Exemplo n.º 1
0
/**
  * @brief  Automatic test switch to LSE clock from HSI and return to HSI
  * @caller auto_test
  * @param None
  * @retval None
  */
void test_LSE(void)
{
	
/* Switch the clock to LSE */
	
  LCD_GLASS_DisplayString("LSE");
  
  CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);
  CLK_LSEConfig(CLK_LSE_ON);
  delay_ms(LSE_DELAY);	
  
  if((CLK->ECKCR & CLK_ECKCR_LSERDY) == RESET)
  {
    LCD_GLASS_DisplayString("LSE");
    delay_ms(LSE_DELAY);
    if((CLK->ECKCR & CLK_ECKCR_LSERDY) == RESET)
    {
      LCD_GLASS_DisplayString("LSE");
      delay_ms(LSE_DELAY);
      if((CLK->ECKCR & CLK_ECKCR_LSERDY) == RESET)
      {			
        /* Switch the clock to HSI*/
        CLK_LSEConfig(CLK_LSE_OFF);
        CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_8);
        CLK_HSICmd(ENABLE);
        while (((CLK->ICKCR)& 0x02)!=0x02);
        CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
        CLK_SYSCLKSourceSwitchCmd(ENABLE);
        while (((CLK->SWCR)& 0x01)==0x01);
        
        while(1)
        {
          LCD_GLASS_ScrollSentence("LSE Not OK ",1,SCROLL_SPEED); //Press reset for exit
          KeyPressed = FALSE;
        }
      }
    }
  }

/* Wait flag LSE ready */
  while (!((CLK->ECKCR)& CLK_ECKCR_LSERDY));	

/* Switch in LSE clock */
  CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_LSE);
  CLK_SYSCLKSourceSwitchCmd(ENABLE);
  while (((CLK->SWCR)& 0x01)==0x01);
  
  LCD_GLASS_DisplayString("LSE OK");

/* Switch the clock to HSI */

  CLK_LSEConfig(CLK_LSE_OFF);
  CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_8);
  CLK_HSICmd(ENABLE);
  while (((CLK->ICKCR)& 0x02)!=0x02);
  CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
  CLK_SYSCLKSourceSwitchCmd(ENABLE);
  while (((CLK->SWCR)& 0x01)==0x01);
  delay_ms(100);
}
Exemplo n.º 2
0
/**
  * @brief this function checks if a NDEF message is available
	* @par Parameters None
  * @retval none
  */
static void User_DisplayMessageActiveHaltMode ( uint8_t PayloadLength )
{

	
		//Switch the clock to LSE and disable HSI
		#ifdef USE_LSE
			CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);
			CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_LSE);	
			CLK_SYSCLKSourceSwitchCmd(ENABLE);
			while (((CLK->SWCR)& 0x01)==0x01);
			CLK_HSICmd(DISABLE);
			CLK->ECKCR &= ~0x01; 
		#else
			CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);
			CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_LSI);
			CLK_SYSCLKSourceSwitchCmd(ENABLE);
			while (((CLK->SWCR)& 0x01)==0x01);
			CLK_HSICmd(DISABLE);
			CLK->ECKCR &= ~0x01; 
		#endif	
		
		// disable interupt				
		sim();
		// To copy function DISPLAYRAM in RAM section DISPLAY
		#ifdef _COSMIC_
			if (!(_fctcpy('D')))
				while(1);
		#endif
				
			Display_Ram (); // Call in RAM
			
		//	state_machine = STATE_VREF;
						
		#ifdef USE_HSI
			//Switch the clock to HSI
			CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_16);
			CLK_HSICmd(ENABLE);
			while (((CLK->ICKCR)& 0x02)!=0x02);			
			CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
			CLK_SYSCLKSourceSwitchCmd(ENABLE);
			while (((CLK->SWCR)& 0x01)==0x01);
		#else
			CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_2);
			// Select 2MHz HSE as system clock source 
			CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSE);
			// wait until the target clock source is ready 
			while (((CLK->SWCR)& 0x01)==0x01);
			// wait until the target clock source is ready 
			CLK_SYSCLKSourceSwitchCmd(ENABLE);
		#endif
							
		// enable interupt				
		rim();
		

