08.08.2020

Circular movement. Equation of motion in a circle. Angular velocity. Normal = centripetal acceleration. Period, frequency of circulation (rotation). Relationship between linear and angular velocity Kinematics of circular motion

Since the linear speed uniformly changes direction, then the movement along the circle cannot be called uniform, it is uniformly accelerated.

Angular velocity

Pick a point on the circle 1 . Let's build a radius. For a unit of time, the point will move to the point 2 . In this case, the radius describes the angle. The angular velocity is numerically equal to the angle of rotation of the radius per unit time.

Period and frequency

Rotation period T is the time it takes the body to make one revolution.

RPM is the number of revolutions per second.

The frequency and period are related by the relationship

Relationship with angular velocity

Line speed

Each point on the circle moves at some speed. This speed is called linear. The direction of the linear velocity vector always coincides with the tangent to the circle. For example, sparks from under a grinder move, repeating the direction of instantaneous speed.


Consider a point on a circle that makes one revolution, the time that is spent - this is the period T. The path traveled by a point is the circumference of a circle.

centripetal acceleration

When moving along a circle, the acceleration vector is always perpendicular to the velocity vector, directed to the center of the circle.

Using the previous formulas, we can derive the following relations


Points lying on the same straight line emanating from the center of the circle (for example, these can be points that lie on the wheel spoke) will have the same angular velocities, period and frequency. That is, they will rotate in the same way, but with different linear speeds. The farther the point is from the center, the faster it will move.

The law of addition of velocities is also valid for rotational motion. If the motion of a body or frame of reference is not uniform, then the law applies to instantaneous velocities. For example, the speed of a person walking along the edge of a rotating carousel is equal to the vector sum of the linear speed of rotation of the edge of the carousel and the speed of the person.

The Earth participates in two main rotational movements: daily (around its axis) and orbital (around the Sun). The period of rotation of the Earth around the Sun is 1 year or 365 days. The Earth rotates around its axis from west to east, the period of this rotation is 1 day or 24 hours. Latitude is the angle between the plane of the equator and the direction from the center of the Earth to a point on its surface.

According to Newton's second law, the cause of any acceleration is a force. If a moving body experiences centripetal acceleration, then the nature of the forces that cause this acceleration may be different. For example, if a body moves in a circle on a rope tied to it, then the acting force is the elastic force.

If a body lying on a disk rotates along with the disk around its axis, then such a force is the force of friction. If the force ceases to act, then the body will continue to move in a straight line

Consider the movement of a point on a circle from A to B. The linear velocity is equal to v A And v B respectively. Acceleration is the change in speed per unit of time. Let's find the difference of vectors.

  • Basic Laws of Dynamics. Newton's laws - first, second, third. Galileo's principle of relativity. The law of universal gravitation. Gravity. Forces of elasticity. Weight. Friction forces - rest, sliding, rolling + friction in liquids and gases.
  • Kinematics. Basic concepts. Uniform rectilinear motion. Uniform movement. Uniform circular motion. Reference system. Trajectory, displacement, path, equation of motion, speed, acceleration, relationship between linear and angular velocity.
  • simple mechanisms. Lever (lever of the first kind and lever of the second kind). Block (fixed block and movable block). Inclined plane. Hydraulic Press. The golden rule of mechanics
  • Conservation laws in mechanics. Mechanical work, power, energy, law of conservation of momentum, law of conservation of energy, equilibrium of solids
  • You are here now: Circular movement. Equation of motion in a circle. Angular velocity. Normal = centripetal acceleration. Period, frequency of circulation (rotation). Relationship between linear and angular velocity
  • Mechanical vibrations. Free and forced vibrations. Harmonic vibrations. Elastic oscillations. Mathematical pendulum. Energy transformations during harmonic vibrations
  • mechanical waves. Velocity and wavelength. Traveling wave equation. Wave phenomena (diffraction, interference...)
  • Hydromechanics and Aeromechanics. Pressure, hydrostatic pressure. Pascal's law. Basic equation of hydrostatics. Communicating vessels. Law of Archimedes. Sailing conditions tel. Fluid flow. Bernoulli's law. Torricelli formula
  • Molecular physics. Basic provisions of the ICT. Basic concepts and formulas. Properties of an ideal gas. Basic equation of the MKT. Temperature. The equation of state for an ideal gas. Mendeleev-Klaiperon equation. Gas laws - isotherm, isobar, isochore
  • Wave optics. Corpuscular-wave theory of light. Wave properties of light. dispersion of light. Light interference. Huygens-Fresnel principle. Diffraction of light. Light polarization
  • Thermodynamics. Internal energy. Job. Quantity of heat. Thermal phenomena. First law of thermodynamics. Application of the first law of thermodynamics to various processes. Heat balance equation. The second law of thermodynamics. Heat engines
  • Electrostatics. Basic concepts. Electric charge. The law of conservation of electric charge. Coulomb's law. The principle of superposition. The theory of close action. Electric field potential. Capacitor.
  • Constant electric current. Ohm's law for a circuit section. Operation and DC power. Joule-Lenz law. Ohm's law for a complete circuit. Faraday's law of electrolysis. Electrical circuits - serial and parallel connection. Kirchhoff's rules.
  • Electromagnetic vibrations. Free and forced electromagnetic oscillations. Oscillatory circuit. Alternating electric current. Capacitor in AC circuit. An inductor ("solenoid") in an alternating current circuit.
  • Elements of the theory of relativity. Postulates of the theory of relativity. Relativity of simultaneity, distances, time intervals. Relativistic law of addition of velocities. The dependence of mass on speed. The basic law of relativistic dynamics...
  • Errors of direct and indirect measurements. Absolute, relative error. Systematic and random errors. Standard deviation (error). Table for determining the errors of indirect measurements of various functions.

