使用453-00140R和PIC18F4455实现低功耗的远距离安全可靠数据传输

适用于868MHz物联网应用的超低功耗LoraWAN解决方案

已发布 9月 06, 2024

点击板

LR 11 Click - 868MHz

开发板

EasyPIC v8

编译器

NECTO Studio

微控制器单元

PIC18F4455

这是任何需要可靠、远距离且节能的868MHz无线通信应用的完美选择

硬件概览

它是如何工作的？

LR 11 Click - 868MHz 基于 Ezurio 的 453-00140R，这是一款超低功耗 LoRaWAN 模块，属于 Ezurio RM126x 系列，特别是 RM1261。该模块集成了 Silicon Labs 的 EFR32 系列系统芯片 (SoC) 和 Semtech 的 SX1261 射频芯片，提供了一个高效、低功耗、长距离的解决方案，用于开发广泛的 LoRaWAN™ 应用，并获得 LoRa 联盟的认证。该模块配备了内置的 MHF4 连接器、温度补偿晶体振荡器 (TCXO) 和 DC-DC 转换器，确保在各种环境中的可靠性能。453-00140R 支持 LoRaWAN 类别 A、B 和 C，提供安全、可扩展和双向通信。它具有广泛的监管区域支持，包括欧洲、英国、台湾、日本和印度，并拥有 FCC、ISED 和 AS/NZS 等认证，使其成为各种需要可靠长距离通信的用例的高效解决方案。除了 LoRaWAN 功能外，453-00140R 还具有 LoRa 点对点 (LoRa P2P) 功能，支持在两个 RM126x 模块之间创建私有的超长距离无线电网络。该功能支持单播和广播模式，每个网络可容纳多达 64 台设备。该模块设计为可在主机模式和无主机模式下操作。在主机模式下，它通过 AT 命令集进行编程，而在无主机模式

下，它使用其内置的 Cortex-M33 核心，具有 512kB 闪存和 32kB RAM。模块的主要特性还包括 863-870MHz 的频率范围（典型为 868MHz）、最大发射功率可达 14dBm，以及在开放空间中的通信范围可达 15 公里。此 Click board™ 是物联网设备、资产跟踪与控制、智能家居系统、公用或私有网络、灌溉与农业应用、工业自动化及任何长距离、依赖电池供电的传感器应用的理想选择。453-00140R 模块与主机 MCU 通过 UART 接口进行通信，使用标准的 UART RX 和 TX 引脚，以及硬件流控制引脚（CTS/RTS- Clear to Send/Ready to Send）以实现高效的数据传输。默认通信速度为 115200bps，允许通过 AT 命令进行数据交换。在 LR 11 Click 的底部，有一个额外的未填充接头，提供对调试和编程功能的全面支持。通过此接头，用户可以使用串行线调试接口（通过 SWD 接口引脚 SWDIO、SWCLK 和 SWO 提供）进行编程和调试。除了接口引脚外，该 Click board™ 还具有一个复位引脚/按钮 (RESET) 用于直接重置模块，以及一个 BOOT 按钮用于确定何时执行引导加载程序。复位后，引导加载程序开始执行。当

按下 BOOT 按钮时，引导加载程序通过 UART 执行固件更新。松开按钮时，引导加载程序停止执行并将控制权交给主应用固件。LR 11 Click 的一个特殊功能是额外的 mikroBUS™ 插座，它通过 UART、SPI 或 I2C 接口与板载的 453-00140R 模块通信，为外设（如传感器和 LCD）扩展了板子的功能。由于 453-00140R 的 GPIO PD02 和 PD03 引脚在多个信号之间共享（可用于所有三个接口），因此在选择通信模式时必须适当地配置它们。这可以通过位于外围 mikroBUS™ 插座部分的六个焊盘来实现，使得模块的 PD02 和 PD03 引脚可以设置为所需的接口。默认情况下，选择 SPI 通信，并连接 CIPO 和 COPI 引脚。如果需要其他接口，则需要切断这些走线（断开它们），然后焊接所需接口引脚（UART 或 I2C）的焊盘。此 Click board™ 拥有外围 mikroBUS™ 插座所需的两个 mikroBUS™ 电源轨，但仅使用 3.3V 电压作为 453-00140R 模块的主电源。在使用具有不同逻辑电平的 MCU 之前，必须执行适当的逻辑电压电平转换。它还配备了包含功能和示例代码的库，可作为进一步开发的参考。

