Motion in 2D Vectors Projectile Motion

1. Physics -101 Piri Reis University 2010 • Motion in 2D • Vectors • Projectile Motion

2. Lecture 3 • Aim of the lecture • Cover material relevant to 2-D and 3-D kinematics: • speed, acceleration • vector representation • projectile motion •   Main learning outcomes • familiarity with • vectors • vector algebra and calculus • equations of motion using vectors • projectile motion • ability to • solve kinetics problems in multiple dimensions • compute projectile trajectories

3. Vectors written as aa a a a & others They all mean the same thing – a direction and magnitude Review of some Mathematics

4. y (north) 10 The vector (5,4) means 5 10 5 X (east)

5. y (north) 10 The vector (5,4) means 5 5 km in the x direction (east) 10 5 X (east)

6. y (north) 10 The vector (5,4) means 5 4 km in the y direction (north) (5,4) total 10 5 X (east)

7. y (north) Can also make (5,4) by going north first: 10 (5,4) is the sum of (5,0) and (0,4) And the order does not matter (5,4) = (5,0) + (0,4) = (0,4) + (5,0) 5 10 5 X (east)

8. y (north) 10 In fact (5,4) can be made by adding lots of vectors: 5 The sum of lots of ‘short walks’ is the shortest distance between The starting and ending place. (5,4) 10 5 X (east)

9. y (north) 10 What does it mean to subtract vectors? b -b 5 Subtracting means to go in the opposite direction but for the same distance. a-b a a+b 10 5 X (east)

10. y (north) 10 5 10 5 X (east) a+b b Two vectors are added by adding the components a= (3,4) b = (6,9) then a + b = (3+6,4+9) Similarly to subtract them a – b = (3-6,4-9) a a-b

11. Review of some Mathematics

12. Review of some Mathematics

13. Review of some Mathematics Its usual to use a ˆ above unit vectors, but not always, eg i,j

14. Review of some Mathematics

15. z Vectors in 3-D z y r • Vectors in 3-D are an extension of vectors in 2-D • Three components r = (x,y,z) • The formalism is identical • There is no way to tell from a vector equation if it is 2-D or 3-D • It doesn’t really matter because all the algebra is the same • The same relationships exist between vectors • The same rules, but with one more component • This is one of the advantages of working with vectors • effectively you are manipulating all the dimensions simultaneously y x x

16. Review of some Mathematics

17. Product of vectors • Multiplying vectors is more complicated than multiplying simple numbers • Multiplying by a scalar simply keeps the direction the same, but makes it longer: • if a = (3,5) then aa = (3a,5a) • The scalar product, written a.b can be defined as • a.b = IaI IbI cos(a) where a is the angle between the two vector directions • The scalar product is also called the ‘dot’ product • The scalar product is a scalar, it is an ordinary number • The scalar product can also be evaluated from components: • If a = (7,2) and b = (4,9), then a.b = 7x4 + 2x9 • Generally a.b = a1b1 + a2b2 where a = (a1,a2) and b = (b1,b2)

18. Dr = r2-r1 r1 r2 Motion in 2-D - Projectiles y (north) 10 • If a particle starts from position r1 at time t = t1 • and moves to position r2 at time t = t2 • then its displacement vector is • Dr = r2-r1 • which it moved in time • Dt = t2 – t1 5 10 5 X (east)

19. Dr = r2-r1 r1 r2 Motion in 2-D - Projectiles y (north) 10 • Its average velocity is then defined as • v = Dr / Dt • Velocity is a vector quantity, • its magnitude IvI is the speed of motion • its direction is the direction of motion. 5 10 5 X (east)

20. Dr = r2-r1 r1 rd Motion in 2-D - Projectiles y (north) 10 As the change becomes small, part of a path then v = dr / Dt becomes the instantaneous velocity v = dr/dt which is the derivative of displacement with respect to time. 5 dr = rd-r1 10 5 X (east)

