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1. Selecciona un puente desde la librería de componentes:
   • Busca un componente como un "2-Pin Jumper". Esto suele ser un conector simple de dos pines que puedes cerrar con un jumper físico.
2. Coloca el puente en tu diseño:
   • Posiciona el puente donde desees en tu esquema. Si no estás seguro de dónde debería ir, dime más sobre cómo planeas usarlo, y puedo ofrecer recomendaciones más específicas.
3. Conecta el puente al circuito:
   • Para conectar el puente, normalmente se colocaría en serie con el camino de la señal que deseas habilitar/deshabilitar.
   • Ejemplo:
     • Si deseas interrumpir una conexión entre $U1$:D13/GPIO6 y algún otro componente, conecta el puente entre estos dos puntos.
4. Opciones adicionales:
   • Si necesitas que el puente controle más de una conexión, podrías considerar usar un interruptor DIP o un conector más grande.

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• MPN (Manufacturer Part Number): ABX00053
• Pins:
  • 1: D13/GPIO6
  • 2: +3V3
  • 3: AREF
  • 4: A0/DAC0/GPIO26
  • 5: A1/GPIO27
  • 6: A2/GPIO28
  • 7: A3/GPIO29
  • 8: A4/GPIO12
  • 9: A5/GPIO13
  • 10: A6
  • 11: A7
  • 12: +5V
  • 13: QSPI_~RESET
  • 14: GND
  • 15: VIN
  • 16: TX
  • 17: RX
  • 18: ~RESET
  • 19: GND__1
  • 20: D2/GPIO25
  • 21: D3/GPIO15
  • 22: D4/GPIO26
  • 23: D5/GPIO17
  • 24: D6/GPIO18
  • 25: D7/GPIO19
  • 26: D8/GPIO20
  • 27: D9/GPIO21
  • 28: D10/GPIO5
  • 29: D11/GPIO7/COPI
  • 30: D12/GPIO4/CIPO

• Parts:
  • ABX00053: This part number corresponds to the Arduino Nano RP2040 Connect which is a small, powerful board based on the Raspberry Pi RP2040 microcontroller.

• Digi-Key:
  • Price: $30.60
  • Stock: 518
  • Life Cycle Status: Active
• LCSC:
  • Price: $33.78
  • Stock: 3
  • Life Cycle Status: N/A
• Arrow:
  • Price: $28.14
  • Stock: 269
  • Life Cycle Status: N/A
• Verical:
  • Price: $28.14–$53.716
  • Stock: 24–269
  • Life Cycle Status: N/A
• Mouser:
  • Price: $28.69
  • Stock: 1.3K
  • Life Cycle Status: N/A

• This project sets up the template for an Arduino Nano RP2040 Connect Board with its pin mapping defined.
• No connection or additional components are linked yet, meaning you will need to connect components like sensors, actuators, or other peripherals.

josepa22

copilot

• VCC: Conectar el VCC del HC-SR04 a $U1:2 +3V3$.
• GND: Conectar el GND del HC-SR04 a $U1:14 GND$.
• TRIG: Conectar el pin TRIG del HC-SR04 a $U1:20 D2/GPIO25$.
• ECHO: Conectar el pin ECHO del HC-SR04 a $U1:21 D3/GPIO15$.

• VCC: Conectar VCC del NRF24L01 a $U1:2 +3V3$.
• GND: Conectar GND del NRF24L01 a $U1:14 GND$.
• CE: Conectar CE del NRF24L01 a $U1:22 D4/GPIO26$.
• CSN: Conectar CSN del NRF24L01 a $U1:23 D5/GPIO17$.
• SCK: Conectar SCK del NRF24L01 a $U1:28 D10/GPIO5$.
• MOSI: Conectar MOSI del NRF24L01 a $U1:29 D11/GPIO7/COPI$.
• MISO: Conectar MISO del NRF24L01 a $U1:30 D12/GPIO4/CIPO$.

