• "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"
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  • "Distance and Linear Motion: #PhysicsBasics #LinearMotion #DistanceConcepts #ScienceExplained #PhysicsTutorial"
    "Distance and Linear Motion: #PhysicsBasics #LinearMotion #DistanceConcepts #ScienceExplained #PhysicsTutorial"
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  • The Advantages of Online Learning: Enhancing Education in the Digital Age #OnlineLearning, #DigitalEducation, #EdTech, #Elearning, #DistanceLearning, #VirtualClassroom, #RemoteLearning, #OnlineCourses, #EducationTechnology, #LearningFromHome






    🥰🥰🥰The Advantages of Online Learning: Enhancing Education in the Digital Age #OnlineLearning, #DigitalEducation, #EdTech, #Elearning, #DistanceLearning, #VirtualClassroom, #RemoteLearning, #OnlineCourses, #EducationTechnology, #LearningFromHome
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  • Here are the geometrical rules for drawing ray diagrams:

    1. *Incident ray*: Draw a straight line from the object to the mirror/lens.
    2. *Normal*: Draw a perpendicular line to the mirror/lens at the point of incidence.
    3. *Reflected ray*: Draw a straight line from the mirror/lens to the image, making the same angle with the normal as the incident ray.
    4. *Refraction*: Draw a straight line from the object to the lens, and another from the lens to the image, bending at the lens surface.
    5. *Virtual image*: Draw a dashed line from the mirror/lens to the virtual image, behind the mirror/lens.
    6. *Real image*: Draw a solid line from the mirror/lens to the real image, in front of the mirror/lens.
    7. *Object distance*: Measure from the mirror/lens to the object.
    8. *Image distance*: Measure from the mirror/lens to the image.

    Remember to use a ruler and protractor to ensure accuracy!

    Let me know if you have any specific questions or need help with a ray diagram!
    Here are the geometrical rules for drawing ray diagrams: 1. *Incident ray*: Draw a straight line from the object to the mirror/lens. 2. *Normal*: Draw a perpendicular line to the mirror/lens at the point of incidence. 3. *Reflected ray*: Draw a straight line from the mirror/lens to the image, making the same angle with the normal as the incident ray. 4. *Refraction*: Draw a straight line from the object to the lens, and another from the lens to the image, bending at the lens surface. 5. *Virtual image*: Draw a dashed line from the mirror/lens to the virtual image, behind the mirror/lens. 6. *Real image*: Draw a solid line from the mirror/lens to the real image, in front of the mirror/lens. 7. *Object distance*: Measure from the mirror/lens to the object. 8. *Image distance*: Measure from the mirror/lens to the image. Remember to use a ruler and protractor to ensure accuracy! Let me know if you have any specific questions or need help with a ray diagram!
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  • 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.
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  • 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.
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  • 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.
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