private/hsb
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity

Added Interlock

Browse Source 
Fixed PID regulation functionality

git-svn-id: https://svn.vbchaos.nl/svn/hsb/trunk@250 05563f52-14a8-4384-a975-3d1654cca0fa
This commit is contained in:
mmi
2017-10-12 07:16:50 +00:00
parent 3df93a80d7
commit 54b6afe5a3
19 changed files with 504 additions and 261 deletions
Download Patch File Download Diff File Expand all files Collapse all files

1
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/HAL/Makefile
View File

@@ -24,6 +24,7 @@ ARFLAGS = rs
OBJECTS = \
DisplayDevice.o \
Interlock.o \
IODevice.o \
KeyboardDevice.o \
Logger.o \

133
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/HAL/inc/Interlock.h Normal file
View File

@@ -0,0 +1,133 @@
// -----------------------------------------------------------------------------
/// @file Interlock.h
/// @brief File description
// -----------------------------------------------------------------------------
// Micro-Key bv
// Industrieweg 28, 9804 TG Noordhorn
// Postbus 92, 9800 AB Zuidhorn
// The Netherlands
// Tel: +31 594 503020
// Fax: +31 594 505825
// Email: support@microkey.nl
// Web: www.microkey.nl
// -----------------------------------------------------------------------------
/// $Revision$
/// $Author$
/// $Date$
// (c) 2015 Micro-Key bv
// -----------------------------------------------------------------------------
/// @defgroup {group_name} {group_description}
/// Description
/// @file Interlock.h
/// @ingroup {group_name}
#ifndef INC_INTERLOCK_H_
#define INC_INTERLOCK_H_
// -----------------------------------------------------------------------------
// Include files
// -----------------------------------------------------------------------------
#include <stdbool.h>
#include "stm32f10x.h"
#include "platform.h"
#include "gpio.h"
#include "stm32f10x_exti.h"
// -----------------------------------------------------------------------------
// Constant and macro definitions
// -----------------------------------------------------------------------------
// -----------------------------------------------------------------------------
// Type definitions.
// -----------------------------------------------------------------------------
struct InterlockElement
{
struct Gpio* io;
EXTI_InitTypeDef ioEXTI;
};
struct Interlock
{
struct InterlockElement NO;
struct InterlockElement NC;
bool initialized;
};
// -----------------------------------------------------------------------------
// Function declarations
// -----------------------------------------------------------------------------
/** ----------------------------------------------------------------------------
* Interlock_construct
* Description of function
*
* @param self
* @param NO
* @param NOEXTI
* @param NC
* @param NCEXTI
*
* @return ErrorStatus
*
* @todo
* -----------------------------------------------------------------------------
*/
extern ErrorStatus Interlock_construct(struct Interlock* self, struct Gpio* NO, EXTI_InitTypeDef NOEXTI, struct Gpio* NC, EXTI_InitTypeDef NCEXTI);
/** ----------------------------------------------------------------------------
* Interlock_getStatus
* Get the current status of the interlock
*
* @param self Interlock object
* @param command Interrupt status
* @param NO value on GPIO NO
* @param NC value on GPIO NC
*
* @return void
*
* @todo
* -----------------------------------------------------------------------------
*/
extern void Interlock_getStatus(struct Interlock* self, FunctionalState* command, int* NO, int* NC);
/** ----------------------------------------------------------------------------
* Interlock_isClosed
* Check for interlock closed. Scans both I/Os
*
* @param self The interlock object
*
* @return bool TRUE is NC=1 and NO=0
*
* @todo
* -----------------------------------------------------------------------------
*/
extern bool Interlock_isClosed(struct Interlock* self);
/** ----------------------------------------------------------------------------
* Interlock_setEXTI
* Description of function
*
* @param self
* @param command
*
* @return void
*
* @todo
* -----------------------------------------------------------------------------
*/
extern void Interlock_setEXTI(struct Interlock* self, FunctionalState command);
#endif /* INC_INTERLOCK_H_ */

4
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/HAL/inc/PID.h
View File

@@ -39,7 +39,7 @@
// Constant and macro definitions
// -----------------------------------------------------------------------------
#define PID_FIXED_POINT_FACTOR (1000)
#define PID_FIXED_POINT_FACTOR (10000)
// -----------------------------------------------------------------------------
// Type definitions.
@@ -92,6 +92,6 @@ extern ErrorStatus PID_construct(struct Pid* self, int Kp, int Ki, int Kd, int i
* @todo
* -----------------------------------------------------------------------------
*/
extern int PID_calculate(struct Pid* self, int input, int error);
extern int PID_calculate(struct Pid* self, int error);
#endif /* INC_PID_H_ */

114
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/HAL/src/Interlock.c Normal file
View File

@@ -0,0 +1,114 @@
// -----------------------------------------------------------------------------
/// @file Interlock.c
/// @brief Description
// -----------------------------------------------------------------------------
// Micro-Key bv
// Industrieweg 28, 9804 TG Noordhorn
// Postbus 92, 9800 AB Zuidhorn
// The Netherlands
// Tel: +31 594 503020
// Fax: +31 594 505825
// Email: support@microkey.nl
// Web: www.microkey.nl
// -----------------------------------------------------------------------------
/// $Revision$
/// $Author$
/// $Date$
// (c) 2017 Micro-Key bv
// -----------------------------------------------------------------------------
/// @file Interlock.c
/// @ingroup {group_name}
// -----------------------------------------------------------------------------
// Include files
// -----------------------------------------------------------------------------
#include "Interlock.h"
// -----------------------------------------------------------------------------
// Constant and macro definitions
// -----------------------------------------------------------------------------
// -----------------------------------------------------------------------------
// Type definitions
// -----------------------------------------------------------------------------
// -----------------------------------------------------------------------------
// File-scope variables
// -----------------------------------------------------------------------------
// -----------------------------------------------------------------------------
// Function declarations
// -----------------------------------------------------------------------------
// -----------------------------------------------------------------------------
// Function definitions
// -----------------------------------------------------------------------------
ErrorStatus Interlock_construct(struct Interlock* self, struct Gpio* NO, EXTI_InitTypeDef NOEXTI, struct Gpio* NC, EXTI_InitTypeDef NCEXTI)
{
ErrorStatus returnValue = SUCCESS;
if (!self->initialized)
{
self->NO.io = NO;
self->NO.ioEXTI = NOEXTI;
self->NC.io = NC;
self->NC.ioEXTI = NCEXTI;
self->initialized = true;
}
else
{
returnValue = ERROR;
}
return returnValue;
}
void Interlock_getStatus(struct Interlock* self, FunctionalState* command, int* NO, int* NC)
{
*command = self->NO.ioEXTI.EXTI_LineCmd;
IODevice_read((struct IODevice*)self->NO.io, (char*)NO, 1, NULL);
IODevice_read((struct IODevice*)self->NC.io, (char*)NC, 1, NULL);
}
bool Interlock_isClosed(struct Interlock* self)
{
bool returnValue;
char no;
char nc;
IODevice_read((struct IODevice*)self->NO.io, &no, 1, NULL);
IODevice_read((struct IODevice*)self->NC.io, &nc, 1, NULL);
if ((no != 0) && (nc == 0))
{
returnValue = true;
}
else
{
returnValue = false;
}
return returnValue;
}
void Interlock_setEXTI(struct Interlock* self, FunctionalState command)
{
self->NO.ioEXTI.EXTI_LineCmd = command;
EXTI_Init(&self->NO.ioEXTI);
self->NC.ioEXTI.EXTI_LineCmd = command;
EXTI_Init(&self->NC.ioEXTI);
}

