WiFi ESP Click-Platine
WiFi ESP Click-Platine
Overview
Das WiFi ESP Click Board™ verfügt über das ESP-WROOM-02-Modul, das auf dem ESP8266EX basiert.
Das WiFi ESP Click Board™ ist für den Betrieb mit einer 3,3-V-Stromversorgung ausgelegt. Es kommuniziert mit dem Zielmikrocontroller über die UART-Schnittstelle und die folgenden MikroBUS-Signale: RST, CS.
The WiFi ESP Click Board™ carries the ESP-WROOM-02 module that integrates ESP8266EX. The click is designed to run on a 3.3V power supply. It communicates with the target microcontroller over UART interface and the following pins on the mikroBUS™ line: RST, CS.
ACCESS POINT AND WIFI CLIENT MODE
WiFi ESP click can function in both AP (Access Point) WiFi mode, as well as in WiFi client mode. The click brings easy implementation and usage.
The module supports the following network protocols: IPv4/TCP/UDP/HTTP/FTP. Thanks to this the click can operate as a client device requesting a file from a file server device (FTP - file transfer protocol) in local network systems, or request a web page via internet (IP/TCP/HTTP). It can also be used as a small web server, for example a wireless weather station prototype, etc.
Station mode is default when the click is in WiFi client mode.
ESP-WROOM-02 MODULE FEATURES
ESP-WROOM-02 carries ESP8266EX highly integrated Wi-Fi SoC solution to meet the continuous demands for efficient power usage, compact design and reliable performance in the industry.
Besides the Wi-Fi functionalities, ESP8266EX integrates an enhanced version of Tensilica's L106 Diamond series 32-bit processor and on-chip SRAM. As well as antenna switches, RF balun, power amplifier, low noise receiver amplifier, filters and power management modules.
With the complete and self-contained Wi-Fi networking capabilities, it can perform as either a standalone application (WROOM module itself) or the slave to an MCU host which is the primary intention of the click board as a whole. So, this click board is applied to any microcontroller design as a Wi-Fi adaptor through UART interface (RX,TX lines on mikroBUS pin socket).
For more information see the datasheet.
ADVANCED USAGE
There are additional pad headers onboard (HSPI/GPIO interface of the module) for advanced usage.
For more information see the Documentation tab.
SPECIFICATIONS
Type | WiFi |
Applications | Create smart appliances, home automation systems, wireless data loggers, etc |
On-board modules | ESP-WROOM-02 carries ESP8266EX highly integrated Wi-Fi SoC |
Key Features | Protocols: IPv4, TCP/UDP/HTTP/FTP, 802.11 b/g/n standard, UART interface, 3.3V power supply |
Interface | GPIO,UART |
Compatibility | mikroBUS |
Click board size | M (42.9 x 25.4 mm) |
Input Voltage | 3.3V |
PINOUT DIAGRAM
This table shows how the pinout of the WiFi ESP Click Board™ corresponds to the pinout on the mikroBUS™ socket (the latter shown in the two middle columns).
Notes | Pin | Pin | Notes | ||||
---|---|---|---|---|---|---|---|
NC | 1 | AN | PWM | 16 | NC | ||
HW Reset | RST | 2 | RST | INT | 15 | NC | |
Chip enable (active high) | EN | 3 | CS | TX | 14 | TX | UART0_TXD / Transmit end in UART download (program) mode |
NC | 4 | SCK | RX | 13 | RX | UART0_RXD / Receive end in UART download (program) mode | |
NC | 5 | MISO | SCL | 12 | NC | ||
NC | 6 | MOSI | SDA | 11 | NC | ||
Power supply | +3.3V | 7 | 3.3V | 5V | 10 | NC | |
Ground | GND | 8 | GND | GND | 9 | GND | Ground |
ADDITIONAL PINS
Name | I/O | Description |
---|---|---|
CLK | IO | HSPI_CLK / GPIO14 |
SDO | IO | HSPI_MISO / GPIO12 |
SDI | IO | HSPI_MOSI / GPIO13 |
CS | IO | HSPI_CS / GPIO15 |
IO0 | IO | GPIO0 (UART download mode - pull down, Flash boot - pull up) |
GND | GND |
BUTTONS AND LEDS
Designator | Name | Type (LED, BUTTON…) | Description |
---|---|---|---|
LD1 | PWR | LED | Power Supply ON |
Software Support
Code examples for the , written for MikroElektronika hardware and compilers are available on Libstock.
CODE SNIPPET
This code snippet configures GPIO ports, initializes the display and prepares the WiFi module. In an endless loop, LED is enabled or disabled by a button, and that information is then sent to the server.
