Obverse Units

Rotating Magnetic Field

Magnetic Field

Magnetic Volume

amath $${A_u} = \frac{{{m_e} \cdot {\lambda _C}^3 \cdot {F_q}^2}}{{{e_{emax}}^2}}$$ endamath

amath $$mfld = \frac{{{m_e} \cdot {\lambda _C}^3 \cdot {F_q}}}{{{e_{emax}}^2}}$$ endamath

amath $$mvlm = \frac{{{m_e} \cdot {\lambda _C}^3}}{{4\pi \cdot {e_{emax}}^2}}$$ endamath

Electric Potential

Magnetic Flux

Inductance

amath $$potn = \frac{{{m_e} \cdot {\lambda _C}^2 \cdot {F_q}^2}}{{{e_{emax}}^2}}$$ endamath

amath $$mflx = \frac{{{m_e} \cdot {\lambda _C}^2 \cdot {F_q}}}{{{e_{emax}}^2}}$$ endamath

amath $$indc = \frac{{{m_e} \cdot {\lambda _C}^2}}{{4\pi \cdot {e_{emax}}^2}}$$ endamath

Electric Field Strength

Magnetic Momentum

Permeability

amath $$elfs = \frac{{{m_e} \cdot {\lambda _C} \cdot {F_q}^2}}{{{e_{emax}}^2}}$$ endamath

amath $$emgm = \frac{{{m_e} \cdot {\lambda _C} \cdot {F_q}}}{{{e_{emax}}^2}}$$ endamath

amath $${\mu _0} = \frac{{{m_e} \cdot {\lambda _C}}}{{4\pi \cdot {e_{emax}}^2}}$$ endamath

Diverging Electric Field

Magnetic Flux Density

Electromagnetism

amath $$dvef = \frac{{{m_e} \cdot {F_q}^2}}{{{e_{emax}}^2}}$$ endamath

amath $$mfxd = \frac{{{m_e} \cdot {F_q}}}{{{e_{emax}}^2}}$$ endamath

amath $$mchg = \frac{{{m_e}}}{{{e_{emax}}^2}}$$ endamath

Inverse Units

Permittivity

amath $$? = \frac{{{e_{emax}}^2}}{{{m_e} \cdot {\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{m_e} \cdot {\lambda _C}^3 \cdot {F_q}}}$$ endamath

amath $${\varepsilon _0} = \frac{{4\pi \cdot {e_{emax}}^2}}{{{m_e} \cdot {\lambda _C}^3 \cdot {F_q}^2}}$$ endamath

Conductance

Capacitance

amath $$? = \frac{{{e_{emax}}^2}}{{{m_e} \cdot {\lambda _C}^2}}$$ endamath

amath $$cond = \frac{{{e_{emax}}^2}}{{{m_e} \cdot {\lambda _C}^2 \cdot {F_q}}}$$ endamath

amath $$capc = \frac{{4\pi \cdot {e_{emax}}^2}}{{{m_e} \cdot {\lambda _C}^2 \cdot {F_q}^2}}$$ endamath

Curl?

Conductance Momentum

amath $$curl = \frac{{{e_{emax}}^2}}{{{m_e} \cdot {\lambda _C}}}$$ endamath

amath $$cmom = \frac{{{e_{emax}}^2}}{{{m_e} \cdot {\lambda _C} \cdot {F_q}}}$$ endamath

amath $$? = \frac{{4\pi \cdot {e_{emax}}^2}}{{{m_e} \cdot {\lambda _C} \cdot {F_q}^2}}$$ endamath

Exposure

Conductance Density

amath $$\exp r = \frac{{{e_{emax}}^2}}{{{m_e}}}$$ endamath

amath $$cden = \frac{{{e_{emax}}^2}}{{{m_e} \cdot {F_q}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{m_e} \cdot {F_q}^2}}$$ endamath

Obverse Units

Friction

Drag

Vorticular Opposition

amath $$fric = \frac{{{m_e} \cdot {\lambda _C}^3 \cdot {F_q}^2}}{{{e_{emax}}^4}}$$ endamath

amath $$drag = \frac{{{m_e} \cdot {\lambda _C}^3 \cdot {F_q}}}{{{e_{emax}}^4}}$$ endamath

amath $$vopp = \frac{{{m_e} \cdot {\lambda _C}^3}}{{4\pi \cdot {e_{emax}}^4}}$$ endamath