14
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/HAL/src/PID.c
View File

@@ -89,20 +89,18 @@ ErrorStatus PID_construct(struct Pid* self, int Kp, int Ki, int Kd, int iMin, in
}
int PID_calculate(struct Pid* self, int input, int error)
int PID_calculate(struct Pid* self, int error)
{
int returnValue = 0;
int dTerm;
int pTerm;
input *= PID_FIXED_POINT_FACTOR;
error *= PID_FIXED_POINT_FACTOR;
if (self->initialized)
{
// Calculate integral
self->iTerm += (self->Ki * error);
// Control integrator
if (self->iTerm > self->iMax)
{
@@ -114,14 +112,14 @@ int PID_calculate(struct Pid* self, int input, int error)
}
// Calculate differential
dTerm = (input - self->input_d1) * self->Kd;
dTerm = ((error - self->input_d1) * self->Kd);
// Calculate proportional
pTerm = self->Kp * error;
pTerm = (self->Kp * error);
LOGGER_WARNING(mainLog, "pTerm %d, Kp %d, error %d", pTerm, self->Kp, error);
returnValue = (self->iTerm + dTerm + pTerm) / PID_FIXED_POINT_FACTOR;
self->input_d1 = input;
self->input_d1 = error;
}
else
{

34
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/HAL/src/nhd0420.c
View File

@@ -69,7 +69,6 @@ static int nhd0420_cursorRowOffset[NHD0420_NUMBER_OF_ROWS] =
static ErrorStatus setState(const struct DisplayDevice* self, DisplayDevice_functionalState state);
static ErrorStatus write(const struct DisplayDevice* self, const char* buffer, size_t length, size_t row, size_t column);
static ErrorStatus clear(const struct DisplayDevice* self);
static ErrorStatus clearLine(const struct DisplayDevice* self, size_t row);
static ErrorStatus setBrightness(const struct DisplayDevice* self, size_t brightness);
static ErrorStatus setContrast(const struct DisplayDevice* self, size_t contrast);
@@ -95,7 +94,7 @@ ErrorStatus NHD0420_construct(struct NHD0420* self, const struct IODevice* devic
ddParameters.brightnessMax = NHD0420_BRIGHTNESS_MAX;
ddParameters.contrastMin = NHD0420_CONTRAST_MIN;
ddParameters.contrastMax = NHD0420_CONTRAST_MAX;
DisplayDevice_construct(&self->displayDevice, &ddParameters, NULL, setState, write, clear, clearLine, setBrightness, setContrast, NULL);
DisplayDevice_construct(&self->displayDevice, &ddParameters, NULL, setState, write, clear, NULL, setBrightness, setContrast, NULL);
self->initialized = true;
NHD0420_sendData(self, "Hallo", 5);
@@ -422,37 +421,6 @@ static ErrorStatus clear(const struct DisplayDevice* self)
}
static ErrorStatus clearLine(const struct DisplayDevice* self, size_t row)
{
ErrorStatus returnValue = SUCCESS;
if (self->initialized)
{
// Set cursor on display
returnValue = NHD0420_setCursorToPosition((const struct NHD0420*)self, row, 1);
char buffer[self->parameters.numberOfColumns];
int loopcounter;
for (loopcounter = 0; loopcounter < self->parameters.numberOfColumns; loopcounter++)
{
buffer[loopcounter] = 0x20;
}
if (returnValue == SUCCESS)
{
returnValue = NHD0420_sendData((const struct NHD0420*)self, buffer, self->parameters.numberOfColumns);
}
}
else
{
returnValue = ERROR;
}
return returnValue;
}
static ErrorStatus setBrightness(const struct DisplayDevice* self, size_t brightness)
{
if (self->initialized)

11
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/Platform/inc/platform.h
View File

@@ -83,10 +83,10 @@ extern struct Keypad* const keypad;
extern struct Gpio* const ledGreen;
extern struct Gpio* const ledOrange;
extern struct Gpio* const power6v5Enable;
extern struct Gpio* const tesla1;
extern struct Gpio* const tesla2;
extern struct Gpio* const interlock1;
extern struct Gpio* const interlock2;
extern struct Gpio* const interlockNO;
extern struct Gpio* const interlockNC;
extern struct Gpio* const teslaNO;
extern struct Gpio* const teslaNC;
extern struct Gpio* const solenoid;
extern struct Gpio* const mcp0Relay;
extern struct Gpio* const mcp1Relay;
@@ -94,7 +94,8 @@ extern struct Gpio* const mcp2Relay;
extern struct Gpio* const cat0Relay;
extern struct Gpio* const cat1Relay;
extern struct Gpio* const cat2Relay;
extern struct Gpio* const teslaLock;
extern struct Interlock* const interlock;
extern struct Interlock* const teslalock;
// -----------------------------------------------------------------------------
// Function declarations

3
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/Platform/src/internalADC.c
View File

@@ -214,7 +214,8 @@ ErrorStatus ADCChannel_read(const struct AdcChannel* self, uint16_t* value)
if (self->parent->useRanks)
{
// Rank starts with 1 - must be reduced by one in order tu be used as index
*value = self->parent->channelValue[self->Rank - 1];
// *value = self->parent->channelValue[self->Rank - 1];
*value = self->parent->channelValue[self->channel];
}
return returnValue;

114
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/Platform/src/oli_stm32_h107.c
View File

