make mistakes (similar to a number of libraries and languages that already do dimension checking for scalar arithmetic). I'll give an example of what I am talking about, and then I have a few questions building from there.
(cribbing a random mixed-units linear programming example from here, although this is not a homework question as will hopefully become clear)
Bob’s bakery sells bagel and muffins. To bake a dozen bagels Bob needs 5 cups of flour, 2 eggs, and one cup of sugar. To bake a dozen muffins Bob needs 4 cups of flour, 4 eggs and two cups of sugar. Bob can sell bagels in $10/dozen and muffins in $12/dozen. Bob has 50 cups of flour, 30 eggs and 20 cups of sugar. How many bagels and muffins should Bob bake in order to maximize his revenue?
So let's put that in matrix form (arbitrary concrete syntax...):
A = [ [ 5 cups of flour / dozen bagels, 4 cups of flour / dozen muffins ], [ 2 eggs / dozen bagels, 4 eggs / dozen muffins ], [ 1 cups of sugar / dozen bagels, 2 cups of sugar / dozen muffins ] ] B = [ [ 10 dollars / dozen bagels, 12 dollars / dozen muffins ] ] C = [ [ 50 cups of flour ], [ 30 eggs ], [ 20 cups of sugar ] ]
We now want to maximize the inner product
B * X such that
A * X <= C and
X >= 0, an ordinary linear programming problem.
In a hypothetical language with unit checking, how would we ideally represent the types of these matrices?
I'm thinking that an m by n matrix only needs m + n units and not the full m * n units, because unless the units are distributed in a sensible way into rows and columns then the only sensible operation remaining is to add/subtract the fully general matrix with another of the exact same shape or multiply it by a scalar.
What I mean is that the arrangement of units in
A is far more useful than that in:
WTF = [ [ 6 pigeons, 11 cups of sugar ], [ 1 cup of sugar, 27 meters ], [ 2 ohms, 2 meters ] ]
And that furthermore situations like the latter simply don't arise in practice. (Anyone got a counterexample?)
Under this simplifying assumption, we can represent the units of a matrix with m + n units as follows. For each of the m rows, we figure out what units are common to all entries in that row, and similarly for the n columns. Let's put the row units in column vectors and the column units in row vectors because that makes
Units(M) = RowUnits(M) * ColUnits(M), which seems like a nice property. So, in the example:
RowUnits(A) = [ [ cups of flour ], [ eggs ], [ cups of sugar ] ] ColUnits(A) = [ [ dozen bagels ^ -1, dozen muffins ^ -1 ] ] RowUnits(B) = [ [ dollars ] ] ColUnits(B) = [ [ dozen bagels ^ -1, dozen muffins ^ -1 ] ] RowUnits(C) = [ [ cups of flour ], [ eggs ], [ cups of sugar ] ] ColUnits(C) = [ [ 1 ] ]
It seems that (although I'm not sure how to prove it...) the units of
M1 * M2 are
RowUnits(M1 * M2) = RowUnits(M1),
ColUnits(M1 * M2) = ColUnits(M2), and for the multiplication to make sense we require
ColUnits(M1) * RowUnits(M2) = 1.
We can now infer units for
X, because the expression
A * X <= C must mean that
A * X and
C have the same units. This means that
RowUnits(A) = RowUnits(C) (which checks out),
ColUnits(X) = ColUnits(C), and
RowUnits(X) is the element-wise reciprocal of the transpose of
ColUnits(A), in other words
RowUnits(X) = [ [ dozen bagels ], [ dozen muffins ] ].
("Hooray", I hear you cheering, "we have just gone around the moon to look at something completely obvious!")
My questions are these:
- Can you think of real world examples where elements of a matrix have units that do not fall into "row units" and "column units" like this?
- Can you think of an elegant way to deal with situations where the same unit is a factor in every cell, and so it could equivalently be placed in every "row" or in every "column" and thus the row units and column units are not a unique representation? What should the side condition be that holds them in "lowest terms" and removes silliness like multiplying every row by
furlongs ^ 17just so that you can multiply every column by
furlongs ^ -17?
- Can you prove the rules I mentioned for propagating these unit annotations through matrix multiplications?
- Can you discover/show the rule for how these unit annotations propagate through matrix inverse operations? Some hand calculations I did with a 2x2 matrix suggest that the units of
Inverse(M)are the element-wise reciprocal of the units of
Transpose(M), but I don't know how to show it for the general case or even if it is true for the general case.
- Are you aware of any academic work on these issues? Or software that performs this static analysis for programs in some language? I may be using the wrong search terms, but I am having trouble finding anything.
My real-world applications of interest are preventing screw ups in signal processing/controller software by making sure that all the filter gains etc have the correct units everywhere, using matrices like these with different units in different cells is extremely common in those applications.