sx1278+stm8slora通信及信号强度提取_sx1278spi通信资源-CSDN文库

共140个文件

c：28个

h：28个

o：26个

lora

sx1276

stm8s

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标题中的“sx1278+stm8s lora通信及信号强度提取”是指使用SX1278 LoRa芯片与STM8S微控制器进行无线通信，并实现信号强度的检测和提取。LoRa（Long Range）是一种远距离、低功耗的无线通信技术，广泛应用于物联网(IoT)设备中。STM8S是意法半导体(STMicroelectronics)生产的一款8位微控制器，具有高效能和低功耗的特点。描述中提到，基于STM8S处理器，通过SPI（Serial Peripheral Interface）接口与SX1276（与SX1278相似，常被混淆）进行通信。SPI是一种同步串行通信协议，适用于连接微控制器和外部设备，例如传感器、显示驱动器或在这种情况下，无线收发器。在IAR开发环境中使用C语言编写代码，这意味着开发人员使用了IAR Embedded Workbench，这是一个专为微控制器设计的强大集成开发环境。在LoRa通信中，SX1278芯片负责处理无线传输，它支持扩频技术，可以提供长距离传输和抵抗干扰的能力。STM8S微控制器通过SPI接口发送命令来配置SX1278的参数，如工作频率、数据速率、扩频因子等，并接收来自SX1278的数据。同时，STM8S还能读取SX1278的RSSI（Received Signal Strength Indicator）值，这是一项重要的无线通信指标，用于表示接收到的信号强度。信号强度提取是LoRa通信中的关键环节，因为它可以帮助评估通信质量。在无线通信中，RSSI值越低，表明信号越弱，可能会影响到数据的正确接收。因此，通过读取RSSI并进行适当的处理，可以判断通信链路的状态，适时调整通信参数，优化通信效果。在“压缩包子文件的文件名称列表”中，"IAR_SX1278_ykw_rssiok"可能是项目源代码的文件夹或者一个工程文件，其中包含了使用IAR编译器的C代码，可能包含配置SX1278的函数、处理SPI通信的函数以及解析和处理RSSI值的函数。这些源代码对于理解整个系统的实现过程至关重要。这个项目主要涵盖了以下知识点： 1. LoRa通信技术，特别是SX1278芯片的工作原理和应用。 2. STM8S微控制器的SPI接口编程，包括配置和控制外设。 3. C语言在嵌入式系统中的应用，特别是在IAR开发环境中的编程实践。 4. 无线通信中的信号强度检测，即RSSI的读取和利用。 5. 基于硬件和软件的通信链路优化，如根据RSSI调整通信参数。深入研究这个项目，不仅可以学习到LoRa通信的基本原理，还能掌握如何在实际应用中利用微控制器实现无线通信和信号强度的监测。这对于从事物联网开发的工程师来说是非常有价值的经验。

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sx1278+stm8s lora通信及信号强度提取（140个子文件）