    • Since the linear speed uniformly changes direction, then the movement along the circle cannot be called uniform, it is uniformly accelerated.

    Angular velocity

    Pick a point on the circle 1 . Let's build a radius. For a unit of time, the point will move to the point 2 . In this case, the radius describes the angle. The angular velocity is numerically equal to the angle of rotation of the radius per unit time.

    Period and frequency

    Rotation period T is the time it takes the body to make one revolution.

    RPM is the number of revolutions per second.

    The frequency and period are related by the relationship

    Relationship with angular velocity

    Line speed

    Each point on the circle moves at some speed. This speed is called linear. The direction of the linear velocity vector always coincides with the tangent to the circle. For example, sparks from under a grinder move, repeating the direction of instantaneous speed.


    Consider a point on a circle that makes one revolution, the time that is spent - this is the period T.The path that the point overcomes is the circumference of the circle.

    centripetal acceleration

    When moving along a circle, the acceleration vector is always perpendicular to the velocity vector, directed to the center of the circle.

    Using the previous formulas, we can derive the following relations


    Points lying on the same straight line emanating from the center of the circle (for example, these can be points that lie on the wheel spoke) will have the same angular velocities, period and frequency. That is, they will rotate in the same way, but with different linear speeds. The farther the point is from the center, the faster it will move.

    The law of addition of velocities is also valid for rotational motion. If the motion of a body or frame of reference is not uniform, then the law applies to instantaneous velocities. For example, the speed of a person walking along the edge of a rotating carousel is equal to the vector sum of the linear speed of rotation of the edge of the carousel and the speed of the person.

    The Earth participates in two main rotational movements: daily (around its axis) and orbital (around the Sun). The period of rotation of the Earth around the Sun is 1 year or 365 days. The Earth rotates around its axis from west to east, the period of this rotation is 1 day or 24 hours. Latitude is the angle between the plane of the equator and the direction from the center of the Earth to a point on its surface.

    According to Newton's second law, the cause of any acceleration is a force. If a moving body experiences centripetal acceleration, then the nature of the forces that cause this acceleration may be different. For example, if a body moves in a circle on a rope tied to it, then the acting force is the elastic force.

    If a body lying on a disk rotates along with the disk around its axis, then such a force is the force of friction. If the force ceases to act, then the body will continue to move in a straight line

    Consider the movement of a point on a circle from A to B. The linear velocity is equal to

    Now let's move on to a fixed system connected to the earth. The total acceleration of point A will remain the same both in absolute value and in direction, since the acceleration does not change when moving from one inertial frame of reference to another. From the point of view of a stationary observer, the trajectory of point A is no longer a circle, but a more complex curve (cycloid), along which the point moves unevenly.

    Among the various types of curvilinear motion, of particular interest is uniform movement of the body around the circumference. This is the simplest form of curvilinear motion. At the same time, any complex curvilinear motion of a body in a sufficiently small section of its trajectory can be approximately considered as a uniform motion along circles.

    Such a movement is made by points of rotating wheels, turbine rotors, artificial satellites rotating in orbits, etc. With uniform motion in a circle, the numerical value speed remains constant. However, the direction of the velocity during such a movement is constantly changing.

    The speed of the body at any point of the curvilinear trajectory is directed along tangent to the path at that point. This can be seen by observing the work of a disc-shaped grindstone: pressing the end of a steel rod to a rotating stone, you can see hot particles coming off the stone. These particles fly at the same speed that they had at the moment of separation from the stone. The direction of the sparks always coincides with the tangent to the circle at the point where the rod touches the stone. Sprays from the wheels of a skidding car also move tangentially to the circle.

    Thus, the instantaneous velocity of the body at different points of the curvilinear trajectory has different directions, while the modulus of velocity can either be the same everywhere or change from point to point. But even if the modulus of speed does not change, it still cannot be considered constant. After all, speed is a vector quantity, and for vector quantities, the modulus and direction are equally important. That's why curvilinear motion is always accelerated , even if the modulus of speed is constant.

    Curvilinear motion can change the speed modulus and its direction. Curvilinear motion, in which the modulus of speed remains constant, is called uniform curvilinear motion. Acceleration during such movement is associated only with a change in the direction of the velocity vector.

    Both the modulus and the direction of acceleration must depend on the shape of the curved trajectory. However, it is not necessary to consider each of its myriad forms. Representing each section as a separate circle with a certain radius, the problem of finding acceleration in a curvilinear uniform motion will be reduced to finding acceleration in a body moving uniformly along a circle.

    Uniform motion in a circle is characterized by a period and frequency of circulation.

    The time it takes for a body to make one revolution is called circulation period.

    With uniform motion in a circle, the period of revolution is determined by dividing the distance traveled, i.e. circumference for movement speed:

    The reciprocal of a period is called circulation frequency, denoted by the letter ν . Number of revolutions per unit time ν called circulation frequency:

    Due to the continuous change in the direction of speed, a body moving in a circle has an acceleration that characterizes the speed of change in its direction, the numerical value of the speed in this case does not change.

    With a uniform motion of a body along a circle, the acceleration at any point in it is always directed perpendicular to the speed of movement along the radius of the circle to its center and is called centripetal acceleration.

    To find its value, consider the ratio of the change in the velocity vector to the time interval during which this change occurred. Since the angle is very small, we have



    1 0 0
    If you find an error, please select a piece of text and press Ctrl+Enter.