Learning focus: | A resultant force on an object can cause it to speed up or slow down, depending on the direction of the force. |

Observable learning outcome: | Describe how quickly the speed of an object can be changed if acted on by resultant forces of different size. |

Question type: | Simple multiple choice |

Key words: | Force, Newton, speed |

In *The language of mathematics in science* (2016), Boohan notes that a key difference between calculations in mathematics and science is that in science the numbers we calculate with most often have a unit as well as a number. Students need to pay attention to the manipulation of not just the numbers but the units as well. Addition and subtraction of values can only be done if they are expressed in the same units. In these questions the units have been chosen to be the same.

Students may be tempted to use number lines of positive and negative numbers to combine the forces. When forces are in opposite directions it is simpler to take the smaller force from the larger and to consider the direction separately. This approach can help to clarify the idea that forces have *both *size and direction.

This question gives students the opportunity to consolidate their understanding of balanced and unbalanced forces by calculating and describing resultant forces.

This task is very similar to one used in the key concept PFM1.3: *Balanced and unbalanced forces*. It is intended for discussion in pairs or small groups and is best done as a pencil and paper exercise.

Students should look at the information and follow the instructions on the worksheet. Listening in to the conversations of each group will often give you insights into how your students are thinking. Each member of a group should be able to report back to the class.

*Differentiation*

The quality of the discussions can be improved with a careful selection of groups; or by allocating specific roles to students in the each group. For example, you may choose to select a student with strong prior knowledge as the scribe, and forbid them from contributing any of their own answers. They may question the others and only write down what they have been told. This strategy encourages contributions from more members of each group.

NB in any class, small group discussions typically improve over time and a persistence with this strategy is often very successful in the medium to long term.

Some students, who find this mathematics very straightforward, could be challenged with examples involving both N and kN.

Autole mõjuvad jõud | Mänguautole mõjuv resultantjõud | Resultantjõud suund |

The challenge for students is to work out which number to add or subtract from the other. It is often helpful to support a student through to the correct answer with a series of careful prompts. Done in a supportive and constructive way, and as part of a class discussion, this allows other students to reflect on their own strategies too.

The values in the questions have been chosen to illustrate the idea that it is not necessarily the largest forces that produce the largest resultant force.

You might choose to ask the follow up question: ‘what will the effect of this resultant force be on the car?’

The following BEST ‘response activity’ could be used in follow-up to this diagnostic question:

- Response activity: Calculating resultant force (2)