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Chapter 2: Problem 172

Describe how the uncertainty in a measured value is determined.

Short Answer

Expert verified
The uncertainty in a measured value is determined by first identifying the sources of uncertainty, which can be random or systematic. One can estimate uncertainty by repeating the measurement several times, calculating the mean of the data points, determining the spread of the data points around the mean, and correcting for any known or estimated systematic errors. The measured value and its uncertainty can then be expressed in the format: Measured Value ± Uncertainty. For example, if the mean value of a length measurement is 12.38 cm with a range of 0.3 cm, the result can be written as Length = 12.38 cm ± 0.30 cm.

Step by step solution

01

Define Uncertainty

Uncertainty is a quantitative indication of the quality of a measurement that reflects the range of possible values within which the true value of a measured quantity is likely to lie. In other words, uncertainty is an estimate of how much a measured value might deviate from the true value due to various factors involved in the measurement process.
02

Identify Sources of Uncertainty

There are several sources of uncertainty in a measurement process, which can be broadly categorized into random and systematic uncertainties. Random uncertainties: - Fluctuations in readings due to unpredictable factors like noise from the environment or the observer's judgment while reading instruments, such as a ruler or a thermometer. - These uncertainties can be reduced by repeating the measurement and taking the average of the results. Systematic uncertainties: - Errors in measurements that consistently occur in one direction (either too high or too low), such as zero-offset in instruments or a wrongly calibrated scale. - Systematic uncertainties cannot be reduced by repeating the measurement, but instead require a correction to the measuring device or technique.
03

Estimating Uncertainty from Measurements

To estimate the uncertainty in a measured value, one can follow these steps: 1. Repeat the measurement several times to obtain a set of data points. 2. Calculate the mean (average) of the data points. 3. Determine the spread of the data points around the mean, either by calculating the range, standard deviation, or using accepted uncertainty values from previous studies or standards. 4. If systematic uncertainties are involved, correct the mean value by accounting for the known or estimated systematic error in the measuring device or technique.
04

Expressing Uncertainty

Uncertainty in a measured value is often expressed using the following format: Measured Value ± Uncertainty The uncertainty should be expressed to one or two significant figures, and the measured value should be rounded to the same decimal place as the uncertainty. Example: Suppose you measure the length of an object using a ruler multiple times and obtain the following results: 12.3 cm, 12.5 cm, 12.4 cm, 12.2 cm, and 12.5 cm. From these measurements, the mean value is 12.38 cm, and the range (difference between the highest and lowest values) is 0.3 cm. So you can express the length of the object with its uncertainty as: Length = 12.38 cm ± 0.30 cm

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Random Uncertainty
When measuring something, you might notice that your results vary slightly each time. This is where random uncertainty comes in. It's basically the kind of uncertainty that occurs due to unpredictable factors. Imagine trying to measure a bouncing ball's speed; every time you do it, slight changes like wind or even tiny movements from equipment can affect the readings a bit. But don't worry! There's a simple way to handle this.
  • Repeat your measurements multiple times.
  • Average them out. This gives you a more accurate picture.
The more measurements you have, the better your average will be at representing the true value. Random uncertainty, in essence, is like these small noises in our readings, and repetition is our best friend in minimizing their effect.
Systematic Uncertainty
Systematic uncertainty is trickier. It isn't about fluctuations at all; instead, it's about a consistent error that skews your measurements in the same direction every time. Think of it like a clock that runs consistently five minutes fast. In measurements, these could be due to things like a worn out calibration on a scale or an incorrectly zeroed instrument. Unlike random uncertainty, repeating the measurement won't help reduce this kind.
Here's how you can tackle systematic uncertainty:
  • Calibrate your equipment correctly.
  • Double-check the settings on your measurement tools.
  • Use control measurements to identify any consistent biases.
By recognizing these biases, you can apply corrections, ensuring your results are closer to the true value.
Significant Figures
Significant figures tell us about the precision of a measurement. They include all the certain digits plus one doubtful one in a number. Why does this matter? Because it shows the confidence level and limits in your measurement. Let's say you weigh a bag of sugar, and your scale reads 2.30 kg; the digits here are significant because they tell us the precision of the measurement, including what's certain and the smallest part we're guessing on. Follow these simple guidelines for significant figures:
  • Non-zero numbers are always significant.
  • Zeros between non-zero numbers are significant.
  • Zeros at the end of a number, to the right of a decimal, are significant.
Always round your measurements to match the level of uncertainty, so you're not overestimating how precise you really are!
Standard Deviation
Standard deviation is a great way to describe how varied the data in your measurements are. Simply put, it tells you how much spread or how tightly packed around the mean your data points are. If you have a small standard deviation, that means your data points are close to the mean, and your measurements are fairly consistent. On the other hand, a large standard deviation indicates more spread and less reliability in individual measurements.
To calculate standard deviation, follow these basic steps:
  • Find the mean of your data set.
  • Subtract the mean from each data point and square the result.
  • Find the average of these squared differences.
  • Finally, take the square root of this average.
Understanding standard deviation helps in figuring out not just what the average looks like, but also how reliable or consistent each measurement is compared to others. It's a vital tool in assessing the quality and certainty of your data.

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Most popular questions from this chapter

A student reports a series of five length measurements that are accurate but not precise. Is it more likely that his laboratory technique is very good but the measuring instrument is bad, or that his laboratory technique is bad? Explain.

Dieters are often told that drinking ice-cold water burns more energy than drinking roomtemperature water. Why is this true?

At \(25^{\circ} \mathrm{C}\), air has a density of \(1.3 \times 10^{-3} \mathrm{~g} / \mathrm{mL}\). What is this density in (a) kilograms per liter and (b) pounds per gallon?

A student uses a digital balance to determine the mass of an object. Its digital display reads \(2.635 \mathrm{~g}\). He keeps looking at the balance and it stays fixed at \(2.635 \mathrm{~g}\) for half an hour. He then states, "The mass of the object is \(2.635 \mathrm{~g}\) exactly. There is no uncertainty in this measurement because the last digit '5' stayed constant and did not change over time." Is he right? Is the mass of the object exactly known with no uncertainty? Explain.

A rectangular box measures \(6.00\) in. in length, \(7.00\) in. in width, and \(8.00\) in. in height. What is the volume of the box in liters? \([2.54 \mathrm{~cm}=1\) in.]
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