@@ -37,6 +37,7 @@
#include "Logger.h"
#include "platform.h"
#include "Interlock.h"
#include "internalADC.h"
#include "gpio.h"
#include "PCBA.h"
@@ -122,10 +123,10 @@ static struct Keypad _keypad = {.initialized = false};
static struct Gpio _ledGreen = {.initialized = false};
static struct Gpio _ledOrange = {.initialized = false};
static struct Gpio _power6v5Enable = {.initialized = false};
static struct Gpio _interlock1 = {.initialized = false};
static struct Gpio _interlock2 = {.initialized = false};
static struct Gpio _tesla1 = {.initialized = false};
static struct Gpio _tesla2 = {.initialized = false};
static struct Gpio _interlockNO = {.initialized = false};
static struct Gpio _interlockNC = {.initialized = false};
static struct Gpio _teslaNO = {.initialized = false};
static struct Gpio _teslaNC = {.initialized = false};
static struct Gpio _solenoid = {.initialized = false};
static struct Gpio _mcp0Relay = {.initialized = false};
static struct Gpio _mcp1Relay = {.initialized = false};
@@ -133,7 +134,9 @@ static struct Gpio _mcp2Relay = {.initialized = false};
static struct Gpio _cat0Relay = {.initialized = false};
static struct Gpio _cat1Relay = {.initialized = false};
static struct Gpio _cat2Relay = {.initialized = false};
static struct Gpio _teslaLock = {.initialized = false};
static struct Interlock _interlock = {.initialized = false};
static struct Interlock _teslalock = {.initialized = false};
// The following pointers are for export (see platform.h) and external use.
@@ -167,10 +170,10 @@ struct Keypad* const keypad = &_keypad;
struct Gpio* const ledGreen = &_ledGreen;
struct Gpio* const ledOrange = &_ledOrange;
struct Gpio* const power6v5Enable = & _power6v5Enable;
struct Gpio* const interlock1 = &_interlock1;
struct Gpio* const interlock2 = &_interlock2;
struct Gpio* const tesla1 = &_tesla1;
struct Gpio* const tesla2 = &_tesla2;
struct Gpio* const interlockNO = &_interlockNO;
struct Gpio* const interlockNC = &_interlockNC;
struct Gpio* const teslaNO = &_teslaNO;
struct Gpio* const teslaNC = &_teslaNC;
struct Gpio* const solenoid = & _solenoid;
struct Gpio* const mcp0Relay = &_mcp0Relay;
struct Gpio* const mcp1Relay = &_mcp1Relay;
@@ -178,7 +181,9 @@ struct Gpio* const mcp2Relay = &_mcp2Relay;
struct Gpio* const cat0Relay = &_cat0Relay;
struct Gpio* const cat1Relay = &_cat1Relay;
struct Gpio* const cat2Relay = &_cat2Relay;
struct Gpio* const teslaLock = &_teslaLock;
struct Interlock* const interlock = &_interlock;
struct Interlock* const teslalock = &_teslalock;
// -----------------------------------------------------------------------------
// Function declarations
@@ -187,6 +192,7 @@ struct Gpio* const teslaLock = &_teslaLock;
static ErrorStatus initClocks(void);
static ErrorStatus initIO (void);
static T_PL_GPIO configureGPIO (GPIO_TypeDef* gpioTypeDef, GPIOMode_TypeDef gpioMode, GPIOSpeed_TypeDef gpioSpeed, uint16_t gpioPin);
static EXTI_InitTypeDef configureEXTI (uint32_t line, EXTIMode_TypeDef mode, EXTITrigger_TypeDef trigger, FunctionalState command);
// -----------------------------------------------------------------------------
// Function definitions
@@ -256,17 +262,17 @@ ErrorStatus initPlatform(void)
struct AdcChannelParameters acParameters;
acParameters.channel = ADC_Channel_1;
acParameters.Rank = 1;
acParameters.ADC_SampleTime = ADC_SampleTime_55Cycles5;
acParameters.ADC_SampleTime = ADC_SampleTime_239Cycles5;
ADCChannel_construct(&adc1->channel[1], adc1, &acParameters);
acParameters.channel = ADC_Channel_2;
acParameters.Rank = 2;
acParameters.ADC_SampleTime = ADC_SampleTime_55Cycles5;
acParameters.ADC_SampleTime = ADC_SampleTime_239Cycles5;
ADCChannel_construct(&adc1->channel[2], adc1, &acParameters);
acParameters.channel = ADC_Channel_0;
acParameters.Rank = 3;
acParameters.ADC_SampleTime = ADC_SampleTime_55Cycles5;
acParameters.ADC_SampleTime = ADC_SampleTime_239Cycles5;
ADCChannel_construct(&adc1->channel[0], adc1, &acParameters);
ADC_setDMAStatus(adc1, ENABLE);
@@ -378,10 +384,23 @@ ErrorStatus initPlatform(void)
GPIO_construct(ledOrange, OUTPUT, ledOrange->gpio);
// 6V5 Power Enable
GPIO_construct(power6v5Enable, OUTPUT, power6v5Enable->gpio);
// Interlock1
GPIO_construct(interlock1, INPUT, interlock1->gpio);
// Interlock2
GPIO_construct(interlock2, INPUT, interlock2->gpio);
IRQ_setInterruptProperties(EXTI0_IRQn, 12, 0, ENABLE);
IRQ_setInterruptProperties(EXTI1_IRQn, 12, 0, ENABLE);
// InterlockNO
EXTI_InitTypeDef intNOEXTI; // = configureEXTI(EXTI_Line0, EXTI_Mode_Interrupt, EXTI_Trigger_Rising_Falling, ENABLE);
intNOEXTI.EXTI_Line = EXTI_Line0;
intNOEXTI.EXTI_Mode = EXTI_Mode_Interrupt;
intNOEXTI.EXTI_Trigger = EXTI_Trigger_Rising_Falling;
intNOEXTI.EXTI_LineCmd = ENABLE;
EXTI_Init(&intNOEXTI);
GPIO_construct(interlockNO, INPUT, interlockNO->gpio);
// InterlockNC
EXTI_InitTypeDef intNCEXTI = configureEXTI(EXTI_Line1, EXTI_Mode_Interrupt, EXTI_Trigger_Rising_Falling, ENABLE);
GPIO_construct(interlockNC, INPUT, interlockNC->gpio);
// Interlock_construct(interlock, interlockNO, intNOEXTI, interlockNC, intNCEXTI);
// Solenoid
GPIO_construct(solenoid, OUTPUT, solenoid->gpio);
if (PCBA_getInstance()->pcba == CathodeMCP)
@@ -402,9 +421,16 @@ ErrorStatus initPlatform(void)
if (PCBA_getInstance()->pcba == Tesla)
{
// Tesla Lock
GPIO_construct(teslaLock, INPUT, teslaLock->gpio);
EXTI_InitTypeDef teslaNOEXTI = configureEXTI(EXTI_Line9, EXTI_Mode_Interrupt, EXTI_Trigger_Rising_Falling, DISABLE);
GPIO_construct(teslaNO, INPUT, teslaNO->gpio);
EXTI_InitTypeDef teslaNCEXTI = configureEXTI(EXTI_Line10, EXTI_Mode_Interrupt, EXTI_Trigger_Rising_Falling, DISABLE);
GPIO_construct(teslaNC, INPUT, teslaNC->gpio);
Interlock_construct(teslalock, teslaNO, teslaNOEXTI, teslaNC, teslaNCEXTI);
}
// Interlock_setEXTI(interlock, ENABLE);
}
return returnValue;
@@ -730,9 +756,11 @@ static ErrorStatus initIO (void)
// 6V5 enable -> PE12 output
power6v5Enable->gpio = configureGPIO(GPIOE, GPIO_Mode_Out_PP, GPIO_Speed_50MHz, GPIO_Pin_12);
// Interlock1 - PB0 input
interlock1->gpio = configureGPIO(GPIOB, GPIO_Mode_IN_FLOATING, GPIO_Speed_50MHz, GPIO_Pin_0);
interlockNO->gpio = configureGPIO(GPIOB, GPIO_Mode_IPU, GPIO_Speed_50MHz, GPIO_Pin_0);
GPIO_EXTILineConfig(GPIO_PortSourceGPIOB, GPIO_PinSource0);
// Interlock2 - PB1 input
interlock2->gpio = configureGPIO(GPIOB, GPIO_Mode_IN_FLOATING, GPIO_Speed_50MHz, GPIO_Pin_1);
interlockNC->gpio = configureGPIO(GPIOB, GPIO_Mode_IPU, GPIO_Speed_50MHz, GPIO_Pin_1);
GPIO_EXTILineConfig(GPIO_PortSourceGPIOB, GPIO_PinSource1);
// Solenoid - PB5 output
solenoid->gpio = configureGPIO(GPIOB, GPIO_Mode_Out_PP, GPIO_Speed_50MHz, GPIO_Pin_5);
@@ -755,7 +783,10 @@ static ErrorStatus initIO (void)
if (PCBA_getInstance()->pcba == Tesla)
{
// Tesla lock PB10 output
teslaLock->gpio = configureGPIO(GPIOB, GPIO_Mode_IN_FLOATING, GPIO_Speed_50MHz, GPIO_Pin_10);
teslaNO->gpio = configureGPIO(GPIOB, GPIO_Mode_IN_FLOATING, GPIO_Speed_50MHz, GPIO_Pin_9);
GPIO_EXTILineConfig(GPIO_PortSourceGPIOB, GPIO_PinSource9);
teslaNC->gpio = configureGPIO(GPIOB, GPIO_Mode_IN_FLOATING, GPIO_Speed_50MHz, GPIO_Pin_10);
GPIO_EXTILineConfig(GPIO_PortSourceGPIOB, GPIO_PinSource10);
}
@@ -776,3 +807,44 @@ static T_PL_GPIO configureGPIO (GPIO_TypeDef* gpioTypeDef, GPIOMode_TypeDef gpio
return gpio;
}
static EXTI_InitTypeDef configureEXTI (uint32_t line, EXTIMode_TypeDef mode, EXTITrigger_TypeDef trigger, FunctionalState command)
{
EXTI_InitTypeDef EXTI_InitStruct;
EXTI_InitStruct.EXTI_Line = line;
EXTI_InitStruct.EXTI_Mode = mode;
EXTI_InitStruct.EXTI_Trigger = trigger;
EXTI_InitStruct.EXTI_LineCmd = command;
EXTI_Init(&EXTI_InitStruct);
return EXTI_InitStruct;
}
void EXTI0_IRQHandler(void)
{
static signed portBASE_TYPE higherPriorityTaskWoken = pdFALSE;
EXTI_ClearITPendingBit(EXTI_Line0);
GPIO_setValue(ledGreen, true);
LOGGER_ERROR_ISR(mainLog, "EXTI0 IRQ TRIGGERED");
portEND_SWITCHING_ISR(higherPriorityTaskWoken);
}
void EXTI1_IRQHandler(void)
{
static signed portBASE_TYPE higherPriorityTaskWoken = pdFALSE;
EXTI_ClearITPendingBit(EXTI_Line1);
LOGGER_ERROR_ISR(mainLog, "EXTI1 IRQ TRIGGERED");
portEND_SWITCHING_ISR(higherPriorityTaskWoken);
}

