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DO STUFF BELOW THIS LINE PLEASE

${\displaystyle {\vec {E}}={\begin{cases}{\frac {\mu _{0}Ni_{0}\omega \sin(\omega t)r}{2l}}{\hat {\tau }},&r<R\\{\frac {\mu _{0}Ni_{0}\omega R^{2}\sin(\omega t)}{2rl}}{\hat {\tau }},&r>R\end{cases}}}$ where r is radial distance of pont in polar coordinates, ${\displaystyle {\hat {\tau }}}$ is unit tangential vector, R is radius of solenoid
${\displaystyle {\vec {E}}=\pm {\begin{cases}{\frac {\mu _{0}Ni_{0}\omega \sin(\omega t)}{2l}}(x{\hat {j}}-y{\hat {i}}),&{\sqrt {x^{2}+y^{2}}}<R\\{\frac {\mu _{0}Ni_{0}\omega R^{2}\sin(\omega t)}{2l(x^{2}+y^{2})}}(x{\hat {j}}-y{\hat {i}}),&{\sqrt {x^{2}+y^{2}}}>R\end{cases}}}$
${\displaystyle F_{0}{\hat {k}}}$

Reduced mass is the "effective" inertial mass appearing in the two-body problem of Newtonian mechanics. This is a quantity with the unit of mass, which allows the two-body problem to be solved as if it were a one-body problem. Note however that the mass determining the gravitational force is not reduced. In the computation one mass can be replaced by the reduced mass, if this is compensated by replacing the other mass by the sum of both mass.

${\displaystyle m_{\text{red}}=\mu ={\cfrac {1}{{\cfrac {1}{m_{1}}}+{\cfrac {1}{m_{2}}}}}={\cfrac {m_{1}m_{2}}{m_{1}+m_{2}}},\!\,}$

Given two bodies, one with mass ${\displaystyle m_{1}\!\,}$ and the other with mass ${\displaystyle m_{2}\!\,}$, they will orbit the barycenter of the two bodies. The equivalent one-body problem, with the position of one body with respect to the other as the unknown, is that of a single body of mass ${\displaystyle \mu }$where the force on this mass is given by the gravitational force between the two bodies. The reduced mass is always less than or equal to the mass of each body and is half of the harmonic mean of the two masses.

Derivation

This can be proven easily. Use Newton's second law, the force exerted by body 2 on body 1 is ${\displaystyle F_{12}=m_{1}a_{1}.\!\,}$ The force exerted by body 1 on body 2 is ${\displaystyle F_{21}=m_{2}a_{2}.\!\,}$ According to Newton's third law, for every action there is an equal and opposite reaction: ${\displaystyle F_{12}=-F_{21}.\!\,}$ Therefore, ${\displaystyle m_{1}a_{1}=-m_{2}a_{2}.\!\,}$ and ${\displaystyle a_{2}=-{m_{1} \over m_{2}}a_{1}.\!\,}$ The relative acceleration between the two bodies is given by ${\displaystyle a=a_{1}-a_{2}=\left({1+{m_{1} \over m_{2}}}\right)a_{1}={{m_{2}+m_{1}} \over {m_{1}m_{2}}}m_{1}a_{1}={F_{12} \over m_{\text{red}}}.}$ So we conclude that body 1 moves with respect to the position of body 2 as a body of mass equal to the reduced mass. Alternatively, a Lagrangian description of the two-body problem gives a Lagrangian of ${\displaystyle L={1 \over 2}m_{1}\mathbf {\dot {r}} _{1}^{2}+{1 \over 2}m_{2}\mathbf {\dot {r}} _{2}^{2}-V(\vert \mathbf {r} _{1}-\mathbf {r} _{2}\vert )\!\,}$ where ${\displaystyle m_{i},\mathbf {r} _{i}}$ are the mass and position vector of the ${\displaystyle i}$ th particle, respectively. The potential energy ${\displaystyle V}$ takes this functional dependence as it is only dependent on the absolute distance between the particles. If we define ${\displaystyle \mathbf {r} \equiv \mathbf {r} _{1}-\mathbf {r} _{2}}$ and let the centre of mass coincide with our origin in this reference frame, i.e. ${\displaystyle m_{1}\mathbf {r} _{1}+m_{2}\mathbf {r} _{2}=0}$, then ${\displaystyle \mathbf {r} _{1}={\frac {m_{2}\mathbf {r} }{m_{1}+m_{2}}},\mathbf {r} _{2}={\frac {-m_{1}\mathbf {r} }{m_{1}+m_{2}}}.}$ Then substituting above gives a new Lagrangian ${\displaystyle L={1 \over 2}m_{\text{red}}\mathbf {\dot {r}} ^{2}-V(r),}$ where ${\displaystyle m_{\text{red}}={\frac {m_{1}m_{2}}{m_{1}+m_{2}}}}$, the reduced mass. Thus we have reduced the two-body problem to that of one body. The reduced mass is frequently denoted by the Greek letter ${\displaystyle \mu \!\,}$; note however that the standard gravitational parameter is also denoted by ${\displaystyle \mu \!\,}$. In the case of the gravitational potential energy ${\displaystyle V(\vert \mathbf {r} _{1}-\mathbf {r} _{2}\vert )=-Gm_{1}m_{2}/\vert \mathbf {r} _{1}-\mathbf {r} _{2}\vert \!\,}$ we find that the position of the first body with respect to the second is governed by the same differential equation as the position of a body with the reduced mass orbiting a body with a mass equal to the sum of the two masses, because ${\displaystyle m_{1}m_{2}=(m_{1}+m_{2})m_{\text{red}}\!\,}$ "Reduced mass" may also refer more generally to an algebraic term of the form ${\displaystyle x_{\text{red}}={1 \over {1 \over x_{1}}+{1 \over x_{2}}}={x_{1}x_{2} \over x_{1}+x_{2}}\!\,}$ that simplifies an equation of the form ${\displaystyle \ {1 \over x_{\text{eq}}}=\sum _{i=1}^{n}{1 \over x_{i}}={1 \over x_{1}}+{1 \over x_{2}}+\cdots +{1 \over x_{n}}.\!\,}$

