Physics for engineer/Motion

Motion is cause by a force interacts with matter to make matter move from one place to another place . Strength to kick a ball to move from place A to place B

Chracteristics of motion

Velocity

Speed indicates the speed of motion to travel a distance over time

 $v={\frac {s}{t}}$

Acceleration

Acceleration indicates the change of speed of motion

 $a={\frac {v}{t}}$

Distance

Distance indicates the length of travel path of motion

 $s=vt$

Force

A physcial quantity intaeracts with matter to perform a task

 $F=ma$

Work

Work indicates the capability of a force to perform a task

 $W=Fs=Fvt$

Energy

Energy indicates the capability of a force to perform a task over time

 $E={\frac {W}{t}}={\frac {Fs}{t}}=Fv$

Formula

Tính Chất	Ký Hiệu	Công thức
Time	$t$	$t$
Acceleration	$a$	${\frac {v}{t}}$
Speed	$v$	$v$
Distance	$s$	$vt$
Force	$F$	$ma$
Work	$W$	$Fs=Fvt$
Energy	$E$	${\frac {W}{t}}=F{\frac {s}{t}}=Fv$

Types of Motion

Linear Motion

Linear Motion represents motion that follows straight line without changing its direction

Accelerationn of linear motion passes through 2 points $(t_{o},v_{o})(t,v)$

a={\frac {v-v_{o}}{t-t_{o}}}={\frac {\Delta v}{\Delta t}}

From above

\Delta v=a\Delta t

\Delta t={\frac {v-v_{o}}{a}}

Speed of linear motion

v=v_{o}+a\Delta t

v_{o}=v-a\Delta t

Distance of linear motion

s=v_{o}\Delta t+{\frac {1}{2}}\Delta v\Delta t=\Delta t(v_{o}+{\frac {\Delta v}{2}})=\Delta t(v_{o}+{\frac {a\Delta t}{2}})=\Delta t(v-{\frac {a\Delta t}{2}})=({\frac {v-v_{o}}{a}})({\frac {2v_{o}+v-v_{o}}{2}})={\frac {v^{2}-v_{o}^{2}}{2a}}

Fromm above

v^{2}=v_{o}^{2}+2as

Linear Motion with acceleration not equal zero

a={\frac {v-v_{o}}{t-t_{o}}}={\frac {\Delta v}{\Delta t}}

v=v_{o}+a\Delta t

s=v_{o}\Delta t+{\frac {1}{2}}\Delta v\Delta t=\Delta t(v_{o}+{\frac {\Delta v}{2}})=\Delta t(v_{o}+{\frac {a\Delta t}{2}})=\Delta t(v-{\frac {a\Delta t}{2}})={\frac {v^{2}-v_{o}^{2}}{2a}}

Chracteristics of Inclined Linear motion are listed below

Tính Chất	Ký Hiệu	Công thức
Time	$t$	$t$
Acceleration	$a$	${\frac {\Delta v}{\Delta t}}={\frac {v-v_{o}}{t-t_{o}}}$
Speed	$v$	$v_{o}+a\Delta t$
Distance	$s$	$(v_{o}+a\Delta t)\Delta t$
Force	$F$	$m{\frac {\Delta v}{\Delta t}}$
Work	$W$	$F(v_{o}+a\Delta t)\Delta t$
Energy	$E$	$F(v_{o}+a\Delta t)$

Linear Motion with acceleration equal zero

a={\frac {\Delta v}{\Delta t}}={\frac {v-v_{o}}{t-t_{o}}}=0

v=v_{o}

s=v_{o}t

Chracteristics of Horizontal Linear motion are listed below

Tính Chất	Ký Hiệu	Công thức
Time	$t$	$t$
Acceleration	$a$	${\frac {\Delta v}{\Delta t}}={\frac {v-v_{o}}{t-t_{o}}}$
Speed	$v$	$v_{o}+a\Delta t$
Distance	$s$	$(v_{o}+a\Delta t)\Delta t$
Force	$F$	$m{\frac {\Delta v}{\Delta t}}$
Work	$W$	$F(v_{o}+a\Delta t)\Delta t$
Energy	$E$	$F(v_{o}+a\Delta t)$

Linear Motion with acceleration equal constant

a=g

v=gt

s=gt^{2}

Chracteristics of Vertical Linear motion are listed below

Tính Chất	Ký Hiệu	Công thức
Time	$t$	$t$
Acceleration	$a$	${\frac {\Delta v}{\Delta t}}={\frac {v-v_{o}}{t-t_{o}}}$
Speed	$v$	$v_{o}+a\Delta t$
Distance	$s$	$(v_{o}+a\Delta t)\Delta t$
Force	$F$	$m{\frac {\Delta v}{\Delta t}}$
Work	$W$	$F(v_{o}+a\Delta t)\Delta t$
Energy	$E$	$F(v_{o}+a\Delta t)$

Curve Motion

Continous motion

Average acceleration for curve motion

a={\frac {\Delta v(t)}{\Delta t}}={\frac {v(t+\Delta t)-v(t)}{(t+\Delta t)-t}}

Average distance for curve motion

s=\Delta t[v(t)+{\frac {\Delta v(t)}{2}}]

As $\Delta t\rightarrow 0$

Acceleration for curve motion

a(t)=\lim _{\Delta t\to 0}\sum {\frac {\Delta v(t)}{\Delta t}}={\frac {d}{dt}}v(t)=v^{'}(t)

Distance for curve motion

s(t)=\lim _{\Delta t\rightarrow 0}\sum [v(t)+{\frac {\Delta v(t)}{2}}]\Delta t=\int v(t)dt=V(t)+C

Non-continous motion

Distance for curve motion from A to B

s=\int \limits _{a}^{b}f(x)dx=F(b)-F(a)

Characteristics of Curve motion are listed below

Tính Chất	Ký hiệu	Công thức
Distance	$s$	$\int v(t)dt$
Time	$t$	$t$
Speed	$v$	$v(t)$
Acceleration	$a$	${\frac {d}{dt}}v(t)$
Force	$F$	$m{\frac {d}{dt}}v(t)$
Work	$W$	$F\int v(t)dt$
Energy	$E$	${\frac {F}{t}}\int v(t)dt$

Example

Chuyển động	v	a	s
Chuyển động cong	$v(t)$	${\frac {d}{dt}}v(t)dt$	$\int v(t)dt$
Chuyển động thẳng ngang	$v$	$0$	$vt+c$
Chuyển động thẳng dọc	$t$	$1$	${\frac {t^{2}}{2}}+c$
Chuyển động thẳng nghiêng	$at$	$a$	${\frac {at^{2}}{2}}+c$
Chuyển động thẳng nghiêng	$at+v$	$a$	${\frac {at^{2}}{2}}+vt+c$