UNCERTAINTY WS

5.4 Double slit interference Calculation sheet

AQA Physics Determining uncertainty Specification references

 3.1.2 Limitation of physical measurements  M0.3 Use ratios, fractions, and percentages  M1.5 Identify uncertainties in measurements and use simple techniques to determine uncertainty when data are combined by addition, subtraction, multiplication, division, and raising to powers

Learning objectives After completing the worksheet you should be able to:  demonstrate knowledge and understanding of percentage errors and uncertainties  evaluate absolute and percentage uncertainties  determine uncertainty when data are combined by addition, subtraction, multiplication, division, and raising to powers.

Percentage uncertainties Introduction When something is measured there will always be a small difference between the measured value and the true value. There are several possible reasons for uncertainty in measurements, including the difficulty of taking the measurement, the precision of the measuring instrument (for example, due to the size of the scale divisions), and the natural variation of the quantity being measured. The word ‘uncertainty’ is generally used in preference to ‘error’, because ‘error’ implies something that is wrong – mistakes in making measurements should be avoided, and are not included in the uncertainty. A measurement of 2.8 g is measured on a scale with divisions of 0.1 g. The true value could be anything from 2.85 g up to (but not including) 2.95 g, but the precision of the scale used does not allow us to measure the value to two decimal places. So we write the value as 2.8 (± 0.1) g. Here, 0.1 g is called the absolute uncertainty. The percentage uncertainty in a measured value is calculated as shown below.

percentage uncertainty 

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(absolute) uncertaint y  100% measured value

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5.4 Double slit interference Calculation sheet

AQA Physics Worked example Question a

The distance from A to B is carefully measured by stretching a 10-metre tape measure across the two points, taking a reading at both ends, and subtracting the larger value from the smaller value. The tape measure is marked in millimetre increments. The measured value is 7.500 m. i Deduce the absolute uncertainty in the measurement. ii Determine the percentage uncertainty in the measurement. b The distance from B to C is measured as 6.5 m using a measuring wheel that gives measurements every 0.5 m. The wheel was reset to 0 and started rolling at point B. i Deduce the absolute uncertainty in the measurement. ii Determine the percentage uncertainty in the measurement. c Calculate the absolute uncertainty in the total distance from A to B to C. d Calculate the percentage uncertainty in the total distance from A to B to C.

Answer a i Step 1 Consider the start point (A) and end point (B) of the measurement, and the scale division size. Due to the method used (a measurement was taken at both ends), there will be an uncertainty in the measurement both at the start point (A) and the end point (B). The uncertainty in the measurement 1 mm at each end, giving a total uncertainty of 2 mm or 0.002 m. Step 2 Write out the measurement with its absolute uncertainty. The uncertainty has the same unit as the measurement. The distance AB is 7.500 ( 0.002) m. ii

Step 3

Calculate the percentage uncertainty using the equation: percentage uncertainty 

uncertaint y  100% measured value

percentage uncertainty 

0.002  100%  0.027% (to 2 significant figures) 7.500

b i

Step 4

This time there will be no uncertainty in the measurement at the start point (B), as the wheel was reset and no measurement was made at the start. The uncertainty and the end point (C) will be 0.5 m, as this is the precision of the measuring wheel.

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5.4 Double slit interference Calculation sheet

AQA Physics Step 5

Write out the measurement with its absolute uncertainty. The distance BC is 6.5 ( 0.5) m. Step 6 The percentage uncertainty 

0.5  100% 6.5

 7.7% (to 2 significant figures) c

Step 7

For the distance ABC the two measurements are added. The overall absolute uncertainty will be the sum of the individual absolute uncertainties. uncertainty in ABC  uncertainty in AB  uncertainty in BC  0.002 m  0.5 m  0.502 m (note, the 0.002 is fairly insignificant here) d Step 8 To find the percentage uncertainty, first calculate the measured value of ABC. ABC  7.500  6.5  14 m Step 9 Calculate the percentage uncertainty using the equation: percentage uncertainty 

uncertaint y  100% calculated value

percentage uncertainty 

0.502  100% 14

 3.6% (to 2 significant figures)

