Difference between revisions of "Self-driving Car"

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== Gitlab ==
 
== Gitlab ==
Create a "master" Gitlab project that contains sub-folders of each project.  Please provide me the access (username: preet) to your master project so I can peek at all of your source code when needed.  The Gitlab will track your commit history so I would also know how much work each person or team is contributing.
+
Create a "master" Gitlab project that contains sub-folders of each project OR a Gitlab project that contains different "master" branches for each controller.  Please provide me the access (Gitlab username: preet) to your master project so I can peek at all of your source code when needed.  The Gitlab will track your commit history so I would also know how much work each person or team is contributing.
  
 
The folder structure should be:
 
The folder structure should be:
TeamX_CmpE_Fall2014
+
TeamX_CmpE_Fall2015
 
*:  Sensor
 
*:  Sensor
 
*:  IO
 
*:  IO
 
*:  <other controller projects>
 
*:  <other controller projects>
 
== Schedule ==
 
{| class="wikitable"
 
|+ Proposed Schedule
 
|-
 
| Week
 
| Milestone
 
|-
 
| October (Week1)
 
|
 
*  Create Wikipedia Project
 
*  Team Collaborations
 
*  Order large RC car (1:5 or 1:4)
 
|-
 
| October (Week2)
 
|
 
* Assemble the RC car
 
* Finish CAN Bus Wiring
 
|-
 
| October (Week3)
 
|
 
* Verify CAN communication
 
* Implement Startup Tests
 
|-
 
| October (Week4)
 
|
 
* Deliver basic functionality (tested)
 
* Log critical/debug data
 
* Basic Android interface
 
|-
 
| October (Week5)
 
|
 
* Project Integration
 
* Implement release control (with change-log)
 
|-
 
| November (Week6)
 
|
 
* Prototype project demonstration
 
|-
 
| November (Week7)
 
|
 
* Implement code review feedback
 
|-
 
| November (Week8)
 
|
 
* Finalize project features
 
|-
 
| November (Week9)
 
|
 
* Testing
 
|-
 
| December(Week10)
 
|
 
* More testing and trial runs
 
* Optimize & Tweak
 
|-
 
| December(Week11)
 
| Project Demonstration
 
|}
 
  
 
== Parts ==
 
== Parts ==
Line 95: Line 36:
 
*:  Tilt (angle of the car)
 
*:  Tilt (angle of the car)
 
|-
 
|-
| '''Motor Controller'''
+
| '''Motor and I/O Controller'''
 
'''(2 members)'''
 
'''(2 members)'''
 
|
 
|
Line 101: Line 42:
 
*:    Provide a means to steer, and drive the car
 
*:    Provide a means to steer, and drive the car
 
*  Provide feedback of the speed using a wheel encoder or speed sensor
 
*  Provide feedback of the speed using a wheel encoder or speed sensor
|-
 
| '''I/O Unit'''
 
'''(2 members)'''
 
|
 
 
*  Provide an LCD screen to report car status
 
*  Provide an LCD screen to report car status
 
*:  Errors and communication status
 
*:  Errors and communication status
Line 111: Line 48:
 
*  Button hard-coded to set a specific destination
 
*  Button hard-coded to set a specific destination
 
*  Provide means to turn on/off the headlights (etc).
 
*  Provide means to turn on/off the headlights (etc).
 +
|-
 
|-
 
|-
 
| '''Communication Bridge + Android'''
 
| '''Communication Bridge + Android'''
'''(3 members)'''
+
'''(2 members)'''
 
|
 
|
 
*  Provide means to communicate and display status on an Android/iPhone device
 
*  Provide means to communicate and display status on an Android/iPhone device
Line 120: Line 58:
 
|-
 
|-
 
| '''Geographical Controller'''
 
| '''Geographical Controller'''
'''(3 members)'''
+
'''(2 members)'''
 
|
 
|
 
*  Interface to a 5Hz or faster GPS
 
*  Interface to a 5Hz or faster GPS
Line 130: Line 68:
 
|-
 
|-
 
| '''Central Controller'''
 
| '''Central Controller'''
'''(3 members)'''
+
'''(2 members)'''
 
|
 
|
 
*  This is the primary unit that communicates with every controller to drive the car
 
