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Because it saves time and space
I don't know what a t.t.l is but I do know that the propagation of the speed of light compared to velocity is explained in Einstien's Special Theory of Relativity. It basically states that as an object approaches the speed of light, distance becomes greater, and time slows down (compared to an object at rest). Unfortunately, there is no way to truly tell if you are at rest. Sure you can say that you are at rest if you are standing still but realize that the Earth is moving through the galaxy at some 30,000 mph at this very moment. The reason for the change in time and space is that the speed of light is constant, no matter how emitted or recorded. This means that light will travel at the speed C even if you are moving at C/2 to begin with. someone approaching you at the same speed will witness the light pass them at the speed C. Someone else standin still (compared to the other two) will also witness the light pass by at the speed C. Get the point? If you need more information just read Einstiens relativity book on the special and general theory; it's tough reading, but it explains everything.
Not easily becauseThe speed at which waves travel depends on the medium that they are travelling through. For example, the speed is affected by whether or not the wave travels through the mantle or the core.The waves are often reflected back to the surface from the core-mantle boundary.The direction of the wave is affected by diffraction because its speed of propagation varies with the density of the medium.But there are statistical models being developed to get around these problems.
According to Einstein's theory of general relativity, objects with mass "bend" space-time, which is part of how gravity works. (Space-time is basically the combination of space at time, using time as a kind of "fourth dimension".) When objects move around, they change the way the space-time is curved around them. In some cases, when an object accelerates, the result changes in the curvature of space-time propagate outwards at the speed of light. The propagation of the changes in the curvature of space-time is what is known as gravitational waves.
The velocity of the object. Velocity involves direction as well as size (the concept of speed does not involve direction) e.g. I can drive round a roundabout at a constant speed of 30 m.p.h., but in doing so my direction continually changes, so my velocity keeps changing
Data Transmission speed is the number of bits per second that can be transmitted. Propagation speed is the speed at which a signal moves through a medium. Gateway Technical College, Elkhorn WI
Propagation time = 6 usec/km × 3000 km = 18 ms Speed(T1) = 1.536 Mbps Transmission time for a frame = 64byte × 8 / 1.536Mbps = 0.3 ms Total transmission time for a frame and its ack = 2 × propagation time + transmission time for a frame = 2 × 18ms + 0.3ms = 36.3ms Window size = 36.3ms / 0.3ms = 121 As 27 = 128 > 121, so the sequence numbers should be 7 bits.
Propagation delay is the time it takes for electronic devices to switch from one logic state to another.
Nothing. Frequency doesn't control the speed of a wave. Increase in frequency will reduce the wavelength of the wave to keep the velocity constant (v=nu x lambda)
Assuming you are running in synchronous mode, a counter with a propagation time of 25 ns can run up to 40 MHz. Since there are other gates involved, I would consider a margin of safety to be 20 MHz.
Propagation time of any pulse is roughly the time needed for the leading edge of the pulse to travel from one point to another. It will be more accurate to say that the pulse is registered at a given point when its leading edge reaches half of the maximum value (amplitude) of the pulse. The propagation time of a sound pulse is equal to the distance between the measuring points divided to the sound velocity in the medium in which it propagates.
Propagation time of any pulse is roughly the time needed for the leading edge of the pulse to travel from one point to another. It will be more accurate to say that the pulse is registered at a given point when its leading edge reaches half of the maximum value (amplitude) of the pulse. The propagation time of a sound pulse is equal to the distance between the measuring points divided to the sound velocity in the medium in which it propagates.
Increased efficiency in plant propagation has decreased the amount of human time involved in agriculture. This has expanded mans ability to explore and expand civilization.
Speed= distance / time distance = speed x time time = distance / speed
That depends on the speed. If you know the speed, use the formula distance = speed x time. Solving for time: time = distance / speed.That depends on the speed. If you know the speed, use the formula distance = speed x time. Solving for time: time = distance / speed.That depends on the speed. If you know the speed, use the formula distance = speed x time. Solving for time: time = distance / speed.That depends on the speed. If you know the speed, use the formula distance = speed x time. Solving for time: time = distance / speed.
Because it saves time and space
The most effective frequency at a specified time for ionosperic propagation of radio waves between two specified points: also known as Frequency Optimum Traffic; Optimum Traffic Frequency