4
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/STM32F10x_StdPeriph_Lib_V3.5.0/.settings/language.settings.xml
View File

@@ -5,7 +5,7 @@
<provider copy-of="extension" id="org.eclipse.cdt.ui.UserLanguageSettingsProvider"/>
<provider-reference id="org.eclipse.cdt.core.ReferencedProjectsLanguageSettingsProvider" ref="shared-provider"/>
<provider-reference id="org.eclipse.cdt.managedbuilder.core.MBSLanguageSettingsProvider" ref="shared-provider"/>
<provider class="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" console="false" env-hash="-965619469903595948" id="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" keep-relative-paths="false" name="Ac6 SW4 STM32 MCU Built-in Compiler Settings" parameter="${COMMAND} ${FLAGS} -E -P -v -dD &quot;${INPUTS}&quot;" prefer-non-shared="true">
<provider class="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" console="false" env-hash="-24990244560702828" id="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" keep-relative-paths="false" name="Ac6 SW4 STM32 MCU Built-in Compiler Settings" parameter="${COMMAND} ${FLAGS} -E -P -v -dD &quot;${INPUTS}&quot;" prefer-non-shared="true">
<language-scope id="org.eclipse.cdt.core.gcc"/>
<language-scope id="org.eclipse.cdt.core.g++"/>
</provider>
@@ -16,7 +16,7 @@
<provider copy-of="extension" id="org.eclipse.cdt.ui.UserLanguageSettingsProvider"/>
<provider-reference id="org.eclipse.cdt.core.ReferencedProjectsLanguageSettingsProvider" ref="shared-provider"/>
<provider-reference id="org.eclipse.cdt.managedbuilder.core.MBSLanguageSettingsProvider" ref="shared-provider"/>
<provider class="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" console="false" env-hash="-965619469903595948" id="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" keep-relative-paths="false" name="Ac6 SW4 STM32 MCU Built-in Compiler Settings" parameter="${COMMAND} ${FLAGS} -E -P -v -dD &quot;${INPUTS}&quot;" prefer-non-shared="true">
<provider class="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" console="false" env-hash="-24990244560702828" id="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" keep-relative-paths="false" name="Ac6 SW4 STM32 MCU Built-in Compiler Settings" parameter="${COMMAND} ${FLAGS} -E -P -v -dD &quot;${INPUTS}&quot;" prefer-non-shared="true">
<language-scope id="org.eclipse.cdt.core.gcc"/>
<language-scope id="org.eclipse.cdt.core.g++"/>
</provider>

