Physics for engineer/Force

Force represents a strength interacts with matter to perform a task . For example, strength to push and pull a cart to move forward or backward . Force is denoted as F and measured in Newton unit N = Kgm/s

${\displaystyle F=ma=m\frac{d^2}{d{t}^2}s(t)=m\frac{d}{dt}v(t)=\frac{d}{dt}p(t)}$

${\displaystyle F=ma=m\frac{d^2}{d{t}^2}s(t)=m\frac{d}{dt}v(t)=\frac{d}{dt}p(t)}$

${\displaystyle -F=-mg=-m\frac{MG}{h^2}}$

Force opposes motion force

${\displaystyle F_{\mu }=\mu F_N}$

${\displaystyle F=m\frac{v}{t}=\frac{p}{t}}$

${\displaystyle p=mv=Ft}$

Horizontal Elastic Force

${\displaystyle F_x=-kx}$

Vertical Elastic Force

${\displaystyle F_y=-ky}$

Inclined Elastic Force

${\displaystyle F_{\theta }=-l\theta }$

Force acts on an area of a surface

${\displaystyle F=\frac{F_N}{A}}$

${\displaystyle F=mvr=pr}$

${\displaystyle F=m\frac{v}{r}=\frac{p}{r}}$

Force acts on electric charge to set electric charge in horizontal linear motion thus creates an electric field

${\displaystyle F_E=QE}$

Force acts on electric charge to set electric charge in vertical motion perpendicular to initial motion thus creates magnetic field

${\displaystyle F_E=\pm QvB}$

Sum of 2 forces Electromotive Force and Electromagnetomotive Force act on electric charge to set electric charge in titlted motion thus creates Electromagnetic field

${\displaystyle F_E=F_E+F_B=QE\pm QvB=Q(E\pm vB)}$

Force negative electric charge attracts positive electric charge

${\displaystyle F_Q=K\frac{Q_{+}{Q}_{-}}{r^2}}$

Work idicates the capability of force to perform a task . Work denoted as W , measured in unit Newton Meter Nm . work can be calculated by

${\displaystyle W=Fs=Fvt=pv}$

Energy idicates the capability of force to perform a task over unit of time . Work denoted as E , measured in unit Newton Meter per second N m/s . work can be calculated by

${\displaystyle E=\frac{W}{t}=F\frac{s}{t}=Fv=Fat=pa}$