A fictitious force, also called a pseudo force[1], d'Alembert force[2][3] or inertial force[4][5], is an apparent force that acts on all masses in a non-inertial frame of reference, such as a rotating reference frame. In Physics, a force is whatever can cause an object with Mass to Accelerate. A non-inertial reference frame is a frame that is not an Inertial reference frame. A rotating frame of reference is a special case of a Non-inertial reference frame that is rotating relative to an Inertial reference frame. The force F does not arise from any physical interaction but rather from the acceleration a of the non-inertial reference frame itself. A non-inertial reference frame is a frame that is not an Inertial reference frame. Due to Newton's second law in the form F = m a, fictitious forces always are proportional to the mass m acted upon. Newton's laws of motion are three Physical laws which provide relationships between the Forces acting on a body and the motion of the

Non-inertial reference frames may be a convenience in calculation, or an intuitively appealing explanation of everyday life, but whenever using a non-inertial reference frame, its acceleration results in fictitious forces. Four fictitious forces are defined in accelerated frames: one caused by any acceleration of the origin in a straight line (rectilinear acceleration),[6] two caused by any rotation (centrifugal force and Coriolis force) and a fourth, called the Euler force, caused by a variable rate of rotation, should that occur. In physics the Coriolis effect is an apparent deflection of moving objects when they are viewed from a Rotating frame of reference. In Classical mechanics, the Euler acceleration (named for Leonhard Euler) also known as azimuthal acceleration is an Acceleration that appears

## Fictitious forces on Earth

The surface of the Earth is a rotating reference frame. A reactive centrifugal force is the reaction Force to a Centripetal force. In physics the Coriolis effect is an apparent deflection of moving objects when they are viewed from a Rotating frame of reference. A rotating frame of reference is a special case of a Non-inertial reference frame that is rotating relative to an Inertial reference frame. To solve classical mechanics problems exactly in an Earth-bound reference frame, two fictitious forces must be introduced, the Coriolis force and the centrifugal force (described below). Classical mechanics is used for describing the motion of Macroscopic objects from Projectiles to parts of Machinery, as well as Astronomical objects In physics the Coriolis effect is an apparent deflection of moving objects when they are viewed from a Rotating frame of reference. Both of these fictitious forces are weak compared to most typical forces in everyday life, but they can be detected under careful conditions. For example, Léon Foucault was able to show the Coriolis force that results from the Earth's rotation using the Foucault pendulum. Jean Bernard Léon Foucault (ʒɑ̃ bɛʁnaʁ leɔ̃ fu'ko ( 18 September 1819 &ndash 11 February 1868) was a French physicist In physics the Coriolis effect is an apparent deflection of moving objects when they are viewed from a Rotating frame of reference. The Foucault pendulum (fuːˈkoʊ "foo-KOH" or Foucault's pendulum, named after the French physicist Léon Foucault, was conceived as If the Earth were to rotate a thousand times faster (making each day only ~86 seconds long), people could easily get the impression that such fictitious forces are pulling on them, as on a spinning carousel.

## Detection of non-inertial reference frame

Observers inside a closed box that is moving with a constant velocity cannot detect their own motion; however, observers within an accelerating reference frame can detect that they are in a non-inertial reference frame from the fictitious forces that arise. In Physics, velocity is defined as the rate of change of Position. [7] They can even map out the magnitude and direction of the acceleration at every point with a plumb bob and a protractor. Another example of the detection of a non-inertial reference frame is the way a Foucault pendulum precesses.

## Examples of fictitious forces

### Acceleration in a straight line

When a car accelerates hard, the common human response is to feel "pushed back into the seat. " In an inertial frame of reference attached to the road, there is no physical force moving the rider backward. However, in the rider's non-inertial reference frame attached to the accelerating car, there is a backward fictitious force. We mention two possible ways of analyzing the problem:[8]

1. From the viewpoint of an inertial reference frame with constant velocity matching the initial motion of the car, the car is accelerating. In Physics, an inertial frame of reference is a Frame of reference which belongs to a set of frames in which Physical laws hold in the same and simplest In order for the passenger to stay inside the car, a force must be exerted on him. This force is exerted by the seat, which has started to move forward with the car and compressed against the passenger until it transmits the full force to keep the passenger inside. Thus, the passenger is accelerating in this frame, due to the unbalanced force of the seat.
2. From the point of view of the interior of the car, an accelerating reference frame, there is a fictitious force pushing the passenger backwards, with magnitude equal to the mass of the passenger times the acceleration of the car. Mass is a fundamental concept in Physics, roughly corresponding to the Intuitive idea of how much Matter there is in an object This force pushes the passenger back into the seat, until the seat compresses and provides an equal and opposite force. Thereafter, the passenger is stationary in this frame, because the fictitious force and the (real) force of the seat are balanced.