4
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/hsb-mrts/.settings/language.settings.xml
View File

@@ -6,7 +6,7 @@
<provider-reference id="org.eclipse.cdt.core.ReferencedProjectsLanguageSettingsProvider" ref="shared-provider"/>
<provider-reference id="org.eclipse.cdt.managedbuilder.core.MBSLanguageSettingsProvider" ref="shared-provider"/>
<provider copy-of="extension" id="org.eclipse.cdt.managedbuilder.core.GCCBuildCommandParser"/>
<provider class="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" console="false" env-hash="-965619469903595948" id="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" keep-relative-paths="false" name="Ac6 SW4 STM32 MCU Built-in Compiler Settings" parameter="${COMMAND} ${FLAGS} -E -P -v -dD &quot;${INPUTS}&quot;" prefer-non-shared="true">
<provider class="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" console="false" env-hash="-24990244560702828" id="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" keep-relative-paths="false" name="Ac6 SW4 STM32 MCU Built-in Compiler Settings" parameter="${COMMAND} ${FLAGS} -E -P -v -dD &quot;${INPUTS}&quot;" prefer-non-shared="true">
<language-scope id="org.eclipse.cdt.core.gcc"/>
<language-scope id="org.eclipse.cdt.core.g++"/>
</provider>
@@ -18,7 +18,7 @@
<provider-reference id="org.eclipse.cdt.core.ReferencedProjectsLanguageSettingsProvider" ref="shared-provider"/>
<provider-reference id="org.eclipse.cdt.managedbuilder.core.MBSLanguageSettingsProvider" ref="shared-provider"/>
<provider copy-of="extension" id="org.eclipse.cdt.managedbuilder.core.GCCBuildCommandParser"/>
<provider class="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" console="false" env-hash="-965619469903595948" id="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" keep-relative-paths="false" name="Ac6 SW4 STM32 MCU Built-in Compiler Settings" parameter="${COMMAND} ${FLAGS} -E -P -v -dD &quot;${INPUTS}&quot;" prefer-non-shared="true">
<provider class="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" console="false" env-hash="-24990244560702828" id="fr.ac6.mcu.ide.build.CrossBuiltinSpecsDetector" keep-relative-paths="false" name="Ac6 SW4 STM32 MCU Built-in Compiler Settings" parameter="${COMMAND} ${FLAGS} -E -P -v -dD &quot;${INPUTS}&quot;" prefer-non-shared="true">
<language-scope id="org.eclipse.cdt.core.gcc"/>
<language-scope id="org.eclipse.cdt.core.g++"/>
</provider>

9
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/hsb-mrts/inc/hwValidationMenu.h
View File

@@ -61,10 +61,10 @@ struct HwValidationMenuItems
struct Adc* internalADC; // Internal ADC with channel array
struct MAX5715* externalDAC; // External DAC with channel array
struct Gpio* power6v5Enable;
struct Gpio* interlock1;
struct Gpio* interlock2;
struct Gpio* tesla1;
struct Gpio* tesla2;
struct Gpio* interlockNO;
struct Gpio* interlockNC;
struct Gpio* teslaNO;
struct Gpio* teslaNC;
struct Gpio* solenoid;
struct Gpio* mcp0Relay;
struct Gpio* mcp1Relay;
@@ -72,7 +72,6 @@ struct HwValidationMenuItems
struct Gpio* cat0Relay;
struct Gpio* cat1Relay;
struct Gpio* cat2Relay;
struct Gpio* teslaLock;
struct Pcba* pcba;
struct Keypad *keypad;
// struct Eeprom* eeprom; // Not implemented yet

19
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/hsb-mrts/inc/repairProcess.h
View File

@@ -46,7 +46,7 @@
// Constant and macro definitions
// -----------------------------------------------------------------------------
#define REPAIRPROCESS_NUMBER_OF_ROWS (3)
// -----------------------------------------------------------------------------
// Type definitions.
@@ -58,6 +58,7 @@ typedef enum
SOFTSTART,
VOLTAGE_HOLD,
PAUSE,
PAUSE_RESTORE,
FINISH_VERIFY,
FINISHED
} RepairState;
@@ -80,19 +81,17 @@ struct RepairProcess
uint16_t stackSize;
bool runTask;
SemaphoreHandle_t secondsSyncronisation;
uint32_t startTime;
uint32_t secondsCounter;
uint32_t softStartTimer;
uint32_t voltageHoldTimer;
RepairState currentState;
bool initialized;
size_t currentPresetIndex;
struct RepairPreset* repairPreset;
const struct AdcChannel* adcRow1;
const struct AdcChannel* adcRow2;
const struct AdcChannel* adcRow3;
const struct MAX5715_DAC* dacRow1;
const struct MAX5715_DAC* dacRow2;
const struct MAX5715_DAC* dacRow3;
struct Pid pidRow1;
struct Pid pidRow2;
struct Pid pidRow3;
const struct AdcChannel* adc[REPAIRPROCESS_NUMBER_OF_ROWS];
const struct MAX5715_DAC* dac[REPAIRPROCESS_NUMBER_OF_ROWS];
struct Pid pid[REPAIRPROCESS_NUMBER_OF_ROWS];
};
// -----------------------------------------------------------------------------

10
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/hsb-mrts/src/Display.c
View File

@@ -138,7 +138,15 @@ ErrorStatus Display_clearScreen(struct Display* self)
ErrorStatus Display_clearLine(struct Display* self, size_t line)
{
return DisplayDevice_clearLine(self->displayDevice, line);
char buffer[self->displayDevice->parameters.numberOfColumns];
int loopcounter;
for (loopcounter = 0; loopcounter < self->displayDevice->parameters.numberOfColumns; loopcounter++)
{
buffer[loopcounter] = 0x20;
}
return Display_write(self, buffer, self->displayDevice->parameters.numberOfColumns, line, 1);
}