*  This is the primary unit that communicates with every controller to drive the car
Line 141: Line 79:
  
 
== Communication ==
 
== Communication ==
Each controller shall provide a means to communicate with the other controllers.  Before you read any further, it requires that you have deep knowledge of the CAN bus.  CAN is a BROADCAST communication bus, but in our software we can add addressing such that we can have 1:1 communication (rather than 1:many).  Each controller shall pick a controller number.  The controller with the highest priority shall pick the lowest ID.  Using this protocol, each controller can specifically send a message to any other controller, and likewise, upon a received message, we can tell who it came from.
+
Each controller shall provide a means to communicate with the other controllers.  Before you read any further, it requires that you have deep knowledge of the CAN bus.  CAN is a BROADCAST communication bus, and the controller or message with the highest priority shall pick a lower CAN message ID.
  
 
=== Recommended CAN Message ID format ===
 
=== Recommended CAN Message ID format ===
We split the 29-bit CAN message ID into 3 portions to support peer-to-peer communication.  When a CAN message arrives, we will have its 29-bit ID, and out of this, we can determine who sent it, and what message number they sent.
+
We can split the 11-bit CAN message ID into 2 portions, one that dictates the priority of the message (message type), and the other that dictates the priority of the controller.  For example, the airbag sensor ECU should use lowest controller ID and lowest message type.
  
'''You should configure your CAN hardware filter based on your controller ID.''' So if your controller is ID 0x50, you should accept all messages in this range: '''<code>0x50.00.000 - 0x50.FF.FFF</code>'''.  In particular, your CAN hardware filter needs a single EXTENDED GROUP filter.
+
The split of message ID can also help filter out unwanted messages from arriving into your microcontroller as the CAN peripheral of the microcontroller will filter out the unwanted dataFor example, you can choose to accept all messages from the sensor controller, while making sure you receive no messages from the motor controller.  In particular, your CAN hardware filter needs a single EXTENDED GROUP filter.
 
 
You should use 0xFF as a "BROADCAST" address.  So if a node sends a message with destination address 0xFF and message number is 0x101, then ALL controllers should respond to this command.  So this means you need another acceptance filter with this range: '''<code>0xFF.00.000 - 0xFF.FF.FFF</code>'''
 
  
 
{| class="wikitable"
 
{| class="wikitable"
|+ CAN Communication Protocol (29-bit CAN ID)
+
|+ CAN Communication Protocol (11-bit CAN ID)
 
|-
 
|-
 
| Reserved bit
 
| Reserved bit
| Destination Controller
 
 
| Source Controller
 
| Source Controller
| Message number
+
| Message type
|-
 
| <code>1-bit : B28</code>
 
| <code>8-bit : B27:B20</code>
 
| <code>8-bit : B19:B13</code>
 
| <code>12-bit: B12:B00</code>
 
|}
 
 
 
{| class="wikitable"
 
|+ Message Numbers
 
|-
 
| Reserved
 
| <code>0x000 - 0x0FF</code>
 
 
|-
 
|-
| Common commands
+
| <code>1-bit : B10</code>
| <code>0x100 - 0x1FF</code>
+
| <code>6-bit : B9:B4</code>
|-
+
| <code>4-bit : B3:B0</code>
| Common responses
 
| <code>0x200 - 0x2FF</code>
 
|-
 
| Controller specific commands
 
| <code>0x300 - 0x3FF</code>
 
|-
 
| Reserved
 
| <code>0x400 - 0x4FF</code>
 
|-
 
| Data messages
 
| <code>0x500 - 0x5FF</code>
 
 
|}
 
|}
  
=== Example Controller Communication Table ===
+
=== [[DBC Format]] ===
 
+
DBC format is a well known format to describe the format of a CAN message. This is essentially the schema of the data that is communicated over the CAN bus. Please view the linked [[DBC Format]] article for details before reading further.
 