This serves as an illustration of the manner in which fictitious forces arise from switching to a non-inertial reference frame. Calculations of physical quantities made in any frame give the same answers, but in some cases calculations are easier to make in a non-inertial frame. (In this simple example, the calculations are equally complex for the two frames described. )

### Circular motion

A similar effect occurs in circular motion, circular for the standpoint of an inertial frame of reference attached to the road, with the fictitious force called the centrifugal force, fictitious when seen from a non-inertial frame of reference. In Physics, circular motion is Rotation along a Circle: a circular path or a circular Orbit. There are two types of Circular motion: uniform circular motion and Non-uniform circular motion. A time derivative is a Derivative of a function with respect to Time, usually interpreted as the Rate of change of the value of the function In Physics, circular motion is Rotation along a Circle: a circular path or a circular Orbit. If a car is moving at constant speed around a circular section of road, the occupants will feel pushed outside, away from the center of the turn. Again the situation can be viewed from inertial or non-inertial frames:

1. From the viewpoint of an inertial reference frame stationary with respect to the road, the car is accelerating toward the center of the circle. This is called centripetal acceleration and requires a centripetal force to maintain the motion. The centripetal force is the external force required to make a body follow a curved path The centripetal force is the external force required to make a body follow a curved path This force is exerted by the ground on the wheels, in this case thanks to the friction between the wheels and the road. Friction is the Force resisting the relative motion of two Surfaces in contact or a surface in contact with a fluid (e [9] The car is accelerating, due to the unbalanced force, which causes it to move in a circle.
2. From the viewpoint of a rotating frame, moving with the car, there is a fictitious centrifugal force that tends to push the car toward the outside of the road (and the occupants toward the outside of the car). The centrifugal force balances out the friction between wheels and road, making the car stationary in this non-inertial frame.

To consider another example, taking as our reference frame the surface of the rotating Earth, centrifugal force reduces the apparent force of gravity by about one part in a thousand, depending on latitude. This is zero at the poles, maximum at the equator.

Another fictitious force that arises in rotating frames is the Coriolis force, which is ordinarily visible only in very large-scale motion like the projectile motion of long-range guns or the circulation of the earth's atmosphere. In physics the Coriolis effect is an apparent deflection of moving objects when they are viewed from a Rotating frame of reference. Neglecting air resistance, an object dropped from a 50-meter-high tower at the equator will fall 7. The equator (sometimes referred to colloquially as "the Line") is the intersection of the Earth 's surface with the plane perpendicular to the 7 millimeters eastward of the spot below where it is dropped because of the Coriolis force. [10]

In the case of distant objects and a rotating reference frame, what must be taken into account is the resultant force of centrifugal and Coriolis force. Consider a distant star observed from a rotating spacecraft. In the reference frame co-rotating with the spacecraft, the distant star appears to move along a circular trajectory around the spacecraft. The apparent motion of the star is an apparent centripetal acceleration. Just like in the example above of the car in circular motion, the centrifugal force has the same magnitude as the fictitious centripetal force, but is directed in the opposite, centrifugal direction. In this case the Coriolis force is twice the magnitude of the centrifugal force, and it points in centripetal direction. The vector sum of the centrifugal force and the Coriolis force is the total fictitious force, which in this case points in centripetal direction.

### Fictitious forces and work

Fictitious forces can be considered to do work, provided that they move an object on a trajectory that changes its energy from potential to kinetic. In Physics, mechanical work is the amount of Energy transferred by a Force. Trajectory is the path a moving object follows through space The object might be a Projectile or a Satellite, for example In Physics and other Sciences energy (from the Greek grc ἐνέργεια - Energeia, "activity operation" from grc ἐνεργός Potential energy can be thought of as Energy stored within a physical system The kinetic energy of an object is the extra Energy which it possesses due to its motion For example, consider a person in a rotating chair holding a weight in his outstretched arm. If he pulls his arm inward, from the perspective of his rotating reference frame he has done work against centrifugal force. If he now lets go of the weight, from his perspective it spontaneously flies outward, because centrifugal force has done work on the object, converting its potential energy into kinetic. From an inertial viewpoint, of course, the object flies away from him because it is suddenly allowed to move in a straight line. This illustrates that the work done, like the total potential and kinetic energy of an object, can be different in a non-inertial frame than an inertial one.

## Gravity as a fictitious force

Main article: General relativity

General relativity is outside the scope of this article. General relativity or the general theory of relativity is the geometric theory of Gravitation published by Albert Einstein in 1916 However, the notion of "fictitious force" comes up in general relativity, so it is discussed briefly here. [11][12] Notice however, that this use of the term "fictitious force" is not covered by the analysis in this article, which all is based upon the traditional Euclidean geometry of space, not upon "curved space time".