9
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/hsb-mrts/src/hwValidationMenu.c
View File

@@ -881,8 +881,8 @@ static void hwValidationMenuSM(struct HwValidationMenu* self, Button_Pressed_t b
bool value2 = false;
if( self->menuItemSelected == MENU_TEST_INTERLOCK_1)
{
if( GPIO_getValue(self->testItems->interlock1, &value1) == SUCCESS &&
GPIO_getValue(self->testItems->interlock2, &value2) == SUCCESS
if( GPIO_getValue(self->testItems->interlockNO, &value1) == SUCCESS &&
GPIO_getValue(self->testItems->interlockNC, &value2) == SUCCESS
){
outputBufferLength = sprintf(self->outputBuffer, "Interlock: NO: %d - NC: %d\r\n", value1, value2);
}
@@ -898,8 +898,8 @@ static void hwValidationMenuSM(struct HwValidationMenu* self, Button_Pressed_t b
if(pcba->pcba == Tesla)
{
if( GPIO_getValue(self->testItems->tesla1, &value1) == SUCCESS &&
GPIO_getValue(self->testItems->tesla2, &value2) == SUCCESS
if( GPIO_getValue(self->testItems->teslaNO, &value1) == SUCCESS &&
GPIO_getValue(self->testItems->teslaNC, &value2) == SUCCESS
){
outputBufferLength = sprintf(self->outputBuffer, "Interlock (tesla): NO: %d - NC: %d\r\n", value1, value2);
}
@@ -1106,7 +1106,6 @@ static void hwValidationMenuSM(struct HwValidationMenu* self, Button_Pressed_t b
{
if( self->menuItemSelected == MENU_TEST_GENERIC_KEYPAD)
{
char key;
Keypad_KeyState keyState;
char data[CMD_BUFFER_SIZE] = {0};

13
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/hsb-mrts/src/main.c
View File

@@ -197,7 +197,7 @@ static void initTask(void* parameters)
xTaskCreate(ledBlinkTask, (const char* const)"ledTask", 100, &ledTaskArguments, 0, &ledTaskHandle);
Logger_construct(mainLog, &uart3->device, 1, 512);
Logger_construct(mainLog, &uart1->device, 1, 512);
Storm700_construct(storm700, &keypad->device);
@@ -242,10 +242,10 @@ static void initTask(void* parameters)
hwTestItems.internalADC = adc1;
hwTestItems.externalDAC = &max5715;
hwTestItems.power6v5Enable = power6v5Enable;
hwTestItems.interlock1 = interlock1;
hwTestItems.interlock2 = interlock2;
hwTestItems.tesla1 = tesla1;
hwTestItems.tesla1 = tesla2;
hwTestItems.interlockNO = interlockNO;
hwTestItems.interlockNC = interlockNC;
hwTestItems.teslaNO = teslaNO;
hwTestItems.teslaNC = teslaNC;
hwTestItems.solenoid = solenoid;
hwTestItems.mcp0Relay = mcp0Relay;
hwTestItems.mcp1Relay = mcp1Relay;
@@ -253,11 +253,10 @@ static void initTask(void* parameters)
hwTestItems.cat0Relay = cat0Relay;
hwTestItems.cat1Relay = cat1Relay;
hwTestItems.cat2Relay = cat2Relay;
hwTestItems.teslaLock = teslaLock;
hwTestItems.pcba = pcba;
hwTestItems.keypad = keypad;
// EEPROM TO BE DONE
HwValidationMenu_construct(hwValidation, &uart1->device, &hwTestItems, 1, 512);
// HwValidationMenu_construct(hwValidation, &uart1->device, &hwTestItems, 1, 1024);
// Construct the repair menu
repairMenu_construct(rm, display, 2, 512);

10
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/hsb-mrts/src/repairMenu.c
View File

@@ -155,8 +155,8 @@ static void repairMenu_task(void* parameters)
// struct RepairPresetParameters presetStage1 = {.voltage = 0xE00, .duration = 300, .softstartDuration = 120};
// struct RepairPresetParameters presetStage2 = {.voltage = 0x600, .duration = 120, .softstartDuration = 30};
struct RepairPresetParameters presetStage1 = {.voltage = 0xE00, .duration = 300, .softstartDuration = 120};
struct RepairPresetParameters presetStage2 = {.voltage = 0x600, .duration = 120, .softstartDuration = 30};
struct RepairPresetParameters presetStage1 = {.voltage = 0xE00, .duration = 7200, .softstartDuration = 1800};
struct RepairPresetParameters presetStage2 = {.voltage = 0x600, .duration = 1800, .softstartDuration = 900};
struct RepairPreset repairPreset;
repairPreset.numberOfStages = 2;
@@ -186,15 +186,15 @@ static void repairMenu_task(void* parameters)
Display_write(self->display, "R3", strlen("R3"), 3, 17);
uint16_t value;
ADCChannel_read(rp->adcRow1, &value);
ADCChannel_read(rp->adc[0], &value);
snprintf(buffer, sizeof(buffer) / sizeof(buffer[0]), "%04xV", value);
Display_write(self->display, buffer, strlen(buffer), 4, 1);
ADCChannel_read(rp->adcRow2, &value);
ADCChannel_read(rp->adc[1], &value);
snprintf(buffer, sizeof(buffer) / sizeof(buffer[0]), "%04xV", value);
Display_write(self->display, buffer, strlen(buffer), 4, 8);
ADCChannel_read(rp->adcRow3, &value);
ADCChannel_read(rp->adc[2], &value);
snprintf(buffer, sizeof(buffer) / sizeof(buffer[0]), "%04xV", value);
Display_write(self->display, buffer, strlen(buffer), 4, 15);

254
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/hsb-mrts/src/repairProcess.c
View File