 
{| class="wikitable"
 
|+ Common Communication Table
 
|-
 
| Message Number
 
| Purpose / Data layout
 
|-
 
| 0x101
 
| Get version and boot info (0x201 will be sent)
 
|-
 
| 0x102
 
| Get general info (0x202 will be sent)
 
|-
 
| 0x103
 
| Synchronize (set) time:
 
byte [0-3] : System time
 
|-
 
| 0x201
 
|
 
byte [0-3] : Version Info
 
byte [4-7] : boot timestamp
 
|-
 
| 0x202
 
|
 
byte [0-3] : Current time
 
byte [4]  : CPU usage %
 
|}
 
 
 
{| class="wikitable"
 
|+ Geographical Controller Communication Table
 
|-
 
| Message Number
 
| Purpose
 
| Data layout
 
|-
 
| 0x301
 
| Set GPS destination
 
|
 
  byte [0-3] : (float) Longitude
 
byte [4-7] : (float) Latitude
 
|-
 
| 0x501
 
| GPS Data Message
 
|
 
byte [0-3] : (float) Longitude
 
  byte [4-7] : (float) Latitude
 
|-
 
| 0x502
 
| Compass Data Message
 
|
 
byte [0-1] : (uint16) Current compass degree
 
byte [2-3] : (uint16) Destination compass degree
 
|}
 
 
 
{| class="wikitable"
 
|+ Sensor Controller Communication Table
 
|-
 
| Message Number
 
| Purpose
 
| Data layout
 
|-
 
| 0x501
 
| Sensor Data Message
 
|
 
byte [0] : Front sensor value in inches
 
byte [1] : Left sensor value in inches
 
byte [2] : Right sensor value in inches
 
etc.
 
|}
 
  
 
== How will communication work? ==
 
== How will communication work? ==
After startup, begin to send your data messages at the desired periodic rates using the periodic API as listed below in the example.  Whichever controller wants to listen to your periodic message shall intercept your message and use it for its needs.
+
After startup, begin to send your data messages at the desired periodic rates using the periodic scheduler as listed below in the example.  Whichever controller wants to listen to your periodic message shall intercept your message and use it for its needs. You can have global variables for the CAN data messages, and tasks should update the data within these messages.
 
 
You can have global variables for the CAN data messages, and tasks should update the data within these messages.  Assuming that you've added periodic message to be sent to broadcast address (0xFF), the periodic tasks will always grab the latest CAN message and send it out for you.
 
  
 
== Features ==
 
== Features ==
Line 270: Line 111:
  
 
*  Each controller shall display its version information at startup, for example:
 
*  Each controller shall display its version information at startup, for example:
*:  "Version 1.2"
+
*:  printf("Vesion: %s %s\n", __DATE__, __TIME__);
*:  "Fixed rear sensor reporting zero value"
 
*:  "Version 1.1"
 
*: "Added rear sensor value"
 
 
*  Each controller shall use the 2-digit LED display to display meaningful info
 
*  Each controller shall use the 2-digit LED display to display meaningful info
 
*:  Maybe Geo Controller can display # of feet to destination
 
*:  Maybe Geo Controller can display # of feet to destination
 
*:  Central controller can display number of CAN messages received per second.
 
*:  Central controller can display number of CAN messages received per second.
 
*  Each controller shall use the 4-LED lights for some indication
 
*  Each controller shall use the 4-LED lights for some indication
*:  LED0 should be lit if an error happens (common to everyone)
+
*:  LED0 should be lit if an error happens '''(common to everyone)'''
*:  Each LED should be labeled about what it means(maybe with a label machine?)
+
*:  Each LED should be labeled about what it means (maybe with a label maker?)
  
