German rockets directed at Southern England during World War 2.
v1 = initial velocity v2 = final velocity
( | V1 - V2 | / ((V1 + V2)/2) ) * 100
v1 is design speed and v2 rotation speed
[ ((v2 - v1) / |v1|) * 100 ]
Rip V1 is Classful routing protocol Rip V2 is Classless routing Protocol
The most common multi output systems are used for getting differential output. i.e., if V1 and V2 are the 2 outputs, then usually the difference, V2-V1 or V1-V2 is used.
The equations of motion that relate velocity, distance, time and acceleration for the specific case of "constant acceleration" can be written as follow, acceleration a = (v2 - v1)/t from which v2 = v1 + at The distance covered during t time d = vav x t, where vav refers to average velocity in the process from v1 to v2. For the case of constant acceleration vav = (v1 + v2)/2. Substituting in d we get d = (v1 + v2)/2 x t from which, v2 = 2d/t - v1 If we take the constant acceleration to be zero, a = 0, you can see that the second equation we wrote becomes, v2 = v1 (There is no acceleration), so our equation for the distance d becomes, d = v1 x t = v2 x t
Two vectors; V1 + V2=0 where V1= -V2, two opposite vectors.
the V2 rocket was bigger and faster than the V1 flying bomb. the V1 being a flying bomb was smaller and had a pulse jet engine and the V2 which was a rocket had a bigger rocket engine. ACTUAL SIZE COMPARISON: V1: Length: 25' 4" wingspan: 8.32 meters V2: length 14 m (45 ft 11 in)
Vresultant = V1 + V2
by Hitler's jizz
SR={((V1-V2)/V2)*100}/(W1-W2) where,SR=srinkage ratio v1=initial volume v2=final w1=initial moisture content w2-final