21. The tangent to the curve is the direction of the velocity the magnitude CANNOT be determined from this plot as the time is not given Here the particle stopped going south and started to go north Motion in 2-D - Projectiles y (north) 10 5 Consider a particle following the dotted trajectory 10 5 X (east)

22. Projectiles Motion if an object is in motion, its position can be described by the equation x = vt + x0 where x is its location at time t, v is its velocity, x0 its starting displacement if the velocity is not constant then x = x0 + ∫ vdt (this was discussed last week) A special case is when the acceleration, a, is constant, in which case x = x0 + ∫ vdt = x0 + v0t + ½at2 where v0 is the starting velocity or Dx = v0t + ½at2 this is often written as s = ut + ½at2 for the distance traveled in time t in 1-D

23. Projectiles Motion These equations all have 1-D equivalents – vectors are just a ‘shorthand’ x = vt + x0 is the same as x = vxt = x0 and y = vyt + y0 where x, y are locations at time t, x0 starting x position etc.. if the velocity is not constant then x = x0 + ∫ vxdt and y = y0 + ∫ vydt A special case is when the acceleration is constant, in which case x = x0 + ∫ vxdt = x0 + vx0t + ½axt2 & y = y0 + ∫ vydt = y0 + vy0t + ½ayt2 or Dx = vx0t + ½axt2 & Dy = vy0t + ½ayt2 Each dimension has its own set of equations BUT TIME IS SAME FOR BOTH

24. This is NOT what falling apples do, They fall directly downwards and the reason is gravity. They do however get faster and faster as they fall, they move with constant acceleration

25. Falling apples obey the equations y = y0 + ½at2 v = at but a is caused by gravity and is -9.81 m/s2 we use the symbol g for the acceleration caused by gravity at the surface of the earth. The minus sign just means that the acceleration is downwards

26. y = y0 + ½at2 v = gt2 so y = 8 – 9.81t2m 2 When the apple hits the ground 0 = 8 – 9.81t2 2 so t = √(16 / 9.81) = 1.28 s y = y0 + ½at2 v = gt more generally t = √(2y0/g) so the speed of impact on the ground is vground = gt = g√(2y0/g) = √(2gy0) 8m Check the dimensions v - in [m/s] √(2gy0) g in [ms-2] y0 in [m] so √([ms-2][m])

27. 2-D projectile In the x direction the equation of motion is x = vx0t vx = vx0 (constant speed in x direction) In the y direction it is the same as for the falling apple, except that the initial velocity is not zero and the apple starts from ground level For falling apple: y = y0 + ½at2 vy = at But now y0 is 0 as the apple starts from ground And the initial velocity, vy0 is no longer zero. So: y = vy0t + ½at2 vy = vy0 + at

28. 2-D projectile x = vx0t vx = vx0 y = vy0t + ½at2 vy = vy0 + at t = x/vx0 y = vy0{x/vx0} + ½a{x/vx0}2 but a = g = -9.81 m/s so: y = {vy0/vx0}x - {4.9/vx02}x2 Which describes a parabola

29. 2-D projectile x = vx0t vx = vx0 y = {vy0/vx0}x - {4.9/vx02}x2 y = vy0t + ½at2 vy = vy0 + at vy = vy0 + gt = vy0 + g{x/vx0} = vy0 + {g/vx0}x = vy0 – {9.81/vx0}x If ax2+bx + c = 0 then x = -b±√(b2-4ac) 2a So the value for x for a given y can be evaluated by regarding y as a constant and solving as a quadratic

30. 2-D projectile y = {vy0/vx0}x - {4.9/vx02}x2 vy = vy0 - {9.81/vx0}x vx = vx0 Note that because of the negative sign (which came from g) the vertical speed starts out +ve but becomes negative The horizontal speed never changes – this assumes no air resistance

31. Projectile motion can be described using a vector equation instead r = r0 + v0t + ½at2 y More on gravity in another lecture r x

32. There are several closely related projectile problems • the differences are essentially the ‘boundary conditions’, • which means the starting values. • the equations are the same, but the values at the start are different y y r x y x x