Sect3 1

SECTION 3.1

INTRODUCTION TO LINEAR SYSTEMS
This initial section takes account of the fact that some students remember only hazily the method of
elimination for 2 × 2 and 3 × 3 systems. Moreover, high school algebra courses generally
emphasize only the case in which a unique solution exists. Here we treat on an equal footing the
other two cases — in which either no solution exists or infinitely many solutions exist.

1. Subtraction of twice the first equation from the second equation gives −5 y = −10, so
y = 2, and it follows that x = 3.

2. Subtraction of three times the second equation from the first equation gives 5 y = −15, so
y = –3, and it follows that x = 5.

1 3
3. Subtraction of 3/2 times the first equation from the second equation gives y = , so
2 2
y = 3, and it follows that x = –4.

11 44
4. Subtraction of 6/5 times the first equation from the second equation gives y= ,
5 5
so y = 4, and it follows that x = 5.

5. Subtraction of twice the first equation from the second equation gives 0 = 1, so no
solution exists.

6. Subtraction of 3/2 times the first equation from the second equation gives 0 = 1, so no
solution exists.

7. The second equation is –2 times the first equation, so we can choose y = t arbitrarily.
The first equation then gives x = −10 + 4t.

8. The second equation is 2/3 times the first equation, so we can choose y = t arbitrarily.
The first equation then gives x = 4 + 2t.

9. Subtraction of twice the first equation from the second equation gives −9 y − 4 z = −3.
Subtraction of the first equation from the third equation gives 2 y + z = 1. Solution of
these latter two equations gives y = −1, z = 3. Finally substitution in the first equation
gives x = 4.

10. Subtraction of twice the first equation from the second equation gives y + 3 z = −5.
Subtraction of twice the first equation from the third equation gives − y − 2 z = 3.
Solution of these latter two equations gives y = 1, z = −2. Finally substitution in the
first equation gives x = 3.

11. First we interchange the first and second equations. Then subtraction of twice the new
first equation from the new second equation gives y − z = 7, and subtraction of three
times the new first equation from the third equation gives −2 y + 3 z = −18. Solution of
these latter two equations gives y = 3, z = −4. Finally substitution in the (new) first
equation gives x = 1.

12. First we interchange the first and third equations. Then subtraction of twice the new first
equation from the second equation gives −7 y − 3 z = −36, and subtraction of twice the
new first equation from the new third equation gives −16 y − 7 z = −83. Solution of these
latter two equations gives y = 3, z = 5. Finally substitution in the (new) first equation
gives x = 1.

13. First we subtract the second equation from the first equation to get the new first equation
x + 2 y + 3z = 0. Then subtraction of twice the new first equation from the second
equation gives 3 y − 2 z = 0, and subtraction of twice the new first equation from the
third equation gives 2 y − z = 0. Solution of these latter two equations gives
y = 0, z = 0. Finally substitution in the (new) first equation gives x = 0 also.

x + 8 y − 4 z = 45. Then subtraction of twice the new first equation from the second
equation gives −23 y + 28 z = −181, and subtraction of twice the new first equation from
the third equation gives −9 y + 11z = −71. Solution of these latter two equations gives
y = 3, z = −4. Finally substitution in the (new) first equation gives x = 5.

15. Subtraction of the first equation from the second equation gives −4 y + z = −2.
Subtraction of three times the first equation from the third equation gives (after division
by 2) −4 y + z = −5 / 2. These latter two equations obviously are inconsistent, so the
original system has no solution.

16. Subtraction of the first equation from the second equation gives 7 y − 3z = −2.
Subtraction of three times the first equation from the third equation gives (after division
by 3) 7 y − 3z = −10 / 3. These latter two equations obviously are inconsistent, so the

17. First we subtract the first equation from the second equation to get the new first equation
x + 3 y − 6 z = −4. Then subtraction of three times the new first equation from the second
equation gives −7 y + 16 z = 15, and subtraction of five times the new first equation from
the third equation gives (after division by 2) −7 y + 16 z = 35 / 2. These latter two
equations obviously are inconsistent, so the original system has no solution.

18. Subtraction of the five times the first equation from the second equation gives
−23 y − 40 z = −14. Subtraction of eight times the first equation from the third equation

gives −23 y − 40 z = −19. These latter two equations obviously are inconsistent, so the

19. Subtraction of twice the first equation from the second equation gives 3 y − 6 z = 9.
Subtraction of the first equation from the third equation gives y − 2 z = 3. Obviously
these latter two equations are scalar multiples of each other, so we can choose z = t
arbitrarily. It follows first that y = 3 + 2t and then that x = 8 + 3t.

x − y + 6 z = −5. Then subtraction of the new first equation from the second equation
gives 5 y − 5 z = 25, and subtraction of the new first equation from the third equation
gives 3 y − 3 z = 15. Obviously these latter two equations are both scalar multiples of the
equation y − z = 5, so we can choose z = t arbitrarily. It follows first that y = 5 + t and
then that x = −5t.

