260 likes | 388 Views
Two-and Three-Dimentional Motion (Kinematic). Position Vector. y. C. The location of a particle relative to the origin of a coordinate system is given by a position vector r , which in unit – vector notation is. A. B. x. D.
E N D
Position Vector y C The location of a particle relative to the origin of a coordinate system is given by a position vector r , which in unit – vector notation is A B x D Student Activity : State position points A, B, C, D using unit-vector notation.
Position as a function of timeExample : Student Activity : Determine position of a particle that has function of time as stete above at : a. Initially b. t = 2 second c. t = 4 second
Displacement If a particle moves so that its position vector changes from to , the particle’s displacement is The displacement can also be written as :
Student Activity : Determine the displacement vector : • From point A to point C • b. From point A to point B The magnitude of displacement : y C A The direction of displacement is tate in angle : B x D
Student Activity Suppose the position vector of a particle is given by : t is in second and r in meter. Determine the magnitude and direction of particle displacement from t1 = 1 s to t2 = 2 s
Average Velocity If a particle undergoes a displacement in time interval , its average velocity for that time interval is : The magnitude of average velocity is : Direction of average velocity is :
Student Activity • A particle is moving on an x-y coordinat plane. The change of particle position follows the equation : • Where t is in second and r is in meter. • Determine : • Vector of average velocity if particle moves from t = 0 to t = 2 s • Magnitude of average velocity from t = 0 to t = 2 s • c. Direction of average velocity
C C B B A A CONSTANT ACCELERATION CONSTANT VELOCITY Instantenous velocity = average velocity Instantenous velocity = average velocity
Instantaneous Velocity When Dt is shrunk to 0, reaches a limit called either the velocity or the instantaneous velocity Dr Dt
How to Calculate Instantaneous Velocity r C B2 rB1 : position when t = t rB2 : position when t = t + Dt B Dr Or can be determine by “Deferential” function A B1 t Dt Student Activity
Student Activity • A particle is moving on an x-y coordinate plane. The change of particle position follows the equation • Where t is in second and is in meter • Determine : • The vector instantaneous velocity at t = 2 s • b. The magnitude and direction of instantaneous velocity at • = 2 s
Kerjakan soal berikut : • Vektor posisi sebuah partikel yang bergerak dinyatakan oleh : r = 40ti + (30t-5t2)j a. Tentukan kecepatan dua detik pertama b. Tentukan kecepatan mula-mula c. Tentukan kecepatan saat t = 2 s
Acceleration • Average acceleration If a velocity of a particle change in time interval , its average acceleration for that time interval is : The magnitude of average acceleration is : Direction of average acceleration is : Or can be determine by “Deferential” function
Student Activity • The velocity equation of a moving particle is stated by : v = 4ti + (10 + 0.75t2)j Determine the average acceleration from t = 0 to t = 2s
Acceleration • Instantenous Acceleration v1 : velocity when t = t v2 : velocity when t = t + Dt Or can be determine by “Deferential” function
Student Activity A bird flying on the XY plane with velocity that is stated by : v = (2.1 – 3.6t2)i + 5.0tj. Initially the bird is on the (0;0) • Determine the vector of acceleration as time function • Determine the bird acceleration at t = 2s • Determine the average acceleration in interval of time from t = 0 to t = 2 s
Determination velocity from acceleration equation To determine velocity from acceleration equation, we use integral function to change acceleration equation become velocity equation Integral Function to use Integral function in a simple way :
Student Activity • A particle moves on the y axis with acceleration of a = 2t , if initially its velocity is 3 m/s, determine the velocity at • t = 2 s • t = 4 s
Determination position from velocity equation To determine position from velocity equation, we use integral function to change velocity equation become position equation Integral Function to use Integral function in a simple way :
Percepatan gerak partikel dinyatakan dengan persamaan a = 2ti + 4j, a dlm m/s2. jika mula-mula partikel beada di posisi 2i + j, dalam keadaan diam, tentukan kecepatan dan posisinya saat t = 4s.
Sebuah partikel P bergerak dengan percepatan a. Tentukan vektor kecepatan dan vektor posisi P pada saat t. jika diketahui a = 15t2i + 8tj. Mula-mula partikel di titik asal dan sedang bergerak dengan kecepatan i + 2j
Kecepatan gerak partikel dinyatakan dalam persamaan : v = 3t2i + 4tj, mula-mula partikel berada di posisi 3j. Tentukan a. posisi partikel saat t = 3s b. percepatan partikel saat t = 2s