Creating a quiz using the Hartley Oscillator circuit in TINA
This video covers how to create a quiz using the Hartley Oscillator circuit in TINA.
TINA’s AI assists you in generating quizzes for any circuit. Simply provide the circuit’s name if it’s well-known, or add a title and description for circuits that are less familiar. The AI analyzes your request and then provides a detailed summary of your learning progress.
Remember that questions are randomized, so you’ll likely face different questions even when using the same circuit.
Once you’ve answered five questions, you’ll be asked by the TINA AI to either retake or stop the test.
Creating step-by-step solution of simple DC/AC circuits
This video demonstrates step-by-step solutions for simple DC/AC circuits.
You’ll discover how TINA’s AI-powered analysis employs fundamental circuit theory to generate exact analytical results, perfectly aligning with the numerical outputs from TINA’s interactive DC analysis tool.
Our First Example: DC Circuit Analysis
First, we’ll analyze a circuit consisting of four resistors, a voltage source, and a voltmeter. We’ll use both AI and numerical simulation. After adjusting component values as needed, the circuit will be ready. We’ll then instruct the AI to “Calculate the voltage on R2.” The detailed analytical solution will immediately appear in the AI Assistant Window. We’ll compare this with the numerical simulation, confirming the results are identical. As an alternative, we can also have the AI “Calculate the voltage displayed by the Voltmeter.”
Our Second Example: Complex Circuits with Superposition
Next, we’ll analyze a more complex circuit with two sources. We’ll add a current source to our current setup. Our request to the AI will be: “Calculate the VM1 voltage.”
Here, the AI produces the analytical solution using the superposition method, calculating the effect of each source independently. Initially, the current source is considered while the voltage source is short-circuited. Then, the voltage source’s effect is determined, with the IS1 Current Source replaced by an open circuit.
Summing the results from these individual superposition runs yields the final VM1 voltage. We’ll conclude by comparing this result again with the numerical simulation.
TINA’s AI-powered analysis, using fundamental circuit theory, delivers results that precisely match numerical simulations, provided by the interactive DC analysis tool of TINA.
Click here to watch our video.
You can learn more about TINA here: www.tina.com
You can learn more about TINACloud here: www.tinacloud.com