21. Subtraction of three times the first equation from the second equation gives 3 y − 6 z = 9.
Subtraction of four times the first equation from the third equation gives −3 y + 9 z = −6.
Obviously these latter two equations are both scalar multiples of the equation y − 3 z = 2,
so we can choose z = t arbitrarily. It follows first that y = 2 + 3 t and then that
x = 3 − 2 t.

22. Subtraction of four times the second equation from the first equation gives 2 y + 10 z = 0.
Subtraction of twice the second equation from the third equation gives y + 5 z = 0.
Obviously the first of these latter two equations is twice the second one, so we can
choose z = t arbitrarily. It follows first that y = −5 t and then that x = −4 t.

23. The initial conditions y (0) = 3 and y′(0) = 8 yield the equations A = 3 and 2 B = 8, so
A = 3 and B = 4. It follows that y ( x ) = 3cos 2 x + 4sin 2 x.

24. The initial conditions y (0) = 5 and y′(0) = 12 yield the equations A = 5 and 3B = 12,
so A = 5 and B = 4. It follows that y ( x) = 5cosh 3x + 4sinh 3 x.

25. The initial conditions y (0) = 10 and y ′(0) = 20 yield the equations A + B = 10 and
5 A − 5 B = 20 with solution A = 7, B = 3. Thus y ( x ) = 7e5 x + 3e −5 x .

26. The initial conditions y (0) = 44 and y′(0) = 22 yield the equations A + B = 44 and
11A − 11B = 22 with solution A = 23, B = 21. Thus y ( x) = 23e11 x + 21e −11 x .

27. The initial conditions y (0) = 40 and y′(0) = −16 yield the equations A + B = 40 and
3 A − 5 B = −16 with solution A = 23, B = 17. Thus y ( x) = 23e3 x + 17e −5 x .

28. The initial conditions y (0) = 15 and y ′(0) = 13 yield the equations A + B = 15 and
3 A + 7 B = −13 with solution A = 23, B = −8. Thus y ( x ) = 23e3 x − 8e 7 x .

2 A + 3 B = 11 with solution A = 52, B = −45. Thus y ( x ) = 52e − 45e x / 3 .
1 1 x/2

4 7
A − B = 164 with solution A = 81, B = −40. Thus y ( x ) = 81e 4 x / 3 − 40e −7 x / 5 .
3 5

31. The graph of each of these linear equations in x and y is a straight line through the
origin (0, 0) in the xy-plane. If these two lines are distinct then they intersect only at the
origin, so the two equations have the unique solution x = y = 0. If the two lines
coincide, then each of the infinitely many different points ( x, y ) on this common line
provides a solution of the system.

32. The graph of each of these linear equations in x, y, and z is a plane in xyz-space. If these
two planes are parallel — that is, do not intersect — then the equations have no solution.
Otherwise, they intersect in a straight line, and each of the infinitely many different
points ( x, y , z ) on this line provides a solution of the system.

33. (a) The three lines have no common point of intersection, so the system has no
solution.
(b) The three lines have a single point of intersection, so the system has a unique
solution.
(c) The three lines — two of them parallel — have no common point of intersection,
so the system has no solution.
(d) The three distinct parallel lines have no common point of intersection, so the
system has no solution.
(e) Two of the lines coincide and intersect the third line in a single point, so the
system has a unique solution.
(f) The three lines coincide, and each of the infinitely many different points ( x, y , z )
on this common line provides a solution of the system.

34. (a) If the three planes are parallel and distinct, then they have no common point of
intersection, so the system has no solution.
(b) If the three planes coincide, then each of the infinitely many different points
( x, y , z ) of this common plane provides a solution of the system.
(c) If two of the planes coincide and are parallel to the third plane, then the three
planes have no common point of intersection, so the system has no solution.

(d) If two of the planes intersect in a line that is parallel to the third plane, then the
three planes have no common point of intersection, so the system has no solution.
(e) If two of the planes intersect in a line that lies in the third plane, then each of the
infinitely many different points ( x, y , z ) of this line provides a solution of the system.
(f) If two of the planes intersect in a line that intersects the third plane in a single
point, then this point ( x, y , z ) provides the unique solution of the system.

Sect3 1

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Sect3 1