LR 11 Click - 868MHz hardware overview image

功能概述

开发板

EasyPIC v8 是一款专为快速开发嵌入式应用的需求而特别设计的开发板。它支持许多高引脚计数的8位PIC微控制器，来自Microchip，无论它们的引脚数量如何，并且具有一系列独特功能，例如首次集成的调试器/程序员。开发板布局合理，设计周到，使得最终用户可以在一个地方找到所有必要的元素，如开关、按钮、指示灯、连接器等。得益于创新的制造技术，EasyPIC v8 提供了流畅而沉浸式的工作体验，允许在任何情况下、任何地方、任何时候都能访问。

EasyPIC v8 开发板的每个部分都包含了使同一板块运行最高效的必要组件。除了先进的集成CODEGRIP程序/调试模块，该模块提供许多有价值的编程/调试选项和与Mikroe软件环境的无缝集成外，该板还包括一个干净且调节过的开发板电源供应模块。它可以使用广泛的外部电源，包括电池、外部12V电源供应和通过USB Type-C（USB-C）连接器的电源。通信选项如USB-UART、USB DEVICE和CAN也包括在内，包括广受好评的mikroBUS™标准、两种显示选项（图形和

基于字符的LCD）和几种不同的DIP插座。这些插座覆盖了从最小的只有八个至四十个引脚的8位PIC MCU的广泛范围。EasyPIC v8 是Mikroe快速开发生态系统的一个组成部分。它由Mikroe软件工具原生支持，得益于大量不同的Click板™（超过一千块板），其数量每天都在增长，它涵盖了原型制作和开发的许多方面。

微控制器概述

MCU卡片 / MCU

建筑

PIC

MCU 内存 (KB)

硅供应商

Microchip

引脚数

RAM (字节)

2048

你完善了我！

配件

Sub-GHz FlexDIPOLE天线，特别是Ezurio 868/915 MHz型号，是一款紧凑且高度多功能的天线，设计用于在整个868和915 MHz ISM频段内提供强大且一致的性能。其小巧的尺寸与灵活的偶极天线技术相结合，使其成为LoRaWAN和其他Sub-GHz技术等苛刻应用的理想选择。该天线配备了MHF4L连接器选项，确保易于集成到各种系统中。此外，其背胶设计允许快速且简便的安装，在挑战性的实际环境中提供从863到928 MHz的可靠覆盖。

LR 11 Click - 868MHz accessories 1 image

使用的MCU引脚

mikroBUS™映射器

Reset / ID SEL

RE1

RST

UART CTS / ID COMM

RE0

SCK

MISO

MOSI

Power Supply

3.3V

Ground

GND

PWM

UART RTS

RB0

INT

UART TX

RC6

UART RX

RC7

SCL

SDA

Power Supply

Ground

GND

“仔细看看！”

Click board™ 原理图

LR 11 Click - 868MHz Schematic schematic

一步一步来

项目组装

EasyPIC v8 front image hardware assembly

从选择您的开发板和Click板™开始。以EasyPIC v8作为您的开发板开始。

GNSS2 Click front image hardware assembly

GNSS2 Click complete accessories setup image hardware assembly

EasyPIC v8 Access DIPMB 1 - upright/background hardware assembly

NECTO Compiler Selection Step Image hardware assembly

NECTO Output Selection Step Image hardware assembly

Necto DIP image step 7 hardware assembly

实时跟踪您的结果

应用程序输出

1. 应用程序输出 - 在调试模式下，“应用程序输出”窗口支持实时数据监控，直接提供执行结果的可视化。请按照提供的教程正确配置环境，以确保数据正确显示。

2. UART 终端 - 使用UART Terminal通过USB to UART converter监视数据传输，实现Click board™与开发系统之间的直接通信。请根据项目需求配置波特率和其他串行设置，以确保正常运行。有关分步设置说明，请参考提供的教程。

