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make circut for on buzzer for 3 second
flux2002

flux2002

@copilot make circut for on buzzer for 3 second
1y

copilot

To create a simple circuit that turns on a buzzer for 3 seconds, you'll need a microcontroller, a buzzer, and probably a resistor to limit the current (depending on the type of buzzer you're using). For simplicity, let's use an Arduino as our microcontroller because it's beginner-friendly and versatile.
Components:
  • Microcontroller: Arduino Uno (MCU:1)
  • Buzzer: Active buzzer suitable for direct drive from an Arduino pin (BUZ:1)
  • Resistor (optional): ~220 ohms (R1) - may not be necessary if you're using an active buzzer rated for direct connection to 5V.
  • Power Source: Assuming the Arduino is powered via USB for simplicity.
Assumptions:
  • You're using an active buzzer (it generates sound when powered, without needing a specific signal pattern).
  • The buzzer operates at 5V, compatible with Arduino's output voltage.
  • Direct connection to a digital I/O pin of the Arduino is acceptable (check your buzzer's datasheet).
Connections:
  1. Connect MCU:1 5V to BUZ:1 VCC.
  2. Connect MCU:1 GND to BUZ:1 GND.
    • If using a resistor (for passive buzzers not in your case but as a general note) Connect BUZ:1 - to R1:1, then connect R1:2 to MCU:1 GND.
  3. Choose a digital I/O pin on the Arduino for controlling the buzzer, for example, Digital Pin 7. Connect MCU:1 D7 to BUZ:1 SIGNAL.
Software:
You'd program the Arduino using its IDE. Here is sample code that turns on the buzzer for 3 seconds and then stops:
Cpp
void setup() {
  pinMode(7, OUTPUT); // Set digital pin 7 as an output
}

void loop() {
  digitalWrite(7, HIGH); // Turn the buzzer on
  delay(3000); // Wait for 3 seconds (3000 milliseconds)
  digitalWrite(7, LOW); // Turn the buzzer off
  
  while(true){ 
    // Stop doing anything else
  }
}
This code sets up pin 7 as an output in the setup() function. In the loop(), it turns the buzzer on by setting pin 7 high, waits for 3 seconds, then turns the buzzer off and stops further execution with an infinite loop to prevent restarting.
Ensure to verify the exact requirements and datasheet of the specific buzzer you're using, as there might be variations in terms of voltage and whether an in-line resistor is required.
1y
what is problem in this circut
flux2002

flux2002

@copilot what is problem in this circut
1y

copilot

Based on the project description you've provided for "Lively Black Mr. Fusion," let's analyze the circuit connections as detailed. Here's a summary and analysis of your circuit:
Circuit Components:
  • BZ1: A buzzer with pins N (negative) and P (positive).
  • V1: A generic voltage source with pins ANODE and CATHODE, specified as 12V.
  • U1: An Arduino Nano with various digital, analog, power, and ground pins.
Circuit Nets and their Connections:
  1. U1:(COM/GND) is connected to V1:(ANODE).
    • Generally, in a circuit, the ANODE of a voltage source should not be directly connected to GND as it represents the positive terminal. This seems to be a major mistake in the wiring as it could cause a short circuit.
  2. U1:(COM/GND__1) is connected to BZ1:(N).
    • This connection seems appropriate for grounding the negative side of the buzzer.
  3. BZ1:(P) is connected to U1:(D6).
    • This configuration allows the buzzer to be controlled by pin D6 of the Arduino, which is a reasonable setup for a digital control application.
  4. V1:(CATHODE) is connected to U1:(VIN).
    • This is the correct way to supply power to the Arduino; the CATHODE (negative terminal) of a battery or power supply should be connected to GND, and the positive terminal should be connected to VIN for power.
Identified Problem:
  • Incorrect Power Supply Connection: The direct connection of V1:(ANODE) to U1:(COM/GND) must be a mistake. The V1 ANODE should not be tied to the ground but to the positive supply input (e.g., VIN) of the Arduino if intended to power it, which seems to be partially accomplished in net 31e3f709360567e928d77725753116ea.
To fix this circuit, you should:
  • Disconnect V1:(ANODE) from U1:(COM/GND).
  • Ensure V1:(ANODE) is correctly connected to U1:(VIN) to power the Arduino, which seems to be intended in net 31e3f709360567e928d77725753116ea alongside the connection from V1:(CATHODE) to U1:(VIN), which is not a practical configuration. The V1:(CATHODE) should be connected to a ground pin on the Arduino, possibly indicating a typographical mistake in describing the net configurations.
Please review the suggested corrections and check if there might have been a misunderstanding in the net descriptions, particularly regarding the power connections.
1y
3
BZ1
V1
U1
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Lively Black Mr. Fusion

Lively Black Mr. Fusion
Description

Created
Last updated by flux2002
1 Contributor(s)
flux2002

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