}
Exemplo n.º 3
0
void LowPower_CLK_Config(void)
{
  CLK_SYSCLKSourceSwitchCmd(ENABLE);//使能时钟切换
  CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_LSI);//选择内部低速时钟作为时钟源
  CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);//设置系统时钟分频
  while (CLK_GetSYSCLKSource() != CLK_SYSCLKSource_LSI);//等待时钟稳定
  CLK_HSICmd(DISABLE);                          //关闭原先的 CLK source
  CLK_HSEConfig(CLK_HSE_OFF);                   //关闭外部 CLK source
}
Exemplo n.º 4
0
/**
  * @brief  Configure System Clock 
  * @param  None
  * @retval None
  */
static void CLK_Config(void)
{
  /* Select HSE as system clock source */
  CLK_SYSCLKSourceSwitchCmd(ENABLE);
  CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSE);
  /* system clock prescaler: 1*/
  CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);
  while (CLK_GetSYSCLKSource() != CLK_SYSCLKSource_HSE)
  {}
}
Exemplo n.º 5
0
/***********************************************************************
  * @brief		Configure System Clock 
  * @param	None
  * @retval   None
************************************************************************/
static void CLK_Config(void)
{
  	// Select HSI as system clock source 
  	CLK_SYSCLKSourceSwitchCmd(ENABLE);
  	CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
  
  	// system clock prescaler: 1
  	CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);
  	while (CLK_GetSYSCLKSource() != CLK_SYSCLKSource_HSI)
  	{}
}
Exemplo n.º 6
0
/**
  * @brief this function checks if a NDEF message is available
	* @par Parameters None
  * @retval none
  */
static void User_DisplayMessage (uint8_t message[],uint8_t PayloadLength )
{

	//Switch the clock to LSE and disable HSI
	#ifdef USE_LSE
		CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);
		CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_LSE);	
		CLK_SYSCLKSourceSwitchCmd(ENABLE);
		while (((CLK->SWCR)& 0x01)==0x01);
		CLK_HSICmd(DISABLE);
		CLK->ECKCR &= ~0x01; 
	#else
		CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);
		CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_LSI);
		CLK_SYSCLKSourceSwitchCmd(ENABLE);
		while (((CLK->SWCR)& 0x01)==0x01);
		CLK_HSICmd(DISABLE);
		CLK->ECKCR &= ~0x01; 
	#endif		
		
		LCD_GLASS_ScrollSentenceNbCar(message,30,PayloadLength+6);		
		
	#ifdef USE_HSI
			//Switch the clock to HSI
			CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_16);
			CLK_HSICmd(ENABLE);
			while (((CLK->ICKCR)& 0x02)!=0x02);			
			CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
			CLK_SYSCLKSourceSwitchCmd(ENABLE);
			while (((CLK->SWCR)& 0x01)==0x01);
		#else
			CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_2);
			// Select 2MHz HSE as system clock source 
			CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSE);
			// wait until the target clock source is ready 
			while (((CLK->SWCR)& 0x01)==0x01);
			// wait until the target clock source is ready 
			CLK_SYSCLKSourceSwitchCmd(ENABLE);
		#endif
}
Exemplo n.º 7
0
/**
  * @brief Function to initialize the entry in low power and wait modes
  * @caller test low power mode
  * @param None   
  * @retval None
  */
void LPR_init(void)
{

/*Switch the clock to LSE and disable HSI*/
  #ifdef USE_LSE
    CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_LSE);	
    CLK_SYSCLKSourceSwitchCmd(ENABLE);
    while (((CLK->SWCR)& 0x01)==0x01);
    CLK_HSICmd(DISABLE);
  #else
    CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);
    CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_LSI);
    CLK_SYSCLKSourceSwitchCmd(ENABLE);
    while (((CLK->SWCR)& 0x01)==0x01);
    CLK_HSICmd(DISABLE);
  #endif

/*Configure event for WAKEUP and FUNCTION, disable the interrupts*/

  sim();
	
/* To copy function LPR_Ram in RAM section LPRUN*/
#ifdef _COSMIC_
  if (!(_fctcpy('L')))
    while(1);
#endif

  LPR_Ram(); // Call in RAM
  
  /*Switch the clock to HSI*/
  CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_8);
  CLK_HSICmd(ENABLE);
  while (((CLK->ICKCR)& 0x02)!=0x02);
  
  CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
  CLK_SYSCLKSourceSwitchCmd(ENABLE);
  while (((CLK->SWCR)& 0x01)==0x01);

}
Exemplo n.º 8
0
void clock_config(void)
{
 CLK_HSICmd(ENABLE);
 CLK_RTCClockConfig(CLK_RTCCLKSource_HSI,CLK_RTCCLKDiv_64);
 CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
 CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);
 while(CLK_GetFlagStatus(CLK_FLAG_HSIRDY)==RESET); 
 CLK_PeripheralClockConfig(CLK_Peripheral_LCD, ENABLE);
 CLK_PeripheralClockConfig(CLK_Peripheral_RTC, ENABLE); 
 CLK_PeripheralClockConfig(CLK_Peripheral_TIM4, ENABLE);
 CLK_PeripheralClockConfig(CLK_Peripheral_TIM2, ENABLE);
 CLK_PeripheralClockConfig(CLK_Peripheral_TIM3, ENABLE);
 CLK_PeripheralClockConfig(CLK_Peripheral_ADC1, ENABLE);
};
Exemplo n.º 9
0
/**
  * @brief  Configure peripherals Clock   
  * @param  None
  * @retval None
  */
static void CLK_Config(void)
{
  /* High speed internal clock prescaler: 1 */
  CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_1);

  /* Select HSE as system clock source */
  CLK_SYSCLKSourceSwitchCmd(ENABLE);
  CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSE);

  while (CLK_GetSYSCLKSource() != CLK_SYSCLKSource_HSE)
  {}

  /* Enable TIM4 CLK */
  CLK_PeripheralClockConfig(CLK_Peripheral_TIM4, ENABLE);
}
Exemplo n.º 10
0
/**
  * @brief  Configure peripheral clock 
  * @param  None
  * @retval None
  */
static void CLK_Config(void)
{
  /* Select HSE as system clock source */
  CLK_SYSCLKSourceSwitchCmd(ENABLE);
  CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSE);
  
  /*High speed external clock prescaler: 1*/
  CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_2);

  while (CLK_GetSYSCLKSource() != CLK_SYSCLKSource_HSE)
  {}

  /* Enable SPI clock */
  CLK_PeripheralClockConfig(CLK_Peripheral_SPI1, ENABLE);
  /* Enable DMA clock */
  CLK_PeripheralClockConfig(CLK_Peripheral_DMA1, ENABLE);
}
Exemplo n.º 11
0
void main(void)
{
    deInitClock();
    deInitGPIO();

    CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
    CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_16);

    initDigitalControls();
    initAnalogControls();

    GPIO_Init(GPIOF, GPIO_Pin_0, GPIO_Mode_In_FL_IT);
    EXTI_SetPinSensitivity(EXTI_Pin_0, EXTI_Trigger_Rising);

    enableInterrupts();
    initMemory();

    while (1)
    {
        halt();
    }
}
Exemplo n.º 12
0
/**
  * @brief main entry point.
  * @par Parameters None
  * @retval void None
  * @par Required preconditions: None
  */
void main(void)
{ 
uint8_t PayloadLength,
				data_sensor,
				*bufMessage;
		
	/* deinit I/O ports */
	DeInitClock();
	DeInitGPIO();
	
	/* Select HSI as system clock source */
	#ifdef USE_HSI
		CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
		CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_16);	
	 #else
		CLK_SYSCLKSourceSwitchCmd(ENABLE);
		/* Select 2MHz HSE as system clock source */
		CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSE);
		CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_4);	
		CLK_HSICmd(DISABLE);
	#endif

	// Initializes the LCD glass 
  LCD_GLASS_Init();

	
	/* LED button init: GPIO set in push pull */
	GPIO_Init( LED_GPIO_PORT, LED_GPIO_PIN, GPIO_Mode_Out_PP_Low_Fast);
	// set to 0 
	GPIOE->ODR &= ~LED_GPIO_PIN;
	
	/* USER button init: GPIO set in input interrupt active mode */
  GPIO_Init( BUTTON_GPIO_PORT, USER_GPIO_PIN, GPIO_Mode_In_FL_IT);
	EXTI_SetPinSensitivity(EXTI_Pin_7, EXTI_Trigger_Falling);

  //* Init Bar on LCD all are OFF
  BAR0_OFF;
  BAR1_OFF;
  BAR2_OFF;
  BAR3_OFF;	
	
	enableInterrupts();
	