LCD_RF.cspy.bat 1KB

LCD_RF.pbd.browse 910KB

stm8s_tim1.c 84KB

stm8s_tim5.c 50KB

stm8s_can.c 48KB

stm8s_tim2.c 46KB

stm8s_tim3.c 37KB

stm8s_i2c.c 32KB

stm8s_uart2.c 29KB

stm8s_uart1.c 26KB

stm8s_flash.c 25KB

stm8s_uart3.c 24KB

stm8s_adc1.c 23KB

stm8s_clk.c 22KB

stm8s_tim6.c 15KB

SX1276.C 14KB

stm8s_spi.c 14KB

stm8s_adc2.c 13KB

stm8s_it.c 12KB

stm8s_tim4.c 12KB

stm8s_itc.c 10KB

stm8s_gpio.c 8KB

main.c 6KB

stm8s_awu.c 6KB

stm8_interrupt_vector.c 6KB

stm8s_exti.c 6KB

stm8s_beep.c 5KB

stm8s_wwdg.c 4KB

stm8s_iwdg.c 3KB

stm8s_rst.c 3KB

stm8s-a_stdperiph_drivers_um.chm 3.62MB

SX1276.pbi.cout 11KB

main.pbi.cout 10KB

stm8s_uart2.pbi.cout 10KB

stm8s_tim2.pbi.cout 10KB

stm8s_gpio.pbi.cout 10KB

stm8s_exti.pbi.cout 10KB

stm8s_tim1.pbi.cout 10KB

stm8s_clk.pbi.cout 10KB

stm8s_it.pbi.cout 10KB

LCD_RF.dbgdt 6KB

LCD_RF.dep 20KB

LCD_RF.dni 3KB

LCD_RF.ewd 11KB

Backup of LCD_RF.ewd 11KB

LCD_RF.ewp 43KB

Backup of LCD_RF.ewp 42KB

rf_lcd.eww 160B

stm8s.h 113KB

stm8s_i2c.h 27KB

stm8s_tim1.h 26KB

stm8s_can.h 25KB

stm8s_tim5.h 19KB

stm8s_uart2.h 19KB

stm8s_clk.h 17KB

stm8s_uart1.h 16KB

stm8s_uart3.h 15KB

stm8s_adc1.h 15KB

stm8s_tim2.h 14KB

stm8s_flash.h 13KB

stm8s_spi.h 13KB

stm8s_tim3.h 13KB

stm8s_adc2.h 11KB

stm8s_tim6.h 9KB

Sx1276.h 7KB

stm8s_itc.h 7KB

stm8s_gpio.h 6KB

stm8s_it.h 5KB

stm8s_tim4.h 5KB

stm8s_awu.h 5KB

stm8s_exti.h 5KB

stm8s_conf.h 4KB

stm8s_iwdg.h 4KB

stm8s_beep.h 3KB

stm8s_rst.h 3KB

stm8s_wwdg.h 2KB

Release_Notes.html 68KB

sx1278.IAB 488KB

Untitled Project.IAB 480KB

sx1278.IAD 5KB

Untitled Project.IAD 5KB

sx1278.IMB 124KB

Untitled Project.IMB 124KB

sx1278.IMD 2KB

Untitled Project.IMD 2KB

LCD_RF.map 29KB

stm8s_tim1.o 170KB

stm8s_tim2.o 98KB

stm8s_tim3.o 79KB

RF_si4463.o 75KB

RF_si4432.o 72KB

SX1276.o 68KB

lcd_disp.o 60KB

stm8s_uart2.o 58KB

stm8s_clk.o 56KB

A7129.o 55KB

stm8s_adc1.o 55KB

stm8s_uart1.o 53KB

stm8s_flash.o 47KB

si4432.o 45KB

共 140 条

/** ****************************************************************************** * @file stm8s_tim1.c * @author MCD Application Team * @version V2.1.0 * @date 18-November-2011 * @brief This file contains all the functions for the TIM1 peripheral. ****************************************************************************** * @attention * * THE PRESENT FIRMWARE WHICH IS FOR GUIDANCE ONLY AIMS AT PROVIDING CUSTOMERS * WITH CODING INFORMATION REGARDING THEIR PRODUCTS IN ORDER FOR THEM TO SAVE * TIME. AS A RESULT, STMICROELECTRONICS SHALL NOT BE HELD LIABLE FOR ANY * DIRECT, INDIRECT OR CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING * FROM THE CONTENT OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE * CODING INFORMATION CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS. * * <h2><center>© COPYRIGHT 2011 STMicroelectronics</center></h2> ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include "stm8s_tim1.h" /** @addtogroup