@@ -55,13 +55,14 @@
// -----------------------------------------------------------------------------
// -----------------------------------------------------------------------------
// Function declarations
// -----------------------------------------------------------------------------
static void repairProcess_task(void* parameters);
static int SignalProfileGenerator(uint32_t startTime, uint32_t currentTime, struct RepairPreset* repairPreset, int presetIndex);
static int SignalProfileGenerator(struct RepairProcess* self);
// -----------------------------------------------------------------------------
// Function definitions
@@ -91,21 +92,21 @@ ErrorStatus repairProcess_construct(struct RepairProcess* self, struct RepairPro
self->initialized = true;
self->currentState = PREPARE;
self->adcRow1 = parameters->adcRow1;
self->adcRow2 = parameters->adcRow2;
self->adcRow3 = parameters->adcRow3;
self->dacRow1 = parameters->dacRow1;
self->dacRow2 = parameters->dacRow2;
self->dacRow3 = parameters->dacRow3;
self->adc[0] = parameters->adcRow1;
self->adc[1] = parameters->adcRow2;
self->adc[2] = parameters->adcRow3;
self->dac[0] = parameters->dacRow1;
self->dac[1] = parameters->dacRow2;
self->dac[2] = parameters->dacRow3;
self->pidRow1.initialized = false;
self->pidRow2.initialized = false;
self->pidRow3.initialized = false;
self->pid[0].initialized = false;
self->pid[1].initialized = false;
self->pid[2].initialized = false;
PID_construct(&self->pidRow1, 10, 10, 10, 0, 10000000);
PID_construct(&self->pidRow2, 100, 0, 0, 0, 10000000);
PID_construct(&self->pidRow3, 10, 10, 10, 0, 10000000);
PID_construct(&self->pid[0], 5000, 3000, 0, 0, 10000000);
PID_construct(&self->pid[1], 5000, 3000, 0, 0, 100000000);
PID_construct(&self->pid[2], 5000, 3000, 0, 0, 10000000);
LOGGER_INFO(mainLog, "Repair Process task started");
}
@@ -165,34 +166,73 @@ static void repairProcess_task(void* parameters)
{
struct RepairProcess* self = (struct RepairProcess*)parameters;
uint8_t presetIndex = 0;
uint32_t startTime = 0;
uint32_t softStartTimer = 0;
uint32_t voltageHoldTimer = 0;
uint32_t pidError;
uint16_t voltageRow1 = 0;
uint16_t voltageRow2 = 0;
uint16_t voltageRow3 = 0;
uint16_t adcVoltageRow1 = 0;
uint16_t adcVoltageRow2 = 0;
uint16_t adcVoltageRow3 = 0;
uint16_t voltageTarget = 0;
uint16_t dacVoltageRow1 = 0;
uint16_t dacVoltageRow2 = 0;
uint16_t dacVoltageRow3 = 0;
int signal;
uint16_t adcValue;
int error;
int pid;
int loopCounter;
// Reset the seconds counter to 0
self->secondsCounter = 0;
MAX5715Channel_setValue(self->dac[0], 0);
MAX5715Channel_setValue(self->dac[1], 0);
MAX5715Channel_setValue(self->dac[2], 0);
while(self->runTask)
{
xSemaphoreTake(self->secondsSyncronisation, portMAX_DELAY);
LOGGER_DEBUG(mainLog, "----------------------------------------");
// The signal profile is identical for all rows in the regulation process
signal = SignalProfileGenerator(self);
LOGGER_DEBUG(mainLog, "Signal: %d", signal);
// Check for correct signal
if (signal >= 0)
{
// Regulation is unique for each row
// For TESLA repair only row 1 (out of 0,1,2) is used
// For ANODE and Cathode/MCP, all 3 rows are used
for (loopCounter = ((PCBA_getInstance()->pcba == Tesla) ? 1 : 0); loopCounter <= ((PCBA_getInstance()->pcba == Tesla) ? 1 : 2); loopCounter++)
{
// Read the last ADC channel value
ADCChannel_read(self->adc[loopCounter], &adcValue);
// Calculate the error
error = signal - (int)adcValue;
// Calculate the PID
pid = PID_calculate(&self->pid[loopCounter], error);
///TODO MUST BE MOVED TO DACDevice
// Verify that pid value does not overflow the DAC
if (pid > 0xFFF)
{
pid = 0xFFF;
}
else if (pid < 0)
{
pid = 0;
}
// Send the PID value to the DAC
MAX5715Channel_setValue(self->dac[loopCounter], pid);
LOGGER_DEBUG(mainLog, "Row %d --- ADC: %d Error: %d PID: %d", loopCounter, adcValue, error, pid);
}
}
self->secondsCounter++;
}
LOGGER_INFO(mainLog, "Deleting repairProcess task");
vTaskDelete(self->taskHandle);
}
static int SignalProfileGenerator(struct RepairProcess* self)
{
int returnValue = 0;
if (self->initialized)
{
switch (self->currentState)
{
@@ -201,110 +241,61 @@ static void repairProcess_task(void* parameters)
LOGGER_DEBUG(mainLog, "Repair Process: Preparing new stage of repair process");
// Prepare a new repair process
//Load the timers
startTime = self->secondsCounter;
softStartTimer = self->secondsCounter + self->repairPreset->preset[presetIndex].softstartDuration;
LOGGER_DEBUG(mainLog, "Softstart timer is %d (%d + %d)", softStartTimer, self->secondsCounter, self->repairPreset->preset[presetIndex].softstartDuration);
voltageHoldTimer = self->secondsCounter + self->repairPreset->preset[presetIndex].duration;
LOGGER_DEBUG(mainLog, "Voltagehold timer is %d (%d + %d)", voltageHoldTimer, self->secondsCounter, self->repairPreset->preset[presetIndex].duration);
voltageTarget = self->repairPreset->preset[presetIndex].voltage;
voltageRow1 = 0;
voltageRow2 = 0;
voltageRow3 = 0;
// Anode and CathodeMCP run all 3 ADCs and DACs
MAX5715Channel_setValue(self->dacRow1, voltageRow1);
MAX5715Channel_setValue(self->dacRow2, voltageRow2);
MAX5715Channel_setValue(self->dacRow3, voltageRow3);
///TODO CHECK FOR SAFETLY BEFORE START
self->startTime = self->secondsCounter;
self->softStartTimer = self->secondsCounter + self->repairPreset->preset[self->currentPresetIndex].softstartDuration;
LOGGER_DEBUG(mainLog, "Softstart timer is %d (%d + %d)", self->softStartTimer, self->secondsCounter, self->repairPreset->preset[self->currentPresetIndex].softstartDuration);
self->voltageHoldTimer = self->secondsCounter + self->repairPreset->preset[self->currentPresetIndex].duration;
LOGGER_DEBUG(mainLog, "Voltagehold timer is %d (%d + %d)", self->voltageHoldTimer, self->secondsCounter, self->repairPreset->preset[self->currentPresetIndex].duration);