3. Plot 输出 - Plot功能提供了一种强大的方式来可视化实时传感器数据，使趋势分析、调试和多个数据点的对比变得更加直观。要正确设置，请按照提供的教程，其中包含使用Plot功能显示Click board™读数的分步示例。在代码中使用Plot功能时，请使用以下函数：plot(insert_graph_name, variable_name);。这是一个通用格式，用户需要将“insert_graph_name”替换为实际图表名称，并将“variable_name”替换为要显示的参数。

软件支持

库描述

该库包含 LR 11 Click - 868MHz 驱动程序的 API。

关键功能:

lr11868mhz_reset_device - 此函数通过切换复位引脚的逻辑状态来重置设备。
lr11868mhz_cmd_run - 此函数向 Click 模块发送指定的命令（带或不带参数）。
lr11868mhz_cmd_set - 此函数为 Click 模块的指定命令参数设置值。

开源

代码示例

完整的应用程序代码和一个现成的项目可以通过NECTO Studio包管理器直接安装到NECTO Studio。应用程序代码也可以在MIKROE的GitHub账户中找到。

/*!
 * @file main.c
 * @brief LR 11 868MHz Click Example.
 *
 * # Description
 * This example demonstrates the use of LR 11 868MHz click board by showing
 * the communication between two click boards configured in P2P network mode.
 *
 * The demo application is composed of two sections :
 *
 * ## Application Init
 * Initializes the driver and logger.
 *
 * ## Application Task
 * Application task is split in few stages:
 *  - LR11868MHZ_POWER_UP:
 * Powers up the device, performs a device factory reset and reads system information.
 *  - LR11868MHZ_CONFIG_EXAMPLE:
 * Configures device for the LoRa P2P network mode.
 *  - LR11868MHZ_EXAMPLE:
 * Performs a LoRa P2P example by exchanging messages with another LR 11 868MHz click board.
 * One device should be set to NODE_0_ADDRESS, and the other to NODE_1_ADDRESS.
 *
 * ## Additional Function
 * - static void lr11868mhz_clear_app_buf ( void )
 * - static void lr11868mhz_log_app_buf ( void )
 * - static err_t lr11868mhz_process ( lr11868mhz_t *ctx )
 * - static err_t lr11868mhz_read_response ( lr11868mhz_t *ctx, uint8_t *rsp )
 * - static err_t lr11868mhz_power_up ( lr11868mhz_t *ctx )
 * - static err_t lr11868mhz_config_example ( lr11868mhz_t *ctx )
 * - static err_t lr11868mhz_example ( lr11868mhz_t *ctx )
 *
 * @author Stefan Filipovic
 *
 */

#include "board.h"
#include "log.h"
#include "lr11868mhz.h"
#include "conversions.h"
#include "generic_pointer.h"

// Node address selection macros
#define NODE_0_ADDRESS      0
#define NODE_1_ADDRESS      1
#define NODE_ADDRESS        NODE_0_ADDRESS

// Text message for transmittion
#define DEMO_TEXT_MESSAGE   "MIKROE - LR 11 868MHz click board"

static lr11868mhz_t lr11868mhz;
static log_t logger;

// Application buffer size
#define APP_BUFFER_SIZE     600
#define PROCESS_BUFFER_SIZE 200

static uint8_t app_buf[ APP_BUFFER_SIZE ] = { 0 };
static int32_t app_buf_len = 0;

