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Physics1: Mechanics

Physics1: Mechanics. Ch1. Physics and Measurement. Lecture 1. Iksan Bukhori, M.Phil. iksan.bukhori@president.ac.id. Original Presentation by Dr. –Ing Erwin Sitompul. 2018. Textbook and Syllabus. Textbook:

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Physics1: Mechanics

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  1. Physics1: Mechanics Ch1. Physics and Measurement Lecture 1 Iksan Bukhori, M.Phil iksan.bukhori@president.ac.id • Original Presentation by Dr. –Ing Erwin Sitompul 2018

  2. Textbook and Syllabus Textbook: • Wu, C. Thomas. An Introduction to Object-Oriented Programming With Java. MCGraw-Hill: New York, USA. 2010. • Deitel, H. M. & Deitel, P. J. JAVA How to Program (Seventh Edition). Pearson Education, Inc.: New Jersey, USA. 207. Syllabus: (tentative) Chapter 1: Intro to OOP Chapter 2: Getting Started with Java Chapter 3: Numerical Data Chapter 4: Defining Your Own Classes – Part 1 Chapter 5: Selection Statements Chapter 6: Repetition Statements Chapter 7: Defining Your Own Classes – Part 2 Chapter 10: Arrays and Collections

  3. Grade Policy Grade Point: 85 – 100 : A (GPA = 4) 70 – 84 : B (GPA = 3) 60 – 69 : C (GPA = 2) 55 – 59 : D (GPA = 1) 0 – 54 : E (GPA = 0) • Always bring a laptop installed with IDE to class. • The use of smartphone in quizzes and exams is prohibited.

  4. Grade Policy Grades: Final Grade = 10% Homeworks + 20% Quizzes + 30% Midterm Exam + 40% Final Exam + Extra Points • Homeworks will be given in fairly regular basis. The average of homework grades contributes 10% of final grade. • Homeworks are to be written on A4 papers, otherwise they will not be graded. • Homeworks must be submitted on time, during class. If you submit late, the penalty will be –10·n points, where n is the total number of lateness made. • There will be 3 quizzes. Only the best 2 will be counted. The average of quiz grades contributes 20% of final grade. • Midterm and final exam schedule will be announced in time.

  5. Grade Policy • Extra points will be given if you solve a problem in front of the class. You will earn 1, 2, or 3 points. • Make up of quizzes and exams will be held withinone week after the schedule of the respective quizzes and exams. • To maintain the integrity, the maximum score of a make up quiz or exam can be set to 90. Basic Physics 1Homework 6Rudi Bravo00920170000821 March 2021No.1. Answer: . . . . . . . . Heading of Homework Papers (Required)

  6. Lecture Activities • Lectures will be held in the form of PowerPoint presentations. • You are expected to write a note along the lectures to record your own conclusions or materials which are not covered by the lecture slides. How to get good grades in this class? • Do the homeworks by yourself • Solve problems in front of the class • Take time to learn at home • Ask questions

  7. Lecture Material • You are responsible to read and understand the lecture slides. I am responsible to answer your questions. • Quizzes, midterm exam, and final exam will be open-book. Be sure to have your own copy of lecture slides. You are not allowed to borrow or lend anything during quizzes or exams. • But: A homework can be submitted late without penalty if a scanned or photographed version of the homework is sent to iksan.bukhori@president.ac.idat least one day before the schedule of the class.

  8. The International System of Units • Physics is based on measurement. • Each physical quantity is measured in its own units, by comparison with a standard. • The exact definition of a unit is arbitrary, but is chosen so that scientists around the world will agree that the definitions are both sensible and practical. • By international agreement, there are seven base quantities: • length (unit name: meter, unit symbol: m) • mass (kilogram, kg) • time (second, s) • electric current (ampere, A) • thermodynamic temperature (kelvin, K) • amount of substance (mole, mol) • luminous intensity (candela, cd) • All other physical quantities are defined in terms of these base quantities and their standards (called base standards).