• VCC: Conectar VCC del módulo de relé al suministro de 12V.
• GND: Conectar GND del módulo de relé al GND del suministro de 12V.
• IN: Conectar IN del módulo de relé a $U1:24 D6/GPIO18$.

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1. Motor Connections:
   • Connect L293D:IN1 to U1:D2/GPIO25
   • Connect L293D:IN2 to U1:D4/GPIO26
   • Connect L293D:IN3 to U1:D6/GPIO18
   • Connect L293D:IN4 to U1:D7/GPIO19

2. VCC and GND Connections:
   • Connect L293D:VCC1 (logic supply voltage) to U1:+5V
   • Connect L293D:GND (all ground pins) to U1:GND
   • Connect L293D:VCC2 (motor supply voltage) to your Motor Power Supply: Positive
   • Connect your Motor Power Supply: Ground to U1:GND

3. IR Sensor Connections:
   • Connect IR Sensor:VCC to U1:+5V
   • Connect IR Sensor:GND to U1:GND
   • Connect IR Sensor:OUT1 to U1:A1/GPIO27
   • Connect IR Sensor:OUT2 to U1:A2/GPIO28
4. Motor Output Connections:
   • Connect L293D:OUT1 to Motor M1: Terminal1
   • Connect L293D:OUT2 to Motor M1: Terminal2
   • Connect L293D:OUT3 to Motor M2: Terminal1
   • Connect L293D:OUT4 to Motor M2: Terminal2

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• Project Title: Untitled Project
• Template: This project uses a template for the Arduino Nano RP2040 Connect Board.
• Keywords: #template, #project-template, #arduino, #rp2040

• Main Component: Arduino Nano RP2040 Connect
  • Designator: /handle/documentSlug
  • Manufacturer Part Number (MPN): ABX00053

1. D13/GPIO6
2. +3V3
3. AREF
4. A0/DAC0/GPIO26
5. A1/GPIO27
6. A2/GPIO28
7. A3/GPIO29
8. A4/GPIO12
9. A5/GPIO13
10. A6
11. A7
12. +5V
13. QSPI_$\sim$RESET
14. GND
15. VIN
16. TX
17. RX
18. $\sim$RESET
19. GND__1
20. D2/GPIO25
21. D3/GPIO15
22. D4/GPIO26
23. D5/GPIO17
24. D6/GPIO18
25. D7/GPIO19
26. D8/GPIO20
27. D9/GPIO21
28. D10/GPIO5
29. D11/GPIO7/COPI
30. D12/GPIO4/CIPO

• Manufacturer Name: Texas Instruments Inc.
• Available Distributors:
  • Digi-Key: $30.60, 518 in stock.
  • LCSC: $33.7804, 3 in stock.
  • Arrow: $28.14, 269 in stock.
  • Verical: $28.14–$53.716, 24–269 in stock.
  • Mouser: $28.69, 1.3K in stock.

• No electrical connections have been made in this project yet.

1. Define the components you want to connect to the Arduino Nano RP2040 Connect board.
2. Specify the connections by using the pin names and designators.
3. Ensure power sources and required peripherals are considered in your design.
4. Make any necessary assumptions for values and clarify them if needed.

copilot

• The project is a template for using the Arduino Nano RP2040 Connect Board.
• This includes setting up a basic schematic involving the Arduino Nano RP2040 Connect Board.

• No specific properties or requirements have been set beyond creating a template for the Arduino Nano RP2040 Connect Board.