 
=== Robustness ===
 
=== Robustness ===
Line 285: Line 123:
  
 
Likewise, if you send a message, and it fails (in case the other controller is down), your CAN bus may go to abnormal state and turn off. In this condition, all of your messages will fail, and you will have to handle this.  I recommend the following:
 
Likewise, if you send a message, and it fails (in case the other controller is down), your CAN bus may go to abnormal state and turn off. In this condition, all of your messages will fail, and you will have to handle this.  I recommend the following:
Attach a BUS off callback function that gives "can_bus_crashed" semaphore.
+
In 1Hz periodic callback, check if the Bus if OFF, and simply reset it
If the semaphore is ever given, reset your CAN bus after a 3 second timeout.
+
Do not reset it in the CAN ISR callback from bus-off since a bad controller can continuously cause errors without the delay of 1Hz
  
 
=== Startup Tests ===
 
=== Startup Tests ===
Line 299: Line 137:
 
*  Where is the kill switch?
 
*  Where is the kill switch?
 
*  Can you remotely shut down the car in 3 seconds?
 
*  Can you remotely shut down the car in 3 seconds?
*  Where is the kill switch?
 
 
*  If your controller goes down, will it fully recover to "last known configuration"?
 
*  If your controller goes down, will it fully recover to "last known configuration"?
 
*  If critical sensor data stops coming, how will you stop the car?
 
*  If critical sensor data stops coming, how will you stop the car?
Line 313: Line 150:
 
<BR/>
 
<BR/>
 
=== Part 1: Basic structure and CAN initialization ===
 
=== Part 1: Basic structure and CAN initialization ===
<syntaxhighlight lang="C">
 
/************** can_msg_id.h *************/
 
#ifndef CAN_MSG_ID_H_
 
#define CAN_MSG_ID_H_
 
 
 
/**
 
* Have an enumeration of controller IDs
 
*/
 
typedef enum :uint8_t {
 
    cid_geographical_controller = 1,
 
    cid_central_controller = 2,
 
    cid_broadcast = 0xff
 
} cid_t;
 
 
/// TODO Each controller shall set its own ID
 
#define OUR_CONTROLLER_ID      (cid_central_controller)
 
 
/**
 
* Create a "union" whose struct overlaps with the uint32_t of CAN message id
 
*/
 
typedef union {
 
    /// This "raw" overlaps with <DST> <SRC> <ID>
 
    uint32_t raw;
 
 
    /// Struct members overlap with "raw"
 
    struct {
 
        uint32_t msg_num : 12; ///< Message number
 
        uint32_t src :  8;    ///< Source ID
 
        uint32_t dst :  8;    ///< Destination ID
 
    };
 
} __attribute__((packed)) controller_id_t;
 
 
/**
 
* Creates a message ID based on the message ID protocol
 
* @param [in] dst  The destination controller ID
 
* @param [in] msg_num  The message number to send to the dst controller
 
*
 
* @returns  The 32-bit message ID created by the input parameters
 
*/
 
static inline uint32_t make_id(uint8_t dst, uint16_t msg_num)
 
{
 
    controller_id_t cid = { 0 };
 
    cid.msg_num  = msg_num;
 
    cid.src = OUR_CONTROLLER_ID;
 
    cid.dst = dst;
 
    return cid.raw;
 
}
 
 
#endif /* CAN_MSG_ID_H_ */
 
</syntaxhighlight>
 
 
 
 
<syntaxhighlight lang="cpp">
 
<syntaxhighlight lang="cpp">
/************** main.cpp ************/
+
/************** periodic_callbacks.cpp ************/
#include "can_msg_task_mgr.hpp"
 
 
#include "can.h"
 
#include "can.h"
  
int main(void)
+
bool period_init(void)
 
{
 
{
 
     /* Initialize CAN Bus and set the acceptance filter(s) */
 
     /* Initialize CAN Bus and set the acceptance filter(s) */
 
     CAN_init(can1, 100, 10, 10, NULL, NULL);
 