  9. The International System of Units • For University Physics: Mechanics, we will use the base quantities length, time, and mass. • From these we can define, or derive other quantities that we will discover as we proceed: • Velocity (length/time) • Acceleration (velocity/time, or length/time2) • Force (massacceleration or masslength/time2)

  10. Dimensional Analysis • The word dimension has a special meaning in physics. It usually denotes the physical nature of a quantity. Whether a distance is measured in the length unit feet or the length unit meters, it is still a distance. We say the dimension—the physical nature—of distance is length. • The symbols we use in this book to specify length, mass, and time are L, M, and T, respectively. We shall often use brackets [ ] to denote the dimensions of aphysical quantity. • For example, the symbol we use for speed in this book is v, and in our notation the dimensions of speed are written as

  11. Scientific Notation and Ten Power Prefixes • To express the very large and very small quantities that we often meet in physics, we use scientific notation, which employs powers of 10. • 3 560 m = 3.56  103 m = 3.56 kilometers = 3.56 km • 0.000 000 492 s = 4.92  10–7 s = 0.492  10–6 s = 0.492 microseconds = 0.492 μs • 1.27  109 watts = 1.27 gigawatts = 1.27 GW • What about millimeter, centimeter, kilogram, megabyte, megahertz?

  12. Changing Units • We often need to change the units in which a physical quantity is expressed. • In doing so, we use a method called chain-link conversion.  The original measurement is multiplied by a conversion factor (a ratio of units that is equal to unity). Example: Convert 2.5 hours into seconds. Solution:

  13. Changing Units Example: A PU student goes to Jakarta using Bus 121 (Blok M – Cikarang, via Semanggi, Rp13000,-). As the bus drives on the toll road, the student measures the time needed by the bus to travel between km 20.0 and km 19.0 using his stopwatch. If the stopwatch shows that the time is 42 s, determine the average velocity of the bus in km/h. Solution:

  14. Length • In 1792, the newborn Republic of France established a new system of weights and measures. • 1 meter is defined to be one ten-millionth of the distance from the north pole to the equator. • Later in 1889, the meter came to be defined as the distance between two fine lines engraved near the ends of a platinum-iridium bar (standard meter bar). • In 1960, a new standard for the meter, based on the wavelength of light, was adopted.

  15. Length • The standard meter was redefined to be 1 650 763.73 wavelengths of orange-red light emitted by atoms of krypton-86 in a gas discharge tube. • The current definition of the meter is created in 1983, which is the length of the path traveled by light in a vacuum during a time interval of 1/299 792 458 of a second.

  16. Pronunciation of Mathematical Expressions

  17. Time • In old definition, any time standard was calibrated against Earth’s rotation via astronomical observations. • In this way, 1 second is 1/86 400 of the time for a complete earth rotation. • However, the accuracy cannot meet the accuracy called for by modern scientific and engineering technology.

  18. Time • To meet the need for a better time standard, atomic clocks have been developed. • In 1967, a standard second based on the cesium clock was adopted. • One second is the time taken by 9 192 631 770 oscillations of the light (of a specified wavelength) emitted by a cessium-133 atom. The first atomic clock, developed in 1955

  19. Mass • Originally, the standard of mass is the weight of the water. 1 kilogram was defined as the mass of 1000 cubic centimeters of water. • The current SI standard of mass is a platinum-iridium cylinder kept at the International Bureau of Weights and Measures near Paris. It is assign, by international agreement, a mass of 1 kilogram. • Accurate copies have been sent to standardizing laboratories in other countries, and the masses of other bodies can be determined by balancing them against a copy. • The second mass standard is the atomic mass units (u). The carbon-12 atom, by international agreement, has been assigned a mass of 12 u, with 1 u = 1.660 538 86  10–27 kg.

  20. Mass KOMPAS, 11 March 2012

  21. Unit Conversion Error Can Be Expensive • 23 July 1983: Gimli Glider, Air Canada Flight 143 ran completely out of fuel about halfway through its flight from Montreal to Edmonton. Instead of 22300 kg of fuel, they had 22300 pounds on board. 23 September 1999 Due to unit conversion error, the spacecraft Mars Climate Orbiter encountered Mars at a lower than anticipated altitude and disintegrated due to atmospheric stresses. One system produced results in Imperial unit, while a second system that used those results expected them to be in metric units. The total cost of the mission is USD 327.6 million for both orbiter and lander.

  22. Trivia Eight eggs look identical except one is lighter. How can you weigh only 2 times on a balance scale to find out which one is lighter?

