from gra#ity%

I&"MA$I# "A$IO&': 3ORI4O&$A% MO$IO&

*ince a_/ " the #elocity in the horizontal direction remains constant $#_/  #_o/% and the position in the / direction can be determined by:

/  /_o ; $#_o/% t

#  #_ ; a_ct

s  s_ ;#_t ; .' a_ct²

#²  #²_ ; 2a_c $s & s_%

I&"MA$I# "A$IO&': ,"R$I#A% MO$IO&

*ince the positi#e y)a/is is directed up-ard" a_y  & g.

Application of the constant acceleration e,uations yields:

#_y  #_oy & g t

y  y_o ; $#_oy% t & H g t²

#_y²  #_oy² & 2 g $y & y_o%

#  #_ ; a_ct

s  s_ ;#_t ; .' a_ct²

#²  #²_ ; 2a_c $s & s_%

IMPOR$A&$ "A$IO&' /OR PRO"#$I%" MO$IO&

or Iorizontal otion: /  /_ ; $#_/% t

or 4ertical otion:

#_y  #_y & g t

y  y_ ; $#_y% t & H g t²

#_y²  #_y² & 2 g $y & y_%

3mportant: +ime" Jt  is the only common term that

appears in the horizontal and #ertical motion e,uations.

9/ample: A s!i umper starts -ith a horizontal ta!e)off

#elocity of 2' m8s and lands on a straight landing hill inclined at DL. 0etermine $a% the time bet-een ta!e)off and landing" $b% the length d  of the ump.

9/ample: A golf ball is struc! -ith a #elocity of  ft8s as sho-n. 0etermine the distance" d " to -here it -ill land.

9/ample: A pump is located near the edge of the horizontal  platform sho-n. +he nozzle at A discharges -ater -ith an

initial #elocity of 2' ft8s at an angle of ''M -ith the

#ertical. 0etermine the range of #alues of the height h for -hich the -ater enters the opening BC .

12.5: 6"&RA% #R,I%I&"AR MO$IO& - Introduction

+he path of motion of a plane

A roller coaster car 

Cur#ilinear motion occurs -hen the particle mo#es along a cur#ed path.

Cur#ed road

#R,I%I&"AR MO$IO&

*ince the path is often described in D)0" #ector analysis -ill be used to formulate the particle5s position" #elocity and

acceleration.

+he position of the particle at any instant is designated by the #ector  r   r $t%. Noth the magnitude and direction of r  may #ary -ith time.

A particle mo#es along a cur#e defined by the path function" s.

,"%O#I$

4elocity represents the rate of change in the position of a  particle.

+he instantaneous #elocity is the time)deri#ati#e of position

v  dr 8dt .

+he #elocity #ector" v" is al-ays tangent to the path of motion.

A##"%"RA$IO&

Acceleration represents the rate of change in the #elocity of a particle.

+he instantaneous acceleration is the time)deri#ati#e of #elocity:

a  dv8dt  d²r 8dt²

A&A%'I' O/ #R,I%I&"AR MO$IO&

1% sing Eectangular $/" y" z% Components

2% sing ormal and +angential Components $n)t %

D% Cylindrical Coordinates $r" Q" z%

#R,I%I&"AR MO$IO&: R"#$A&6%AR #OMPO&"&$' ('ection 12.7)

3t is often con#enient to describe the motion of a particle in

terms of its /" y" z or rectangular components" relati#e to a fi/ed frame of reference.

+he magnitude of the position #ector is: r  $/² ; y² ; z²%^.'

+he position of the particle can be defined at any instant by the

 position #ector 

r  x i ; y j ; z k .

+he /" y" z components may all be functions of time" i.e."

/  /$t%" y  y$t%" and z  z$t% .