     CAN_init(can1, 100, 10, 10, NULL, NULL);
 +
 
     /* TODO Initialize acceptance filters */
 
     /* TODO Initialize acceptance filters */
 
     CAN_reset_bus(can1);
 
     CAN_reset_bus(can1);
 
+
      
    /* This creates all of the periodic message tasks */
+
     return true;
    can_msg_task_init();
 
 
 
    /* TODO Add more tasks... */
 
 
 
    /* Start the scheduler to run all the tasks */
 
     scheduler_start();
 
 
 
     return 0;
 
 
}
 
}
 
</syntaxhighlight>
 
</syntaxhighlight>
 
<BR/>
 
<BR/>
  
=== Part 2: CAN Rx Task ===
+
=== Part 2: Periodic Parsing Task ===
Only one FreeRTOS task should be responsible to receive CAN messages (while any task can send a CAN message).  This receiving task should "route" the incoming messages to the appropriate "consumers" in your code.
+
Only one FreeRTOS periodic function should be responsible to receive CAN messages (while any task can send a CAN message).  This receiving task should "route" the incoming messages to the appropriate "consumers" in your code.
 +
 
 +
See the [[DBC Format]] article for more sample code related to handling the received messages over the CAN bus.
  
 
<syntaxhighlight lang="C">
 
<syntaxhighlight lang="C">
/* Either a "plain vanilla" FreeRTOS task, or run() method of scheduler_task */
+
void period_100Hz(void)
void rx_fanout_task(void *p)
 
 
{
 
{
 
     can_msg_t msg;
 
     can_msg_t msg;
    while(1) {
+
        // Process all messages that arrived in the last 10ms
         if (CAN_rx(can1, &msg, portMAX_DELAY)) {
+
         while (CAN_rx(can1, &msg, 0))  
             /* TODO This is psuedocode, so add your real logic here */
+
        {
            if (msgid.dst != cid_broadcast_addr && msgid.dst != OUR_CONTROLLER_ID) {
+
             /* TODO: Call auto generated code from DBC parser to parse the message */
                LOG_ERROR("CAN acceptance filter must be incorrect (0x%08X)!", msg.msg_id);
 
            }
 
            else if (common_command_message) {        /* 0x100 - 0x1FF */
 
                handle_common_cmd(msg);              /* 0x200 - 0x2FF */
 
            }
 
            else if (other_controller_response_msg) { /* 0x200 - 0x2FF */
 
                handle_cmd_rsp_msg(msg);
 
            }
 
            else if (our_command_message) {          /* 0x300 - 0x3FF */
 
                handle_our_cmd(msg);
 
            }
 
            else if (other_controller_data_message) { /* 0x500 - 0x5FF */
 
                handle_data_msg(msg);
 
            }
 
            else {
 
                LOG_ERROR("Unexpected Message ID: 0x%08X", msg.msg_id);
 
            }
 
 
         }
 
         }
    }
 
 
}
 
}
 
</syntaxhighlight>
 
</syntaxhighlight>
 
<BR/>
 
 
=== Part 3: Infrastructure code for sending CAN messages periodically ===
 
 
==== can_msg_task.hpp ====
 
<syntaxhighlight lang="cpp">
 
#ifndef CAN_TASK_HPP_
 
#define CAN_TASK_HPP_
 
 
#include <stdint.h>
 
#include "can.h"
 
#include "vector.hpp"
 
#include "scheduler_task.hpp"
 
 
/**
 
* The task that sends out the periodic messages of a list at the defined frequency.
 