  23. Trivia Solution: • We number the eggs, from 1 to 8. • Put egg 1, 2, and 3 on the left and egg 4, 5 and 6 on the right and weight them. • If they are balanced then we know egg 1 to 6 are all identical. We just need to put egg 7 on one side and egg 8 on the other side and weight them. The lighter egg is found. • If they are not balanced, assuming the left side is lighter, put egg 1 on the left, egg 2 on the right, weight them one more time. • If egg 1 and egg 2 are still balanced, then egg 3 is lighter.

  24. University Physics: Mechanics Ch2. STRAIGHT LINE MOTION Lecture 1 Physics1: Mechanics Iksan Bukhori, M.Phil iksan.bukhori@president.ac.id • Original Presentation by Dr. –Ing Erwin Sitompul 2018

  25. Position and Displacement • To locate an object means to find its position relative to some reference point, often the origin (or zero point) of an axis. • The positive direction of the axis is in the direction of increasing numbers (coordinates). • The opposite direction is the negative direction. • A change from one position x1 to another position x2 is called a displacement Δx, where

  26. Average Velocity and Average Speed • Average velocity (vector) = ratio of the displacement to the time interval • Average speed (scalar) = ratio of the total distance traveled to the time interval • Note that the average velocity points in the same direction as the displacement vector • If the displacement points in the + direction, then the velocity is + • If the displacement points in the – direction, then the velocity is –

  27. Average Velocity and Average Speed • Circuit Length: 4.574 km • Number of Laps: 67 • Race Distance: 306.458 km • Time: 1:33:42.914 NicoRosberg won the Germany GP on 20 July 2014 • What is Nico’ average speed? • What is Nico’ average velocity? The start and finish line are identical, so Nico’ displacement after 67 laps is zero.

  28. Average Velocity and Average Speed • Average velocity can be found a graph of x versus t, which is equal to the slope from the initial to the final position.

  29. Average Velocity and Average Speed • Position vs. Time graph orx-t graph vavg > 0 vavg < 0

  30. Average Velocity and Average Speed • So for the round trip, your displacement Δx = x2–x1 = 0, and your average velocity vavg = Δx / Δt = 0. • However, your average speed was 40 km/h. At time t1 = 0, your position is x1 = 0 At time t2 = 30 min, your position is x2 = 0

  31. Questions The figure below shows four paths along which objects move from a starting point to a final point, all in the same time. The lines are equally spaced. Rank the paths according to (a) The average velocity of the objects. (b) The average speed of the objects. All tie 4, tie of 1 and 2, 3

  32. Example: Grand Livina You drive a Grand Livina from city J to city B, which are separated by 150 km, with a constant velocity of 80 km/h. After reaching B, you directly travel back to city J, with constant velocity of 60 km/h. What is your average speed?

  33. Homework 1: Truck You drive a truck along a straight road for 8.4 km at 70 km/h, at which point the truck runs out of gasoline and stops. Over the next 30 min, you walk another 2.0 km farther along the road to a gasoline station. (a) What is your overall displacement from the beginning of your drive to your arrival at the station? (b) What is the time interval Δt from the beginning of your drive to your arrival at the station? (c) What is your average velocity vavg from the beginning of your drive to your arrival at the station? Find it both numerically and graphically. (d) Suppose that to pump the gasoline, pay for it, and walk back to the truck takes you another 45 min. What is your average speed from the beginning of your drive to you return to the truck with the gas?

  34. Homework 1A: Car You start driving a car with constant velocity to a shopping center at 10:15. The road is straight and the shopping center is 6 km away from your initial position. At 10:35 you are only 2 km away from destination and make a stop. (a) What is your average velocity vavg from the beginning of your drive to your stop? (b) After a very short stop, you continue driving. You want to reach the shopping center at 10:40, how fast do you have to drive the rest of the distance? (c) You reach the destination exactly at 10:40. What is your average velocity vavg from the beginning of your drive to your arrival at the shopping center? (d) Draw the graph of your movement (position vs. time). Homeworks are to be written on A4 papers

  35. Homework 1B: Interview You are to drive to an interview in another town, at a distance of 300 km on an expressway. The interview is at 11:15. You plan to drive at 100 km/h, so you leave at 8:00 to allow some extra time. You drive at that speed for the first 100 km, but then construction work forces you to slow to 40 km/h for 60 km. (a) What would be the least speed needed for the rest of the trip to arrive in time for the interview? (b) Draw the graph of your movement (position vs. time). (c) If the maximum allowable speed on the expressway is 120 km/h, how long does the interviewer have to wait? Homeworks are to be written on A4 papers

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