R"#$A&6%AR #OMPO&"&$': ,"%O#I$

+he magnitude of the #elocity

#ector is

#  R$#_/%² ; $#_y%² ; $#_z%²S^.' +he direction of v is tangent to the path of motion.

+he #elocity #ector is the time deri#ati#e of the position #ector:

v  dr 8dt  d$/i %8dt ; d$y j %8dt ; d$zk %8dt

*ince the unit #ectors i " j " k  are constant in magnitude and direction" this e,uation reduces to #  #_/i  ; #_y j  ; #_zk 

-here #_/  /^•  d/8dt" #_y  y^•  dy8dt" #_z  z^•  dz8dt

R"#$A&6%AR #OMPO&"&$': A##"%"RA$IO&

+he direction of a is usually not tangent to the path of the  particle.

+he acceleration #ector is the time deri#ati#e of the

#elocity #ector $second deri#ati#e of the position #ector%:

a  dv8dt  d²r 8dt²  a_/ i  ; a_y j  ; a_zk 

+he magnitude of the acceleration #ector is

a  R$a_/%² ; $a_y%² ; $a_z%² S^.'

"8a!+le: +he bo/ slides do-n the slope described by the e,uation y  $.' x²% m" -here x is in meters.

#_/  )D m8s" a _x  )1.' m8s² at x  ' m. ind the y

components of the #elocity and the acceleration of the bo/

at x  ' m.

12.9 #R,I%I&"AR MO$IO&

&ORMA% A&* $A&6"&$IA% #OMPO&"&$'

O;ective: 0etermine the #elocity and acceleration of a particle tra#eling along a cur#ed path using normal and tangential components.

&ORMA% A&* $A&6"&$IA% #OMPO&"&$'

$*ection 12.>%

hen a particle mo#es along a cur#ed path" it is sometimes con#enient to describe its motion using coordinates other than Cartesian. hen the  path of motion is !no-n" normal $n% and tangential $t % coordinates are

often used.

3n the n-t  coordinate system" the origin" O" is located on the

 particle $the origin mo#es -ith the particle%.

+he t )a/is is tangent to the path $cur#e% at the instant considered"

 positi#e in the direction of the particle5s motion.

+he n)a/is is perpendicular to the t )a/is -ith the positi#e direction to-ard the center of cur#ature of the cur#e.

&ORMA% A&* $A&6"&$IA% #OMPO&"&$'

$continued%

+he positi#e n and t  directions are defined by the unit #ectors u_n and u_t"

respecti#ely.

+he center of cur#ature" OT" al-ays lies on the conca#e side of the cur#e.

+he radius of cur#ature"

ρ

" is defined as the perpendicular distance from the cur#e to the center of cur#ature at that point.

,"%O#I$ I& $3" n-t #OOR*I&A$" ''$"M

+he #elocity #ector is al-ays tangent to the path of motion

$t )direction%.

v  # u_t

A##"%"RA$IO& I& $3" n-t #OOR*I&A$" ''$"M Acceleration is the time rate of change of #elocity :

a  dv8dt  d$#u_t%8dt  #. u_t ; #u. _t

a  v u. _t ; $#²8

ρ

% u_n  a_tu_t ; a_nu_n. After mathematical manipulation"

the acceleration #ector can be e/pressed as:

A##"%"RA$IO& I& $3" n-t #OOR*I&A$" ''$"M

$continued%

*o" there are t-o components to the acceleration #ector:

a  a_tu_t ; a_nu_n

• +he normal or centripetal component is al-ays directed to-ard the center of cur#ature of the cur#e. a_n  #²8

ρ

• +he tangential component is tangent to the cur#e and in the direction of increasing or decreasing #elocity.

a_t  #.

• +he magnitude of the acceleration #ector is  a  R$a_t%² ; $a_n%²S^.'

3POE+A+ 9UA+3O*

+he magnitude of the acceleration #ector is a  R$a

_t 

%

²

 ; $a

_n

%

²

S

^.'

+angential Acceleration" a

_t 

  d#8dt

 ormal Acceleration" a

_n

 #

²

8V

'P"#IA% #A'"' O/ MO$IO&

+here are some special cases of motion to consider.

1% +he particle mo#es along a straight line.

ρ ∞

W a_n  #²8

ρ = 0 =>

a  a_t  #

+he tangential component represents the time rate of change in the magnitude of the #elocity.