Rub

Resistance

Angular Opposition

amath $$rub = \frac{{{m_e} \cdot {\lambda _C}^2 \cdot {F_q}^2}}{{{e_{emax}}^4}}$$ endamath

amath $$resn = \frac{{{m_e} \cdot {\lambda _C}^2 \cdot {F_q}}}{{{e_{emax}}^4}}$$ endamath

amath $$aopp = \frac{{{m_e} \cdot {\lambda _C}^2}}{{4\pi \cdot {e_{emax}}^4}}$$ endamath

Plow

Skid

Linear Opposition

amath $$plow = \frac{{{m_e} \cdot {\lambda _C} \cdot {F_q}^2}}{{{e_{emax}}^4}}$$ endamath

amath $$skid = \frac{{{m_e} \cdot {\lambda _C} \cdot {F_q}}}{{{e_{emax}}^4}}$$ endamath

amath $$lopp = \frac{{{m_e} \cdot {\lambda _C}}}{{4\pi \cdot {e_{emax}}^4}}$$ endamath

Hold

Stop

Electromagnetic Opposition

amath $$hold = \frac{{{m_e} \cdot {F_q}^2}}{{{e_{emax}}^4}}$$ endamath

amath $$stop = \frac{{{m_e} \cdot {F_q}}}{{{e_{emax}}^4}}$$ endamath

amath $$eopp = \frac{{{m_e}}}{{{e_{emax}}^4}}$$ endamath

Inverse Units

amath $$? = \frac{{{e_{emax}}^4}}{{{m_e} \cdot {\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{e_{emax}}^4}}{{{m_e}\cdot{\lambda _C}^3\cdot{F_q}}}$$ endamath

amath $$? = \frac{{4\pi \cdot {e_{emax}}^4}}{{{m_e} \cdot {\lambda _C}^3 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^4}}{{{m_e} \cdot {\lambda _C}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^4}}{{{m_e} \cdot {\lambda _C}^2 \cdot {F_q}}}$$ endamath

amath $$? = \frac{{4\pi \cdot {e_{emax}}^4}}{{{m_e} \cdot {\lambda _C}^2 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^4}}{{{m_e}\cdot{\lambda _C}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^4}}{{{m_e}\cdot{\lambda _C}\cdot{F_q}}}$$ endamath

amath $$? = \frac{{4\pi \cdot {e_{emax}}^4}}{{{m_e} \cdot {\lambda _C} \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^4}}{{{m_e}}}$$ amath

amath $$? = \frac{{{e_{emax}}^4}}{{{m_e} \cdot {F_q}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^4}}{{{m_e} \cdot {F_q}^2}}$$ endamath

Obverse Units

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C}^3 \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C}^3 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C}^3 \cdot {F_q}}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C}^3}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C}^2 \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C}^2 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C}^2 \cdot {F_q}}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C}^2}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C} \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C} \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C} \cdot {F_q}}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {\lambda _C}}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2 \cdot {F_q}}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2}}$$ endamath

Inverse Units

amath $$? = {e_{emax}}^2 \cdot {\lambda _C}^3$$ endamath

amath $$? = {e_{emax}}^2 \cdot {\lambda _C}^3 \cdot {F_q}$$ endamath

amath $$? = {e_{emax}}^2 \cdot {\lambda _C}^3 \cdot {F_q}^2$$ endamath

amath $$? = {e_{emax}}^2 \cdot {\lambda _C}^3 \cdot {F_q}^3$$ endamath

Surface Charge

Magnetic Moment

Ball Lightning?

amath $$sfch = {e_{emax}}^2 \cdot {\lambda _C}^2$$ endamath

amath $$magm = {e_{emax}}^2 \cdot {\lambda _C}^2 \cdot {F_q}$$ endamath

amath $$? = {e_{emax}}^2 \cdot {\lambda _C}^2 \cdot {F_q}^2$$ endamath

amath $$? = {e_{emax}}^2 \cdot {\lambda _C}^2 \cdot {F_q}^3$$ endamath

Charge Length

amath $$chgl = {e_{emax}}^2 \cdot {\lambda _C}$$ endamath

amath $$? = {e_{emax}}^2 \cdot {\lambda _C} \cdot {F_q}$$ endamath

amath $$? = {e_{emax}}^2 \cdot {\lambda _C} \cdot {F_q}^2$$ endamath

amath $$? = {e_{emax}}^2 \cdot {\lambda _C} \cdot {F_q}^3$$ endamath

Charge

Current

amath $$chrg = {e_{emax}}^2$$ endamath

amath $$curr = {e_{emax}}^2 \cdot {F_q}$$ endamath

amath $$? = {e_{emax}}^2 \cdot {F_q}^2$$ endamath

amath $$? = {e_{emax}}^2 \cdot {F_q}^3$$ endamath

Obverse Units

Specific Charge

amath $$? = \frac{{{\lambda _C}^3}}{{{e_{emax}}^2 \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{{{\lambda _C}^3}}{{{e_{emax}}^2 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}^3}}{{{e_{emax}}^2 \cdot {F_q}}}$$ endamath

