
What figure? You cannot copy and paste here.
posted by PsyDAG
Respond to this Question
Similar Questions

maths
in the following fig two tangents PQ and PR are drawn to a circle with centre O from an external point P.prove that QPR=2OQR 
Physics
Question 2. 3 Consider a box that explodes into two pieces while moving with Fig. 924 a constant positive velocity along an x axis. If one piece, with mass : m1, ends up with positive velocity v1, then the second piece, with : 
Maths  check please
Fig.1. Shows a signwave on the its horizontal axis "Time in (ms)" means that time is measured in milliseconds. The time taken is 20 ms in total Question asks for frequency of the sinewave ? Cant really draw Fig.. here :0( But the 
math
I always thought I understood significant figures...until I attempted to tutor someone. Some of the rules seem counterintuitive. For instance... 10.070 why is it 5 sig fig's? the "0" on the right is useless. without it the # holds 
maths
If the sum of the squares of the roots of the quadratic equation ax^2 + bx + c = 0 is m:n, prove that b^2= 2ac + 4a^2 I really have no idea how to prove it so pls help 
maths
express 4_3_ as a decimal to 3 sig fig plz 4 
Physics
A point charge (m = 1.0 g) at the end of an insulating string of length L = 51 cm (Fig. 1666) is observed to be in equilibrium in a uniform horizontal electric field of E = 9200 N/C, when the pendulum's position is as shown in 
Physics
A point charge (m = 1.0 g) at the end of an insulating string of length L = 51 cm (Fig. 1666) is observed to be in equilibrium in a uniform horizontal electric field of E = 9200 N/C, when the pendulum's position is as shown in 
Physics
A point charge (m = 1.0 g) at the end of an insulating string of length L = 51 cm (Fig. 1666) is observed to be in equilibrium in a uniform horizontal electric field of E = 9200 N/C, when the pendulum's position is as shown in 
Physics
A point charge (m = 1.0 g) at the end of an insulating string of length L = 46 cm (Fig. 1666) is observed to be in equilibrium in a uniform horizontal electric field of E = 8800 N/C, when the pendulum's position is as shown in