Section 1 - Measurements and Errors

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Created by
Anna Hunter

Cards (34)

  • SI units
    • Mass (m): kg (kilograms)
    • Length (l): m (metres)
    • Time (t): s (seconds)
    • Amount of substance (n): mol (moles)
    • Temperature (t): K (kelvin)
    • Electric current (I): A (amperes)
  • Derived SI units

    Derived from equations of physical quantities, e.g. F=ma gives N (newtons) as the SI unit of force
  • Deriving SI units of voltage

    1. V=E/Q, where E is energy and Q is charge
    2. E=1/2 mv^2, so the SI units for energy is kg m^2 s^-2
    3. Q=It, so the units for Q are As (ampere seconds)
    4. Therefore V=kg m^2 s^-3 A^-1
  • SI prefixes

    • Tera (T): 10^12
    • Giga (G): 10^9
    • Mega (M): 10^6
    • Kilo (k): 10^3
    • Centi (c): 10^-2
    • Milli (m): 10^-3
    • Micro ): 10^-6
    • Nano (n): 10^-9
    • Pico (p): 10^-12
    • Femto (f): 10^-15
  • Converting mega electron volts to joules
    1. 1 eV = 1.6x10^-19 J
    2. 76 MeV = 76 x 10^6 eV = 1.216 x 10^-11 J
  • Converting kilowatt hours to joules
    1. 1 kW = 1000 J/s
    2. 1 hour = 3600 s
    3. 1 kWh = 1000 x 3600 J = 3.6 x 10^6 J = 3.6 MJ
  • Random errors
    Affect precision, cause differences in measurements which causes a spread about the mean, cannot be eliminated
  • SI units
    • Mass (m): kg (kilograms)
    • Length (l): m (metres)
    • Time (t): s (seconds)
    • Amount of substance (n): mol (moles)
    • Temperature (t): K (kelvin)
    • Electric current (I): A (amperes)
  • Derived SI units

    Derived from equations of physical quantities, e.g. F=ma gives N (newtons) as the SI unit of force
  • Deriving SI units of voltage

    1. V=E/Q, where E is energy and Q is charge
    2. E=1/2 mv^2, so the SI units for energy is kg m^2 s^-2
    3. Q=It, so the units for Q are As (ampere seconds)
    4. Therefore V=kg m^2 s^-3 A^-1
  • SI prefixes

    • Tera (T): 10^12
    • Giga (G): 10^9
    • Mega (M): 10^6
    • Kilo (k): 10^3
    • Centi (c): 10^-2
    • Milli (m): 10^-3
    • Micro ): 10^-6
    • Nano (n): 10^-9
    • Pico (p): 10^-12
    • Femto (f): 10^-15
  • Converting mega electron volts to joules
    1. 1 eV = 1.6x10^-19 J
    2. 76 MeV = 76 x 10^6 eV = 1.216 x 10^-11 J
  • Converting kilowatt hours to joules
    1. 1 kW = 1000 J/s
    2. 1 hour = 3600 s
    3. 1 kWh = 1000 x 3600 J = 3.6 x 10^6 J = 3.6 MJ
  • Random errors

    Affect precision, cause differences in measurements which causes a spread about the mean, cannot be eliminated
  • Reducing random errors

    • Take at least 3 repeats and calculate a mean
    • Use computers/data loggers/cameras to reduce human error
    • Use appropriate equipment with higher resolution
  • Systematic errors

    Affect accuracy, cause all results to be too high or too low by the same amount each time
  • Reducing systematic errors

    • Calibrate apparatus by measuring a known value
    • Correct for background radiation in radiation experiments
    • Read the meniscus at eye level to reduce parallax error, use controls in experiments
  • Precision
    Measurements are consistent, fluctuate slightly about a mean value
  • Repeatability
    Original experimenter can redo the experiment and get the same results
  • Reproducibility

    Experiment is redone by a different person or with different techniques and equipment and the same results are found
  • Resolution
    The smallest change in the quantity being measured that gives a recognisable change in reading
  • Accuracy
    A measurement close to the true value
  • Uncertainty
    The bounds in which the accurate value can be expected to lie
  • Types of uncertainty
    • Absolute uncertainty: fixed quantity e.g. 7±0.6 V
    • Fractional uncertainty: uncertainty as a fraction of the measurement e.g. 7±3/35 V
    • Percentage uncertainty: uncertainty as a percentage of the measurement e.g. 7±8.6% V
  • Uncertainty in a reading
    ±half the smallest division
  • Uncertainty in a measurement
    At least ±1 smallest division
  • Uncertainty in digital readings and given values

    ±the last significant digit
  • Uncertainty in repeated data

    Half the range (largest - smallest value), show as mean ±range/2
  • Reducing uncertainty

    • Fix one end of a ruler
    • Measure multiple instances and divide uncertainty by number of instances
  • Combining uncertainties
    • Adding/subtracting: add absolute uncertainties
    • Multiplying/dividing: add percentage uncertainties
    • Raising to a power: multiply percentage uncertainty by power
  • Showing uncertainties on graphs
    • Use error bars
    • Line of best fit should go through all error bars (excluding anomalous points)
    • Uncertainty in gradient found from lines of best and worst fit
  • Order of magnitude
    Powers of ten which describe the size of an object
  • Estimating physical quantities to the nearest order of magnitude
    Calculate the value and give it only as a power of ten
  • Estimation
    Approximating the values of physical quantities to make comparisons or check if a calculated value is reasonable