Physics equations/Uniform circular motion

${\displaystyle \mathrm{\Sigma }\overrightarrow{F}=m\overrightarrow{a}=m\frac{\mathrm{d}\overrightarrow{\mathrm{v}}}{\mathrm{d}\mathrm{t}}=m\frac{{\mathrm{d}}^{\mathrm{2}}\overrightarrow{\mathrm{r}}}{\mathrm{d}\mathrm{t}},}$

Solution: Σ has no units (i.e. is dimensionless}; it is an instruction to sum all the forces acting on an object. The symbol Σ is a simple example of an operator. Another dimensionless operator is d, which is an instruction to take the difference beteen two values that are nearly equal to each other. In our SI system of units: m (mass) is measured in kg; a (acceleration) is measured in m s^-2. The equation informs us that F (force) is measured in kg m s^-2, which is also called a Newton (abbreviated as N). Note that F and a are boldfaced to indicate that they are vectors.

A 2kg concrete block is being dragged along by a rope with a tension of 4N. The block is moving west at a constant speed of 10m/s. What is the net force?

Solution: If v is constant then a is zero. Therefore the net force is zero (possibly because 4N of friction is acting in the easterly direction. Newton's first law states that if the net force (the vector sum of all forces acting on an object) is zero, then the velocity of the object is constant.^[1]

Newton published this in 1687, his knowledge of the numerical value of the gravitational constant was a crude estimate. For our purposes, it can be conveniently state as follows ^[2]:

${\displaystyle {𝐅}_{12}=-G\frac{m_1{m}_2}{{|{𝐫}_{12}|}^2}{\widehat{𝐫}}_{12}\text{ where }G\approx 6.674\times 10^{-11}{\text{m}}^3{\text{kg}}^{-1}{\text{s}}^{-2}}$

Solution:

${\displaystyle {𝐅}_{12}}$ is the force applied on object 2 due to object 1

${\displaystyle G}$ is the gravitational constant

${\displaystyle m_1}$ and ${\displaystyle m_2}$ are respectively the masses of objects 1 and 2

${\displaystyle |{𝐫}_{12}|=|{𝐫}_2-{𝐫}_1|}$ is the distance between objects 1 and 2

${\displaystyle {\widehat{𝐫}}_{12}\stackrel{\mathrm{d}\mathrm{e}\mathrm{f}}{=}\frac{{𝐫}_2-{𝐫}_1}{|{𝐫}_2-{𝐫}_1|}}$ is the unit vector from object 1 to 2

(Note: the minus sign is a complexity that is often ignored in simple calculations. Don't fuss with minus signs unless you have to.)

The force of gravity is called weight, ${\displaystyle \overrightarrow{w}}$, If one of two masses greatly exceeds the other, it is convenient to refer to the smaller mass, (e.g.stone held held by person) as the test mass, ${\displaystyle m_0}$. A vastly more massive body (e.g. Earth or Moon) can be referred to as the central body, with a mass equal to ${\displaystyle m_C}$. It is convenient to express the magnitude of the weight (${\displaystyle w=|\overrightarrow{w}|}$) as,

${\displaystyle w=F=G\frac{m_0{m}_C}{r^2}=m_{0}g}$,

where ${\displaystyle g=G{m}_C/r^2}$ is called the acceleration of gravity (or gravitational acceleration). Near Earth's surface, ${\displaystyle \overrightarrow{g}=}$ is nearly uniform and equal to 9.8 m/s². In general the gravitational acceleration is a vector field, meaning that it depends on location, g = g(r) or even location and time, g = g(r,t).

Consider a particle is moving in a circle or radius, R, at a uniform speed, v. The period of orbit is T, and is defined by

${\displaystyle vT=2\pi R}$.

It is convenient to define angular frequency, ω, by the relation,

${\displaystyle \omega T=2\pi }$,

so that ${\displaystyle v=\omega R}$. It can be shown that the acceleration is towards the center, and has magnitude given by,

${\displaystyle a=\frac{v^2}{R}=\omega v={\omega }^{2}R}$

Solution: Two solutions are offered:

Without Calculus:

The figure depicts a change in the position and velocity of a particle during a brief time interval ${\displaystyle \mathrm{\Delta }t}$. The distance traveled is ${\displaystyle \mathrm{\Delta }\ell =a\mathrm{\Delta }t}$, and the change in velocity ${\displaystyle |\mathrm{\Delta }\overrightarrow{v}|=a\mathrm{\Delta }t}$. The two triangles are similar, so that ${\displaystyle a\mathrm{\Delta }t/v=v\mathrm{\Delta }t/r}$, which leads to ${\displaystyle a/v=v/r}$