*/
 
class canMsgTask : public scheduler_task
 
{
 
    public:
 
        canMsgTask(can_t canBusNum,  ///< The CAN bus to use
 
                  float rateHz,      ///< The message rate of this task
 
                  uint8_t capacity,  ///< The max capacity of the message list
 
                  uint8_t priority  ///< The priority of this task
 
                  );
 
 
        /// Init function
 
        bool init(void);
 
 
        /// FreeRTOS task method
 
        bool run(void *p);
 
 
        /// Add a periodic message to be sent by this task
 
        /// You probably cannot access it directly, so use can_msg_task_mgr.hpp's API
 
        bool addPeriodicMsg(uint8_t dst,          ///< Destination address
 
                            uint16_t msgNum,      ///< Message number
 
                            can_msg_t *pCanMsg    ///< Actual CAN message pointer
 
                          );
 
 
    private:
 
        /**
 
        * Structure of a periodic message
 
        */
 
        typedef struct {
 
            uint8_t dstAddr;        ///< The destination address of a node
 
            uint16_t msgNum;        ///< The message number for the node
 
            can_msg_t *canMsgPtr;  ///< Pointer to the actual CAN message pointer
 
        } periodicMsg_t;
 
 
        canMsgTask();              ///< Private default constructor, do not use.
 
        const float mTaskRateHz;              ///< The run duration of the task
 
        const can_t mCanBusNum;                ///< The CAN Bus number
 
        VECTOR<periodicMsg_t> mPeriodicMsgList; ///< The periodic message list
 
};
 
#endif /* CAN_TASK_HPP_ */
 
</syntaxhighlight><BR/>
 
 
=== can_msg_task.cpp ===
 
<syntaxhighlight lang="cpp">
 
#include "can_msg_task.hpp"
 
#include "can_msg_id.h"
 
#include "file_logger.h"
 
 
canMsgTask::canMsgTask(can_t canBusNum, float rateHz, uint8_t capacity, uint8_t priority) :
 
    scheduler_task("sendMsg", 3 * 512, priority),  ///< base class constructor calls
 
    mTaskRateHz(rateHz),        ///< Task rate in Hz
 
    mCanBusNum(canBusNum),      ///< CAN Bus to use
 
    mPeriodicMsgList(capacity)  ///< Construct the list
 
{
 
    /* Nothing to do */
 
}
 
 
bool canMsgTask::init(void)
 
{
 
    bool status = false;
 
    const uint32_t rateMs = 1000 / mTaskRateHz;
 
 
    /* The rate must be within reasonable bounds */
 
    const uint32_t minMs = 1;
 
    const uint32_t maxMs = 60 * 1000;
 
    if (rateMs >= minMs && rateMs <= maxMs) {
 
        setRunDuration(rateMs);
 
        status = true;
 
    }
 
 
    return status;
 
}
 
 
bool canMsgTask::run(void *p)
 
{
 
    can_msg_t msg;
 
    const uint32_t timeoutMs = 50; /* Some reasonable time */
 
 
    for (unsigned int i = 0; i < mPeriodicMsgList.size(); i++)
 
    {
 
        /* Use a const reference to avoid copying the item (it's like a const pointer) */
 
        const periodicMsg_t &periodicMsg = mPeriodicMsgList[i];
 
 
        /* Copy the CAN message from the CAN message pointer, this includes the
 
        * data length field which should've been set by the caller of addPeriodicMsg()
 
        * TODO: You may need a critical section here to avoid copying partial data
 
        */
 
        msg = *(periodicMsg.canMsgPtr);
 
 
        /* Form the message ID that we need to use */
 
        msg.msg_id = make_id(periodicMsg.dstAddr, periodicMsg.msgNum);
 
 
        /* We must be able to at least queue the message without a timeout otherwise
 
        * either the CAN Bus is over-utilized or our queue sizes are too small.
 