  
  //* At power on VDD diplays 
	bufMessage = NDEFmessage;
	
	if (EEMenuState > STATE_TEMPMEAS) 
		EEMenuState = STATE_CHECKNDEFMESSAGE;
		
	FLASH_Unlock(FLASH_MemType_Data );
	
	state_machine = EEMenuState ; 
	
	delayLFO_ms (1);
	
	if (EEInitial == 0)
	{
			User_WriteFirmwareVersion ();
			EEInitial =1;
	}
	
  while (1)
  {
    
    switch (state_machine)
    {
			  
				case STATE_VREF:
					// measure the voltage available at the output of the M24LR04E-R
					Vref_measure();

					delayLFO_ms (2);
        break;
			
        case STATE_CHECKNDEFMESSAGE:
				
						// read the NDEF message from the M24LR04E-R EEPROM and display it if it is found 				
					if (User_ReadNDEFMessage (&PayloadLength) == SUCCESS)						
						User_DisplayMessage (bufMessage,PayloadLength);
	//					User_DisplayMessageActiveHaltMode (PayloadLength);
					else 
						User_DisplayMessage((uint8_t*)ErrorMessage,20);		
		
					
	
        break;
				
				case STATE_TEMPMEAS:
						
						// read the ambiant tempserature from the STTS751
						User_GetOneTemperature (&data_sensor);
						// display the temperature
						User_DisplayOneTemperature (data_sensor);
			
						delayLFO_ms (2);
						
				break;
			
			break;
  
        /* for safe: normaly never reaches */ 			
        default:
					LCD_GLASS_Clear();
					LCD_GLASS_DisplayString("Error");
					state_machine = STATE_VREF;
        break;
      }
    
		
    }
}	
Exemplo n.º 13
0
/**
  * @brief main entry point.
  * @par Parameters None
  * @retval void None
  * @par Required preconditions: None
  */
void main(void)
{ 
uint8_t PayloadLength,
				data_sensor,
				*bufMessage;
		
	/* deinit I/O ports */
	DeInitClock();
	DeInitGPIO();
	
	/* Select HSI as system clock source */
	#ifdef USE_HSI
		CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSI);
		CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_16);	
	 #else
		CLK_SYSCLKSourceSwitchCmd(ENABLE);
		/* Select 2MHz HSE as system clock source */
		CLK_SYSCLKSourceConfig(CLK_SYSCLKSource_HSE);
		CLK_SYSCLKDivConfig(CLK_SYSCLKDiv_4);	
		CLK_HSICmd(DISABLE);
	#endif

	// Initializes the LCD glass 
  LCD_GLASS_Init();

	
	/* LED button init: GPIO set in push pull */
	GPIO_Init( LED_GPIO_PORT, LED_GPIO_PIN, GPIO_Mode_Out_PP_Low_Fast);
	// set to 0 
	GPIOE->ODR &= ~LED_GPIO_PIN;
	
	/* USER button init: GPIO set in input interrupt active mode */
  GPIO_Init( BUTTON_GPIO_PORT, USER_GPIO_PIN, GPIO_Mode_In_FL_IT);
	EXTI_SetPinSensitivity(EXTI_Pin_7, EXTI_Trigger_Falling);

  //* Init Bar on LCD all are OFF
  BAR0_OFF;
  BAR1_OFF;
  BAR2_OFF;
  BAR3_OFF;	
	
	enableInterrupts();
	
  
  //* At power on VDD diplays 
	bufMessage = NDEFmessage;
	
	if (EEMenuState > STATE_TEMPMEAS) 
		EEMenuState = STATE_CHECKNDEFMESSAGE;
		
	FLASH_Unlock(FLASH_MemType_Data );

	
	state_machine = EEMenuState ; 
	
	delayLFO_ms (1);
	
	if (EEInitial == 0)
	{
			User_WriteFirmwareVersion ();
			EEInitial =1;
	}
	
  while (1)
  {
    
    switch (state_machine)
    {
			  
				case STATE_VREFF:
					// measure the voltage available at the output of the M24LR04E-R

					Vref_measure();
					delayLFO_ms (2);
					//turn on led
					GPIO_SetBits(GPIOE, GPIO_Pin_6);
			
        break;
				
				case STATE_VBIO:
				//measure the output voltage of biosensor through Pin 7 Port E
				
