The left-hand member of this equation is what is called the determinant of the given system of equations. We proceed to investigate the law of its formation. Multiply the first by b,, the second by a,, and subtract, and we get We may remark in passing that we shall obtain the same result by eliminating A,, A, between the equations A like theorem will be proved to be true for all determinants. 4. Next, suppose we have the three equations Multiply these equations in order by the arbitrary multipliers A, A, A, and add them together. Let the two ratios A,λ be determined by the conditions that the coefficients of x and x in the resulting equation shall each be zero, i. e. let The resulting equation is then reduced to (a ̧λ ̧ + b ̧λ ̧+¢ ̧λ ̧) x ̧ = 0, ..(A). which requires that = ...... Multiply the first of equations (A) by a,, the second by a,, and subtract, we then get Hence, dividing each term of (B) by the corresponding member of (C) we get It will be seen that the above process is really equivalent to that of eliminating A,, A, A, between the equations (A) and (B). Hence To effect the elimination, multiply the equations in order by λ, λ λ λ, add them, and equate the coefficients of x, x, x severally to zero. We shall then have ɑ3λ1 +b3λ1⁄2 + €3λg+dgλ1 = 0 ¤ ̧λ1 + b1λ1⁄2 + çλ ̧+d ̧λ=0] which equations involve as a consequence .(A'), а1λ1 + b1λ1⁄2 + c1λ ̧ + d12λ = 0.....................(B'). To determine the three ratios λ: λ ̧: λ ̧: λ, multiply equations (A') in order by M2, M3, M1, add, and equate to zero the coefficients of A, A. We thus get Now, treating equations (C') as equations (A) were treated, we see that |