All fictitious forces are proportional to the mass of the object upon which they act, which is also true for gravity. Gravitation is a natural Phenomenon by which objects with Mass attract one another This led Albert Einstein to wonder whether gravity was a fictitious force as well. Albert Einstein ( German: ˈalbɐt ˈaɪ̯nʃtaɪ̯n; English: ˈælbɝt ˈaɪnstaɪn (14 March 1879 – 18 April 1955 was a German -born theoretical He noted that a freefalling observer in a closed box would not be able to detect the force of gravity; hence, freefalling reference frames are equivalent to an inertial reference frame (the equivalence principle). Free fall is motion with no Acceleration other than that provided by Gravity. The equivalence principle Following up on this insight, Einstein was able to formulate a theory with gravity as a fictitious force; attributing the apparent acceleration to the curvature of spacetime. In Mathematics, curvature refers to any of a number of loosely related concepts in different areas of geometry SpaceTime is a patent-pending three dimensional graphical user interface that allows end users to search their content such as Google Google Images Yahoo! YouTube eBay Amazon and RSS This is the essential physics of Einstein's theory of general relativity. General relativity or the general theory of relativity is the geometric theory of Gravitation published by Albert Einstein in 1916

## Mathematical derivation of fictitious forces

Figure 1: An object located at xA in inertial frame A is located at location xB in accelerating frame B. The origin of frame B is located at XAB in frame A. The orientation of frame B is determined by the unit vectors along its coordinate directions, uj with j = 1, 2, 3. Using these axes, the coordinates of the object according to frame B are xB = ( x1, x2, x3 ).

### General derivation

Many problems require use of noninertial reference frames, for example, those involving satellites[14][15] and particle accelerators. [16] Figure 1 shows a particle with mass m and position vector xA(t) in a particular inertial frame A. Mass is a fundamental concept in Physics, roughly corresponding to the Intuitive idea of how much Matter there is in an object In Physics, an inertial frame of reference is a Frame of reference which belongs to a set of frames in which Physical laws hold in the same and simplest Consider a non-inertial frame B whose origin relative to the inertial one is given by XAB(t). Let the position of the particle in frame B be xB(t). What is the force on the particle as expressed in the coordinate system of frame B? [17][18]

To answer this question, let the coordinate axis in B be represented by unit vectors uj with j any of { 1, 2, 3 } for the three coordinate axes. Then

$\mathbf{x}_{B} = \sum_{j=1}^3 x_j\ \mathbf{u}_j \ .$

The interpretation of this equation is that xB is the vector displacement of the particle as expressed in terms of the coordinates in frame B at time t. From frame A the particle is located at:

$\mathbf{x}_A =\mathbf{X}_{AB} + \sum_{j=1}^3 x_j\ \mathbf{u}_j \ .$

As an aside, the unit vectors { uj } cannot change magnitude, so derivatives of these vectors express only rotation of the coordinate system B. On the other hand, vector XAB simply locates the origin of frame B relative to frame A, and so cannot include rotation of frame B.

Taking a time derivative, the velocity of the particle is:

$\frac {d \mathbf{x}_{A}}{dt} =\frac{d \mathbf{X}_{AB}}{dt}+ \sum_{j=1}^3 \frac{dx_j}{dt} \ \mathbf{u}_j + \sum_{j=1}^3 x_j \ \frac{d \mathbf{u}_j}{dt} \ .$

The second term summation is the velocity of the particle, say vB as measured in frame B. That is:

$\frac {d \mathbf{x}_{A}}{dt} =\mathbf{v}_{AB}+ \mathbf{v}_B + \sum_{j=1}^3 x_j \ \frac{d \mathbf{u}_j}{dt} \ .$

The interpretation of this equation is that the velocity of the particle seen by observers in frame A consists of what observers in frame B call the velocity, namely vB, plus extra terms related to the rate of change of the frame-B coordinate axes.

To find the acceleration, another time differentiation provides:

$\frac {d^2 \mathbf{x}_{A}}{dt^2} = \mathbf{a}_{AB}+\frac {d\mathbf{v}_B}{dt} + \sum_{j=1}^3 \frac {dx_j}{dt} \ \frac{d \mathbf{u}_j}{dt} + \sum_{j=1}^3 x_j \ \frac{d^2 \mathbf{u}_j}{dt^2}\ .$

Using the same formula already used for the time derivative of xB, the velocity derivative on the right is:

$\frac {d\mathbf{v}_B}{dt} =\sum_{j=1}^3 \frac{d v_j}{dt} \ \mathbf{u}_j+ \sum_{j=1}^3 v_j \ \frac{d \mathbf{u}_j}{dt} =\mathbf{a}_B + \sum_{j=1}^3 v_j \ \frac{d \mathbf{u}_j}{dt} \ .$

Consequently,

$\frac {d^2 \mathbf{x}_{A}}{dt^2}=\mathbf{a}_{AB}+\mathbf{a}_B + 2\ \sum_{j=1}^3 v_j \ \frac{d \mathbf{u}_j}{dt} + \sum_{j=1}^3 x_j \ \frac{d^2 \mathbf{u}_j}{dt^2}\ .$

The interpretation of this equation is as follows: the acceleration of the particle in frame A consists of what observers in frame B call the particle acceleration aB, but in addition there are three acceleration terms related to the movement of the frame-B coordinate axes: one term related to the acceleration of the origin of frame B, namely aAB, and two terms related to rotation of frame B. Consequently, observers in B will see the particle motion as possessing "extra" acceleration, which they will attribute to "forces" acting on the particle, but which observers in A say are "fictitious" forces arising simply because observers in B do not recognize the non-inertial nature of frame B. To put matters in terms of forces, the accelerations are multiplied by the particle mass:

$\mathbf{F}_A = \mathbf{F}_B + m\ \mathbf{a}_{AB}+ 2m\ \sum_{j=1}^3 v_j \ \frac{d \mathbf{u}_j}{dt} + m\ \sum_{j=1}^3 x_j \ \frac{d^2 \mathbf{u}_j}{dt^2}\ .$

The force observed in frame B, FB = m aB is related to the actual force on the particle, FA, by:

$\mathbf{F}_B = \mathbf{F}_A + \mathbf{F}_{\mbox{fictitious}} \ .$

where:

$\mathbf{F}_{\mbox{fictitious}} =-m\ \mathbf{a}_{AB} -2m\ \sum_{j=1}^3 v_j \ \frac{d \mathbf{u}_j}{dt} - m\ \sum_{j=1}^3 x_j \ \frac{d^2 \mathbf{u}_j}{dt^2}\ .$

Thus, we can solve problems in frame B by assuming that Newton's second law holds (with respect to quantities in that frame) and treating Ffictitious as an additional force. [19][20][21]

### Rotating coordinate systems

A common situation in which noninertial reference frames are useful is when the reference frame is rotating. Because such rotational motion is non-inertial, due to the acceleration present in any rotational motion, a fictitious force can always be invoked by using a rotational frame of reference. Despite this complication, the use of fictitious forces often simplifies the calculations involved.

To derive expressions for the fictitious forces, derivatives are needed for the apparent time rate of change of vectors that take into account time-variation of the coordinate axes. If the rotation of frame B is represented by a vector Ω pointed along the axis of rotation with orientation given by the right-hand rule, and with magnitude given by

$|\boldsymbol{\Omega} | = \frac {d \theta }{dt} = \omega (t) \ ,$

then the time derivative of any of the three unit vectors describing frame B is:[19][22]

$\frac {d \mathbf{u}_j (t)}{dt} = \boldsymbol{\Omega} \times \mathbf{u}_j (t) \ ,$

and

$\frac {d^2 \mathbf{u}_j (t)}{dt^2}= \frac{d\boldsymbol{\Omega}}{dt} \times \mathbf{u}_j +\boldsymbol{\Omega} \times \frac{d \mathbf{u}_j (t)}{dt}$$= \frac{d\boldsymbol{\Omega}}{dt} \times \mathbf{u}_j+ \boldsymbol{\Omega} \times \left( \boldsymbol{\Omega} \times \mathbf{u}_j (t) \right)\ ,$

as is verified using the properties of the vector cross product. For the related yet different principle relating to electromagnetic coils see Right hand grip rule. In Mathematics, the cross product is a Binary operation on two vectors in a three-dimensional Euclidean space that results in another vector which These derivative formulas now are applied to the relationship between acceleration in an inertial frame, and that in a coordinate frame rotating with time-varying angular velocity ω ( t ). From the previous section, where subscript A refers to the inertial frame and B to the rotating frame, setting aAB = 0 to remove any translational acceleration, and focusing on only rotational properties:

$\frac {d^2 \mathbf{x}_{A}}{dt^2}=\mathbf{a}_B + 2\ \sum_{j=1}^3 v_j \ \frac{d \mathbf{u}_j}{dt}$$+ \sum_{j=1}^3 x_j \ \frac{d^2 \mathbf{u}_j}{dt^2}\ ,$
$\mathbf{a}_A=\mathbf{a}_B +\ 2\ \sum_{j=1}^3 v_j \boldsymbol{\Omega} \times \mathbf{u}_j (t)\$$+\ \sum_{j=1}^3 x_j \frac{d\boldsymbol{\Omega}}{dt} \times \mathbf{u}_j \ + \sum_{j=1}^3 x_j \boldsymbol{\Omega} \times \left( \boldsymbol{\Omega} \times \mathbf{u}_j (t) \right)\$
$=\mathbf{a}_B$$+ 2\ \boldsymbol{\Omega} \times\sum_{j=1}^3 v_j \mathbf{u}_j (t) \$$+ \frac{d\boldsymbol{\Omega}}{dt} \times \sum_{j=1}^3 x_j \mathbf{u}_j \$$+\ \boldsymbol{\Omega} \times \left( \boldsymbol{\Omega} \times \sum_{j=1}^3 x_j \mathbf{u}_j (t) \right)\ .$

Collecting terms, the result is the so-called acceleration transformation formula:[23]

$\mathbf{a}_A=\mathbf{a}_B + 2\ \boldsymbol{\Omega} \times\mathbf{v}_B\$$+ \frac{d\boldsymbol{\Omega}}{dt} \times \mathbf{x}_B \ + \boldsymbol{\Omega} \times \left( \boldsymbol{\Omega} \times \mathbf{x}_B \right)\ .$

The physical acceleration aA due to what observers in the inertial frame A call real external forces on the object is. Proper acceleration is the physical acceleration experienced by an object therefore, not simply the acceleration aB seen by observers in the rotational frame B , but has in addition several additional geometric acceleration terms associated with the rotation of B. As seen in the rotational frame, the acceleration aB of the particle is given by rearrangement of the above equation as:

$\mathbf{a}_{B} = \mathbf{a}_A - 2 \boldsymbol\Omega \times \mathbf{v}_{B} - \boldsymbol\Omega \times (\boldsymbol\Omega \times \mathbf{x}_B ) - \frac{d \boldsymbol\Omega}{dt} \times \mathbf{x}_B \ .$

The net force upon the object according to observers in the rotating frame is FB = m aB. If their observations are to result in the correct force on the object when using Newton's laws, they must consider that the additional force Ffict is present, so the end result is FB = FA + Ffict. Thus, the fictitious force used by observers in B to get the correct behavior of the object from Newton's laws equals:

$\mathbf{F}_{\mathrm{fict}} = - 2 m \boldsymbol\Omega \times \mathbf{v}_{B} - m \boldsymbol\Omega \times (\boldsymbol\Omega \times \mathbf{x}_B )$$\ - m \frac{d \boldsymbol\Omega }{dt} \times \mathbf{x}_B \ .$

Here, the first term is the Coriolis force,[24] the second term is the centrifugal force,[25] and the third term is the Euler force. In physics the Coriolis effect is an apparent deflection of moving objects when they are viewed from a Rotating frame of reference. In Classical mechanics, the Euler acceleration (named for Leonhard Euler) also known as azimuthal acceleration is an Acceleration that appears [26][27] When the rate of rotation doesn't change, as is typically the case for a planet, the Euler force is zero.

### Orbiting coordinate systems

Figure 2: An orbiting but fixed orientation coordinate system B, shown at three different times. The unit vectors uj, j = 1, 2, 3 do not rotate, but maintain a fixed orientation, while the origin of the coordinate system B moves at constant angular rate ω about the fixed axis Ω. Axis Ω passes through the origin of inertial frame A, so the origin of frame B is a fixed distance R from the origin of inertial frame A.

As a related example, suppose the moving coordinate system B rotates in a circle of radius R about the fixed origin of inertial frame A, but maintains its coordinate axes fixed in orientation, as in Figure 2. The acceleration of an observed body is now:

$\frac {d^2 \mathbf{x}_{A}}{dt^2}=\mathbf{a}_{AB}+\mathbf{a}_B$$+ 2\ \sum_{j=1}^3 v_j \ \frac{d \mathbf{u}_j}{dt}$$+ \sum_{j=1}^3 x_j \ \frac{d^2 \mathbf{u}_j}{dt^2}\ .$
$=\mathbf{a}_{AB}\ +\mathbf{a}_B\ ,$

where the summations are zero inasmuch as the unit vectors have no time dependence. The origin of system B is located according to frame A at:

$\mathbf{X}_{AB} = R \left( \cos ( \omega t) , \ \sin (\omega t) \right) \ ,$

leading to a velocity of the origin of frame B as:

$\mathbf{v}_{AB} = \frac{d}{dt} \mathbf{X}_{AB} = \mathbf{\Omega \times X}_{AB} \ ,$

leading to an acceleration of the origin of B given by:

$\mathbf{a}_{AB} = \frac{d^2}{dt^2} \mathbf{X}_{AB}$$= \mathbf{ \Omega \ \times } \left( \mathbf{ \Omega \times X}_{AB}\right)$$= - \omega^2 \mathbf{X}_{AB} \ .$

The observers in frame B therefore must introduce a fictitious force, this time due to the acceleration from the orbital motion of their entire coordinate frame, that is radially outward away from the center of rotation of the origin of their coordinate system:

$\mathbf{F}_{\mathrm{fict}} = m \omega^2 \mathbf{X}_{AB} \ ,$

and of magnitude:

$|\mathbf{F}_{\mathrm{fict}}| = m \omega^2 R \ .$

Notice that this force is a centrifugal force, but has differences from the case of a rotating frame. In the rotating frame the centrifugal force is related to the distance of the object from the origin of frame B, while in the case of an orbiting frame, the centrifugal force is independent of the distance of the object from the origin of frame B, but instead depends upon the distance of the origin of frame B from its center of rotation, resulting in the same centrifugal fictitious force for all objects observed in frame B.

### Orbiting and rotating

Figure 3: An orbiting coordinate system B similar to Figure 2, but in which unit vectors uj, j = 1, 2, 3 rotate to face the rotational axis, while the origin of the coordinate system B moves at constant angular rate ω about the fixed axis Ω.

As a combination example, Figure 3 shows a coordinate system B that orbits inertial frame A as in Figure 2, but the coordinate axes in frame B turn so unit vector u1 always points toward the center of rotation. This example might apply to a test tube in a centrifuge, where vector u1 points along the axis of the tube toward its opening at its top. In this example, unit vector u3 retains a fixed orientation, while vectors u1, u2 rotate at the same rate as the origin of coordinates. That is,

$\mathbf{u}_1 = (-\cos \omega t ,\ -\sin \omega t )\ ;\$$\mathbf{u}_2 = (\sin \omega t ,\ -\cos \omega t ) \ .$
$\frac{d}{dt}\mathbf{u}_1 = \mathbf{\Omega \times u_1}= \omega\mathbf{u}_2\ ;$$\ \frac{d}{dt}\mathbf{u}_2 = \mathbf{\Omega \times u_2} = -\omega\mathbf{u}_1\ \ .$