/**
 * @brief Example states.
 * @details Predefined enum values for application example state.
 */
typedef enum
{
    LR11868MHZ_POWER_UP = 1,
    LR11868MHZ_CONFIG_EXAMPLE,
    LR11868MHZ_EXAMPLE

} lr11868mhz_app_state_t;

static lr11868mhz_app_state_t app_state = LR11868MHZ_POWER_UP;

/**
 * @brief LR 11 868MHz clearing application buffer.
 * @details This function clears memory of application buffer and reset its length.
 * @note None.
 */
static void lr11868mhz_clear_app_buf ( void );

/**
 * @brief LR 11 868MHz log application buffer.
 * @details This function logs data from application buffer to USB UART.
 * @note None.
 */
static void lr11868mhz_log_app_buf ( void );

/**
 * @brief LR 11 868MHz data reading function.
 * @details This function reads data from device and concatenates data to application buffer. 
 * @param[in] ctx : Click context object.
 * See #lr11868mhz_t object definition for detailed explanation.
 * @return @li @c  0 - Read some data.
 *         @li @c -1 - Nothing is read.
 * See #err_t definition for detailed explanation.
 * @note None.
 */
static err_t lr11868mhz_process ( lr11868mhz_t *ctx );

/**
 * @brief LR 11 868MHz read response function.
 * @details This function waits for a response message, reads and displays it on the USB UART.
 * @param[in] ctx : Click context object.
 * See #lr11868mhz_t object definition for detailed explanation.
 * @param[in] rsp  Expected response.
 * @return @li @c  0 - OK response.
 *         @li @c -2 - Timeout error.
 *         @li @c -3 - Command error.
 * See #err_t definition for detailed explanation.
 * @note None.
 */
static err_t lr11868mhz_read_response ( lr11868mhz_t *ctx, uint8_t *rsp );

/**
 * @brief LR 11 868MHz power up function.
 * @details This function powers up the device, performs device factory reset and reads system information.
 * @param[in] ctx : Click context object.
 * See #lr11868mhz_t object definition for detailed explanation.
 * @return @li @c    0 - OK.
 *         @li @c != 0 - Read response error.
 * See #err_t definition for detailed explanation.
 * @note None.
 */
static err_t lr11868mhz_power_up ( lr11868mhz_t *ctx );

/**
 * @brief LR 11 868MHz config example function.
 * @details This function configures device for LoRa P2P example.
 * @param[in] ctx : Click context object.
 * See #lr11868mhz_t object definition for detailed explanation.
 * @return @li @c    0 - OK.
 *         @li @c != 0 - Read response error.
 * See #err_t definition for detailed explanation.
 * @note None.
 */
static err_t lr11868mhz_config_example ( lr11868mhz_t *ctx );

/**
 * @brief LR 11 868MHz example function.
 * @details This function performs a LoRa P2P example by exchanging messages with another LR 11 868MHz click board.
 * @param[in] ctx : Click context object.
 * See #lr11868mhz_t object definition for detailed explanation.
 * @return @li @c    0 - OK.
 *         @li @c != 0 - Read response error.
 * See #err_t definition for detailed explanation.
 * @note None.
 */
static err_t lr11868mhz_example ( lr11868mhz_t *ctx );

void application_init ( void ) 
{
    log_cfg_t log_cfg;  /**< Logger config object. */
    lr11868mhz_cfg_t lr11868mhz_cfg;  /**< Click config object. */

    /** 
     * 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.
    lr11868mhz_cfg_setup( &lr11868mhz_cfg );
    LR11868MHZ_MAP_MIKROBUS( lr11868mhz_cfg, MIKROBUS_1 );
    if ( UART_ERROR == lr11868mhz_init( &lr11868mhz, &lr11868mhz_cfg ) ) 
    {
        log_error( &logger, " Communication init." );
        for ( ; ; );
    }
    
    log_info( &logger, " Application Task " );

    app_state = LR11868MHZ_POWER_UP;
    log_printf( &logger, ">>> APP STATE - POWER UP <<<\r\n\n" );
}

