Vergeltungswaffe, "vengeance weapon".
The V1 and V2 Rockets
the V1:The V1 flying bomb also know as the doodle bug, buzz bomb and V1 rocket, was a missile driven by a pulse jet engine was used by the Germans in world war 2 to bomb England to get ready for the invasion of Britain (operation sea lion) which later was called off, it used a gyroscope navigation system to guide it to its target, the fuel would run out above England and the bomb would fall out of the sky and explode. the V1 bomb had a large launch ramp which meant it could be sighted and bombed and could move. the V2:the V2 was also used by the Germans in world war 2 to bomb the British, unlike the V1 the V2 had a proper rocket engine (newly invented by the Germans) it was much faster than the V1 and had a bigger warhead the launch sites could be bombed because they were mobile and could be towed and set up anywhere. The V2 also was impossible for any fighters to catch up with unlike the V1 which was slow enough that the British invented the Hawker tempest and typhoon .the V in V1 and V2 stands for Vengeance weapon
ACCORDING TO MY CHILDHOOD DIARY, THE LAST V2 TO FALL NEAR OUR HOUSE (lONDON nW4) WAS ON MARCH 4, 1945
The V1 was not a rocket, but a flying bomb powered by a simple form of jet engine called a pulse jet. It was equivalent to a modern cruise missile. A V2, on the other hand, was a rocket propelled rocket. The V1 could be stopped with gunfire or by attacks from fast fighters such as the Hawker Tempest, de Havilland Mosquito. The V2, on the other hand was undetectable, as it was fired into the stratosphere and hit its target with a speed higher than that of sound.
The V1 and V2 rocket technology was developed and perfected by a team of German scientists under the leadership of pioneering rocketeer Dr. Wernher von Braun. It was von Braun, considered to be the top rocket engineer of the century, who was Germany's key leader in rocket technology that led to the success of the V1 and V2 rockets. Toward the end of the war, pioneer pioneer von Braun led his team to the American lines and surrendered to the Allies, rather than face being captured by the advancing Soviets. He and his team were brought to the United States, and after a period where their records were "bleached" by U.S. intelligence of their former past, they were put to work on the U.S. rocket programs. Von Braun became NASA's leader in rocket development, which culminated in the design and success of the Saturn V rocket.
Yes, a unit vector can have negative component since a unit vector has same magnitude and direction as a negative unit vector. Here is the general work out of the problem: Let |v| be the norm of (v1, v2). Then, the unit vector is (v1/|v|, v2/|v|). Determine the "modulus" or the norm |(v1/|v|, v2/|v|)| to get 1, which is the new norm. If we determine the norm of |(-v1/|v|, -v2/|v|)|, we still have the same norm 1.
the v1 and v2 were German rockets and i asume they stand for something German (the "v" i mean). Because of the places they were made and what they were made out of. They, although stand for nothing, were covert-ops type missiles designed mainly for clearing out garrisons and launching sneak attacks.
A Compound Graph is an extension of a standard graph. Let G be a graph, G=(V,E) where V is a set of vertices and E is a set of edges, that is e = (v1, v2) in V2 A compound graph C is defined by a tree T=(V,F) where V is the same set as G and F are tree edges f=(v1,v2) in V2. C=(G,T) where G=(V,E) and T=(V,F) Furthermore, C has two additional constraints: e=(v1,v2) in E implies: 1) v1 is not on the path of v2 to the root of T AND 2) v2 is not on the path of v1 to the root of T. Intuitively, T defines a hierarchy. All the vertices sharing the same parent in T are in the same "group". The constraints state that you cannot have an edge connecting a vertex to one of its parent in the hierarchy.
v1 = initial velocity v2 = final velocity
Charles's Law relates volume and temperature of gases under changing conditions of one of the examined varables. It may be written as V1T1=V2T2 Where V is gas volume at conditions 1 and 2, and T is the absolute temperature at conditions 1 and 2.
v1 is design speed and v2 rotation speed
( | V1 - V2 | / ((V1 + V2)/2) ) * 100
V =piR^2 H , Since R=D/2 V= pi (D^2/4)H V1= pi(D1^2/4) H1 ( Vol first cylinder , Diameter D1 , height H1) V2= pi(D2^2/4) H2 Divide both V1/V2 =( D1^2/D2^2) (H1/H2) V1/V2= (D1/D2)^2 (H1/H2) V1/V2= (1/2)^2 (3/1) V1/V2= 3/4 then V1: V2 = 3:4
Vector
Relates that if held under constant pressure the ratio of Vol/Temp remains constant. i.e, V1 / T1 = V2 / T2 (where T is in Kelvin)
[ ((v2 - v1) / |v1|) * 100 ]
Rip V1 is Classful routing protocol Rip V2 is Classless routing Protocol