PLASMA PHYSICS LECTURE 7 | Wave function, phase velocity, group velocity, plasma frequency. |
PLASMA PHYSICS LECTURE 7 | Wave function, phase velocity, group velocity, plasma frequency. |
Buscar
Descubre nuevas personas, crear nuevas conexiones y hacer nuevos amigos
- 0 Commentarios 0 Acciones 538 Views 0 Vista previa2
- "Average Speed and Velocity: #PhysicsBasics #Speed #Velocity #Motion #Kinematics #Distance #Displacement #Time #VectorQuantities #PhysicsTutorial""Average Speed and Velocity: #PhysicsBasics #Speed #Velocity #Motion #Kinematics #Distance #Displacement #Time #VectorQuantities #PhysicsTutorial"1 Commentarios 1 Acciones 1036 Views 70 0 Vista previa1
- In Advanced Level Maths, the equations of linear motion are:
1. Constant Acceleration:
- v = u + at
- s = ut + (1/2)at^2
- v^2 = u^2 + 2as
Where:
v = final velocity
u = initial velocity
a = acceleration
t = time
s = displacement
1. Uniform Motion:
- s = vt
- v = s/t
Where:
s = distance
v = constant velocity
t = time
1. Motion with Variable Acceleration:
- dv/dt = a(t)
- v = ∫a(t)dt
- s = ∫v(t)dt
Where:
a(t) is the acceleration function
v(t) is the velocity function
s(t) is the position function
These equations describe linear motion in one dimension. In two or three dimensions, vector equations are used to describe motion.In Advanced Level Maths, the equations of linear motion are: 1. Constant Acceleration: - v = u + at - s = ut + (1/2)at^2 - v^2 = u^2 + 2as Where: v = final velocity u = initial velocity a = acceleration t = time s = displacement 1. Uniform Motion: - s = vt - v = s/t Where: s = distance v = constant velocity t = time 1. Motion with Variable Acceleration: - dv/dt = a(t) - v = ∫a(t)dt - s = ∫v(t)dt Where: a(t) is the acceleration function v(t) is the velocity function s(t) is the position function These equations describe linear motion in one dimension. In two or three dimensions, vector equations are used to describe motion.
0 Commentarios 0 Acciones 512 Views 0 Vista previa - In Advanced Level Maths, the equations of linear motion are:
1. Constant Acceleration:
- v = u + at
- s = ut + (1/2)at^2
- v^2 = u^2 + 2as
Where:
v = final velocity
u = initial velocity
a = acceleration
t = time
s = displacement
1. Uniform Motion:
- s = vt
- v = s/t
Where:
s = distance
v = constant velocity
t = time
1. Motion with Variable Acceleration:
- dv/dt = a(t)
- v = ∫a(t)dt
- s = ∫v(t)dt
Where:
a(t) is the acceleration function
v(t) is the velocity function
s(t) is the position function
These equations describe linear motion in one dimension. In two or three dimensions, vector equations are used to describe motion.In Advanced Level Maths, the equations of linear motion are: 1. Constant Acceleration: - v = u + at - s = ut + (1/2)at^2 - v^2 = u^2 + 2as Where: v = final velocity u = initial velocity a = acceleration t = time s = displacement 1. Uniform Motion: - s = vt - v = s/t Where: s = distance v = constant velocity t = time 1. Motion with Variable Acceleration: - dv/dt = a(t) - v = ∫a(t)dt - s = ∫v(t)dt Where: a(t) is the acceleration function v(t) is the velocity function s(t) is the position function These equations describe linear motion in one dimension. In two or three dimensions, vector equations are used to describe motion.
0 Commentarios 0 Acciones 517 Views 0 Vista previa - In Advanced Level Maths, the equations of linear motion are:
1. Constant Acceleration:
- v = u + at
- s = ut + (1/2)at^2
- v^2 = u^2 + 2as
Where:
v = final velocity
u = initial velocity
a = acceleration
t = time
s = displacement
1. Uniform Motion:
- s = vt
- v = s/t
Where:
s = distance
v = constant velocity
t = time
1. Motion with Variable Acceleration:
- dv/dt = a(t)
- v = ∫a(t)dt
- s = ∫v(t)dt
Where:
a(t) is the acceleration function
v(t) is the velocity function
s(t) is the position function
These equations describe linear motion in one dimension. In two or three dimensions, vector equations are used to describe motion.In Advanced Level Maths, the equations of linear motion are: 1. Constant Acceleration: - v = u + at - s = ut + (1/2)at^2 - v^2 = u^2 + 2as Where: v = final velocity u = initial velocity a = acceleration t = time s = displacement 1. Uniform Motion: - s = vt - v = s/t Where: s = distance v = constant velocity t = time 1. Motion with Variable Acceleration: - dv/dt = a(t) - v = ∫a(t)dt - s = ∫v(t)dt Where: a(t) is the acceleration function v(t) is the velocity function s(t) is the position function These equations describe linear motion in one dimension. In two or three dimensions, vector equations are used to describe motion.
0 Commentarios 0 Acciones 514 Views 0 Vista previa
English
Arabic
French
Portuguese
Deutsch
Turkish
Dutch
Italiano
Russian
Romaian
Portuguese (Brazil)
Greek