void application_task ( void ) 
{
    switch ( app_state )
    {
        case LR11868MHZ_POWER_UP:
        {
            if ( LR11868MHZ_OK == lr11868mhz_power_up( &lr11868mhz ) )
            {
                app_state = LR11868MHZ_CONFIG_EXAMPLE;
                log_printf( &logger, ">>> APP STATE - CONFIG EXAMPLE <<<\r\n\n" );
            }
            break;
        }
        case LR11868MHZ_CONFIG_EXAMPLE:
        {
            if ( LR11868MHZ_OK == lr11868mhz_config_example( &lr11868mhz ) )
            {
                app_state = LR11868MHZ_EXAMPLE;
                log_printf( &logger, ">>> APP STATE - EXAMPLE <<<\r\n\n" );
            }
            break;
        }
        case LR11868MHZ_EXAMPLE:
        {
            lr11868mhz_example( &lr11868mhz );
            break;
        }
        default:
        {
            log_error( &logger, " APP STATE." );
            break;
        }
    }
}

int main ( void ) 
{
    /* Do not remove this line or clock might not be set correctly. */
    #ifdef PREINIT_SUPPORTED
    preinit();
    #endif
    
    application_init( );
    
    for ( ; ; ) 
    {
        application_task( );
    }

    return 0;
}

static void lr11868mhz_clear_app_buf ( void ) 
{
    memset( app_buf, 0, app_buf_len );
    app_buf_len = 0;
}

static void lr11868mhz_log_app_buf ( void )
{
    for ( int32_t buf_cnt = 0; buf_cnt < app_buf_len; buf_cnt++ )
    {
        log_printf( &logger, "%c", app_buf[ buf_cnt ] );
    }
}

static err_t lr11868mhz_process ( lr11868mhz_t *ctx ) 
{
    uint8_t rx_buf[ PROCESS_BUFFER_SIZE ] = { 0 };
    int32_t overflow_bytes = 0;
    int32_t rx_cnt = 0;
    int32_t rx_size = lr11868mhz_generic_read( ctx, rx_buf, PROCESS_BUFFER_SIZE );
    if ( ( rx_size > 0 ) && ( rx_size <= APP_BUFFER_SIZE ) ) 
    {
        if ( ( app_buf_len + rx_size ) > APP_BUFFER_SIZE ) 
        {
            overflow_bytes = ( app_buf_len + rx_size ) - APP_BUFFER_SIZE;
            app_buf_len = APP_BUFFER_SIZE - rx_size;
            memmove ( app_buf, &app_buf[ overflow_bytes ], app_buf_len );
            memset ( &app_buf[ app_buf_len ], 0, overflow_bytes );
        }
        for ( rx_cnt = 0; rx_cnt < rx_size; rx_cnt++ ) 
        {
            if ( rx_buf[ rx_cnt ] ) 
            {
                app_buf[ app_buf_len++ ] = rx_buf[ rx_cnt ];
            }
        }
        return LR11868MHZ_OK;
    }
    return LR11868MHZ_ERROR;
}

static err_t lr11868mhz_read_response ( lr11868mhz_t *ctx, uint8_t *rsp ) 
{
    #define READ_RESPONSE_TIMEOUT_MS 30000
    uint32_t timeout_cnt = 0;
    lr11868mhz_clear_app_buf ( );
    lr11868mhz_process( ctx );
    while ( ( 0 == strstr( app_buf, rsp ) ) &&
            ( 0 == strstr( app_buf, LR11868MHZ_RSP_ERROR ) ) )
    {
        lr11868mhz_process( ctx );
        if ( timeout_cnt++ > READ_RESPONSE_TIMEOUT_MS )
        {
            lr11868mhz_clear_app_buf( );
            log_error( &logger, " Timeout!" );
            return LR11868MHZ_ERROR_TIMEOUT;
        }
        Delay_ms( 1 );
    }
    Delay_ms ( 200 );
    lr11868mhz_process( ctx );
    if ( strstr( app_buf, rsp ) )
    {
        lr11868mhz_log_app_buf( );
        log_printf( &logger, "--------------------------------\r\n" );
        return LR11868MHZ_OK;
    }
    lr11868mhz_log_app_buf( );
    return LR11868MHZ_ERROR_CMD;
}

