1001 Algebra Problems.PDF

none of these systems span the entire Cartesian

plane. In fact, it is impossible for such a system

of linear inequalities to have a solution set that

spans the entire Cartesian plane.

350. b.Note that the graphs of the lines y= x+ 3
     and y= x– 1 are parallel, where the graph of
     y= x+ 3 lies strictly above the graph ofy= x– 1.
     Using the first inequality specified in the system,
     any point that it is in the solution set of the
     system to yx + 3,yx– 1 would necessarily
     be above the line y= x+ 3, and therefore, by
     the previous observation, also above the line
     y= x– 1. However, the second inequality in
     the system requires that the point be belowthe
     line y= x– 1, which is not possible. Hence, the
     solution set of this system is the empty set.


351. d.The boundaries of Quadrant III are the
     x-axis and y-axis; the equations of these axes
     are y= 0 and x= 0, respectively. Since points
     in the solution set are not to be on either axis,
     both inequalities comprising the system we
     seek must involve one of the signsor.
     Next, note that the sign of both the x- and
     y-coordinate of a point in Quadrant III is neg-
     ative. We conclude that the system with this
     solution set is given by x0,y0.


352. b.A system of linear inequalities whose solu-
     tion set consists of the points on a single line
     must be of the form y mx + b,y mx+ b,
     assuming that the lines are not vertical. Observe
     that the first inequality in the system 2y– 6x
     4, or y 2 + 3x, is equivalent to y 2 + 3x,so
     this system is of the form specified. The solu-
     tion set consists of those points on the line
     y= 3x+ 2.

Section 3—Polynomial

Expressions

Set 23(Page 66)

353. d.
     (x^2 – 3x+ 2) + (x^3 – 2x^2 + 11) =
     x^3 + x^2 – 2x^2 – 3x+ 2 + 11 =
     x^3 – x^2 + 3x+ 13


354. a.
     (3x^2 – 5x+ 4) – (–^23 x+ 5)
     = 3x^2 – 5x+ 4 + ^23 x– 5
     = 3x^2 – 5x + ^23 x+ 4 – 5
     = 3x^2 – ^135 x+ ^23 x– 1
     = 3x^2 – ^133 x– 1


355. b.
     (^13 x^2 – ^15 x– ^23 ) – (^23 x^2 –  170 x+ ^12 )
     = ^13 x^2 – ^15 x– ^23 – ^23 x^2 +  170 x– ^12 
     =^13 x^2 – ^23 x^2 – ^15 x+  170 x– ^23 – ^12 
     = –^13 x^2 –  120 x+  170 x–^46 –^36 
     = –^13 x^2 +  150 x– ^76 
     = –^13 x^2 + ^12 x– ^76 


356. c.
     (9a^2 b+ 2ab– 5a^2 ) – (–2ab– 3a^2 + 4a^2 b)
     = 9a^2 b+ 2ab– 5a^2 + 2ab+ 3a^2 – 4a^2 b
     = 9a^2 b– 4a^2 b+ 2ab+ 2ab– 5a^2 + 3a^2
     = 5a^2 b+ 4ab– 2a^2


357. a.
     (^16 x^2 + ^23 x+ 1) + (2x– ^23 x^2 + 4) – ^72 + 3x+ ^12 x^2 )
     = ^16 x^2 + ^23 x+ 1 + 2x– ^23 x^2 + 4 – ^72 – 3x– ^12 x^2
     = ^16 x^2 – ^23 x^2 – ^12 x^2 + ^23 x+ 2x– 3x+ 1 + 4 – ^72 
     = ^16 x^2 – ^46 x^2 – ^36 x^2 + ^23 x– x+ 5 – ^72 
     = –x^2 – ^13 x+ ^32 

ANSWERS & EXPLANATIONS–