self->currentState = SOFTSTART;
break;
}
case SOFTSTART:
{
// Perform softstart / ramp-up
// Still in Softstart
int startVoltage = 0;
LOGGER_DEBUG(mainLog, "------------------------------");
if (PCBA_getInstance()->pcba == Tesla)
// If first preset, start voltage is 0
if (self->currentPresetIndex == 0)
{
// Tesla repair only runs ADC row2 and DAC row2
voltageRow2 = SignalProfileGenerator(startTime, self->secondsCounter, self->repairPreset, presetIndex);
LOGGER_DEBUG(mainLog, "Softstart running -> new target is %x", voltageRow2);
ADCChannel_read(self->adcRow3, &adcVoltageRow2);
LOGGER_DEBUG(mainLog, "Softstart running ->ADC reads %x", adcVoltageRow2);
pidError = voltageRow2 - adcVoltageRow2;
LOGGER_DEBUG(mainLog, "Softstart running ->PID Error %x", pidError);
int pidCalc = PID_calculate(&self->pidRow2, voltageRow2, pidError);
LOGGER_DEBUG(mainLog, "Softstart running ->PID calculates %x", pidCalc);
if (pidCalc >= 0)
{
MAX5715Channel_setValue(self->dacRow2, pidCalc);
}
startVoltage = 0;
}
else if ((PCBA_getInstance()->pcba == Anode) || (PCBA_getInstance()->pcba == CathodeMCP))
else
{
// Softstart for another stage - start voltage is hold voltage of previous preset
startVoltage = self->repairPreset->preset[self->currentPresetIndex - 1].voltage;
}
returnValue = ((self->repairPreset->preset[self->currentPresetIndex].voltage - startVoltage) / self->repairPreset->preset[self->currentPresetIndex].softstartDuration) * (self->secondsCounter - self->startTime) + startVoltage;
// Check for end of softstart
if (softStartTimer < self->secondsCounter)
if (self->softStartTimer < self->secondsCounter)
{
// softstart finished
self->currentState = VOLTAGE_HOLD;
}
break;
}
case VOLTAGE_HOLD:
{
// Actual repair state - hold target voltage until duration has passed
LOGGER_DEBUG(mainLog, "------------------------------");
returnValue = self->repairPreset->preset[self->currentPresetIndex].voltage;
if (PCBA_getInstance()->pcba == Tesla)
{
// Tesla repair only runs ADC row2 and DAC row2
voltageRow2 = SignalProfileGenerator(startTime, self->secondsCounter, self->repairPreset, presetIndex);
LOGGER_DEBUG(mainLog, "Voltage Hold running -> new target is %x", voltageRow2);
ADCChannel_read(self->adcRow3, &adcVoltageRow2);
LOGGER_DEBUG(mainLog, "Voltage Hold running ->ADC reads %x", adcVoltageRow2);
pidError = voltageRow2 - adcVoltageRow2;
LOGGER_DEBUG(mainLog, "Voltage Hold running ->PID Error %x", pidError);
int pidCalc = PID_calculate(&self->pidRow2, voltageRow2, pidError);
LOGGER_DEBUG(mainLog, "Voltage Hold running ->PID calculates %x", pidCalc);
if (pidCalc >= 0)
{
MAX5715Channel_setValue(self->dacRow2, pidCalc);
}
}
else if ((PCBA_getInstance()->pcba == Anode) || (PCBA_getInstance()->pcba == CathodeMCP))
{
}
// Check for end of softstart
if (voltageHoldTimer < self->secondsCounter)
// Check for end of voltage hold
if (self->voltageHoldTimer < self->secondsCounter)
{
// softstart finished
self->currentState = FINISH_VERIFY;
}
break;
}
case PAUSE:
{
break;
}
case PAUSE_RESTORE:
{
break;
}
case FINISH_VERIFY:
{
// The current preset might contain multiple stages, so before going to FINISHED state
@@ -313,10 +304,10 @@ static void repairProcess_task(void* parameters)
// presetIndex carries the current index in the preset array
// number of stages is 1-based (Starting with 1) while presetIndex is 0-based
// So, the verification must compensate for the different bases
if (self->repairPreset->numberOfStages > (presetIndex + 1))
if (self->repairPreset->numberOfStages > (self->currentPresetIndex + 1))
{
// A next stage is available
presetIndex++;
self->currentPresetIndex++;
self->currentState = PREPARE;
LOGGER_DEBUG(mainLog, "Another stage is available");
}
@@ -327,62 +318,17 @@ static void repairProcess_task(void* parameters)
}
break;
}
case FINISHED:
{
voltageRow1 = 0;
voltageRow2 = 0;
voltageRow3 = 0;
// Anode and CathodeMCP run all 3 ADCs and DACs
MAX5715Channel_setValue(self->dacRow1, voltageRow1);
MAX5715Channel_setValue(self->dacRow2, voltageRow2);
MAX5715Channel_setValue(self->dacRow3, voltageRow3);
// LOGGER_DEBUG(mainLog, "Repair process finished");
returnValue = 0;
break;
}
default:
LOGGER_ERROR(mainLog, "Repair Process state machine reached unknown state");
}
self->secondsCounter++;
}
LOGGER_INFO(mainLog, "Deleting repairProcess task");
vTaskDelete(self->taskHandle);
}
static int SignalProfileGenerator(uint32_t startTime, uint32_t currentTime, struct RepairPreset* repairPreset, int presetIndex)
{
int returnValue = 0;
// Differ between softstart period and voltage hold
if (currentTime - startTime < repairPreset->preset[presetIndex].softstartDuration)
{
// Still in Softstart
int startVoltage = 0;
// If first preset, start voltage is 0
if (presetIndex == 0)
{
startVoltage = 0;
}
else
{
// Softstart for another stage - start voltage is hold voltage of previous preset
startVoltage = repairPreset->preset[presetIndex - 1].voltage;
}
returnValue = ((repairPreset->preset[presetIndex].voltage - startVoltage) / repairPreset->preset[presetIndex].softstartDuration) * (currentTime - startTime) + startVoltage;
}
else
{
// In voltage hold
returnValue = repairPreset->preset[presetIndex].voltage;
returnValue = -1;
}
return returnValue;
}

5
S - Software/0 - HSB MRTS Kathode-MCP/3 - Implementation/0 - Code/hsb-mrts/src/stm32f10x_it.c
View File

@@ -101,6 +101,7 @@ void IRQ_setKeypadEXTI(struct Keypad* self, FunctionalState command)
}
/**
* @brief This function handles SVCall exception.
* @param None
@@ -229,6 +230,10 @@ void SPI3_IRQHandler (void)
portEND_SWITCHING_ISR(higherPriorityTaskWoken);
}
void EXTI4_IRQHandler(void)
{
static signed portBASE_TYPE higherPriorityTaskWoken = pdFALSE;