- Calculus, Volume 2: Multi-Variable Calculus and Linear Algebra with Applications to Differential Equations and Probability
- Tom M. Apostol
- Second Edition
- 1991
- 978-1-119-49676-2
2.8 Exercises
In each of Exercises 13 through 20, a function $T: V_3 \rightarrow V_3$ is defined by the formula given for $T(x, y, z),$ where $(x, y, z)$ is an arbitrary point in $V_3.$ In each case, determine whether $T$ is one-to-one on $V_3.$ If it is, describe its range $T(V_3);$ for each point $(u, v, w)$ in $T(V_3),$ let $(x, y, z) = T^{-1}(u, v, w)$ and give formulas for determining $x,$ $y,$ and $z$ in terms of $u,$ $v,$ and $w.$
15.$\quad$ $T(x, y, z) = (x, 2y, 3z).$
Solution. $\quad$ Let $A = (x, y, z)$ and $B = (p, q, r)$ be two points in $V_3.$ Then $T(A) = (x, 2y, 3z)$ and $T(B) = (p, 2q, 3r).$ If $T(A) = T(B)$ then we have $x = p,$ $2y = 2q,$ and $3z = 3r.$ In other words, $T(A) = T(B)$ implies $A = B,$ making $T$ one-to-one on $V_3.$ The range of $T$ is $V_3,$ and for each point $(u, v, w)$ in $T(V_3),$ if we let $(x, y, z) = T^{-1}(u, v, w),$ we have the formulas $$x = u, \quad y = \frac{1}{2}v, \quad z = \frac{1}{3}w. \quad \blacksquare$$