STM8S_StdPeriph_Driver * @{ */ /* Private typedef -----------------------------------------------------------*/ /* Private define ------------------------------------------------------------*/ /* Private macro -------------------------------------------------------------*/ /* Private variables ---------------------------------------------------------*/ /* Private function prototypes -----------------------------------------------*/ static void TI1_Config(uint8_t TIM1_ICPolarity, uint8_t TIM1_ICSelection, uint8_t TIM1_ICFilter); static void TI2_Config(uint8_t TIM1_ICPolarity, uint8_t TIM1_ICSelection, uint8_t TIM1_ICFilter); static void TI3_Config(uint8_t TIM1_ICPolarity, uint8_t TIM1_ICSelection, uint8_t TIM1_ICFilter); static void TI4_Config(uint8_t TIM1_ICPolarity, uint8_t TIM1_ICSelection, uint8_t TIM1_ICFilter); /** * @addtogroup TIM1_Public_Functions * @{ */ /** * @brief Deinitializes the TIM1 peripheral registers to their default reset values. * @param None * @retval None */ void TIM1_DeInit(void) { TIM1->CR1 = TIM1_CR1_RESET_VALUE; TIM1->CR2 = TIM1_CR2_RESET_VALUE; TIM1->SMCR = TIM1_SMCR_RESET_VALUE; TIM1->ETR = TIM1_ETR_RESET_VALUE; TIM1->IER = TIM1_IER_RESET_VALUE; TIM1->SR2 = TIM1_SR2_RESET_VALUE; /* Disable channels */ TIM1->CCER1 = TIM1_CCER1_RESET_VALUE; TIM1->CCER2 = TIM1_CCER2_RESET_VALUE; /* Configure channels as inputs: it is necessary if lock level is equal to 2 or 3 */ TIM1->CCMR1 = 0x01; TIM1->CCMR2 = 0x01; TIM1->CCMR3 = 0x01; TIM1->CCMR4 = 0x01; /* Then reset channel registers: it also works if lock level is equal to 2 or 3 */ TIM1->CCER1 = TIM1_CCER1_RESET_VALUE; TIM1->CCER2 = TIM1_CCER2_RESET_VALUE; TIM1->CCMR1 = TIM1_CCMR1_RESET_VALUE; TIM1->CCMR2 = TIM1_CCMR2_RESET_VALUE; TIM1->CCMR3 = TIM1_CCMR3_RESET_VALUE; TIM1->CCMR4 = TIM1_CCMR4_RESET_VALUE; TIM1->CNTRH = TIM1_CNTRH_RESET_VALUE; TIM1->CNTRL = TIM1_CNTRL_RESET_VALUE; TIM1->PSCRH = TIM1_PSCRH_RESET_VALUE; TIM1->PSCRL = TIM1_PSCRL_RESET_VALUE; TIM1->ARRH = TIM1_ARRH_RESET_VALUE; TIM1->ARRL = TIM1_ARRL_RESET_VALUE; TIM1->CCR1H = TIM1_CCR1H_RESET_VALUE; TIM1->CCR1L = TIM1_CCR1L_RESET_VALUE; TIM1->CCR2H = TIM1_CCR2H_RESET_VALUE; TIM1->CCR2L = TIM1_CCR2L_RESET_VALUE; TIM1->CCR3H = TIM1_CCR3H_RESET_VALUE; TIM1->CCR3L = TIM1_CCR3L_RESET_VALUE; TIM1->CCR4H = TIM1_CCR4H_RESET_VALUE; TIM1->CCR4L = TIM1_CCR4L_RESET_VALUE; TIM1->OISR = TIM1_OISR_RESET_VALUE; TIM1->EGR = 0x01; /* TIM1_EGR_UG */ TIM1->DTR = TIM1_DTR_RESET_VALUE; TIM1->BKR = TIM1_BKR_RESET_VALUE; TIM1->RCR = TIM1_RCR_RESET_VALUE; TIM1->SR1 = TIM1_SR1_RESET_VALUE; } /** * @brief Initializes the TIM1 Time Base Unit according to the specified parameters. * @param TIM1_Prescaler specifies the Prescaler value. * @param TIM1_CounterMode specifies the counter mode from @ref TIM1_CounterMode_TypeDef . * @param TIM1_Period specifies the Period value. * @param TIM1_RepetitionCounter specifies the Repetition counter value * @retval None */ void