BTEC Unit 47 Analogue Electronic Systems HND Level 5 Assignment Sample UK

Course: Pearson BTEC Level 5 Higher National Diploma in Engineering

The BTEC Level 5 Higher National Diploma in Engineering course includes Unit 47, Analogue Electronic Systems. This unit focuses on exploring the specialist applications of analogue electronic systems and aims to develop students’ understanding of designing electronic circuits using analogue and digital devices. Students will learn about the characteristics of electronic devices and gain practical experience in designing, testing, and constructing physical circuits. The course also covers the representation and processing of information within analogue and digital subsystems. By the end of the unit, students will be familiar with techniques used in the design and evaluation of electronic systems.

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Assignment Activity 1: Design single stage analogue amplifier circuits to predict and measure, by simulation, the gain, frequency response and input and output resistances. 

To predict and measure the gain, frequency response, and input/output resistances of single-stage analog amplifier circuits, you can follow these steps:

• Choose an amplifier configuration: Select a suitable amplifier configuration, such as common-emitter for a transistor-based amplifier or non-inverting for an operational amplifier-based amplifier.
• Determine the desired gain: Decide on the desired amplification factor (gain) for your circuit. This will depend on the specific application or requirements of your design.
• Calculate component values: Use the amplifier configuration’s equations and specifications to calculate the required component values. These values may include resistors, capacitors, and biasing elements.
• Simulate the circuit: Utilize a circuit simulation software, such as LTSpice or Multisim, to simulate the designed circuit. Input the appropriate input signal and measure the output response.
• Measure gain: Analyze the simulation results to determine the actual gain of the amplifier circuit. Compare it with the predicted gain to evaluate the accuracy of your design.
• Analyze frequency response: Apply a range of input frequencies to the simulated circuit and observe the corresponding output amplitudes. Plot the frequency response curve to understand how the circuit behaves at different frequencies.
• Measure input and output resistances: Analyze the circuit simulation results to determine the input and output resistances. These values indicate the impedance seen by the input and output signals, respectively.

Assignment Activity 2: Develop functional subsystems through an understanding of the characteristics of operational amplifiers. 

To develop functional subsystems utilizing operational amplifiers, consider the following steps:

• Identify the system requirements: Understand the specific requirements and functionalities desired for the subsystem you intend to design. Determine the input and output characteristics, as well as any necessary signal processing operations.
• Select the appropriate operational amplifier configuration: Choose an operational amplifier circuit configuration that suits the requirements of your subsystem. Examples include inverting amplifier, non-inverting amplifier, summing amplifier, difference amplifier, integrator, differentiator, etc.
• Design the circuit: Calculate the necessary component values (resistors, capacitors) based on the desired characteristics of the subsystem. Take into account any gain, frequency response, or filtering requirements.
• Simulate and verify: Use circuit simulation software to simulate the operational amplifier-based subsystem. Verify that the circuit meets the desired specifications and functions as expected.
• Implement and test: Construct the designed circuit using physical components on a breadboard or PCB. Apply appropriate input signals and measure the output response. Compare the measured results with the simulated values to validate the functionality of the subsystem.

Assignment Activity 3: Examine the characteristics of information represented in analogue and digital format to assess techniques for the conversion of signals between analogue and digital formats. 

To assess techniques for the conversion of signals between analog and digital formats, follow these steps:

• Understand analog and digital signals: Familiarize yourself with the characteristics and representations of analog and digital signals. Analog signals are continuous and vary smoothly, while digital signals are discrete and represented as binary values (0s and 1s).
• Study analog-to-digital conversion: Explore various analog-to-digital conversion techniques such as successive approximation, delta-sigma modulation, and flash ADCs. Understand the principles, advantages, and limitations of each technique.
• Study digital-to-analog conversion: Learn about different digital-to-analog conversion methods like pulse width modulation (PWM), weighted resistor networks, and sigma-delta modulation. Understand their working principles, benefits, and constraints.
• Compare conversion techniques: Analyze the strengths and weaknesses of different conversion techniques based on factors like resolution, speed, complexity, accuracy, and cost. Consider the specific requirements of your application when evaluating the suitability of each technique.
• Consider practical considerations: Take into account factors such as signal bandwidth, noise, distortion, sampling rate, and quantization error when selecting the most appropriate conversion technique for a given application.

Assignment Activity 4: Design electronic circuits using physical components.

To design electronic circuits using physical components, follow these steps:

• Define the circuit requirements: Clearly understand the functionality, input/output characteristics, and any other specific requirements for your circuit.
• Select the components: Identify the necessary components based on your circuit design. This may include resistors, capacitors, inductors, transistors, diodes, operational amplifiers, etc. Choose components with appropriate values and specifications.
• Design the circuit schematic: Create a circuit schematic diagram using a software tool like EAGLE, KiCad, or Altium Designer. Connect the components as per the desired circuit configuration and desired functionality.
• Calculate component values: Use circuit analysis techniques, such as Kirchhoff’s laws or voltage/current divider rules, to calculate the required component values based on the desired circuit characteristics.
• Prototype and assemble: Gather the physical components required for the circuit and assemble them on a breadboard or a custom-designed PCB. Take necessary precautions to ensure proper connections and component placements.
• Test and measure: Apply appropriate input signals to the circuit and use oscilloscopes, multimeters, or other measurement tools to observe and measure the circuit’s behavior. Verify if the circuit meets the desired specifications and functions correctly.
• Iterate and refine: If necessary, iterate on the design by making adjustments to component values, circuit layout, or configuration. Continue testing and refining the circuit until it meets the desired performance.

Note: While designing electronic circuits with physical components, always prioritize safety precautions and follow best practices to avoid any damage to the components or harm to yourself.

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