Integrate sensors, drivers, and other components into your project setup without hassle
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Hardware Overview
How does it work?
Adapter Click represents an adapter board that simplifies the connection of add-ons with IDC10 headers to the mikroBUS™ socket. One 2x5-position 2.54mm pitch header allows you to add sensors, drivers, and various components in a way that suits your project needs. Each header pin corresponds to a pin on the mikroBUS™ socket (except AN and RST pins). Thanks to these pins, the connection with the Click board™ remains firm and stable, always retaining a perfect connection quality. There are two ways to establish such a connection: male or female IDC10 connectors. Both
are provided with the package. You may solder the male IDC10 header on the top side of the Adapter Click and connect the add-on board directly or via IDC10 flat cable. In some cases, a female header socket is a better choice. Solder it either on the top or the bottom side, depending on which is more convenient in given circumstances. Adapter Click allows using both I2C and SPI interfaces, where each mikroBUS™ line is covered, except, as mentioned before, AN and RST lines. The selection can be made by positioning jumpers labeled as INTERFACE SELECTION in an appropriate
position marked as SPI or I2C. Note that all the jumpers' positions must be on the same side, or the Click board™ may become unresponsive. This Click board™ can operate with both 3.3V and 5V logic voltage levels selected via the PWR SEL jumper. This way, it is allowed for both 3.3V and 5V capable MCUs to use the communication lines properly. Also, this Click board™ comes equipped with a library containing easy-to-use functions and an example code that can be used as a reference for further development.
Features overview
Development board
Fusion for TIVA v8 is a development board specially designed for the needs of rapid development of embedded applications. It supports a wide range of microcontrollers, such as different 32-bit ARM® Cortex®-M based MCUs from Texas Instruments, regardless of their number of pins, and a broad set of unique functions, such as the first-ever embedded debugger/programmer over a WiFi network. The development board is well organized and designed so that the end-user has all the necessary elements, such as switches, buttons, indicators, connectors, and others, in one place. Thanks to innovative manufacturing technology, Fusion for TIVA v8 provides a fluid and immersive working experience, allowing access
anywhere and under any circumstances at any time. Each part of the Fusion for TIVA v8 development board contains the components necessary for the most efficient operation of the same board. An advanced integrated CODEGRIP programmer/debugger module offers many valuable programming/debugging options, including support for JTAG, SWD, and SWO Trace (Single Wire Output)), and seamless integration with the Mikroe software environment. Besides, it also includes a clean and regulated power supply module for the development board. It can use a wide range of external power sources, including a battery, an external 12V power supply, and a power source via the USB Type-C (USB-C) connector.
Communication options such as USB-UART, USB HOST/DEVICE, CAN (on the MCU card, if supported), and Ethernet is also included. In addition, it also has the well-established mikroBUS™ standard, a standardized socket for the MCU card (SiBRAIN standard), and two display options for the TFT board line of products and character-based LCD. Fusion for TIVA v8 is an integral part of the Mikroe ecosystem for rapid development. Natively supported by Mikroe software tools, it covers many aspects of prototyping and development thanks to a considerable number of different Click boards™ (over a thousand boards), the number of which is growing every day.
Microcontroller Overview
MCU Card / MCU
Type
8th Generation
Architecture
ARM Cortex-M4
MCU Memory (KB)
512
Silicon Vendor
Texas Instruments
Pin count
212
RAM (Bytes)
262144
Used MCU Pins
mikroBUS™ mapper
Take a closer look
Schematic
Step by step
Project assembly
Track your results in real time
Application Output via UART Mode
1. Once the code example is loaded, pressing the "FLASH" button initiates the build process, and programs it on the created setup.
2. After the programming is completed, click on the Tools icon in the upper-right panel, and select the UART Terminal.
3. After opening the UART Terminal tab, first check the baud rate setting in the Options menu (default is 115200). If this parameter is correct, activate the terminal by clicking the "CONNECT" button.
4. Now terminal status changes from Disconnected to Connected in green, and the data is displayed in the Received data field.
Software Support
Library Description
This library contains API for Adapter Click driver.
Key functions:
adapter_generic_write
- This function writes data to the desired register.adapter_generic_read
- This function reads data from the desired register.
Open Source
Code example
This example can be found in NECTO Studio. Feel free to download the code, or you can copy the code below.
/*!
* \file
* \brief Adapter Click example
*
* # Description
* Adapter click is a breakout board which simplifies connection of add-on boards.
* There are two ways of establishing connection: using male or female IDC10 connectors.
* Male header must be soldered on the top side of Adapter Click to connect the add-on board
* directly or via flat cable. Female header can be soldered either on the top, or the bottom
* side, depending on which one is more convenient in given circumstances.
* There are two jumpers for SPI/I2C selection and one for selection of power supply range.
*
* The demo application is composed of two sections :
*
* ## Application Init
* Initalizes I2C or SPI driver and makes an initial log.
*
* ## Application Task
* This is an example that shows the use of the Adapter click board (SPI mode - set as default).
* In I2C mode we are reading internal temperature from another device (THERMO 5 click board).
* In SPI mode example we are writing "mikroElektronika" to SRAM click board,
* and then reading from the same memory location.
*
* ## Additional Functions
* - float thermo5_read_inter_temp ( adapter_t *ctx ) -
* @description Function reads measurements made by internal diode.
* - void sram_write_byte ( adapter_t *ctx, uint32_t reg_address, uint8_t write_data ) -
* @description Function writes the 8-bit data to the target 24-bit register address of 23LC1024 chip.
