Introduction to 1118 Labs

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Name: Partner(s): 1118 section: Desk # Date: Introduction to 1118 Labs Introductory materials are at: www.langaraphysics.com/lab.html. You may find following 3 links useful for this lab: Measurements: Basic, Lab Report Requirements and Sample Lab Report under For 1114/1118 Labs. Purpose To learn the basic elements of 1118 labs and to practice writing a lab report. Part 1 How to record data The rules for recording data are: Provide a description of your data. Record all certain digits plus one estimated digit. These are all significant digits. Determine the uncertainty. See the examples below on how to decide the uncertainty. Give the units. Use the units of the measuring tool. In other words, all data must have meaning, value, uncertainty and units. You must assign an uncertainty to every data while making measurements. If the only factor that affects the reading accuracy is the measuring device, you can take half of the smallest division to be the uncertainty. This is based on you can estimate between the division lines (see Example 1 below). However, quite often, there are other factors that affect the reading accuracy, and you should assign an uncertainty that is big enough so that the actual value lies within the plus-minus range. It is common to get different uncertainty with the same measuring device (Example 2 and 3). The uncertainty, when estimated by you, should have only one non-zero digit. However, if you calculate the uncertainty based on the manual or read it from a digital device, then it sometimes can have two non-zero digits (Example 4). In all cases, the value and the uncertainty must have the same decimal place and same units 1. Let s see how the rules work in the following examples. 1 The power of 10 in scientific notation is part of the units. Therefore, the value and the uncertainty must also use the same power of 10. However, in most cases, you should not need to use scientific notation when recording data. 1118 Introduction of 1118 Labs - 1 Saved: 12/9/17, printed: 12/9/17

Example 1: A student uses a 2-pan balance to measure the mass of a metal cylinder. When the balance is reached, the pointer is just above the 23.7 g line. She thinks the mass is 23.71 g, where 1 is an estimated digit. Half of the smallest division is 0.05 g. So she records: The mass of the metal cylinder m = (23.71 0.05) g. Example 2: A student tries to drop a rubber ball from a 90 cm height. He lines up the upper edge of the ball to the 90 cm mark on the metre stick. Because the ball is round, he figures he could line it up within 0.2 cm at best. In other words, the 0 after the decimal point in 90.0 cm is already an estimate, and there is no way to estimate another digit. So he records: The drop height yd is (90.0 ± 0.2) cm. Example 3: The student above measures how high the ball bounces by judging the highest point of the upper edge with his eyes. It was close to 81 cm, but could be anywhere between 80 and 82 cm. With a 2 cm range, he records: The bounce height yb is (81 ± 1) cm. Example 4: A student reads from the 2-pan balance that the mass of a metal block is 473.45 g, because the pointer was between 0.4 and 0.5 g. She used two counter masses. The instructor told her that each counter mass has an uncertainty of ±0.05 g, and the 2-pan balance itself also has ±0.05 g. The overall uncertainty, including the uncertainty from the counter masses and the scale itself, is ±0.15 g. So she records: The mass of the metal block m = (473.45 0.15) g. Now, try it for yourself. Activity 1-1: Record the data for the following measurements. See http://langaraphysics.com/1118/pictures.html for photos showing the measurements. 1. The mass of metal cylinder m is g. 2. The length of the metal cylinder l is cm. 3. The position of the end of the spring s hook is at cm. 4. The length of the thin Nichrome wire is cm. 5. The voltage across the light bulb is V. 1118 Introduction of 1118 Labs - 2 Saved: 12/9/17, printed: 12/9/17

Activity 1-2: Determining the number of significant figures in the data. After taking measurements and deciding on the uncertainty, you should know how many digits in your measurement are significant figures (sig. figs). This will eventually decide how many sig. figs. you will report in your final conclusions. Let s look at the following data. One thing we need to remember is that the value and uncertainty must have the same decimal places and the same unit, otherwise they do not match. (a) (90.00 ± 0.05) g (b) (90 ± 0.05) g (c) (90 ± 2) cm (d) (9 ± 2) cm (e) (9.0 ± 2) cm (f) (9.0 ± 0.2) cm (g) (0.49 ± 0.05) g (h) (0.49 ± 0.05) 10-3 kg (i) 0.00049 kg ± 0.05 g (j) (233.18 ± 0.20) g (k) (2.12 ± 0.22) s Is the format correct? How many sig. figs are there? (for correct formats only) Explanation/hints: (a) has the correct format because both the uncertainty and the last sig. fig are at the second decimal place. All digits one 9 and three 0 s are significant: the number of sig. figs. is 4. Note that the trailing 0 s count towards sig. figs. In (b) the value 90 does not match the uncertainty 0.05 in decimal places so the format is wrong. (c) has the right format and there are 2 sig. figs. (d) has a value that is much shorter than (c), and there is only 1 sig. fig. It shows that for the same uncertainty, larger quantities tend to have more sig. figs. and higher precisions. It is wrong trying to force to 2 sig. figs. in (e) by adding another 0 to the value, because then the value does not match the uncertainty. In order to have more sig. figs. you need to reduce the uncertainty like (f). (g) and (h) are actually the same data so they should have the same sig. figs. This tells us that the unit conversion does not change the number of sig. figs. Note that leading zeroes do not count towards sig figs. (i) has a wrong format because the value uses a different unit than the uncertainty. (j) and (k) are the special cases where the uncertainty has two non-zero digits. To find the number of sig. figs., you need to first underline the last sig. fig., which is at where the uncertainty kicks in: for both, it is the digit 1. 1118 Introduction of 1118 Labs - 3 Saved: 12/9/17, printed: 12/9/17