amath $$spch = \frac{{{\lambda _C}^3}}{{{e_{emax}}^2}}$$ endamath

Charge Distribution

amath $$? = \frac{{{\lambda _C}^2}}{{{e_{emax}}^2 \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2}}{{{e_{emax}}^2 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2}}{{{e_{emax}}^2 \cdot {F_q}}}$$ endamath

amath $$chgd = \frac{{{\lambda _C}^2}}{{{e_{emax}}^2}}$$ endamath

Charge Radius

amath $$? = \frac{{{\lambda _C}}}{{{e_{emax}}^2 \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{{{\lambda _C}}}{{{e_{emax}}^2 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}}}{{{e_{emax}}^2 \cdot {F_q}}}$$ endamath

amath $$chgr = \frac{{{\lambda _C}}}{{{e_{emax}}^2}}$$ endamath

Inverse Units

Charge Density

amath $$chgd = \frac{{{e_{emax}}^2}}{{{\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2 \cdot {F_q}}}{{{\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2 \cdot {F_q}^2}}{{{\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2 \cdot {F_q}^3}}{{{\lambda _C}^3}}$$ endamath

Electric Flux Density

Current Density

amath $$efxd = \frac{{{e_{emax}}^2}}{{{\lambda _C}^2}}$$ endamath

amath $$cdns = \frac{{{e_{emax}}^2 \cdot {F_q}}}{{{\lambda _C}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2 \cdot {F_q}^2}}{{{\lambda _C}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2 \cdot {F_q}^3}}{{{\lambda _C}^2}}$$ endamath

Magnetic Field Intensity

amath $$mfdi = \frac{{{e_{emax}}^2}}{{{\lambda _C}}}$$ endamath

amath $$mfdi = \frac{{{e_{emax}}^2 \cdot {F_q}}}{{{\lambda _C}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2 \cdot {F_q}^2}}{{{\lambda _C}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2 \cdot {F_q}^3}}{{{\lambda _C}}}$$ endamath

Obverse Units

Electric Field

Specific Charge

amath $$? = \frac{{{\lambda _C}^3 \cdot {F_q}^3}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}^3 \cdot {F_q}^2}}{{{e_{emax}}^2}}$$ endamath

amath $$efld = \frac{{{\lambda _C}^3 \cdot {F_q}}}{{{e_{emax}}^2}}$$ endamath

amath $$spch = \frac{{{\lambda _C}^3}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2 \cdot {F_q}^3}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2 \cdot {F_q}^2}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2 \cdot {F_q}}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2}}{{{e_{emax}}^2}}$$ endamath

Charge Radius

amath $$? = \frac{{{\lambda _C} \cdot {F_q}^3}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C} \cdot {F_q}^2}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C} \cdot {F_q}}}{{{e_{emax}}^2}}$$ endamath

amath $$chgr = \frac{{{\lambda _C}}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{F_q}^3}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{F_q}^2}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{{{F_q}}}{{{e_{emax}}^2}}$$ endamath

amath $$? = \frac{1}{{{e_{emax}}^2}}$$ endamath

Inverse Units

Charge Density

amath $$chgd = \frac{{{e_{emax}}^2}}{{{\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C}^3 \cdot {F_q}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C}^3 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C}^3 \cdot {F_q}^3}}$$ endamath

Electric Flux Density

amath $$efxd = \frac{{{e_{emax}}^2}}{{{\lambda _C}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C}^2 \cdot {F_q}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C}^2 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C}^2 \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C}\cdot{F_q}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C}\cdot{F_q}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{\lambda _C} \cdot {F_q}^3}}$$ endamath