.

2% +he particle mo#es along a cur#e at constant speed.

 a_t  #   ^. W a  a_n  #²8

ρ

'P"#IA% #A'"' O/ MO$IO& $continued%

D% *ometimes" the e,uation of the cur#e path follo-ed  by the particle may be gi#en" y   $ x%. +he radius of

cur#ature" V" at any point on the path can be calculated from the follo-ing e,uation:

D

"8a!+le: A oat travels around a circular +ath at a s+eed that increases with ti!e< v = (>.>027 t ²) !?s. /ind the

!agnitudes of the oat@s velocity and acceleration at the instant t  = 1> s.

"8a!+le: $he !otorcyclist travels along the curve at a constant s+eed of > ft?s. *eter!ine his acceleration when he is located at +oint A. 3int: $reat the !otorcycle and rider as a +article.

"8a!+le: $he auto!oile has a s+eed of > ft?s at +oint A and an acceleration< a< having a !agnitude of 1> ft?s²< acting in the direction shown. *eter!ine the radius of curvature of the +ath at +oint A and the tangential co!+onent of

acceleration.

R"%A$I,"-MO$IO& A&A%'I' O/ $CO PAR$I#%"'

All motion is relati#e to some frame of reference

2 trains approaching each other $along a line% at B' !m8h each. Obser#ers on either train see the other coming at B'

; B'  1B !m8h. Obser#er on ground sees

±

 B' !m8h.

Velocity depends on reference frame!!

R"%A

R"%A$$I," I," PO'I$IO&PO'I$IO& $*ection 12.1%$*ection 12.1%

+he

+he absolute positionabsolute position of t-o of t-o  particles A

 particles A and N -ith respect toand N -ith respect to the fi/ed /"

the fi/ed /" y" y" z reference frame arez reference frame are gi#en by

gi#en by r r  _A A and and r r  _B B. +he. +he position of position of N relati#e to A

N relati#e to A is represented by is represented by r 

 ote: r r  _B!A B!A means position of means position of B B as obser#ed from as obser#ed from A A r 

r  _A!B A!B means position of means position of A A as obser#ed from as obser#ed from B B

R"%A$I," ,"%O#I$

R"%A$I," ,"%O#I$

+o determine the

+o determine the relati#e #elocityrelati#e #elocity of N of N -ith respect to A" the time deri#ati#e o -ith respect to A" the time deri#ati#e off the relati#e position e,uation is ta!en.

the relati#e position e,uation is ta!en.

v

3n these e,uations" v v _B B and and vv _A A are called are called absolute #elocitiesabsolute #elocities and

and vv _BA BA is the is the relati#e #elocityrelati#e #elocity of N  of N -ith respect to A.-ith respect to A.

 ote that

 ote that vv _BA BA   )) vv _AB AB ..

R"%A$

R"%A$I," I," A##"%"RA$A##"%"RA$IO&IO&

+he time deri#ati#e of the relati#e +he time deri#ati#e of the relati#e

#elocity e,uation yields a similar

#elocity e,uation yields a similar

#ector relationship bet-een the

#ector relationship bet-een the absolute

absolute and and relati#e accelerationsrelati#e accelerations of particles A and N.

of particles A and N.

+hese deri#ati#es yield:

'O%,I&6 PROB%"M'

*ince the relati#e motion e,uations are

#ector e,uations" problems in#ol#ing them re,uires resol#ing #elocity $or acceleration% #ector along x and y and then performing the #ector operation:

v

 _B

 v

 _A

 ; v

 _BA

a

 _B

 a

 _A

 ; a

 _BA

"DAMP%": 'hown in figure are two air+lanes flying at sa!e altitude with their res+ective velocities and direction shown. /ind v_B?A.