• Designator: U1
• Manufacturer Part Number (MPN): ABX00053
• Manufacturer: Texas Instruments Inc.
• Pins:
  • 1: D13/GPIO6
  • 2: +3V3
  • 3: AREF
  • 4: A0/DAC0/GPIO26
  • 5: A1/GPIO27
  • 6: A2/GPIO28
  • 7: A3/GPIO29
  • 8: A4/GPIO12
  • 9: A5/GPIO13
  • 10: A6
  • 11: A7
  • 12: +5V
  • 13: QSPI_~RESET
  • 14: GND
  • 15: VIN
  • 16: TX
  • 17: RX
  • 18: ~RESET
  • 19: GND__1
  • 20: D2/GPIO25
  • 21: D3/GPIO15
  • 22: D4/GPIO26
  • 23: D5/GPIO17
  • 24: D6/GPIO18
  • 25: D7/GPIO19
  • 26: D8/GPIO20
  • 27: D9/GPIO21
  • 28: D10/GPIO5
  • 29: D11/GPIO7/COPI
  • 30: D12/GPIO4/CIPO

• Information regarding the price and stock availability of the Arduino Nano RP2040 Connect Board is provided for several distributors like Digi-Key, LCSC, Arrow, Verical, and Mouser.

• No electrical connections have been made for the component U1 yet.

copilot

1. First Project in Flux: Start by creating your first project in Flux. This is the most direct way to get hands-on experience. You can find guidance on this in the "First project in Flux" section of our help and tutorials[1].
2. Tutorials and Documentation: Dive into our tutorials for in-depth instructions on using Flux. These tutorials cover everything from basic operations to advanced functionalities. You'll also find detailed documentation on all elements of Flux[1].
3. YouTube Content: For visual learners, our YouTube channel offers a range of video tutorials, crash courses, and project examples to help you understand how to make the most of Flux[2].
4. Live Support and Community: If you have specific questions or need assistance, our Slack community is a great place to get support from both the Flux team and fellow users. For direct support from our team, you can also contact us via the "Contact us" option on our homepage[3].
5. Flux Navigator: For quick guidance and answers to specific questions about using the tool, you can use the Flux Navigator. Simply ask a question like "How do I change the stackup of my PCB?" and the Help Expert will guide you[4].

copilot

• Arduino Nano RP2040 Connect Board: This is your central component, with the designator U1 and the Manufacturer Part Number (MPN) ABX00053.

1. Power Pins
   • +3V3: Provides 3.3V power.
   • +5V: Provides 5V power.
   • VIN: Voltage Input, typically accepts 7-12V.
   • Ground (GND): There are multiple ground pins (at positions 14 and 19 on the pin list).
2. Digital Pins
   • These can function as GPIO pins and some have additional functionalities (e.g., PWM, UART, SPI).
3. Analog Pins
   • A0-A7: These pins can be used for analog input and some for digital.
4. Special Function Pins
   • QSPI_~RESET: For Quad SPI reset.
   • ~RESET: For resetting the board.

• Template Creation: This project seems to be focused on setting up a reusable template for the Arduino Nano RP2040 Connect board. Templates are useful because they provide a starting point for future projects, ensuring that the basic configuration of the board's pinout and connectivity is standardized.

1. Power Connections:
   • Connect the +3V3 pin to any components requiring 3.3V.
   • Connect the +5V pin if you have components that require 5V.
   • Ensure all ground connections are made to a common ground.
2. Basic I/O Setup:
   • Determine which digital and analog pins you plan on using.
   • Set up peripherals such as LEDs, switches, or sensors.
3. Communication Interfaces:
   • Configure UART, SPI, or I2C interfaces depending on which peripherals you plan to communicate with.

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1. Accessing Flux: First, ensure you have an internet connection and access Flux through your browser. Flux is a web-based electronics CAD program, so there's no need to install anything on your computer.
2. Creating a New Project: Once you're in Flux, you can start a new project by selecting the option to create a new schematic or PCB layout. This is usually found on the dashboard or menu.
3. Designing the Schematic:
   • Place components: Look for the 'Components' library to find all the electronic components you need. You can search or browse through categories.
   • Wire connections: Use the wiring tool to connect the pins of different components together according to your circuit design.
   • Define net properties: Assign names to different parts of your circuit (nets) for easier reference and troubleshooting.
4. Transitioning to PCB Layout:
   • Once your schematic is complete, you can transition to laying out the PCB.
   • Import your schematic: This should automatically populate your PCB workspace with the components you used in the schematic.
   • Place components on the PCB: Arrange the components on the board, considering optimal layout for functionality and manufacturability.
   • Route traces: Connect the components on the PCB by drawing traces that replicate the connections made in the schematic.
   • Define board layers and shapes: Adjust your PCB's size, shape, and the number of layers according to your project requirements.
5. Review and Export: Review your design thoroughly. Look for any errors or potential improvements. Once satisfied, you can export your design for manufacturing. Common formats include Gerber files for PCB manufacturing or a Bill of Materials (BOM) for component purchasing.