Questions 1 Write down these measurements with their absolute uncertainty. a 6.0 cm length measured with a ruler marked in mm (1 mark) b 0.642 mm diameter measured with a digital micrometer (1 mark) c 36.9 °C temperature measured with a thermometer which has a quoted accuracy of: ‘± 0.1 °C (34 to 42 °C), rest of range ± 0.2 °C’. (1 mark) 2 Calculate the percentage uncertainty in these measurements. a 5.7 ± 0.1 cm (1 mark) b 2.0 ± 0.1 A (1 mark) c 450 ± 2 kg (1 mark) d 10.60 ± 0.05 s(1 mark) e 47.5 ± 0.5 mV (1 mark)

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5.4 Double slit interference Calculation sheet

AQA Physics

f 366 000 ± 1000 J (1 mark) 3 Calculate the absolute uncertainty in these measurements. a 1200 W ± 10% (1 mark) b 34.1 m ± 1% (1 mark) c 330 000 Ω ± 0.5% (1 mark) d 0.008 00 m ± 1% (1 mark) 4 Calculate the absolute and percentage uncertainty in the total mass of suitcases of masses x, y, and z. x  23.3 ( 0.1) kg, y  18 ( 1) kg, z  14.7 ( 0.5) kg (2 marks)

Combining uncertainties Introduction In a calculation, if several of the quantities have uncertainties then these will all contribute to the uncertainty in the answer. The following rules will help you calculate the uncertainty in your final answers.  When quantities are added, the uncertainty is the sum of the absolute uncertainties.  When quantities are subtracted, the uncertainty is also the sum of the absolute uncertainties.  When quantities are multiplied, the total percentage uncertainty is the sum of the percentage uncertainties.  When quantities are divided, the total percentage uncertainty is also the sum of the percentage uncertainties.  When a quantity is raised to the power n, the total percentage uncertainty is n multiplied by the percentage uncertainty – for example, for a quantity x2, total percentage uncertainty  2  percentage uncertainty in x.

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5.4 Double slit interference Calculation sheet

AQA Physics

Worked example Question A current of 2.8 ( 0.1) A passes through a kettle element. The mains power supply is 230 ( 12) V. Calculate the power transferred, including its uncertainty.

Answer Step 1 Calculate the power. P  IV P  (2.8 A)  (230 V)  644 W Step 2 Calculate the percentage uncertainties. The percentage uncertainty in current 

0.1  100%  3.57% 2.8

The percentage uncertainty in voltage 

12  100%  5.22% 230

The percentage uncertainty in power  3.57%  5.22%  8.79%  9% (to nearest %) Step 3 Calculate the absolute uncertainty in the power. The absolute uncertainty 

8.79  644 W  57 W 100

Step 4 State the answer with units. Power  644 ( 57) W

Questions 5 A piece of string 1.000 ( 0.002) m is cut from a ball of string of length 100.000 ( 0.002) m. Calculate the length of the remaining string and the uncertainty in this length. (2 marks) 6 A runner completes 100.0 ( 0.1) m in 18.6 ( 0.2) s. Calculate his average speed and the uncertainty in this value. (2 marks) 7 A car accelerates, with constant acceleration, from 24 ( 1) m s–1 to 31 ( 2) m s–1 in 9.5 ( 0.1) s. Calculate the acceleration. State your answer with its absolute uncertainty. (3 marks)

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5.4 Double slit interference Calculation sheet

AQA Physics

8 A cube has a mass of 7.870 ( 0.001) kg and sides of length 10.0 ( 0.1) cm. Give the value of the density of the cube. (2 marks) 9 In a Young’s slits experiment, two slits that are very close together are illuminated, and on a distant screen an interference pattern of light and dark fringes is seen. The separation of the fringes can be used to calculate the wavelength of the light. In a demonstration of this experiment:  the double slit separation, s  0.20 ( 0.01) mm  the distance from the slits to the screen, D  4.07 ( 0.01) m  the distance between two adjacent bright fringes w  12.0 ( 0.05) mm. The equation for calculating wavelength is λ 

ws . D

a Calculate: i the wavelength, λ, of the light (1 mark) ii the absolute uncertainty in the wavelength. (2 marks) b The distance between 11 fringes (10 spaces)  120.0 ( 0.05) mm. Using this value, calculate the new absolute uncertainty in the wavelength. (2 marks) c Comment on whether the uncertainty in the wavelength could be significantly reduced by increasing the number of fringes measured to, for example, 20 or more. (1 mark)

Maths skills links to other areas You may also need to calculate uncertainties when considering precision and accuracy of measurements and data, including margins of error, percentage errors, and uncertainties in apparatus.

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