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IB Physics SL/Notes/S1.3 Mathematics

IB Physics SLS1.3 MathematicsNotes

Practice General mathematics

Practice

Math errors often hide as physics errors. Keep the model visible, use units as a check, and round only at the end.

Rearrange equations symbolically before substituting numbers where possible.
Use proportional reasoning to predict how one quantity changes when another changes.
Use logarithms or exponentials only when the model requires them, such as exponential decay.
Carry units through calculations as a check.
Round final answers to appropriate significant figures, but avoid premature rounding during calculation.

Match each mathematics cue to its purpose.

Match
Reasons
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Apply general mathematics to a physics calculation.

Substituting numbers before identifying the relationship.

Apply general mathematics to a physics calculation.

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Practice Vectors and diagrams

A good diagram is a calculation aid. It defines the object, axes, directions, components, and sign convention before equations are written.

Vectors have magnitude and direction; diagrams should show both.
Use arrows with labels and consistent directions.
Resolve vectors into perpendicular components when the equations apply component by component.
Resultant vectors come from vector addition, not ordinary scalar addition unless vectors are collinear.
A free-body diagram should show only forces acting on the chosen object.

Repair vector-diagram mistakes.

Spot Errors

Construct or evaluate a vector diagram for a physics situation.

Mixing forces on different bodies.

Construct or evaluate a vector diagram for a physics situation.

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Practice Units and numerical values

Many wrong physics answers are unit errors. Convert before substitution and check whether the final unit matches the quantity asked for.

Use SI units unless the equation or data booklet form clearly uses another unit.
Convert prefixes such as milli, micro, kilo, and mega before substitution.
Carry units through calculations to check dimensions.
Scientific notation reduces place-value errors for very large or small numbers.
Final answers should include units and sensible significant figures.

Repair units and numerical-value mistakes.

Spot Errors

Check units and numerical values in a physics calculation.

Leaving prefixes unconverted.

Check units and numerical values in a physics calculation.

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Practice Uncertainties

Uncertainty is not an afterthought. It tells whether differences or agreement with theory are meaningful.

Random error causes scatter in repeated measurements and can be reduced by repeats.
Systematic error shifts measurements in one direction and requires calibration or method correction.
Absolute uncertainty has the same unit as the measurement.
Percentage uncertainty compares uncertainty with the measured value.
For products and quotients, percentage uncertainties add in simple IB treatment.
Graph uncertainty can be shown with error bars and best/worst acceptable gradients.

Repair uncertainty statements.

Spot Errors

Discuss uncertainty in measured and processed data.

Using vague “human error” explanations.

Discuss uncertainty in measured and processed data.

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Practice Graphing

A graph should answer a model question. The line, gradient, and intercept need physics meaning, not just a high correlation.

Plot the independent variable on the horizontal axis and dependent variable on the vertical axis unless there is a reason not to.
Axes need quantity names, symbols where useful, and units.
Choose scales that use the plotting area well without distorting data.
Use error bars when uncertainty is relevant to the analysis.
A best-fit line should match the expected model; do not force it through the origin unless justified.
Gradient and intercept should be interpreted using the equation of the line and physical model.

Repair graphing mistakes.

Spot Errors

Evaluate a physics graph.

Treating graphing as presentation only.

Evaluate a physics graph.

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Retrieve the Mathematics Model

Review

This summary is the math safety net: equation, diagram, unit, uncertainty, graph, interpretation.

Start calculations from the physics model or equation, not from numbers alone.
Use vector diagrams and components when direction matters.
Convert units and prefixes before substitution and check final dimensions.
Track uncertainty from raw measurements through processed quantities.
Use graphs to test models and extract gradients or intercepts with physical meaning.

Match each mathematics skill to its role.

Match
Reasons
0/6

Summarize mathematical skills needed in physics investigations.

Listing calculations without interpretation.

Summarize mathematical skills needed in physics investigations.

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