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I am not understanding ho to simulate this or any type of circut
flux2002

flux2002

@copilot I am not understanding ho to simulate this or any type of circut
1y

copilot

Simulating circuits can be a powerful way to test and validate your electronic designs before building the physical hardware. Here's a basic guide to help you get started with circuit simulation, especially if you're trying to simulate your Domestic Violet TV Glasses project in an environment like Flux or other simulation tools:
Step 1: Understand the Components and Their Properties
Before simulation, ensure you understand each component in your circuit, including their electrical properties. For example, in your project:
  • LED1 (WP7113SRD/D): A light-emitting diode (LED) with a forward voltage ((V_F)) of 1.85V, where pin 1 is Cathode (K) and pin 2 is Anode (A).
  • V1: A 1.5V voltage source, with pin 1 as ANODE and pin 2 as CATHODE.
Step 2: Circuit Design Software
  • Ensure you're familiar with Flux.ai or any circuit simulation software you're using. These tools typically provide a schematic editor where you can place components and draw connections (nets) between them.
Step 3: Draw Your Circuit
In Flux, you would:
  1. Place the components (LED1 and V1) onto the schematic editor.
  2. Connect the components according to your project nets:
    • Connect V1:ANODE to LED1:K.
    • Connect V1:CATHODE to LED1:A.
This forms a basic circuit where the voltage source (V1) powers the LED ((LED1)).
Step 4: Adding a Current Limiting Resistor (Not Included in Your Original Design)
LEDs require a current limiting resistor to prevent them from drawing too much current, which could damage them. However, your circuit doesn't mention one. For a 1.5V source and an LED with a 1.85V forward voltage, we ideally need a resistor to drop the excess voltage. Since the LED forward voltage is higher than the source, your LED may not light up under these conditions. However, for learning purposes:
  • To calculate the resistor value (assuming your source voltage is sufficient), you'd use Ohm's Law (V=IR), where (V) is the voltage across the resistor, (I) the desired current through the LED (typically 20mA for many standard LEDs), and (R) the resistor's value.
Step 5: Running the Simulation
Most circuit design and simulation software have a 'simulate' button or option. When clicked, it analyses your circuit based on the connections, component properties, and law of physics to give you either a visual outcome (like an LED lighting up) or numerical data (like current and voltage values at different parts of the circuit).
Note:
  • Since the forward voltage of the LED is higher than the source voltage, in a real scenario, you might not see the LED light up. You might need a higher voltage source or a different configuration.
  • Simulation tools vary in capabilities and interfaces. If Flux does not support simulation directly, you might need to use an external simulation tool (like LTSpice, Falstad's Circuit Simulator, or Tinkercad Circuits) where you can recreate your circuit and simulate it.
Let me know if there are specific features or tools within the Flux environment you're curious about or any other components you'd like to add to your simulation!
1y
LED1
PS1
V1
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Domestic Violet TV Glasses

Domestic Violet TV Glasses
Description

Created
Last updated by flux2002
1 Contributor(s)
flux2002

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