In such a two body problem, the moment of inertia of the system about the center of mass is given by:
${\displaystyle I=\mu r^{2}}$
Where r is the distance between the two bodies.

Derivation

Let r1 and r2 be the distances of the two bodies from the center of mass. Taking the center of mass as the origin, the equation for center of mass becomes: ${\displaystyle r_{cm}=0={\frac {m_{1}r_{1}-m_{2}r_{2}}{m_{1}+r_{1}}}}$ From this, we get: ${\displaystyle m_{1}r_{1}=m_{2}r_{2}}$ Now, moment of inertia about center of mass is: ${\displaystyle I=m_{1}r_{1}^{2}+m_{2}r_{2}^{2}}$ As ${\displaystyle m_{1}r_{1}=m_{2}r_{2}}$, ${\displaystyle I=m_{1}r_{1}^{2}+m_{1}r_{1}r_{2}=m_{1}r_{1}(r_{1}+r_{2})=m_{1}r_{1}r}$ But, as ${\displaystyle r_{2}={\frac {m_{1}r_{1}}{m_{2}}}}$, and ${\displaystyle r=r_{1}+r_{2}}$, ${\displaystyle r=r_{1}\left(1+{\frac {m_{1}}{m_{2}}}\right)={\frac {r_{1}(m_{1}+m_{2})}{m_{2}}}}$ Or, ${\displaystyle r_{1}={\frac {rm_{2}}{m_{1}+m_{2}}}}$ Substituting in the expression for I, we get: ${\displaystyle I=m_{1}r_{1}r={\frac {m_{1}m_{2}r^{2}}{m_{1}+m_{2}}}=\mu r^{2}}$

The reduced mass is typically used as a relationship between two system elements in parallel, such as resistors; whether these be in the electrical, thermal, hydraulic, or mechanical domains. This relationship is determined by the physical properties of the elements as well as the continuity equation linking them.

Reduced mass crops up in a multitude of two-body problems. In a collision with a coefficient of restitution e, the change in kinetic energy can be written as ${\displaystyle \Delta K={\frac {1}{2}}\mu v_{rel}^{2}(e^{2}-1)}$, where v_rel is the relative velocity of the bnodies before colission.

• Reduced Mass on HyperPhysics

• Restructure
• Derive moment of inertia of two bodies = mu*r^2, where r is dist betwn two bodies
• Add more "other uses"
• It does not only pertain to two body problem, it crops up in all two-body interactions.
• Images
• Explain spring connection with halfmuvsquared formula.