					CLK_PeripheralClockConfig(CLK_Peripheral_ADC1, ENABLE);
						ADC_DeInit(ADC1);
					ADC_VrefintCmd(ENABLE);
					delay_10us(3);
					GPIO_DeInit(GPIOE);
					GPIO_Init(GPIOE,GPIO_Pin_7 ,/*GPIO_Mode_In_FL_No_IT*/GPIO_Mode_In_PU_No_IT);
					ADC_Cmd(ADC1, ENABLE);
					
					ADC_Init(ADC1, ADC_ConversionMode_Single,ADC_Resolution_12Bit, ADC_Prescaler_1);
					
					ADC_SamplingTimeConfig(ADC1, ADC_Group_FastChannels, ADC_SamplingTime_9Cycles);
					ADC_ChannelCmd(ADC1, ADC_Channel_3, ENABLE);
					delay_10us(3); // Important delay
					res = 0;
					res_2 = 0;
					i=0;
					for(i=8; i>0; i--)
						{
						/* start ADC convertion by software */
							ADC_SoftwareStartConv(ADC1);
						/* wait until end-of-covertion */
							while( ADC_GetFlagStatus(ADC1, ADC_FLAG_EOC) == 0 );
						/* read ADC convertion result */
							res += ADC_GetConversionValue(ADC1);
						}
					/* de-initialize ADC*/ 
					ADC_VrefintCmd(DISABLE);

					ADC_DeInit(ADC1);
 
					/* disable SchmittTrigger for ADC_Channel_24, to save power */
					ADC_SchmittTriggerConfig(ADC1, ADC_Channel_3, DISABLE);
	
					CLK_PeripheralClockConfig(CLK_Peripheral_ADC1, DISABLE);
					ADC_ChannelCmd(ADC1, ADC_Channel_3, DISABLE);
					res = res>>3;
					P_VREFINT_Factory = VREFINT_Factory_CONV_ADDRESS;
					
					
					#ifdef VREFINT_FACTORY_CONV
						if ((*P_VREFINT_Factory>VREFINT_Factory_CONV_MIN ) && (*P_VREFINT_Factory<VREFINT_Factory_CONV_MAX ))
						{
							/* If the value exists:
							Adds the hight byte to FullVREF_FACTORY */
							FullVREF_FACTORY = VREFINT_Factory_CONV_MSB;
							FullVREF_FACTORY += *P_VREFINT_Factory;
							res_2 = (float)(FullVREF_FACTORY*VDD_FACTORY);
							res_2 /= res;
							} else {
											res_2 = (VREF/res) * ADC_CONV; // usally res>>3
											}
											#else
										/* We use the theorcial value */
											res_2 = (VREF/res) * ADC_CONV;
												#endif
						/* Vdd_appli in mV */  
						res_2*= 1000L;
					

						convert_into_char (res_2, tab);
	
							/* To add unit and decimal point  */
						tab[5] = 'V';
						tab[4] = ' ';
						tab[1] |= DOT; /* To add decimal point for display in volt */
						tab[0] = ' ';

						LCD_GLASS_DisplayStrDeci(tab);
						delayLFO_ms (2);
						
					
					//LCD_GLASS_DisplayString("V BIO");
					
					break;
			
			
			
			
        case STATE_CHECKNDEFMESSAGE:
				
						// read the NDEF message from the M24LR04E-R EEPROM and display it if it is found 				
					if (User_ReadNDEFMessage (&PayloadLength) == SUCCESS)						
						User_DisplayMessage (bufMessage,PayloadLength);
	//					User_DisplayMessageActiveHaltMode (PayloadLength);
					else 
						User_DisplayMessage(ErrorMessage,20);		
		
	
        break;
				
				case STATE_TEMPMEAS:
						
						// read the ambiant tempserature from the STTS751
						User_GetOneTemperature (&data_sensor);
						// display the temperature
						User_DisplayOneTemperature (data_sensor);
			
						delayLFO_ms (2);
						
				break;
			
			break;
  
        /* for safe: normaly never reaches */ 			
        default:
					LCD_GLASS_Clear();
					LCD_GLASS_DisplayString("Error");
					state_machine = STATE_VREFF;
        break;
      }
    
		
    }
}