Hence, the acceleration of a moving object is expressed as:

$\frac {d^2 \mathbf{x}_{A}}{dt^2}=\mathbf{a}_{AB}+\mathbf{a}_B + 2\ \sum_{j=1}^3 v_j \ \frac{d \mathbf{u}_j}{dt}$$+\ \sum_{j=1}^3 x_j \ \frac{d^2 \mathbf{u}_j}{dt^2}\$
$=\mathbf{ \Omega \ \times } \left( \mathbf{ \Omega \times X}_{AB}\right) + 2\ \boldsymbol{\Omega} \times\mathbf{v}_B\$$\ +\ \boldsymbol{\Omega} \times \left( \boldsymbol{\Omega} \times \mathbf{x}_B \right)\$
$=\mathbf{ \Omega \ \times } \left( \mathbf{ \Omega \times} (\mathbf{ X}_{AB}+\mathbf{x}_B) \right) + 2\ \boldsymbol{\Omega} \times\mathbf{v}_B\ \ ,$

where the angular acceleration term is zero for constant rate of rotation. For the example of a tube in a centrifuge, if the tube is far enough from the center of rotation, |XAB| = R >> |xB|, so all the matter in the test tube sees the same acceleration (the same centrifugal force). Thus, in this case, the fictitious force is primarily a uniform centrifugal force along the axis of the tube, away from the center of rotation, with a value |FFict| = ω2 R, where R is the distance of the matter in the tube from the center of the centrifuge. Also, the test tube confines motion to the direction down the length of the tube, so vB is opposite to u1 and the Coriolis force is opposite to u2, that is, against the wall of the tube. If the tube is spun for a long enough time, the velocity vB drops to zero as the matter comes to an equilibrium distribution. For more details, see the articles on sedimentation and the Lamm equation. Sedimentation describes the motion of Molecules in Solutions or particles in suspensions in response to an external force such as gravity The Lamm equation describes the sedimentation and diffusion of a Solute under ultracentrifugation in traditional sector -shaped cells

### Crossing a carousel

Figure 4: Crossing a rotating carousel walking at constant speed from the center of the carousel to its edge, a spiral is traced out in the inertial frame, while a simple straight radial path is seen in the frame of the carousel.

Figure 4 shows another example comparing the observations of an inertial observer with those of an observer on a rotating carousel. A carousel ( carrousel in French) is an Amusement ride consisting of a rotating platform with seats for passengers The carousel rotates at a constant angular velocity represented by the vector Ω with magnitude ω, pointing upward according to the right-hand rule. For the related yet different principle relating to electromagnetic coils see Right hand grip rule. A rider on the carousel walks radially across it at constant speed, in what appears to the walker to be the straight line path inclined at 45° in Figure 4 . To the stationary observer, however, the walker travels a spiral path. The points identified on both paths in Figure 4 correspond to the same times spaced at equal time intervals. We ask how two observers, one on the carousel and one in an inertial frame, formulate what they see using Newton's laws.

#### Inertial observer

The observer at rest describes the path followed by the walker as a spiral. Adopting the coordinate system shown in Figure 4, the trajectory is described by r ( t ):

$\boldsymbol{r}(t) =R(t)\mathbf{u}_R = \left( x(t),\ y(t) \right) = \left( R(t)\cos (\omega t + \pi/4),\ R(t)\sin (\omega t + \pi/4) \right) \ ,$

where the added π/4 sets the path angle at 45° to start with, uR is a unit vector in the radial direction pointing from the center of the carousel to the walker at time t. The radial distance R(t) increases steadily with time according to:

$R(t) = s t \ ,$

with s the speed of walking. According to simple kinematics, the velocity is then the first derivative of the trajectory:

$\boldsymbol{v}(t) = \frac {d}{dt} R(t) \left( \cos (\omega t + \pi/4),\ \sin (\omega t + \pi/4) \right) + \omega R(t) \left( -\sin((\omega t + \pi/4),\ \cos (\omega t + \pi/4)) \right) \$
$=\frac {d}{dt} R(t) \mathbf{u}_R + \omega R(t) \mathbf{u}_{\theta}\ ,$

with uθ a unit vector perpendicular to uR at time t (as can be verified by noticing that the vector dot product with the radial vector is zero) and pointing in the direction of travel. In Mathematics, the dot product, also known as the scalar product, is an operation which takes two vectors over the Real numbers R The acceleration is the first derivative of the velocity:

$\boldsymbol {a}(t) = \frac{d^2}{dt^2} R(t)\left( \cos (\omega t + \pi/4),\ \sin (\omega t + \pi/4) \right)$$+ 2 \frac {d}{dt} R(t) \omega \left( -\sin((\omega t + \pi/4),\ \cos (\omega t + \pi/4)) \right)$$-\omega^2 R(t)\left( \cos (\omega t + \pi/4),\ \sin (\omega t + \pi/4) \right) \$
$=2s\ \omega \left( -\sin((\omega t + \pi/4),\ \cos (\omega t + \pi/4)) \right)$$-\omega^2 R(t)\left( \cos (\omega t + \pi/4),\ \sin (\omega t + \pi/4) \right) \$
$=2s\ \omega \ \mathbf{u}_{\theta}-\omega^2 R(t)\ \mathbf{u}_R \ .$