Part 2 Calculating the results In the Calculations section of your report, you use your measured data to calculate a final result. For example, to find the volume of a room, you would measure the length, width and height of the room and then calculate the volume. While there are rules to explicitly calculate the uncertainty in the results, you are not required to do so in this lab course. However, you need to understand that there are uncertainties in the results; therefore, the results have a finite number of significant figures. In the Conclusion section of the lab report, you must report the result to the proper number of sig. figs. There are two rules to determine the number of sig. figs. in a calculated result as introduced in the Measurements: Basic section from the online lab manual. Sig. figs. in the data +/ rule / rule Sig. figs. in the result To avoid round-off error, you should keep plenty of digits (5 non-zero digits recommended) in the calculations. To keep track of the sig. figs., you can underline the last significant digit for intermediate numbers. In the conclusion, the final result must be rounded to the correct number of significant figures with no underlining. Example: Calculations: Length l = 1056 cm = 10.56 m (4 sig. figs.) Width w = 722 cm = 7.22 m (3 sig. figs.) Height h = 254.5 m = 2.545 m (4 sig. figs.) Volume V = lwh = 10.56 m 7.22 m 2.545 m = 194.04 m 3 (3 sig. figs. according to / rule) Conclusion: The volume of the room is 194. m 3. (The decimal point after 194 indicates that it is a rounded result rather than an exact integer.) 1118 Introduction of 1118 Labs - 4 Saved: 12/9/17, printed: 12/9/17

Activity 2-1: Practice the sig. figs. rules with the following calculations. 45.3 (9.81 8.92) 45.3 0.89 Example: 52.592 53. 0.7666 0.7666 # of sig. figs. in the result 2 4.56 17. 23 0.0002 7.54 88. 8 17.1 11. 234 98.5 27.5 = 27.5 20.5 = ( 8.7 6.5) 7. 325 9 (1.3 10 ) 76, 550 2 (2.22) (3.7 3.1) 1.5442 1118 Introduction of 1118 Labs - 5 Saved: 12/9/17, printed: 12/9/17

Activity 2-2: This is a complete practice on calculations. You are required to take measurements of your desktop and then calculate the approximate volume V of the desktop. Data: Measure the dimensions of your desktop and record the results below. Decide the uncertainties while making the measurements. Dimensions of the desktop of Desks # and # (cm) Reading Uncertainty Length l Width w Thickness t Calculations: First convert all data readings (but not the uncertainty) from cm to m: Next calculate the volume in 3 steps: equation numbers result. Do not include uncertainties in the calculation. Keep all units. For the result, keep 5 non-zero digits, then use the uncertainties and the sig. figs. rules to decide how many sig. figs. are in the result, and underline the last sig. fig. V = lwt = Conclusions: (give sig. figs. and units.) The volume of desktop of Desk# and # is. 1118 Introduction of 1118 Labs - 6 Saved: 12/9/17, printed: 12/9/17

Part 3 How to write lab reports Activity 3: Measure of the density of a metal cylinder. Follow the guidelines given in the Lab Report Requirements and the Sample Lab Report documents. Both links can be found at http://www.langaraphysics.com/lab.html under For 1114/1118 labs. Below are some key points of these two documents as applied to this lab: Write everything in ink. Purpose: State the goal of the experiment. Apparatus: List all instruments you will use: a ruler, a 2-pan balance and a metal cylinder. Be sure to quote the identifying number on the cylinder and on the tools. Data: Take one reading of each quantity: the length, the diameter and the mass of the cylinder. Use the units on the equipment (cm and g). Follow the format you learned in Part 1 of this lab. Calculations: You are only dealing with the values of the data, not their uncertainties. First convert 4m units to meters and kilograms. Then calculate the density using. Keep 5 non-zero digits 2 d l for the result, but underline the last sig. fig. based on the sig. figs. rule. Next find the reference value of the density for your cylinder, and calculate the percentage discrepancy between your result and the reference value, using: Percentage discrepancy your value reference reference value value 100% Conclusions: Report your result with only the significant digits. To do so, you will need scientific notation. Provide the percentage discrepancy with the reference value and note the reference value with the same units and order of magnitude as your result. Note: Your future lab reports must follow the same format as in this activity. 1118 Introduction of 1118 Labs - 7 Saved: 12/9/17, printed: 12/9/17

Name: Partner: 1118 Section Desk # Date Density of a Metal Cylinder Purpose Apparatus Data Calculations According to, the reference value is. Percentage discrepancy = Conclusions The density of was found to be, which is than the reference value of. 1118 Introduction of 1118 Labs - 8 Saved: 12/9/17, printed: 12/9/17

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