static err_t lr11868mhz_power_up ( lr11868mhz_t *ctx )
{
    err_t error_flag = LR11868MHZ_OK;
    
    log_printf( &logger, ">>> Reset device.\r\n" );
    lr11868mhz_reset_device( &lr11868mhz );
    while ( LR11868MHZ_OK == lr11868mhz_process( ctx ) )
    {
        lr11868mhz_log_app_buf( );
        lr11868mhz_clear_app_buf ( );
    }
    log_printf( &logger, "--------------------------------\r\n" );

    log_printf( &logger, ">>> Factory reset.\r\n" );
    lr11868mhz_cmd_run( &lr11868mhz, LR11868MHZ_CMD_FACTORY_RESET, NULL );
    error_flag |= lr11868mhz_read_response( &lr11868mhz, LR11868MHZ_RSP_OK );

    log_printf( &logger, ">>> Check communication.\r\n" );
    lr11868mhz_cmd_run( &lr11868mhz, LR11868MHZ_CMD_AT, NULL );
    error_flag |= lr11868mhz_read_response( &lr11868mhz, LR11868MHZ_RSP_OK );

    log_printf( &logger, ">>> Get device type.\r\n" );
    lr11868mhz_cmd_run( ctx, LR11868MHZ_CMD_GET_INFO, LR11868MHZ_PARAM_DEVICE_TYPE );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );

    log_printf( &logger, ">>> Get firmware version.\r\n" );
    lr11868mhz_cmd_run( ctx, LR11868MHZ_CMD_GET_INFO, LR11868MHZ_PARAM_APP_FW_VERSION );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );

    return error_flag;
}

static err_t lr11868mhz_config_example ( lr11868mhz_t *ctx )
{
    uint8_t data_buf[ 10 ] = { 0 };
    err_t error_flag = LR11868MHZ_OK;
    #define DEVICE_CLASS_P2P "3"
    log_printf( &logger, ">>> Set LoRa operation to P2P.\r\n" );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_DEVICE_CLASS, DEVICE_CLASS_P2P );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );

    #define REGION_EU868 "1"
    log_printf( &logger, ">>> Set operation region to EU868.\r\n" );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_REGION, REGION_EU868 );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );

    int16_to_str ( NODE_ADDRESS, data_buf );
    l_trim ( data_buf );
    r_trim ( data_buf );
    log_printf( &logger, ">>> Set P2P node address to %s.\r\n", data_buf );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_P2P_DEVICE_ADDRESS, data_buf );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );

    #define P2P_NETWORK_SIZE "2"
    log_printf( &logger, ">>> Set P2P network size to %s nodes.\r\n", ( char * ) P2P_NETWORK_SIZE );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_P2P_NET_SIZE, P2P_NETWORK_SIZE );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    #define P2P_DATA_RATE_DR2 "2"
    log_printf( &logger, ">>> Set P2P data rate to DR2.\r\n" );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_P2P_DATA_RATE, P2P_DATA_RATE_DR2 );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    #define P2P_LISTEN_DURATION "0"
    log_printf( &logger, ">>> Set P2P listen duration to 0.\r\n" );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_P2P_LISTEN_DURATION, P2P_LISTEN_DURATION );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    #define P2P_LISTEN_INTERVAL "0"
    log_printf( &logger, ">>> Set P2P listen interval to 0.\r\n" );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_P2P_LISTEN_INTERVAL, P2P_LISTEN_INTERVAL );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    #define P2P_BEACON_DATA_RATE_DR2 "2"
    log_printf( &logger, ">>> Set P2P beacon data rate to DR2.\r\n" );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_P2P_BEACON_DATA_RATE, P2P_BEACON_DATA_RATE_DR2 );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    #define P2P_TX_POWER "1"
    log_printf( &logger, ">>> Set P2P TX power to %s dBm.\r\n", ( char * ) P2P_TX_POWER );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_P2P_TX_POWER, P2P_TX_POWER );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    log_printf( &logger, ">>> Save settings.\r\n" );
    lr11868mhz_cmd_run( &lr11868mhz, LR11868MHZ_CMD_SAVE_SETTINGS, NULL );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    log_printf( &logger, ">>> Reboot.\r\n" );
    lr11868mhz_cmd_run( &lr11868mhz, LR11868MHZ_CMD_WARM_RESET, NULL );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    log_printf( &logger, ">>> Get P2P maximum packet size.\r\n" );
    lr11868mhz_cmd_run( ctx, LR11868MHZ_CMD_GET_INFO, LR11868MHZ_PARAM_P2P_SLOT_PACKET_SIZE );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    int16_t packet_size = atoi( &app_buf[ 1 ] ) - 1;
    if ( packet_size < strlen ( DEMO_TEXT_MESSAGE ) )
    {
        log_error( &logger, " DEMO_TEXT_MESSAGE length [%d] exceeds the packet size limit [%d].\r\n", 
                   ( int16_t ) strlen ( DEMO_TEXT_MESSAGE ), packet_size );
        for ( ; ; );
    }
    
    int16_to_str ( strlen ( DEMO_TEXT_MESSAGE ), data_buf );
    l_trim ( data_buf );
    r_trim ( data_buf );
    log_printf( &logger, ">>> Set P2P packet size to %s.\r\n", data_buf );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_P2P_PACKET_SIZE, data_buf );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    log_printf( &logger, ">>> Save settings.\r\n" );
    lr11868mhz_cmd_run( &lr11868mhz, LR11868MHZ_CMD_SAVE_SETTINGS, NULL );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    log_printf( &logger, ">>> Reboot.\r\n" );
    lr11868mhz_cmd_run( &lr11868mhz, LR11868MHZ_CMD_WARM_RESET, NULL );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    log_printf( &logger, ">>> Get P2P minimum window length.\r\n" );
    lr11868mhz_cmd_run( ctx, LR11868MHZ_CMD_GET_INFO, LR11868MHZ_PARAM_P2P_MIN_WINDOW_LENGTH );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    int16_t window_len = atoi( &app_buf[ 1 ] ) + 1;
    int16_to_str ( window_len, data_buf );
    l_trim ( data_buf );
    r_trim ( data_buf );
    log_printf( &logger, ">>> Set P2P window length to %s.\r\n", data_buf );
    lr11868mhz_cmd_set( ctx, LR11868MHZ_CMD_PARAM_ACCESS_NUM, LR11868MHZ_PARAM_ID_P2P_WINDOW_LENGTH, data_buf );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    log_printf( &logger, ">>> Save settings.\r\n" );
    lr11868mhz_cmd_run( &lr11868mhz, LR11868MHZ_CMD_SAVE_SETTINGS, NULL );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    log_printf( &logger, ">>> Reboot.\r\n" );
    lr11868mhz_cmd_run( &lr11868mhz, LR11868MHZ_CMD_WARM_RESET, NULL );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    log_printf( &logger, ">>> Start a P2P session.\r\n" );
    lr11868mhz_cmd_run( &lr11868mhz, LR11868MHZ_CMD_P2P_START_SESSION, NULL );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    Delay_ms ( 1000 );
    Delay_ms ( 1000 );
    Delay_ms ( 1000 );

    return error_flag;
}

static err_t lr11868mhz_example ( lr11868mhz_t *ctx )
{
    err_t error_flag = LR11868MHZ_OK;
    uint8_t param_buf[ 120 ] = { 0 };
    uint8_t msg_hex[ 101 ] = { 0 };
    uint8_t byte_hex[ 3 ] = { 0 };
    uint8_t src_addr[ 10 ] = { 0 };
    uint8_t source[ 10 ] = { 0 };
    uint8_t rssi[ 10 ] = { 0 };
    uint8_t snr[ 10 ] = { 0 };
    uint8_t cnt = 0;

