ESP32-S3_Arduino-Uno/index.md

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title: "ESP32-S3 Uno Development Board"
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<i>Explore new frontiers the ESP32-S3 UNO Development Board.</i>
<p>Unlock a world of innovative possibilities with the ESP32-S3 UNO Development Board. With this versatile development board you may create cutting-edge IoT devices, leveraging the advanced features and robust performance of ESP32-S3 WROOM module. Whether you're working on IoT projects, embedded systems, or projects, the ESP32-S3 UNO Development Board offers the flexibility, power and quick implementation needed to bring your ideas to life.</p>

<img src="assets/ESP32-Uno-assembled.jpg" width="35%"/>

<a href="https://github.com/alexandrebobkov/ESP32-S3_Arduino-Uno/blob/9575373f9068746664d09406c00251d1236720c5/assets/ESP32-S3_Arduino-Schematic_v5.2.pdf">Schematic PDF</a>

[Troubleshooting Steps](troubleshooting.md)

## Compatibility with MicroPython

Integrating the ESP32-S3 UNO Development Board with MicroPython offers several compelling benefits:

1. __Ease of Use:__
MicroPython simplifies the development process by allowing developers to write code in Python, a high-level, easy-to-read programming language. This reduces the learning curve for beginners and accelerates development for experienced programmers.

2. __Rapid Prototyping:__
With MicroPython, developers can quickly prototype and test their ideas. The interactive REPL (Read-Eval-Print Loop) enables immediate feedback and debugging, making it easier to iterate and refine projects.

3. __Extensive Libraries:__
MicroPython comes with a rich set of libraries that support various functionalities, including networking, sensor interfacing, and data processing. This extensive library support allows developers to leverage pre-built modules and focus on the unique aspects of their projects.

4. __Cross-Platform Compatibility:__
MicroPython code can be easily ported across different hardware platforms that support MicroPython. This cross-platform compatibility ensures that projects developed on the ESP32-S3 UNO can be adapted to other MicroPython-compatible boards with minimal changes.

5. __Community Support:__
The MicroPython community is active and growing, providing a wealth of resources, tutorials, and forums for troubleshooting and collaboration. This community support can be invaluable for both novice and experienced developers.

6. __Efficient Resource Management:__
MicroPython is designed to run efficiently on microcontrollers, making it well-suited for resource-constrained environments. It allows developers to manage memory and processing power effectively, ensuring optimal performance of their applications.

7. __Enhanced Connectivity:__
The ESP32-S3 UNO Development Board offers robust connectivity options, including Wi-Fi and Bluetooth. MicroPython's networking libraries make it straightforward to implement IoT applications, enabling seamless communication between devices.

8. __Versatility:__
Combining the ESP32-S3 UNO with MicroPython opens up a wide range of applications, from simple sensor monitoring to complex automation systems. The versatility of this fusion allows developers to explore diverse project ideas and innovate freely.

9. __Educational Value:__
MicroPython's simplicity and the ESP32-S3 UNO's capabilities make this combination an excellent educational tool. It provides a practical platform for learning programming, electronics, and IoT concepts, fostering a deeper understanding of technology.

10. __Cost-Effective Development:__
Both the ESP32-S3 UNO Development Board and MicroPython are cost-effective solutions, making them accessible to hobbyists, educators, and professionals alike. This affordability encourages experimentation and innovation without significant financial investment.


## Features and Specifications of the ESP32-S3 WROOM Module
__Core Components:__
  - Microprocessor: Xtensa® dual-core 32-bit LX7 microprocessor, operating up to 240 MHz.
  - Memory:
    - 384 KB ROM
    - 512 KB SRAM
    - 16 KB SRAM in RTC
    - Up to 16 MB PSRAM

__Connectivity:__
  - Wi-Fi:
    - 802.11b/g/n, up to 150 Mbps (802.11n), frequency range: 2412 ~ 2484 MHz
    - Features: A-MPDU and A-MSDU aggregation, 0.4 μs guard interval support
  - Bluetooth:
    - Bluetooth 5, Bluetooth mesh, 125 Kbps, 500 Kbps, 1 Mbps, 2 Mbps
    - Features: Advertising extensions, multiple advertisement sets, channel selection algorithm #2
  - Co-existence mechanism: Internal co-existence mechanism between Wi-Fi and Bluetooth to share the same antenna

__Peripherals:__
  - GPIOs: Up to 36 GPIOs, including 4 strapping GPIOs
  - Interfaces:
    - SPI
    - LCD interface
    - Camera interface
    - __UART__
    - __I2C__
    - __I2S__
    - Remote control
    - __Pulse counter__
    - __LED PWM__
    - Full-speed USB 2.0 OTG
    - USB Serial/JTAG controller
    - __MCPWM__
    - SDIO host controller
    - GDMA
    - TWAI® controller (compatible with ISO 11898-1)
    - ADC
    - Touch sensor
    - Temperature sensor
    - Timers and watchdogs

__Integrated Components:__
  - Crystal Oscillator: 40 MHz
  - Flash: Up to 16 MB Quad SPI flash
  - Antenna: on-board PCB antenna

__Operating Conditions:__
  - Operating Voltage: 3.0 ~ 3.6 V
  - Ambient Temperature: –40 ~ 65 °C

__Certifications:__
RF Certification: Various certifications available
Green Certification: RoHS/REACH compliant

__Applications:__
Ideal for AI and Artificial Intelligence of Things (AIoT) applications such as:
Wake word detection
Speech commands recognition
Face detection and recognition
Smart home devices
Smart appliances
Smart control panels
Smart speakers

## I2C Pins

The schematic excerpt provided below illustrates the wiring configuration for the __SDA__ and __SCL__ lines. Specifically, the __SDA__ line is connected to _GPIO 8_, while the __SCL__ line is connected to _GPIO 9_ on the ESP32-S3 module.

<img src="assets/ESP32-Uno-Board-Module-Pinout.png" width="50%"/>

The image of the PCB board below depicts the physical locations of the __SDA__ and __SCL__ terminals.
<img src="assets/ESP32-Uno-Board-GPIO.png" width="50%"/>

### Micropython LED Blinky Code

``` python
import esp, esp32, time, os, _thread
from machine import Pin, SoftI2C

# An infinite loop thread to blink LED
def status_led():
    # Blink pattern blink-blink-pause
    while True:
        led.value(1)
        time.sleep_ms(250)
        led.value(0)
        time.sleep_ms(250)
        led.value(1)
        time.sleep_ms(250)
        led.value(0)
        time.sleep_ms(750)

# Display information about ESP32S3 module
print(os.uname())
print("Flash size: ", esp.flash_size()/1024/1024, "Mb")
#rint("MCU Temperature: ", esp32.mcu_temperature(), "C")
print("MCU Temperature: {:4.1f} C".format(esp32.mcu_temperature()))

# Configure LED pin and start the blinky loop thread
led = Pin(45, Pin.OUT)
led.value(0)
_thread.start_new_thread(status_led, ())
```