Charge

amath $$chrg = {e_{emax}}^2$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{F_q}}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{F_q}^2}}$$ endamath

amath $$? = \frac{{{e_{emax}}^2}}{{{F_q}^3}}$$ endamath

Obverse Units

Light

Photon

Rotation

Vortex

amath $$ligt = {m_e} \cdot {\lambda _C}^3 \cdot {F_q}^3$$ endamath

amath $$phtn = {m_e} \cdot {\lambda _C}^3 \cdot {F_q}^2$$ endamath

amath $$rota = {m_e} \cdot {\lambda _C}^3 \cdot {F_q}$$ endamath

amath $$vrtx = {m_e} \cdot {\lambda _C}^3$$ endamath

Power

Energy

Angular Momentum

Moment of Inertia

amath $$powr = {m_e} \cdot {\lambda _C}^2 \cdot {F_q}^3$$ endamath

amath $$enrg = {m_e} \cdot {\lambda _C}^2 \cdot {F_q}^2$$ endamath

amath $$h = {m_e} \cdot {\lambda _C}^2 \cdot {F_q}$$ endamath

amath $$minr = {m_e} \cdot {\lambda _C}^2$$ endamath

Shock Frequency or Light Intensity

Force

Momentum

Torque

amath $$shkf = {m_e} \cdot {\lambda _C} \cdot {F_q}^3$$ endamath

amath $$forc = {m_e}\cdot{\lambda _C}\cdot{F_q}^2$$ endamath

amath $$momt = {m_e}\cdot{\lambda _C}\cdot{F_q}$$ endamath

amath $$torq = {m_e}\cdot{\lambda _C}$$ endamath

Irradiance

Surface Tension

Intensity

Mass

amath $$irrd = {m_e} \cdot {F_q}^3$$ endamath

amath $$sten = {m_e} \cdot {F_q}^2$$ endamath

amath $$ints = {m_e} \cdot {F_q}$$ endamath

amath $$mass = {m_e}$$ endamath

Inverse Units

amath $$? = \frac{1}{{{m_e}}}$$ endamath

amath $$? = \frac{1}{{{m_e} \cdot {F_q}}}$$ endamath

amath $$? = \frac{1}{{{m_e} \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{1}{{{m_e} \cdot {F_q}^3}}$$ endamath

Obverse Units

Mass Density

amath $$? = \frac{{{m_e} \cdot {F_q}^3}}{{{\lambda _C}^3}}$$ amath

amath $$? = \frac{{{m_e} \cdot {F_q}^2}}{{{\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{m_e} \cdot {F_q}}}{{{\lambda _C}^3}}$$ endamath

amath $$masd = \frac{{{m_e}}}{{{\lambda _C}^3}}$$ endamath

Force Density fdns

Surface Density

amath $$? = \frac{{{m_e} \cdot {F_q}^3}}{{{\lambda _C}^2}}$$ endamath

amath $$fdns = \frac{{{m_e} \cdot {F_q}^2}}{{{\lambda _C}^2}}$$ endamath

amath $$? = \frac{{{m_e} \cdot {F_q}}}{{{\lambda _C}^2}}$$ endamath

amath $$sfcd = \frac{{{m_e}}}{{{\lambda _C}^2}}$$ endamath

Pressure

Viscosity

Rebound

amath $$? = \frac{{{m_e} \cdot {F_q}^3}}{{{\lambda _C}}}$$ endamath

amath $$pres = \frac{{{m_e} \cdot {F_q}^2}}{{{\lambda _C}}}$$ endamath

amath $$visc = \frac{{{m_e} \cdot {F_q}}}{{{\lambda _C}}}$$ endamath

amath $$rbnd = \frac{{{m_e}}}{{{\lambda _C}}}$$ endamath

Inverse Units

Specific Volume

amath $$spcv = \frac{{{\lambda _C}^3}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C}^3}}{{{m_e} \cdot {F_q}}}$$ endamath

amath $$? = \frac{{{\lambda _C}^3}}{{{m_e} \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}^3}}{{{m_e} \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2}}{{{m_e} \cdot {F_q}}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2}}{{{m_e} \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2}}{{{m_e} \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{{{\lambda _C}}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C}}}{{{m_e} \cdot {F_q}}}$$ endamath

amath $$? = \frac{{{\lambda _C}}}{{{m_e} \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{\lambda _C}}}{{{m_e} \cdot {F_q}^3}}$$ endamath

Obverse Units

amath $$? = \frac{{{m_e}}}{{{\lambda _C}^3 \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{{{m_e}}}{{{\lambda _C}^3 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{m_e}}}{{{\lambda _C}^3 \cdot {F_q}}}$$ endamath

amath $$? = \frac{{{m_e}}}{{{\lambda _C}^2 \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{{{m_e}}}{{{\lambda _C}^2 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{m_e}}}{{{\lambda _C}^2 \cdot {F_q}}}$$ endamath

amath $$? = \frac{{{m_e}}}{{{\lambda _C} \cdot {F_q}^3}}$$ endamath

amath $$? = \frac{{{m_e}}}{{{\lambda _C} \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{{{m_e}}}{{{\lambda _C} \cdot {F_q}^3}}$$ endamath