    memset( msg_hex, 0, sizeof ( msg_hex ) );
    for ( cnt = 0; ( cnt < strlen ( DEMO_TEXT_MESSAGE ) ) && ( cnt < 50 ); cnt++ ) 
    {
        uint8_to_hex ( DEMO_TEXT_MESSAGE[ cnt ], byte_hex );
        strcat ( msg_hex, byte_hex );
    }
#if ( NODE_ADDRESS == NODE_0_ADDRESS )
    int16_to_str ( NODE_1_ADDRESS, param_buf );
    l_trim ( param_buf );
    r_trim ( param_buf );
#else
    int16_to_str ( NODE_0_ADDRESS, param_buf );
    l_trim ( param_buf );
    r_trim ( param_buf );
#endif
    log_printf( &logger, ">>> Send message \"%s\" to node address %s.\r\n", ( char * ) DEMO_TEXT_MESSAGE, param_buf );
    strcat ( param_buf, ", \"" );
    strcat ( param_buf, msg_hex );
    strcat ( param_buf, "\"" );
    lr11868mhz_cmd_run( ctx, LR11868MHZ_CMD_P2P_SEND_DATA, param_buf );
    error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_RSP_OK );
    
    if ( LR11868MHZ_OK == error_flag )
    {
        memset( msg_hex, 0, sizeof ( msg_hex ) );
        log_printf( &logger, ">>> Waiting for a P2P RX message.\r\n" );
        error_flag |= lr11868mhz_read_response( ctx, LR11868MHZ_EVT_RX_P2P );
    }
    else
    {
        Delay_ms ( 1000 );
        Delay_ms ( 1000 );
        Delay_ms ( 1000 );
        Delay_ms ( 1000 );
        Delay_ms ( 1000 );
    }
    
    if ( LR11868MHZ_OK == error_flag )
    {
        uint8_t * __generic_ptr start_ptr = strstr( app_buf, LR11868MHZ_EVT_RX_P2P );
        uint8_t * __generic_ptr end_ptr = NULL;
        if ( start_ptr )
        {
            start_ptr = start_ptr + strlen ( LR11868MHZ_EVT_RX_P2P );
            end_ptr = strstr ( start_ptr, "," );
            memcpy ( source, start_ptr, end_ptr - start_ptr );
            
            start_ptr = strstr ( end_ptr, ":" ) + 1;
            end_ptr = strstr ( start_ptr, "," );
            memcpy ( rssi, start_ptr, end_ptr - start_ptr );

            start_ptr = strstr ( end_ptr, ":" ) + 1;
            end_ptr = strstr ( start_ptr, "," );
            memcpy ( snr, start_ptr, end_ptr - start_ptr );
            
            start_ptr = end_ptr + 2;
            end_ptr = strstr ( start_ptr, "\n" );
            memcpy ( msg_hex, start_ptr, end_ptr - start_ptr );

            for ( cnt = 0; cnt < strlen ( msg_hex ); cnt += 2 )
            {
                msg_hex[ cnt / 2 ] = hex_to_uint8 ( &msg_hex [ cnt ] );
            }
            msg_hex[ cnt / 2 ] = 0;
            log_printf( &logger, ">>> Parse received message.\r\n" );
            log_printf ( &logger, " Source address: %s\r\n", source );
            log_printf ( &logger, " Message: %s\r\n", msg_hex );
            log_printf ( &logger, " RSSI: %s\r\n", rssi );
            log_printf ( &logger, " SNR: %s\r\n", snr );
            log_printf( &logger, "--------------------------------\r\n" );
        }
    }
    return error_flag;
}

// ------------------------------------------------------------------------ END