Angular displacement

{{Short description|Displacement measured angle-wise when a body is showing circular or rotational motion}}

{{Infobox physical quantity

| name = Angular displacement

| othernames = rotational displacement, angle of rotation

| width =

| background =

| image = File:Examples of Polar Coordinates.svg

| caption = {{longitem|The angle of rotation from the black ray to the green segment is 60°, from the black ray to the blue segment is 210°, and from the green to the blue segment is {{nowrap|1=210° − 60° = 150°}}. A complete rotation about the center point is equal to 1 tr, 360°, or 2π radians.}}

| unit = radians, degrees, turns, etc. (any angular unit)

| otherunits =

| symbols = θ, {{not a typo|ϑ}}, φ

| baseunits = radians (rad)

| dimension =

| extensive =

| intensive =

| conserved =

| transformsas =

| derivations =

}}

The angular displacement (symbol θ, {{not a typo|ϑ}}, or φ) – also called angle of rotation, rotational displacement, or rotary displacement – of a physical body is the angle (in units of radians, degrees, turns, etc.) through which the body rotates (revolves or spins) around a centre or axis of rotation. Angular displacement may be signed, indicating the sense of rotation (e.g., clockwise); it may also be greater (in absolute value) than a full turn.

Context

Image:angulardisplacement1.jpg

When a body rotates about its axis, the motion cannot simply be analyzed as a particle, as in circular motion it undergoes a changing velocity and acceleration at any time. When dealing with the rotation of a body, it becomes simpler to consider the body itself rigid. A body is generally considered rigid when the separations between all the particles remains constant throughout the body's motion, so for example parts of its mass are not flying off. In a realistic sense, all things can be deformable, however this impact is minimal and negligible.

Example

In the example illustrated to the right (or above in some mobile versions), a particle or body P is at a fixed distance r from the origin, O, rotating counterclockwise. It becomes important to then represent the position of particle P in terms of its polar coordinates (r, θ). In this particular example, the value of θ is changing, while the value of the radius remains the same. (In rectangular coordinates (x, y) both x and y vary with time.) As the particle moves along the circle, it travels an arc length s, which becomes related to the angular position through the relationship:

: $s = r\theta .$

Definition and units

Angular displacement may be expressed in radians or degrees. Using radians provides a very simple relationship between distance traveled around the circle (circular arc length) and the distance r from the centre (radius):

: $\theta = \frac{s}{r} \mathrm{rad}$

For example, if a body rotates 360° around a circle of radius r, the angular displacement is given by the distance traveled around the circumference - which is 2πr - divided by the radius: $\theta= \frac{2\pi r}r$ which easily simplifies to: $\theta=2\pi$ . Therefore, 1 revolution is $2\pi$ radians.

The above definition is part of the International System of Quantities (ISQ), formalized in the international standard ISO 80000-3 (Space and time),{{cite web |title=ISO 80000-3:2019 Quantities and units — Part 3: Space and time |publisher=International Organization for Standardization |date=2019 |edition=2 |url=https://www.iso.org/standard/64974.html |access-date=2019-10-23}} [https://www.iso.org/obp/ui/#iso:std:iso:80000:-3:ed-2:v1:en] (11 pages) and adopted in the International System of Units (SI).{{SIbrochure9th}}{{cite web |title=The NIST Guide for the Use of the International System of Units, Special Publication 811 |author-first1=Ambler |author-last1=Thompson |author-first2=Barry N. |author-last2=Taylor |edition=2008 |publisher=National Institute of Standards and Technology |date=2020-03-04 |orig-date=2009-07-02 |ref={{sfnref|NIST|2009}} |url=https://www.nist.gov/pml/special-publication-811 |access-date=2023-07-17}} [https://web.archive.org/web/20230515201622/https://nvlpubs.nist.gov/nistpubs/Legacy/SP/nistspecialpublication811e2008.pdf]

Angular displacement may be signed, indicating the sense of rotation (e.g., clockwise); it may also be greater (in absolute value) than a full turn.

In the ISQ/SI, angular displacement is used to define the number of revolutions, N{{=}}θ/(2π rad), a ratio-type quantity of dimension one.

In three dimensions

Image:Euler Rotation 2.JPG

Image:Euler AxisAngle.png

In three dimensions, angular displacement is an entity with a direction and a magnitude. The direction specifies the axis of rotation, which always exists by virtue of the Euler's rotation theorem; the magnitude specifies the rotation in radians about that axis (using the right-hand rule to determine direction). This entity is called an axis-angle.

Despite having direction and magnitude, angular displacement is not a vector because it does not obey the commutative law for addition.{{cite book|last1=Kleppner|first1=Daniel|last2=Kolenkow|first2=Robert|title=An Introduction to Mechanics|url=https://archive.org/details/introductiontome00dani|url-access=registration|publisher=McGraw-Hill|year=1973|pages=[https://archive.org/details/introductiontome00dani/page/288 288]–89|isbn=9780070350489}} Nevertheless, when dealing with infinitesimal rotations, second order infinitesimals can be discarded and in this case commutativity appears.

= Rotation matrices =

Several ways to describe rotations exist, like rotation matrices or Euler angles. See charts on SO(3) for others.

Given that any frame in the space can be described by a rotation matrix, the displacement among them can also be described by a rotation matrix. Being $A_0$ and $A_f$ two matrices, the angular displacement matrix between them can be obtained as $\Delta A = A_f A_0^{-1}$ . When this product is performed having a very small difference between both frames we will obtain a matrix close to the identity.

In the limit, we will have an infinitesimal rotation matrix.

= Infinitesimal rotation matrices =

References

= Sources =

{{Citation |last1=Goldstein |first1=Herbert |author1-link=Herbert Goldstein |author2-link=Charles P. Poole |last2=Poole |first2=Charles P. |last3=Safko |first3=John L. |year=2002 |title=Classical Mechanics |edition=third |publisher=Addison Wesley |isbn=978-0-201-65702-9}}
{{Citation |last=Wedderburn |first=Joseph H. M. |author-link=Joseph Wedderburn |year=1934 |title=Lectures on Matrices |publisher=AMS |isbn=978-0-8218-3204-2 |url=https://books.google.com/books?id=6eKVAwAAQBAJ}}

Category:Angle

Category:Rotation

Category:Sign (mathematics)