A permutation, regarded as a function from the set
to itself, is one-to-one and onto.
Therefore, each permutation has an inverse.
Find the inverse of each -permutation.
Find the inverse of each -permutation.
Answer
Each of these is easy to check.
permutation
inverse
permutation
inverse
Problem 6
Prove that is multilinear if and only if for all
and , this holds.
Answer
For the "if" half, the first condition of
Definition 3.2 follows from taking
and the second condition follows from taking .
The "only if" half also routine.
From
the first condition of Definition 3.2 gives
and the second condition, applied twice, gives the result.
Problem 7
Find the only nonzero term in the permutation expansion of
this matrix.
Compute that determinant by finding the signum of the associated
permutation.
Answer
To get a nonzero term in the permutation expansion we must use
the entry and the entry.
Having fixed on those two we must also use the entry and
the entry.
The signum of is because from
the two row swaps and will produce the identity matrix.
Problem 8
How would determinants change if we changed property (4) of the
definition to read that ?
Answer
They would all double.
Problem 9
Verify the second and third
statements in Corollary 3.13.
Answer
For the second statement, given a matrix, transpose it, swap rows, and transpose back. The result is swapped columns, and the determinant changes by a factor of . The third statement is similar: given a matrix, transpose it, apply multilinearity to what are now rows, and then transpose back the resulting matrices.
This exercise is recommended for all readers.
Problem 10
Show that if an matrix has a nonzero determinant
then any column vector
can be expressed as a linear combination
of the columns of the matrix.
Answer
An matrix with a nonzero determinant has rank so its columns form a basis for .
Problem 11
True or false: a matrix whose entries are only zeros or ones has a determinant equal to zero, one, or negative one. (Strang 1980)
Answer
False.
Problem 12
Show that there are terms in the permutation
expansion formula of a matrix.
How many are sure to be zero if the entry is zero?
Answer
For the column index of the entry in the first row there are
five choices.
Then, for the column index of the entry in the second row there
are four choices (the column index used in the first row cannot
be used here).
Continuing, we get .
(See also the next question.)
Once we choose the second column in the first row,
we can choose the other entries in
ways.
Problem 13
How many -permutations are there?
Answer
Problem 14
A matrix is skew-symmetric if
, as in this matrix.
Show that skew-symmetric matrices with nonzero
determinants exist only for even .
Answer
In the exponent must be even.
This exercise is recommended for all readers.
Problem 15
What is the smallest number of zeros, and the placement of
those zeros, needed to ensure that a matrix has a
determinant of zero?
Answer
Showing that no placement of three zeros suffices is routine. Four zeroes does suffice; put them all in the same row or column.
This exercise is recommended for all readers.
Problem 16
If we have data points
and want to find a
polynomial
passing through those points
then we can plug in the points to get an equation/ unknown
linear system.
The matrix of coefficients for that system is called the
Vandermonde matrix. Prove that the determinant of the transpose
of that matrix of coefficients
equals the product, over all indices with
, of terms of the form .
(This shows that
the determinant is zero, and the linear system has no solution,
if and only if the 's in the data are not distinct.)
Answer
The case shows what to do.
The pivot operations of and
give this.
Then the pivot operation of gives
the desired result.
Problem 17
A matrix can be divided into blocks, as here,
which shows four blocks, the square and ones
in the upper left and lower right, and the zero blocks in the
upper right and lower left.
Show that if a matrix can be partitioned as
where and are square, and and are all zeroes,
then .
Answer
Let be ,
let be ,
and let be .
Apply the permutation expansion formula
Because the upper right of is all zeroes, if a
has at least one of among its first
column numbers then the term arising
from is
(e.g., if then
is ).
So the above formula reduces to a sum over all permutations
with two halves:
first are rearranged, and after that comes
a permutation of
.
To see this gives , distribute.
This exercise is recommended for all readers.
Problem 18
Prove that for any matrix there are at most
distinct reals such that the matrix has
determinant zero
(we shall use this result in Chapter Five).
Answer
The case shows what happens.
Each term in the permutation expansion has three factors drawn from
entries in the matrix (e.g.,
and ), and so the determinant is
expressible as a polynomial in of degree .
Such a polynomial has at most roots.
In general, the permutation expansion shows that the determinant can be written as a sum of terms, each with factors, giving a polynomial of degree . A polynomial of degree has at most roots.
? Problem 19
The nine positive digits can be arranged into arrays
in ways.
Find the sum of the determinants of these arrays. (Trigg 1963)
Answer
This is how the answer was given in the cited source.
When two rows of a determinant are interchanged, the sign of the determinant is changed. When the rows of a three-by-three determinant are permuted, positive and negative determinants equal in absolute value are obtained. Hence the determinants fall into groups, each of which sums to zero.
This is how the answer was given in the cited source.
When the elements of any column are subtracted from the elements of
each of the other two, the elements in two of the columns of the derived
determinant are proportional, so the determinant vanishes.
That is,
? Problem 21
Let be the sum of the integer elements of a magic square of order
three and let be the value of the square considered as a
determinant.
Show that is an integer.
(Trigg & Walker 1949)
Answer
This is how the answer was given in the cited source.
Let
have magic sum .
Then
and .
Hence, adding rows and columns,
? Problem 22
Show that the determinant of the elements in the upper left
corner of the Pascal triangle
This is how the answer was given in the cited source.
Denote by the determinant in question and by
the element in the -th row and -th column.
Then from the law of formation of the elements we have
Subtract each row of from the row following it, beginning the
process with the last pair of rows.
After the subtractions the above equality shows that
the element
is replaced by the element , and all the
elements in the first column, except , become zeroes.
Now subtract each column from the one following it, beginning with the
last pair.
After this process the element is replaced by
, as shown in the above relation.
The result of the two operations is to replace by
, and to reduce each element in the first row and in
the first column to zero.
Hence and consequently
Silverman, D. L. (proposer); Trigg, C. W. (solver) (1963), "Quickie 237", Mathematics Magazine, American Mathematical Society, 36 (1) {{citation}}: Unknown parameter |month= ignored (help).
Strang, Gilbert (1980), Linear Algebra and its Applications (2nd ed.), Hartcourt Brace Javanovich
Trigg, C. W. (proposer) (1963), "Quickie 307", Mathematics Magazine, American Mathematical Society, 36 (1): 77 {{citation}}: Unknown parameter |month= ignored (help).
Trigg, C. W. (proposer); Walker, R. J. (solver) (1949), "Elementary Problem 813", American Mathematical Monthly, American Mathematical Society, 56 (1) {{citation}}: Unknown parameter |month= ignored (help).
Rupp, C. A. (proposer); Aude, H. T. R. (solver) (1931), "Problem 3468", American Mathematical Monthly, American Mathematical Society, 37 (6): 355 {{citation}}: Unknown parameter |month= ignored (help).