01 void main() { 02 03 // Initialize variables 04 length = 0; 05 state = 0; 06 response_rcvd = 0; 07 responseID = 0; 08 response = 0; 09 i = 0; 10 11 // GPIO Direction 12 GPIO_Digital_Input( &GPIOA_IDR, _GPIO_PINMASK_4 ); 13 GPIO_Digital_Output( &GPIOD_BASE, _GPIO_PINMASK_13 ); 14 GPIO_Digital_Output( &GPIOC_BASE, _GPIO_PINMASK_2 ); 15 GPIO_Digital_Output( &GPIOA_ODR, _GPIO_PINMASK_0 ); 16 17 // UART Initialization 18 UART3_Init_Advanced( 115200, _UART_8_BIT_DATA, 19 _UART_NOPARITY, 20 _UART_ONE_STOPBIT, 21 &_GPIO_MODULE_USART3_PD89); 22 23 // Enable Interrupts 24 RXNEIE_USART3_CR1_bit = 1; 25 NVIC_IntEnable( IVT_INT_USART3 ); 26 EnableInterrupts(); 27 28 display_init(); 29 30 // Initialize WiFI module 31 WiFi_Init(); 32 33 // Setting WiFi Mode - SoftAP + station mode 34 WiFI_Configure(); 35 36 state = 100; 37 i = 0; 38 39 TFT_Write_Text("Please connect to your STAIP...", 50, 100); 40 Delay_ms(20000); 41 WiFi3_Send(); 42 TFT_Write_Text("Entering button toggling loop.", 50, 150); 43 44 LED_switching = 1; 45 46 while( 1 ) 47 { 48 // detect logical one on PA4 pin 49 if (Button(&GPIOA_IDR, 4, 1, 1)) 50 { 51 oldstate_A4 = 1; 52 } 53 // detect logical one-to-zero transition on PA4 pin 54 if (oldstate_A4 && Button(&GPIOA_IDR, 4, 1, 0)) 55 { 56 if ( !strcmp(txt_state_A0, "OFF</p>" )) 57 { 58 strncpy( txt_state_A0, "ON </p>", 8 ); 59 GPIOA_ODR.B0 = 1; 60 } 61 else 62 { 63 strncpy( txt_state_A0, "OFF</p>", 8 ); 64 GPIOA_ODR.B0 = 0; 65 } 66 oldstate_A4 = 0; 67 A0_change = true; 68 WiFi3_Send(); 69 } 70 } 71 }
Software Support
Code examples for the , written for MikroElektronika hardware and compilers are available on Libstock.
CODE SNIPPET
This code snippet configures GPIO ports, initializes the display and prepares the WiFi module. In an endless loop, LED is enabled or disabled by a button, and that information is then sent to the server.
01 void main() { 02 03 // Initialize variables 04 length = 0; 05 state = 0; 06 response_rcvd = 0; 07 responseID = 0; 08 response = 0; 09 i = 0; 10 11 // GPIO Direction 12 GPIO_Digital_Input( &GPIOA_IDR, _GPIO_PINMASK_4 ); 13 GPIO_Digital_Output( &GPIOD_BASE, _GPIO_PINMASK_13 ); 14 GPIO_Digital_Output( &GPIOC_BASE, _GPIO_PINMASK_2 ); 15 GPIO_Digital_Output( &GPIOA_ODR, _GPIO_PINMASK_0 ); 16 17 // UART Initialization 18 UART3_Init_Advanced( 115200, _UART_8_BIT_DATA, 19 _UART_NOPARITY, 20 _UART_ONE_STOPBIT, 21 &_GPIO_MODULE_USART3_PD89); 22 23 // Enable Interrupts 24 RXNEIE_USART3_CR1_bit = 1; 25 NVIC_IntEnable( IVT_INT_USART3 ); 26 EnableInterrupts(); 27 28 display_init(); 29 30 // Initialize WiFI module 31 WiFi_Init(); 32 33 // Setting WiFi Mode - SoftAP + station mode 34 WiFI_Configure(); 35 36 state = 100; 37 i = 0; 38 39 TFT_Write_Text("Please connect to your STAIP...", 50, 100); 40 Delay_ms(20000); 41 WiFi3_Send(); 42 TFT_Write_Text("Entering button toggling loop.", 50, 150); 43 44 LED_switching = 1; 45 46 while( 1 ) 47 { 48 // detect logical one on PA4 pin 49 if (Button(&GPIOA_IDR, 4, 1, 1)) 50 { 51 oldstate_A4 = 1; 52 } 53 // detect logical one-to-zero transition on PA4 pin 54 if (oldstate_A4 && Button(&GPIOA_IDR, 4, 1, 0)) 55 { 56 if ( !strcmp(txt_state_A0, "OFF</p>" )) 57 { 58 strncpy( txt_state_A0, "ON </p>", 8 ); 59 GPIOA_ODR.B0 = 1; 60 } 61 else 62 { 63 strncpy( txt_state_A0, "OFF</p>", 8 ); 64 GPIOA_ODR.B0 = 0; 65 } 66 oldstate_A4 = 0; 67 A0_change = true; 68 WiFi3_Send(); 69 } 70 } 71 }
Frequently Asked Questions
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