copilot

1. 16x2 LCD: This display communicates using either I2C, SPI, or parallel. If it's an I2C LCD, you'll connect SDA and SCL to the SDA and SCL pins on the Arduino (these often aren't labeled explicitly on the Nano, but they should correspond to A4/D18 and A5/D19 respectively). If it's an SPI or parallel LCD, you'll connect it to the SPI or digital IO pins on the Nano, respectively.
2. OLED Display: An OLED typically uses I2C or SPI as well. The connection process is similar to the 16x2 LCD above.
3. TFT LCD Touchscreen: The connection process for this type of display can vary depending on whether it's SPI or parallel. You will often end up connecting it to the SPI pins on your Nano (pins D11, D12, and D13), the ICSP header pins, or some digital IO pins for parallel displays. The touchscreen functions are typically connected to digital or analog IO.

darshansarode

copilot

1. Supply power to the MAX31865 chip by connecting VCC to +3V3 and GND to any GND pin on the Arduino board.
2. Connect the SPI interface: Clock (SCLK) to D13/GPIO6 (SPI Clock on Arduino Nano), DO (MISO) to D12/GPIO4/CIPO (SPI MISO on Arduino Nano), DI (MOSI) to D11/GPIO7/COPI (SPI MOSI on Arduino Nano), and CS to any digital IO pin on the Arduino, such as D8/GPIO20.
3. Connect the PT100 to the RTD+ and RTD- terminals on the MAX31865. A two-wire connection can introduce cable resistance into the measurement. For higher accuracy, you may want to use a three-wire or four-wire connection if your PT100 and MAX31865 support it.

• Connect U1:+3V3 to MAX31865:VCC
• Connect U1:GND to MAX31865:GND
• Connect U1:D13/GPIO6 to MAX31865:SCLK
• Connect U1:D12/GPIO4/CIPO to MAX31865:DO
• Connect U1:D11/GPIO7/COPI to MAX31865:DI
• Connect U1:D8/GPIO20 to MAX31865:CS
• Connect PT100:Wire1 to MAX31865:RTD+
• Connect PT100:Wire2 to MAX31865:RTD-

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• U1: Arduino Nano RP2040 Connect.
• Q1: 2SC3358 RF Transistor.
• R1, R2: Resistors (for biasing the 2SC3358).
• C1: Capacitor (for coupling the RF signal to the 2SC3358).
• D1: LED (as a simple display indicator for RF signal strength).
• R3: Current limiting resistor for D1.

• The 2SC3358's primary role is to amplify the detected RF signal.
• A simple indicator (D1) is used to show the presence of RF signal by turning on the LED.
• For more advanced RF meter functionality like measurable strength indication, additional components and a more complex setup would be needed.

1. RF Detection and Amplification:
   • Connect Q1's collector to U1:3.3V through R1.
   • Connect Q1's base to the RF source through C1.
   • Connect Q1's emitter to U1:GND through R2.
2. Signal Indicator:
   • Connect D1's anode to U1's one of the GPIO pins (e.g., D13/GPIO6) through R3 to limit the current.
   • Connect D1's cathode to U1:GND.