* - uint8_t sram_read_byte ( adapter_t *ctx, uint32_t reg_address ) -
* @description Function reads the 8-bit data to the target 24-bit register address of 23LC1024 chip.
*
* \author MikroE Team
*
*/
// ------------------------------------------------------------------- INCLUDES
#include "board.h"
#include "log.h"
#include "adapter.h"
#define THERMO5_INTER_DIO_DATA_HI_BYTE 0x00
#define THERMO5_INTER_DIO_DATA_LO_BYTE 0x29
#define SRAM_24BIT_DATA 0x00FFFFFF
#define SRAM_CMD_WRITE 0x02
#define SRAM_CMD_READ 0x03
// ------------------------------------------------------------------ VARIABLES
static adapter_t adapter;
static log_t logger;
char send_buffer[ 17 ] = { 'm', 'i', 'k', 'r', 'o', 'E', 'l', 'e', 'k', 't', 'r', 'o', 'n', 'i', 'k', 'a', ' ' };
char mem_data[ 17 ];
uint8_t n_cnt;
// ------------------------------------------------------ ADDITIONAL FUNCTIONS
float thermo5_read_inter_temp ( adapter_t *ctx )
{
uint16_t inter_temp;
uint8_t high_byte;
uint8_t low_byte;
float output;
output = 0.0;
adapter_generic_read ( ctx, THERMO5_INTER_DIO_DATA_HI_BYTE, &high_byte, 1 );
adapter_generic_read ( ctx, THERMO5_INTER_DIO_DATA_LO_BYTE, &low_byte, 1 );
inter_temp = high_byte;
inter_temp <<= 8;
inter_temp |= low_byte;
inter_temp >>= 5;
output = ( float )inter_temp;
output *= 0.125;
return output;
}
void sram_write_byte ( adapter_t *ctx, uint32_t reg_address, uint8_t write_data )
{
uint8_t tx_buf[ 4 ];
uint8_t rx_buf;
reg_address &= SRAM_24BIT_DATA;
tx_buf[ 0 ] = ( uint8_t ) ( reg_address >> 16 );
tx_buf[ 1 ] = ( uint8_t ) ( reg_address >> 8 );
tx_buf[ 2 ] = ( uint8_t ) reg_address;
tx_buf[ 3 ] = write_data;
adapter_generic_write( ctx, SRAM_CMD_WRITE, tx_buf, 4 );
}
uint8_t sram_read_byte ( adapter_t *ctx, uint32_t reg_address )
{
uint8_t tx_buf[ 5 ];
uint8_t rx_buf[ 5 ];
uint8_t read_data;
reg_address &= SRAM_24BIT_DATA;
tx_buf[ 0 ] = SRAM_CMD_READ;
tx_buf[ 1 ] = ( uint8_t ) ( reg_address >> 16 );
tx_buf[ 2 ] = ( uint8_t ) ( reg_address >> 8 );
tx_buf[ 3 ] = ( uint8_t ) reg_address;
adapter_generic_transfer( ctx, tx_buf, 4, rx_buf, 1 );
read_data = rx_buf[ 0 ];
return read_data;
}
// ------------------------------------------------------ APPLICATION FUNCTIONS
void application_init ( void )
{
log_cfg_t log_cfg;
adapter_cfg_t cfg;
/**
* Logger initialization.
* Default baud rate: 115200
* Default log level: LOG_LEVEL_DEBUG
* @note If USB_UART_RX and USB_UART_TX
* are defined as HAL_PIN_NC, you will
* need to define them manually for log to work.
* See @b LOG_MAP_USB_UART macro definition for detailed explanation.
*/
LOG_MAP_USB_UART( log_cfg );
log_init( &logger, &log_cfg );
log_info( &logger, "---- Application Init ----" );
// Click initialization.
adapter_cfg_setup( &cfg );
ADAPTER_MAP_MIKROBUS( cfg, MIKROBUS_1 );
adapter_init( &adapter, &cfg );
}
void application_task ( void )
{
float temp_value;
if ( adapter.master_sel == ADAPTER_MASTER_SPI )
{
log_printf( &logger, " Writing text :\r\n" );
for ( n_cnt = 0; n_cnt < 16; n_cnt++ )
{
sram_write_byte( &adapter, n_cnt, send_buffer[ n_cnt ] );
Delay_ms ( 100 );
log_printf( &logger, "%c", send_buffer[ n_cnt ] );
}
log_printf( &logger, "\r\n" );
log_printf( &logger, " Read text :\r\n" );
for ( n_cnt = 0; n_cnt < 16; n_cnt++ )
{
mem_data[ n_cnt ] = sram_read_byte( &adapter, n_cnt );
Delay_ms ( 100 );
log_printf( &logger, "%c", mem_data[ n_cnt ] );
}
log_printf( &logger, "\r\n" );
log_printf( &logger, "--------------------------\r\n" );
Delay_ms ( 1000 );
}
else if ( adapter.master_sel == ADAPTER_MASTER_I2C )
{
temp_value = thermo5_read_inter_temp( &adapter );
log_printf( &logger, " Thermo 5 internal temperature : %.2f\r\n", temp_value );
log_printf( &logger, "--------------------------\r\n" );
Delay_ms( 2000 );
}
}
void main ( void )
{
application_init( );
for ( ; ; )
{
application_task( );
}
}
// ------------------------------------------------------------------------ END