6iven: #_A  (' !m8h

#_N   !m8h /ind: v _BA

"DAMP%" (continued%

'olution:

v _A  $(' i  % !m8h

v _B  & cos ( i  &  sin ( j 

 $ &@ i  & (B2.  j % !m8h

v _BA  v _B & v _A  $&1' i  & (B2. j % !m8h

# _{B 8 A}

= (−1050)

²

 +(−692.8)

²

= 1258

!m8h θ   tan⁾¹$ %  DD.@

°

_θ 

1050

692.8

9/ample: At the instant sho-n" race car A is passing race car B -ith a relati#e #elocity $#_A8N% of 1 m8s. Kno-ing that the speeds of both cars are constant and that the relati#e

acceleration of car A -ith respect to car B $a_A8N% is .2' m8s² directed to-ard the center of cur#ature" determine the speed of cars A and B at the instant sho-n.

"8a!+le: At a given instant in an air+lane race< air+lane  A is flying horiEontally in a straight line< and its s+eed is eing increased at a rate of 0 !?s². Air+lane B is flying at the sa!e altitude as air+lane A and is following a circular +ath of 2>>-! radius.

nowing that at the given instant the s+eed of  B is eing decreased at the rate of 2 !?s²< deter!ine< for the +ositions shown< the acceleration of B relative to A.

AB'O%$" *"P"&*"&$ MO$IO& A&A%'I' O/

$CO PAR$I#%"' ('ection-12.F)

3n many !inematics

 problems" the motion of one obect -ill depend on the motion of another

obect.

• 3f bloc! A mo#es do-n-ard along the inclined plane" bloc! N -ill mo#e up the other incline.

• +his dependency commonly occurs if the particles are interconnected by ine/tensible8 inelastic cords -hich are -rapped around pulley$s%.

PRO#"*R" /OR A&A%'I'- *"P"&*"&$ MO$IO&

+he motion of each bloc! can be related mathematically by

defining position coordinates" s_A and s_N. 9ach coordinate a/is is defined from a fi/ed point or datum line" measured positi#e along each plane in the direction of motion of each bloc!.

 ote: +he length of the cord connecting the t-o particles -ill al-ays remain same8 constant" irrespecti#e of the  position8 location of the t-o  particles.

*"P"&*"&$ MO$IO&

$continued%

3n this e/ample" position

coordinates s_A and s_N can be defined from fi/ed datum lines e/tending from the center of the pulley along each incline to bloc!s A and N.

*ince" the cord has a fi/ed length" the position coordinates s_A and s_N are related mathematically by the e,uation

s_A ; l_C0 ; s_N  l₊

Iere l₊ is the total cord length and l_C0 is the length of cord  passing o#er the arc C0 on the pulley.

*"P"&*"&$ MO$IO&

$continued%

+he negati#e sign indicates that as A mo#es do-n the incline

$positi#e s_A direction%" N mo#es up the incline $negati#e s_N direction%.

Accelerations can be found by differentiating the #elocity e/pression. a_N  )a_A.

ds_A8dt ; ds_N8dt   W #_N  )#_A

+he #elocities of bloc!s A and N can be related by differentiating the position e,uation. ote that l_C0 and l₊ remain constant" so dl_C08dt  dl₊8dt  

*"P"&*"&$ MO$IO&: PRO#"*R"'

+hese procedures can be used to relate the dependent motion of  particles mo#ing along rectilinear paths $only the magnitudes of

#elocity and acceleration change" not their line of direction%.

@. 0ifferentiate the position coordinate e,uation$s% to relate

#elocities and accelerations. Keep trac! of signsX D. 3f a system contains more than one cord" relate the

 position of a point on one cord to a point on another cord. *eparate e,uations are -ritten for each cord.

2. Eelate the position coordinates to the cord length.

*egments of cord that do not change in length during the motion may be left out.

1. 0efine position coordinates from fi/ed datum lines"

along the path of each particle. 0ifferent datum lines can  be used for each particle.

"DAMP%"-1

=i#en: 3n the figure on the left" the cord at A is pulled do-n -ith a speed of 2 m8s.

 ind: +he speed of bloc! N.

"8a!+le - 2: 'lider locG B !oves to the right with a constant velocity of >>

!!?s. *eter!ine (a) the velocity of

In document Chap12(3)-3 (Page 22-65)