1. RF Detection Circuit using 2SC3358:
   • Assuming R1 = 10K$\Omega$ and R2 = 1K$\Omega$, Connect Q1's base through C1 (0.1µF) to the RF signal source.
   • Connect Q1's emitter to U1:GND through R2.
   • Connect Q1's collector to U1:+3.3V through R1.
2. LED Indicator:
   • Assuming R3 = 330$\Omega$ for a 3.3V supply, Connect D1's anode to U1:D13/GPIO6 through R3.
   • Connect D1's cathode to U1:GND.

• Write a simple Arduino code to turn on D1 when a certain threshold is detected by the 2SC3358.

Cpp
void setup() {
  pinMode(6, OUTPUT); // Assuming D13/GPIO6 is on pin number 6
}

void loop() {
  // Simple example logic to turn on the LED
  // This would need to be adapted based on how you're detecting RF signal strength
  digitalWrite(6, HIGH);
  delay(1000); // Keep LED on for 1 second
  digitalWrite(6, LOW);
  delay(1000); // LED off for 1 second
}

• For a more sophisticated RF strength meter, consider using an analog input on the Arduino to measure the amplified RF signal strength and adjust the display accordingly.
• Ensure the components (especially the 2SC3358 and the display mechanism) are correctly rated and compatible with the voltage levels supplied by the Arduino Nano RP2040 Connect.

clarettetan694728

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• Designator: U2
• MPN: MPU-6050
• Pins:
  • $1 (VCC)$
  • $2 (GND)$
  • $3 (SCL)$
  • $4 (SDA)$
  • $5 (XDA)$
  • $6 (XCL)$
  • $7 (ADO)$
  • $8 (INT)$

• The MPU-6050 will use the Arduino Nano RP2040 Connect's I2C bus for communication.
• ADO on the MPU-6050 will be connected to ground to set the I2C address to $0x68$.
• The INT pin will not be used in this setup.

1. Powering the MPU-6050
   • Connect $U2:1 (VCC)$ to $U1:2 (+3V3)$. This powers the MPU-6050 with 3.3V from the Arduino Nano RP2040 Connect.
   • Connect $U2:2 (GND)$ to $U1:14 (GND)$. This establishes a common ground.
2. I2C Communication
   • Connect $U2:3 (SCL)$ to $U1:8 (A4/GPIO12)$. A4 serves as the I2C clock line (SCL) on the Nano RP2040 Connect.
   • Connect $U2:4 (SDA)$ to $U1:9 (A5/GPIO13)$. A5 serves as the I2C data line (SDA) on the Nano RP2040 Connect.
3. Set the I2C Address for MPU-6050
   • Connect $U2:7 (ADO)$ to $U1:14 (GND)$. This sets the I2C address of the MPU-6050 to $0x68$ by grounding it.

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• Board Name: Arduino Nano RP2040 Connect
• Manufacturer Part Number: ABX00053
• Price and Availability: The board is available from several distributors such as Digi-Key, LCSC, Arrow, Verical, and Mouser.

1. GPIO (General Purpose Input/Output):
   • Pins like D13 ($\text{GPIO6}$), D2 ($\text{GPIO25}$), and others.
2. Power Supply Pins:
   • $+3V3$ (3.3V output), $+5V$, VIN (input voltage), GND (ground).
3. Analog Pins:
   • $A0/DAC0$ ($\text{GPIO26}$), $A1$ ($\text{GPIO27}$), etc.
4. Communication Pins:
   • TX, RX for serial communication.
   • D11 ($\text{GPIO7/COPI}$ - Controller Out Peripheral In), D12 ($\text{GPIO4/CIPO}$ - Controller In Peripheral Out) for SPI interfaces.
5. Special Function Pins:
   • $\text{RESET}$, $QSPI_\text{RESET}$ (used for Quad SPI reset).

• Designator: U1 (indicating this is the main microcontroller unit in the schematic).
• Designator Prefix: U

• No electrical connections have been made yet in the project.

• Prototyping IoT devices.
• Creating sensor interfaces.
• Developing embedded systems requiring Wi-Fi/Bluetooth connectivity.
• Learning or teaching purposes in electronics or microcontroller programming.