TIM1_TimeBaseInit(uint16_t TIM1_Prescaler, TIM1_CounterMode_TypeDef TIM1_CounterMode, uint16_t TIM1_Period, uint8_t TIM1_RepetitionCounter) { /* Check parameters */ assert_param(IS_TIM1_COUNTER_MODE_OK(TIM1_CounterMode)); /* Set the Autoreload value */ TIM1->ARRH = (uint8_t)(TIM1_Period >> 8); TIM1->ARRL = (uint8_t)(TIM1_Period); /* Set the Prescaler value */ TIM1->PSCRH = (uint8_t)(TIM1_Prescaler >> 8); TIM1->PSCRL = (uint8_t)(TIM1_Prescaler); /* Select the Counter Mode */ TIM1->CR1 = (uint8_t)((uint8_t)(TIM1->CR1 & (uint8_t)(~(TIM1_CR1_CMS | TIM1_CR1_DIR))) | (uint8_t)(TIM1_CounterMode)); /* Set the Repetition Counter value */ TIM1->RCR = TIM1_RepetitionCounter; } /** * @brief Initializes the TIM1 Channel1 according to the specified parameters. * @param TIM1_OCMode specifies the Output Compare mode from * @ref TIM1_OCMode_TypeDef. * @param TIM1_OutputState specifies the Output State from * @ref TIM1_OutputState_TypeDef. * @param TIM1_OutputNState specifies the Complementary Output State * from @ref TIM1_OutputNState_TypeDef. * @param TIM1_Pulse specifies the Pulse width value. * @param TIM1_OCPolarity specifies the Output Compare Polarity from * @ref TIM1_OCPolarity_TypeDef. * @param TIM1_OCNPolarity specifies the Complementary Output Compare Polarity * from @ref TIM1_OCNPolarity_TypeDef. * @param TIM1_OCIdleState specifies the Output Compare Idle State from * @ref TIM1_OCIdleState_TypeDef. * @param TIM1_OCNIdleState specifies the Complementary Output Compare Idle * State from @ref TIM1_OCIdleState_TypeDef. * @retval None */ void TIM1_OC1Init(TIM1_OCMode_TypeDef TIM1_OCMode, TIM1_OutputState_TypeDef TIM1_OutputState, TIM1_OutputNState_TypeDef TIM1_OutputNState, uint16_t TIM1_Pulse, TIM1_OCPolarity_TypeDef TIM1_OCPolarity, TIM1_OCNPolarity_TypeDef TIM1_OCNPolarity, TIM1_OCIdleState_TypeDef TIM1_OCIdleState, TIM1_OCNIdleState_TypeDef TIM1_OCNIdleState) { /* Check the parameters */ assert_param(IS_TIM1_OC_MODE_OK(TIM1_OCMode)); assert_param(IS_TIM1_OUTPUT_STATE_OK(TIM1_OutputState)); assert_param(IS_TIM1_OUTPUTN_STATE_OK(TIM1_OutputNState)); assert_param(IS_TIM1_OC_POLARITY_OK(TIM1_OCPolarity)); assert_param(IS_TIM1_OCN_POLARITY_OK(TIM1_OCNPolarity)); assert_param(IS_TIM1_OCIDLE_STATE_OK(TIM1_OCIdleState)); assert_param(IS_TIM1_OCNIDLE_STATE_OK(TIM1_OCNIdleState)); /* Disable the Channel 1: Reset the CCE Bit, Set the Output State , the Output N State, the Output Polarity & the Output N Polarity*/ TIM1->CCER1 &= (uint8_t)(~( TIM1_CCER1_CC1E | TIM1_CCER1_CC1NE | TIM1_CCER1_CC1P | TIM1_CCER1_CC1NP)); /* Set the Output State & Set the Output N State & Set the Output Polarity & Set the Output N Polarity */ TIM1->CCER1 |= (uint8_t)((uint8_t)((uint8_t)(TIM1_OutputState & TIM1_CCER1_CC1E) | (uint8_t)(TIM1_OutputNState & TIM1_CCER1_CC1NE)) | (uint8_t)( (uint8_t)(TIM1_OCPolarity & TIM1_CCER1_CC1P) | (uint8_t)(TIM1_OCNPolarity & TIM1_CCER1_CC1NP))

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