The ESP32 ArduinoCore interface for Wi-Fi provides a straightforward and flexible way to enable Wi-Fi connectivity in projects developed using the ESP32 microcontroller platform with the Arduino IDE. With this interface, developers can easily incorporate Wi-Fi functionality into their projects, enabling devices to connect to wireless networks, access the internet, and communicate with other devices over Wi-Fi.
Features and Capabilities
- Access Point (AP) Mode: The ESP32 can act as an access point, allowing other devices to connect to it and access resources or services hosted by the ESP32.
- Station (STA) Mode: The ESP32 can connect to existing Wi-Fi networks as a client, enabling devices to access the internet or communicate with other networked devices.
- Soft Access Point (SoftAP) Mode: This mode enables the ESP32 to simultaneously act as both an access point and a station, allowing it to connect to an existing Wi-Fi network while also providing Wi-Fi access to other devices.
- Wi-Fi Protected Setup (WPS): The ESP32 supports WPS, a method for easily configuring Wi-Fi network security settings without needing to enter a password manually.
- Advanced Configuration Options: The interface provides access to advanced configuration options for fine-tuning Wi-Fi settings, such as specifying static IP addresses, setting up captive portals, and configuring Wi-Fi sleep modes to optimize power consumption.
- Event Handling: Developers can implement event handlers to respond to Wi-Fi-related events, such as successful connections, disconnections, or errors, allowing for more robust and responsive Wi-Fi functionality.
- Security Features: The ESP32 ArduinoCore interface supports various Wi-Fi security protocols, including WPA and WPA2, to ensure secure communication over Wi-Fi networks.
Overall, the ESP32 ArduinoCore interface for Wi-Fi simplifies the process of adding Wi-Fi connectivity to ESP32-based projects, making it easier for developers to create IoT devices, home automation systems, and other wireless applications.
Scan WiFi
Note: You can use Arduino example code instead of the below code because both are the same (File > Example > WiFi> WiFiScan)
/* https://aruneworld.com/embedded/espressif/esp32
* Tested By : Arun(20170429)
* Example Name : AEW_WiFi_Scan.ino
* This sketch demonstrates how to scan WiFi networks.
* The API is almost the same as with the WiFi Shield library,
* the most obvious difference being the different file you need to include:
*/
#include "WiFi.h"
void setup()
{
Serial.begin(115200);
// Set WiFi to station mode and disconnect from an AP if it was previously connected
WiFi.mode(WIFI_STA);
WiFi.disconnect();
delay(100);
Serial.println("Setup done");
}
void loop()
{
Serial.println("scan start");
// WiFi.scanNetworks will return the number of networks found
int n = WiFi.scanNetworks();
Serial.println("scan done");
if (n == 0) {
Serial.println("no networks found");
} else {
Serial.print(n);
Serial.println(" networks found");
for (int i = 0; i < n; ++i) {
// Print SSID and RSSI for each network found
Serial.print(i + 1);
Serial.print(": ");
Serial.print(WiFi.SSID(i));
Serial.print(" (");
Serial.print(WiFi.RSSI(i));
Serial.print(")");
Serial.println((WiFi.encryptionType(i) == WIFI_AUTH_OPEN)?" ":"*");
delay(10);
}
}
Serial.println("");
// Wait a bit before scanning again
delay(5000);
}
Serial Terminal Output
scan start
scan done
5 networks found
1: ArunEworld (-34)*
2: Exuber_365 (-59)*
3: Bangalore Police (-66)*
4: Tagos-2.4 (-80)*
5: RRL_Internet (-93)*
Code Explanation
Certainly! Here’s the code with explanations provided as snippets:
#include "WiFi.h"
This line includes the WiFi library necessary for working with WiFi on the ESP32.
void setup()
{
Serial.begin(115200);
WiFi.mode(WIFI_STA);
WiFi.disconnect();
delay(100);
Serial.println("Setup done");
}
In the setup()
function:
- The code initializes serial communication at a baud rate of 115200.
- The WiFi mode is set to station mode (
WIFI_STA
) and any previous connection is disconnected using WiFi.disconnect()
.
- The code adds a delay of 100 milliseconds.
- The code prints “Setup done” to the serial monitor.
void loop()
{
Serial.println("scan start");
int n = WiFi.scanNetworks();
Serial.println("scan done");
if (n == 0) {
Serial.println("no networks found");
} else {
Serial.print(n);
Serial.println(" networks found");
for (int i = 0; i < n; ++i) {
Serial.print(i + 1);
Serial.print(": ");
Serial.print(WiFi.SSID(i));
Serial.print(" (");
Serial.print(WiFi.RSSI(i));
Serial.print(")");
Serial.println((WiFi.encryptionType(i) == WIFI_AUTH_OPEN)?" ":"*");
delay(10);
}
}
Serial.println("");
delay(5000);
}
In the loop()
function:
- The code begins by printing “scan start” to the serial monitor.
- Next, the ESP32 scans for nearby WiFi networks using the
WiFi.scanNetworks()
function, storing the number of networks found in variable n
.
- After completing the scan, the code prints “scan done” to the serial monitor.
- The code prints the number of networks found when it detects networks, followed by details of each network, including index, SSID (network name), RSSI (signal strength), and encryption type.
- If no networks are found (when
n == 0
), the message “no networks found” is printed.
- When networks are found, the code prints the number of networks found, followed by details of each network, including index, SSID (network name), RSSI (signal strength), and encryption type.
- Finally, the code adds a delay of 5 seconds before initiating the next scan.
These snippets provide an overview of how the code initializes WiFi and continuously scans for nearby networks, printing details to the serial monitor.
Hits (since 2024-Jan-26) - 366
You must be logged in to post a comment.