The last term in the acceleration is radially inward of magnitude ω2 R, which is therefore the instantaneous centripetal acceleration of circular motion. The centripetal force is the external force required to make a body follow a curved path In Physics, circular motion is Rotation along a Circle: a circular path or a circular Orbit. [28] The first term is perpendicular to the radial direction, and pointing in the direction of travel. Its magnitude is 2sω, and it represents the acceleration of the walker as the edge of the carousel is neared, and the the arc of circle traveled in a fixed time increases, as can be seen by the increased spacing between points for equal time steps on the spiral in Figure 4 as the outer edge of the carousel is approached.

Applying Newton's laws, multiplying the acceleration by the mass of the walker, the inertial observer concludes that the walker is subject to two forces: the inward, radially directed centripetal force, and another force perpendicular to the radial direction that is proportional to the speed of the walker.

#### Rotating observer

The rotating observer sees the walker travel a straight line from the center of the carousel to the periphery, as shown in Figure 4. Moreover, the rotating observer sees that the walker moves at a constant speed in the same direction, so applying Newton's law of inertia, there is zero force upon the walker. These conclusions do not agree with the inertial observer. To obtain agreement, the rotating observer has to introduce fictitious forces that appear to exist in the rotating world, even though there is no apparent reason for them, no apparent gravitational mass, electric charge or what have you, that could account for these fictitious forces.

To agree with the inertial observer, the forces applied to the walker must be exactly those found above. They can be related to the general formulas already derived, namely:

$\mathbf{F}_{\mathrm{fict}} = - 2 m \boldsymbol\Omega \times \mathbf{v}_{B} - m \boldsymbol\Omega \times (\boldsymbol\Omega \times \mathbf{x}_B )$$\ - m \frac{d \boldsymbol\Omega }{dt} \times \mathbf{x}_B \ .$

In this example, the velocity seen in the rotating frame is:

$\boldsymbol{v}_B = s\ \mathbf{u}_R \ ,$

with uR a unit vector in the radial direction. The position of the walker as seen on the carousel is:

$\mathbf{x}_B = R(t)\mathbf{u}_R \ ,$

and the time derivative of Ω is zero for uniform angular rotation. Noticing that

$\boldsymbol\Omega \times \mathbf{u}_R =\omega \mathbf{u}_{\theta} \$

and

$\boldsymbol\Omega \times \mathbf{u}_{\theta} =-\omega \mathbf{u}_R \ ,$

we find:

$\mathbf{F}_{\mathrm{fict}} = - 2 m \omega s\ \mathbf{u}_{\theta} + m \omega^2 R(t) \mathbf{u}_R \ .$

To obtain a straight line motion in the rotating world, a force exactly opposite in sign to the fictitious force must be applied to reduce the net force on the walker to zero, so Newton's law of inertia will predict a straight line motion, in agreement with what the rotating observer sees. The fictitious forces that must be combated are the Coriolis force (first term) and the centrifugal force (second term). (These terms are approximate. [29]) By applying forces to counter these two fictitious forces, the rotating observer ends up applying exactly the same forces upon the walker that the inertial observer predicted were needed.

Because they differ only by the constant walking velocity, the walker and the rotational observer see the same accelerations. From the walker's perspective, the fictitious force is experienced as real, and combating this force is necessary to stay on a straight line radial path holding constant speed. It's like battling a crosswind while being thrown to the edge of the carousel.

### Observation

Notice that this kinematical discussion does not delve into the mechanism by which the required forces are generated. Kinematics ( Greek κινειν, kinein, to move is a branch of Classical mechanics which describes the motion of objects without That is the subject of kinetics. Kinetics in physics In physics kinetics used to be the branch of Classical mechanics that was concerned with the relationship between the motion of bodies In the case of the carousel, the kinetic discussion would involve perhaps a study of the walker's shoes and the friction they need to generate against the floor of the carousel, or perhaps the dynamics of skateboarding, if that is how the walker traveled. Whatever the means of travel across the carousel, the forces calculated above must be realized. A very rough analogy is heating your house: you must have a certain temperature to be comfortable, but whether you heat by burning gas or by burning coal is another problem. Kinematics sets the thermostat, kinetics fires the furnace.