Starting conditions: ${\displaystyle {\vec {B}}=\beta t{\hat {k}},{\vec {J}}=0,\rho =0}$

${\displaystyle {\text{Maxwell's laws:}}{\begin{cases}\nabla \cdot {\vec {E}}=\rho /\epsilon _{0}&\dots (M_{1})\\\nabla \cdot {\vec {B}}=0&\dots (M_{2})\\\nabla \times {\vec {E}}=-\partial _{t}{\vec {B}}&\dots (M_{3})\\\nabla \times {\vec {B}}=\mu _{0}{\vec {J}}+\mu _{0}\epsilon _{0}\partial _{t}{\vec {E}}&\dots (M_{4})\end{cases}}}$
Verifying our choice of B with ${\displaystyle M_{2}}$,
${\displaystyle LHS=\nabla \times {\vec {B}}=\nabla \times (\beta t{\hat {k}})=0=RHS}$
Now, using ${\displaystyle M_{4}}$
${\displaystyle LHS=0,{\vec {J}}=0,}$
${\displaystyle \Rightarrow 0=\mu _{0}0+\mu _{0}\epsilon _{0}\partial _{t}{\vec {E}}}$
${\displaystyle \Rightarrow \partial _{t}E=0}$
Therefore, E is independant of time.

Now, by ${\displaystyle M_{3},\nabla \times {\vec {E}}=-\partial _{t}{\vec {B}}=-\partial _{t}(\beta t{\hat {k}})=-\beta {\hat {k}}}$
Let ${\displaystyle {\vec {E}}=E_{x}{\hat {i}}+E_{y}{\hat {j}}+E_{z}{\hat {k}}}$
${\displaystyle \therefore {\begin{pmatrix}{\hat {i}}(\partial _{y}E_{z}-\partial _{z}E_{y})\\+{\hat {j}}(\partial _{x}E_{z}-\partial _{z}E_{x})\\+{\hat {k}}(\partial _{x}E_{y}-\partial _{y}E_{x})\end{pmatrix}}={\begin{pmatrix}{\hat {i}}(0)\\+{\hat {j}}(0)\\+{\hat {k}}(-\beta )\end{pmatrix}}\qquad \dots (1)}$

Now, by symmetry of the original conditions, we can assume that:
${\displaystyle |E_{x}|=|E_{y}|}$ at a point (x,y,z)
And also, ${\displaystyle |\partial _{x}E_{y}|=|\partial _{y}E_{x}|}$
${\displaystyle =\beta /2}$, by z-component of (1)


${\displaystyle \therefore E_{x}={\frac {\beta y}{2}}+f_{1}(x,z)+c_{1},}$
${\displaystyle E_{x}={\frac {\beta x}{2}}+f_{2}(y,z)+c_{2}}$
${\displaystyle {\text{let }}E_{x}=f_{3}(x,y,z)+c_{3}}$

By x and y components of (1),
${\displaystyle \partial _{y}f_{3}=\partial _{z}f_{2},\partial _{x}f_{3}=\partial _{z}f_{1}}$
For simplicity, we can assume:

${\displaystyle f_{1}=ix+az}$
${\displaystyle f_{2}=my+bz}$
${\displaystyle {\text{let }}f_{3}=ax+by+nz}$
(Where l,m,n,a,b are constants)

${\displaystyle \therefore {\vec {E}}={\hat {i}}({\frac {\beta y}{2}}+lx+az+c_{1})}$
${\displaystyle +{\hat {j}}({\frac {-\beta x}{2}}+my+bz+c_{2}}$
${\displaystyle +{\hat {k}}(ax+by+nz+c_{3})}$

Applying ${\displaystyle (M_{1})}$ to ${\displaystyle {\vec {E}}}$,
${\displaystyle l+m+n=0}$

${\displaystyle \therefore {\text{when }}{\vec {B}}=\beta t{\hat {k}},{\vec {J}}=0,\rho =0,}$
${\displaystyle {\vec {E}}={\hat {i}}({\frac {\beta y}{2}}+lx+az+c_{1})}$
${\displaystyle +{\hat {j}}({\frac {-\beta x}{2}}+my+bz+c_{2}}$
${\displaystyle +{\hat {k}}(ax+by+nz+c_{3})}$
This answer can be verified with the four Maxwell's Laws.