To the nearest foot, determine how far above the vertex the receiver is placed in order to "catch" all of the radio waves that hit the dish. Then, write the equation that models the cross sectional shape of the dish itself. (L2) 2. Y= /4r (x-h)+k と=I4CX-O)4so Yニ/APC×)** Se G2 = 114P ( 41)+s• 12=14P(91)* RL:(0, so+30) X+ So ル。 Rec. length above vertex:3SA ソ= Equation: P=35.02 To verify the receiver is mounted correctly, workers use the location of the directrix, a point on the edge of the dish and the coordinates for the receiver. By using the definition of a parabola they can determine if the receiver is located correctly. (L3) 3. If the calculations using the information above are within one tenth of a foot of being exact, the receiver is considered to be located correctly. Verify the placement you found in problem 2 is correct.

Transcribed Image Text:

2. To the nearest foot, determine how far above the vertex the receiver is placed in order to "catch" all of the radio waves that hit the dish. Then, write the equation that models the cross sectional shape of the dish itself. (L2) Y=/er(x-ト)°+k y =140(x-0)*+ So Y=1/APC x)*. s. G2 = 14P (41)+s. 12=14P(91)* RL:(0,so+30) *トSo 164. Rec. length above vertex: 3SA y= Equation: 1891 P=35.02 (L3) 3. To verify the receiver is mounted correctly, workers use the location of the directrix, a point on the edge of the dish and the coordinates for the receiver. By using the definition of a parabola they can determine if the receiver is located correctly. If the calculations using the information above are within one tenth of a foot of being exact, the receiver is considered to be located correctly. Verify the placement you found in problem 2 is correct.