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R. Field 8/27/2013 University of Florida PHY 2053Page 1 The International System of Units Three Basic Units (SI) QuantityUnit NameSymbol Lengthmeterm Timeseconds.

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Presentation on theme: "R. Field 8/27/2013 University of Florida PHY 2053Page 1 The International System of Units Three Basic Units (SI) QuantityUnit NameSymbol Lengthmeterm Timeseconds."— Presentation transcript:

1 R. Field 8/27/2013 University of Florida PHY 2053Page 1 The International System of Units Three Basic Units (SI) QuantityUnit NameSymbol Lengthmeterm Timeseconds Masskilogramkg Many SI Derived Units: 1 Newton = 1 N = 1 kg ∙ m/s 2 1 Watt = 1 W = 1 N ∙ m = 1 kg ∙ m 2 /s 2 Prefixes for SI Units: FactorPrefixSymbol 10 12 tera-T 10 9 giga-G 10 6 mega-M 10 3 kilo-k 10 -2 centi-c 10 -3 milli-m 10 -6 micro-  10 -9 nano-n 10 -12 pico-p 1 kg = 1 × 10 3 grams 1 ps = 1 × 10 -12 seconds Changing Units: 1 min = 60 s → Conversion Factor

2 R. Field 8/27/2013 University of Florida PHY 2053Page 2 distance: meter 1791: one ten-millionth of a quadrant of the Earth… - - - 1889: platinum-iridium bar - - - 1983: The meter is the length of the path traveled by light in vacuum during a time interval of 1 / (299,792,458) of a second (i.e., by definition, c = 299,792,458 m/s)

3 R. Field 8/27/2013 University of Florida PHY 2053Page 3 time: second Since long ago (Egyptians and Greeks): 1 day = 24 hours 1 s = (1/24) x (1/60) x (1/60) of the full Earth turn However, the Earth rotation period varies by a few ms… 1967: The second is the duration of 9,192,631,770 periods of the radiation emitted by caesium-133 atom

4 R. Field 8/27/2013 University of Florida PHY 2053Page 4 mass: kilogram 1799: 10x10x10 cm 3 of water - - - 1899: platinum-iridium cylinder (d=h=39 mm) atomic mass unit (u): 12 u = mass of 12 C atom universal, reproducible, nor requiring an artifact Density: The density of a material, , is the mass per unit volume:  = m/V  (water) = 1.00 g/cm 3 1 u = 1.66053886 × 10 -27 kg

5 R. Field 8/27/2013 University of Florida PHY 2053Page 5 1-d Motion: Position & Displacement We locate objects by specifying their position along an axis (in this case x-axis). The positive direction of an axis is in the direction of increasing numbers. The opposite is the negative direction. The x-axis: Displacement: The change from position x 1 to position x 2 is called the displacement,  x.  x = x 2 –x 1 Graphical Technique: The displacement has both a magnitude, |  x|, and a direction (positive or negative). A convenient way to describe the motion of an object is to plot the position x as a function of time t (i.e. x(t)). time t x(t)

6 R. Field 8/27/2013 University of Florida PHY 2053Page 6 1-d Motion: Average Velocity Average Velocity The average velocity is defined to be the displacement,  x, that occurred during a particular interval of time,  t (i.e. v ave =  x/  t). Average Speed The average speed is defined to be the magnitude of total distance covered during a particular interval of time,  t (i.e. s ave = (total distance)/  t).

7 R. Field 8/27/2013 University of Florida PHY 2053Page 7 Average Velocity: Example Problem Note that the displacement  x is equal to the average velocity times  t. A train that is initially at the point x i = 3 km at 3:14 pm travels 7 km to the East to the point x E = 10 km. It then reverses direction and travels 36 km to the West to the final point x f = -26 km arriving at 3:56 pm. What is the train’s average velocity (in km/h) for this trip?

8 R. Field 8/27/2013 University of Florida PHY 2053Page 8 Average Speed: Example Problem Note that the total distance d is equal to the average speed times  t. A train that is initially at the point x i = 3 km at 3:14 pm travels 7 km to the East to the point x E = 10 km. It then reverses direction and travels 36 km to the West to the final point x f = -26 km arriving at 3:56 pm. What is the train’s average speed (in km/h) for this trip?

9 R. Field 8/27/2013 University of Florida PHY 2053Page 9 1-d Motion: Instantaneous Velocity t t+  t  tt x(t+  t) x(t) shrink  t t x

10 R. Field 8/27/2013 University of Florida PHY 2053Page 10 1-d Motion: Instantaneous Velocity t t+  t  tt x(t+  t) x(t) shrink  t t x

11 R. Field 8/27/2013 University of Florida PHY 2053Page 11 1-d Motion: Instantaneous Velocity t t+  t  tt x(t+  t) x(t) shrink  t t x

12 R. Field 8/27/2013 University of Florida PHY 2053Page 12 1-d Motion: Instantaneous Velocity t t+  t  tt x(t+  t) x(t) shrink  t t x

13 R. Field 8/27/2013 University of Florida PHY 2053Page 13 1-d Motion: Instantaneous Velocity t x(t) Instantaneous velocity v(t) is slope of x-t tangent line at t tangent line at t t x The velocity v(t) is the rate of change of x(t) with respect to t at time t.

14 R. Field 8/27/2013 University of Florida PHY 2053Page 14 1-d Motion: Acceleration Average Acceleration The average acceleration is defined to be the change in velocity,  v, that occurred during a particular interval of time,  t (i.e. a ave =  v/  t). Instantaneous Acceleration The acceleration a(t) is the rate of change of v(t) with respect to t at time t. Acceleration When a particles velocity changes, the particle is said to undergo acceleration (i.e. accelerate). v1v1 v2v2 v v(t)  v “rise” a vv v v(t) Instantaneous acceleration a(t) is slope of v-t tangent line at t

15 R. Field 8/27/2013 University of Florida PHY 2053Page 15 1-d Motion: Summary Instantaneous Acceleration The acceleration a(t) is the rate of change of v(t) with respect to t at time t. Instantaneous Velocity The velocity v(t) is the rate of change of x(t) with respect to t at time t. v v(t) Instantaneous acceleration a(t) is slope of v-t tangent line at t

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