Inverse Units

amath $$? = \frac{{{\lambda _C}^3 \cdot {F_q}}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C}^3 \cdot {F_q}^2}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C}^3 \cdot {F_q}^3}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2 \cdot {F_q}}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2 \cdot {F_q}^2}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2 \cdot {F_q}^3}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C} \cdot {F_q}}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C} \cdot {F_q}^2}}{{{m_e}}}$$ endamath

amath $$? = \frac{{{\lambda _C} \cdot {F_q}^3}}{{{m_e}}}$$ endamath

Obverse Units

Space-Resonance

Flow

Volume

amath $$dtrd = {\lambda _C}^3 \cdot {F_q}^2$$ endamath

amath $$flow = {\lambda _C}^3 \cdot {F_q}$$ endamath

amath $$volm = {\lambda _C}^3$$ endamath

Radiation Dose or Temperature

Sweep or Angular Velocity

Area

amath $$rdtn = {\lambda _C}^2 \cdot {F_q}^2$$ endamath

amath $$temp = {\lambda _C}^2 \cdot {F_q}^2$$ endamath

amath $$swep = {\lambda _C}^2 \cdot {F_q}$$ endamath

amath $$area = {\lambda _C}^2$$ endamath

Acceleration

Velocity

Line

amath $$accl = {\lambda _C} \cdot {F_q}^2$$ endamath

amath $$velc = {\lambda _C} \cdot {F_q}$$ endamath

amath $$leng = {\lambda _C}$$ endamath

Resonance

Frequency

amath $$rson = {F_q}^2$$ endamath

amath $$freq = {F_q}$$ endamath

Inverse Units

amath $$? = \frac{1}{{{\lambda _C}^3}}$$endamath

amath $$? = \frac{1}{{{\lambda _C}^3 \cdot {F_q}}}$$ endamath

amath $$? = \frac{1}{{{\lambda _C}^3 \cdot {F_q}^2}}$$ endamath

amath $$? = \frac{1}{{{\lambda _C}^2}}$$ endamath

amath $$? = \frac{1}{{{\lambda _C}^2 \cdot {F_q}^2}}$$ endamath

Wavenumber

amath $$wavn = \frac{1}{{{\lambda _C}}}$$ endamath

amath $$? = \frac{1}{{{\lambda _C}\cdot{F_q}}}$$ endamath

amath $$? = \frac{1}{{{\lambda _C}\cdot{F_q}^2}}$$ endamath

Time

Orbit

amath $$time = \frac{1}{{{F_q}}}$$ endamath

amath $$orbt = \frac{1}{{{F_q}^2}}$$ endamath

Obverse Units

Space-Time

amath $$? = \frac{{{\lambda _C}^3}}{{{F_q}^3}}$$ endamath

amath $$? = \frac{{{\lambda _C}^3}}{{{F_q}^2}}$$ endamath

amath $$spct = \frac{{{\lambda _C}^3}}{{{F_q}}}$$ endamath

Active Area

amath $$? = \frac{{{\lambda _C}^2}}{{{F_q}^3}}$$ endamath

amath $$? = \frac{{{\lambda _C}^2}}{{{F_q}^2}}$$ endamath

amath $$acta = \frac{{{\lambda _C}^2}}{{{F_q}}}$$ endamath

Dynamic Length

amath $$? = \frac{{{\lambda _C}}}{{{F_q}^3}}$$ endamath

amath $$? = \frac{{{\lambda _C}}}{{{F_q}^2}}$$ endamath

amath $$dynl = \frac{{{\lambda _C}}}{{{F_q}}}$$ endamath

Inverse Units

amath $$? = \frac{{{F_q}}}{{{\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{F_q}^2}}{{{\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{F_q}^3}}{{{\lambda _C}^3}}$$ endamath

amath $$? = \frac{{{F_q}}}{{{\lambda _C}^2}}$$ endamath

amath $$? = \frac{{{F_q}^2}}{{{\lambda _C}^2}}$$ endamath

amath $$? = \frac{{{F_q}^3}}{{{\lambda _C}^2}}$$ endamath

Scalar Wave

amath $$sclw = \frac{{{F_q}}}{{{\lambda _C}}}$$ endamath

amath $$? = \frac{{{F_q}^2}}{{{\lambda _C}}}$$ endamath

amath $$? = \frac{{{F_q}^3}}{{{\lambda _C}}}$$ endamath