With Calculus Let ${\displaystyle \overrightarrow{r}=x\hat{i}+y\hat{j}=R\cos \omega t\hat{i}+R\sin \omega t\hat{j}}$

Take the derivative twice to get first ${\displaystyle \overrightarrow{v}}$ then ${\displaystyle \overrightarrow{a}}$:

${\displaystyle \overrightarrow{v}=-\omega R\sin \omega t\hat{i}+\omega R\cos \omega t\hat{j}}$

${\displaystyle \overrightarrow{a}=-{\omega }^{2}R\cos \omega t\hat{i}-{\omega }^{2}R\sin \omega t\hat{j}}$

Otain the desired result by taking the magnitude of each vector (i.e. a = (a_x²+a_y²)^1/2

Solution:

${\displaystyle \overrightarrow{a}=\kappa {\left(\frac{d\ell }{dt}\right)}^2\hat{\eta }+\frac{d^2\ell }{d{t}^2}\hat{\tau }}$,

where ${\displaystyle \ell }$ is the path length along the direction of motion, ${\displaystyle \hat{\tau }}$ is a unit vector parallel to that path (so that velocity, ${\displaystyle \overrightarrow{v}=\frac{d^2\ell }{d{t}^2}\hat{\tau }}$, and ${\displaystyle \hat{\eta }}$ is a unit vector that is perpendicular to the direction of motion, and points "inwards" towards the direction of the turn. The curvature, ${\displaystyle \kappa }$ equals ${\displaystyle 1/R}$ where ${\displaystyle R}$ is the radius of curvature of the turn.

Two solutions offered:

1. (from Physics with calculus Wikibook)
2. Wikipedia article(See tangential and centripetal acceleration, if it is still on the current page.

1.     ${\displaystyle ma=m\frac{v^2}{r}=\frac{mMG}{r^2}}$, where m is the mass of the orbiting object, and M>>m is the mass of the central body, and r is the radius (assuming a circular orbit).
2.     ${\displaystyle vT=2\pi r}$, where m is the mass of the orbiting object, and M>>m is the mass of the central body, and r is the radius (assuming a circular orbit). After some algebra:
3.     ${\displaystyle r^3=\frac{MG}{4{\pi }^2}{T}^2}$

<section end=NewtonKeplerThirdDerive/>

• ${\displaystyle a^3=\frac{(M+m)G}{4{\pi }^2}{T}^2}$, is valid for objects of comparable mass, where T is the period, (m+M) is the sum of the masses, and a is the semimajor axis: Template:Nowrap begina = ½(r_min+r_max)Template:Nowrap end where r_min and r_max are the minimum and maximum separations between the moving bodies, respectively.

<section end=NewtonKeplerThirdGeneralized/>

The forces on a collection of N interacting particles can be described as either internal or external forces. Since forces are generally viewed as interactions between particles, the external force on the j-th particle, ${\displaystyle {\overrightarrow{F}}_j^{\text{ext}}}$ is an interaction with particles outside this collection of N particles. The sum of all forces on the jth particle is:

${\displaystyle m_j{\overrightarrow{a}}_j={\displaystyle \sum _{j=1}^N}{\overrightarrow{F}}_{ji}+{\overrightarrow{F}}_j^{\text{ext}}}$

Newton's third law states that the internal force on the j^th particle by the i^th particle is ${\displaystyle {\overrightarrow{F}}_{ji}}$, and Newton's third law states that ${\displaystyle {\overrightarrow{F}}_{ji}=-{\overrightarrow{F}}_{ij}}$. Since the only number that equals its additive inverse is zero, it follows that no particle can exert a force on itself, e.g. ${\displaystyle {\overrightarrow{F}}_{ii}=0}$ (for all i), and one wonders if the motion of physical objects could ever have been fathomed if particles could induce forces on themselves. When many particles are connected (either rigidly or by forces that allow relative motion), it can be shown that Newton's second law (F-ma) applies to the center-of-mass, defined as:

${\displaystyle \overrightarrow{R}=\frac{\sum _i{m}_i{\overrightarrow{r}}_i}{\sum _i{m}_i}=\frac{1}{M}\sum _i{m}_i{\overrightarrow{r}}_i}$