Problem:
Square pyramid ABCDE has base ABCD, which measures 3cm on a side, and altitude AE perpendicular to the base, which measures 6cm. Point P lies on BE, one third of the way from B to E; point Q lies on DE, one third of the way from D to E; and point R lies on CE, two thirds of the way from C to E. What is the area, in square centimeters, of β³PQR ?
Answer Choices:
A. 232ββ
B. 233ββ
C. 22β
D. 23β
E. 32β Solution:
Using the given data, we can label the points A(0,0,0),B(3,0,0),C(3,3,0),D(0,3,0), and E(0,0,6). We can also find the points P=B+31βBE=(3,0,0)+31β(β3,0,6)=(3,0,0)+(β1,0,2)=(2,0,2). Similarly, Q=(0,2,2) and R=(1,1,4).
Using the distance formula, PQ=(β2)2+22+02β=22β,PR=(β1)2+12+22β=6β, and QR=12+(β1)2+22β=6β. Using Heron's formula, or by dropping an altitude from P to find the height, we can then find that the area of β³PQR is (C)22ββ.
OR
As in Solution 1, let A=(0,0,0),B=(3,0,0),C=(3,3,0),D=(0,3,0), and E=(0,0,6), and calculate the coordinates of P,Q, and R as P=(2,0,2),Q=(0,2,2),R=(1,1,4). Now notice that the plane determined by β³PQR is perpendicular to the plane determined by ABCD. To see this, consider the bird's-eye view, looking down upon P,Q, and R projected onto ABCD :
Additionally, we know that PQ is parallel to the plane determined by ABCD, since P and Q have the same z-coordinate. Hence the height of β³PQR is equal to the z-coordinate of R minus the z-coordinate of P, giving 4β2=2. By the distance formula, PQβ=22β, so the area of β³PQR is 21ββ 22ββ 2=(C)22ββ.
OR
By the Pythagorean Theorem, we can calculate EB=ED=35β,EC=36β,ER=6β, and EP=EQ=25β. Now by the Law of Cosines in β³BEC, we have cos(β BEC)=2β EBβ ECEB2+EC2βBC2β=30β5β.
Similarly, by the Law of Cosines in β³EPR, we have PR2=ER2+EP2β2β ERβ EPβ cos(β BEC)=6, so PR=6β. Observe that β³ERPβ β³ERQ (by side-angle-side), so QR=PR=6β.
Next, notice that PQ is parallel to DB, and therefore β³EQP is similiar to β³EDB. Thus we have DBQPβ=EBEPβ=32β. Since DB=32β, this gives PQ=22β.
Now we have the three side lengths of isosceles β³PQR:PR=QR=6β,PQ=22β. Letting the midpoint of PQ be S,RS is the perpendicular bisector of PQ, and so can be used as a height of β³PQR (taking PQ as\
the base). Using the Pythagorean Theorem again, we have RS=PR2βPS2β=2, so the area of β³PQR is 21ββ PQβ RS=21ββ 22ββ 2= (C) 22β.
