ICT/Computing teacher since 2003 and Vice Principal. Interested in technology, gadgets, game design and software/web development. Owner of Barney - a rather grumpy at times but loveable West Highland Terrier who sometimes features in my resources!
ICT/Computing teacher since 2003 and Vice Principal. Interested in technology, gadgets, game design and software/web development. Owner of Barney - a rather grumpy at times but loveable West Highland Terrier who sometimes features in my resources!
This is an 18 lesson unit of work around Microbits, combining programming using the online microbit interface and electronic components. The components I used were sourced from http://microbit-accessories.co.uk but you could make your own or source from elsewhere as well. Helpsheets are provided for each of the electronic components. The students each have a workbook for the whole unit divided into sections that can be easily marked by the teacher, with opportunity/space for student reflection and response.
Students start off learning about microbit theory, i.e. safe handling (static) and polarity, inputs, outputs and programming structures IF statements and loops. They then need to design the “next big thing” - a device that solves a problem, using the microbit. They will need to produce a design brief and circuit diagram. Once they have built it, there is a lesson on gathering user feedback and evaluation. At the end of the unit, they have the opportunity to create a business pitch for their new device. This is a great end to the unit as each student/group gets to share their creation to the rest of the class, with prizes for the best entries (at teacher’s discretion!)
The course mainly links towards the D&T criteria (with reference to the relevant criteria at the end of each powerpoint) but could be used in Computing as well.
Lesson where students learn about the three main storage technologies: optical, magnetic and solid-state. After researching each technology and how it works, they can then apply that knowledge to identify the most appropriate storage technology for each of the given scenarios in the worksheet. There is also an extension worksheet on Cloud storage.
Introduction to AND, OR and NOT gates. Students then complete the truth tables in a worksheet. They can then use the logic.ly website to self-assess whether they got the truth tables correct and create their binary logic gate diagram to program a car safety system.
This lesson looks at the benefits and limitations of networking and three network topologies: Ring, Bus and Star. During the lesson I get students to act out each topology using balloons/screwed up paper balls to represent the data. There are teacher notes that explain how this works for each topology. Students can complete the network worksheet.
This resource converts between binary, hex and denary. It can be used in a whole class situation on the whiteboard or given to students to use to check their answers to any conversion questions. Useful when teaching binary and hex.
Ten pseudocode and python programming challenges that are laid out like an exam question (with a suggested pseudocode and python solution for each question). The challenges build in difficulty as pupils progress through them. The first 4 are based on selection statements, next 3 on iteration, 2 on array/lists and the final one on subroutines.
Some guidance is provided to the pupils on the front sheet to indicate the pseudocode keywords and programming structures. These are primarily aimed at GCSE Computer Science pupils.