## References and notes

1. ^ Richard Phillips Feynman, Leighton R B & Sands M L (2006). The Feynman Lectures on Physics. San Francisco: Pearson/Addison-Wesley, Vol. I, section 12-5. ISBN 0805390499.
2. ^ Cornelius Lanczos (1986). The Variational Principles of Mechanics. New York: Courier Dover Publications, p. 100. ISBN 0486650677.
3. ^ Seligman, Courtney. Fictitious Forces. Retrieved on 2007-09-03. Year 2007 ( MMVII) was a Common year starting on Monday of the Gregorian calendar in the 21st century. Events 36 BC - In the Battle of Naulochus, Marcus Vipsanius Agrippa, Admiral of Octavian, defeats Sextus Pompeius
4. ^ Max Born & Günther Leibfried (1962). Einstein's Theory of Relativity. New York: Courier Dover Publications, pp. 76-78. ISBN 0486607690.
5. ^ NASA notes:(23) Accelerated Frames of Reference: Inertial Forces
6. ^ The term d'Alembert force often is limited to this case. See Lanczos, for example.
7. ^ Vladimir Igorevich Arnolʹd (1989). Mathematical Methods of Classical Mechanics. Berlin: Springer, §27 pp. 129 ff. . ISBN 0387968903.
8. ^ Lloyd Motz & Jefferson Hane Weaver (2002). The Concepts of Science: From Newton to Einstein. Basic Books, p. 101. ISBN 0738208345.
9. ^ The force in this example is known as ground reaction, and it could exist even without friction, e. In Classical mechanics the term ground reaction force (GRF refers generically to any force exerted by the ground on a body in contact with it g. , a sled running down a curve of a bobsled track.
10. ^ Daniel Kleppner and Robert J. Kolenkow (1973). An Introduction to Mechanics. McGraw-Hill, page 363. ISBN 0070350485.
11. ^ Fritz Rohrlich (2007). Classical charged particles. Singapore: World Scientific, p. 40. ISBN 9812700048.
12. ^ Hans Stephani (2004). Relativity: An Introduction to Special and General Relativity. Cambridge UK: Cambridge University Press, p. 105. ISBN 0521010691.
13. ^ Edwin F. Taylor and John Archibald Wheeler (2000) Exploring black holes (Addison Wesley Longman, NY) ISBN 0-201-38423-X
14. ^ Alberto Isidori, Lorenzo Marconi & Andrea Serrani (2003). Robust Autonomous Guidance: An Internal Model Approach. Springer, p. 61. ISBN 1852336951.
15. ^ Shuh-Jing Ying (1997). Advanced Dynamics. Reston VA: American Institute of Aeronautics, and Astronautics, p. 172. ISBN 1563472244.
16. ^ Philip J. Bryant & Kjell Johnsen (1993). The Principles of Circular Accelerators and Storage Rings. Cambridge UK: Cambridge University Press, p. xvii. ISBN 0521355788.
17. ^ Alexander L Fetter & John D Walecka (2003). Theoretical Mechanics of Particles and Continua. Courier Dover Publications, pages 33-39. ISBN 0486432610.
18. ^ Yung-kuo Lim & Yuan-qi Qiang (2001). Problems and Solutions on Mechanics: Major American Universities Ph.D. Qualifying Questions and Solutions. Singapore: World Scientific, 183. ISBN 9810212984.
19. ^ a b John Robert Taylor (2004). Classical Mechanics. Sausalito CA: University Science Books, pp. 343-344. ISBN 189138922X.
20. ^ Vladimir Igorevich Arnolʹd (1989). Mathematical Methods of Classical Mechanics. Berlin: Springer, §27 pp. 129 ff. . ISBN 0387968903.
21. ^ Kleppner, pages 62-63
22. ^ See for example, JL Synge & BA Griffith (1949). Principles of Mechanics, 2nd Edition, McGraw-Hill, pp. 348-349.
23. ^ R. Douglas Gregory (2006). Classical Mechanics: An Undergraduate Text. Cambridge UK: Cambridge University Press, Eq. (17. 16), p. 475. ISBN 0521826780.
24. ^ Georg Joos & Ira M. Freeman (1986). Theoretical Physics. New York: Courier Dover Publications, p. 233. ISBN 0486652270.
25. ^ Percey Franklyn Smith & William Raymond Longley (1910). Theoretical Mechanics. Boston: Gin, p. 118.
26. ^ Cornelius Lanczos (1986). The Variational Principles of Mechanics. New York: Courier Dover Publications, p. 103. ISBN 0486650677.
27. ^ Jerold E. Marsden & Tudor. S. Ratiu (1999). Introduction to Mechanics and Symmetry: A Basic Exposition of Classical Mechanical Systems: Texts in applied mathematics, 17, 2nd Edition, NY: Springer-Verlag, page 251. ISBN 038798643X.
28. ^ Note: There is a subtlety here: the distance R is the instantaneous distance from the rotational axis of the carousel. However, it is not the radius of curvature of the walker's trajectory as seen by the inertial observer, and the unit vector uR is not perpendicular to the path. In Differential geometry of curves, the osculating circle of a sufficiently smooth plane Curve at a given point on the curve is the Circle whose center Thus, the designation "centripetal acceleration" is an approximate use of this term. See, for example, Howard D. Curtis (2005). Orbital Mechanics for Engineering Students. Butterworth-Heinemann, p. 5. ISBN 0750661690.   and S. Y. Lee (2004). Accelerator physics, 2nd Edition, Hackensack NJ: World Scientific, p. 37. ISBN 981256182X.
29. ^ A circle about the axis of rotation is not the osculating circle of the walker's trajectory, so "centrifugal" and "Coriolis" are approximate uses for these terms. In Differential geometry of curves, the osculating circle of a sufficiently smooth plane Curve at a given point on the curve is the Circle whose center See note.