        */
 
        if (!CAN_tx(mCanBusNum, &msg, timeoutMs)) {
 
            LOG_ERROR("Error sending message from %uHz task within %u ms",
 
                      mTaskRateHz, timeoutMs);
 
        }
 
    }
 
 
    return true;
 
}
 
 
bool canMsgTask::addPeriodicMsg(uint8_t dst, uint16_t msgNum, can_msg_t *pCanMsg)
 
{
 
    bool ok = false;
 
 
    /* Populate the fields of the periodic message */
 
    periodicMsg_t periodicMsg;
 
    periodicMsg.dstAddr = dst;
 
    periodicMsg.msgNum = msgNum;
 
    periodicMsg.canMsgPtr = pCanMsg;
 
 
    if (! (ok = (NULL != pCanMsg))) {
 
        LOG_ERROR("pCanMsg was a NULL pointer (%uHz task)", mTaskRateHz);
 
    }
 
    else {
 
        /* Add the periodic message to our list or if no capacity, log an error*/
 
        if ((ok = (mPeriodicMsgList.size() < mPeriodicMsgList.capacity()))) {
 
            /* TODO Double check if this message doesn't already exist */
 
            mPeriodicMsgList.push_back(periodicMsg);
 
        }
 
        else {
 
            LOG_ERROR("List capacity for %uHz task has exceeded maximum periodic messages of %u",
 
                      mTaskRateHz, mPeriodicMsgList.size());
 
        }
 
    }
 
 
    return ok;
 
}
 
</syntaxhighlight><BR/>
 
 
==== can_msg_task_mgr.hpp ====
 
<syntaxhighlight lang="cpp">
 
#ifndef CAN_MSG_TASK_MANAGER_HPP_
 
#define CAN_MSG_TASK_MANAGER_HPP_
 
 
#include "can_msg_task.hpp"
 
#include "scheduler_task.hpp"
 
 
/// Enumeration of message rate
 
typedef enum {
 
    msgRate1Hz  = 0,
 
    msgRate10Hz,
 
    msgRate50Hz,
 
 
    /// Marks the last entry; do not use!
 
    msgRateLast,
 
} msgRate_t;
 
 
/// Initializes all of the CAN periodic message tasks
 
void can_msg_task_init(void);
 
 
/**
 
* Adds a message periodic to be sent at the given rate.
 
* @param [in] rate    The rate of the message
 
* @param [in] dst    The node address of the destination
 
* @param [in] msgNum  The message number of the CAN message ID
 
* @param [in] pCanMsg The pointer to the CAN message
 
*
 
* @returns true if the periodic was added successfully
 
*/
 
bool add_new_periodic_msg(msgRate_t rate, uint8_t dst, uint16_t msgNum, can_msg_t *pCanMsg);
 
 
#endif /* CAN_MSG_TASK_MANAGER_HPP_ */
 
</syntaxhighlight><BR/>
 
 
==== can_msg_task_mgr.cpp ====
 
<syntaxhighlight lang="cpp">
 
#include "can_msg_task_mgr.hpp"
 
 
 
/// Private instances of the canMsgTask pointers we create
 
static canMsgTask *g_MsgTaskPtrs[msgRateLast] = { NULL };
 
 
void can_msg_task_init(void)
 
{
 
    const can_t canbus = can1;  // CAN bus to use for the periodic tasks
 
    const uint32_t listCap = 10; // max periodic messages per periodic task (1Hz, 10Hz, 50Hz)
 
 
    /* Create all of the tasks and add them to the scheduler */
 
    scheduler_add_task((g_MsgTaskPtrs[msgRate1Hz]  = new canMsgTask(canbus,  1, listCap, 1)));
 
    scheduler_add_task((g_MsgTaskPtrs[msgRate10Hz] = new canMsgTask(canbus,  10, listCap, 2)));
 
    scheduler_add_task((g_MsgTaskPtrs[msgRate50Hz] = new canMsgTask(canbus,  50, listCap, 3)));
 
}
 
 
bool add_new_periodic_msg(msgRate_t rate, uint8_t dst, uint16_t msgNum, can_msg_t *pCanMsg)
 
{
 
    bool ok = false;
 
 
    if (NULL != g_MsgTaskPtrs[rate]) {
 
        ok = (g_MsgTaskPtrs[rate])->addPeriodicMsg(dst, msgNum, pCanMsg);
 
    }
 
 
    return ok;
 
}
 
</syntaxhighlight><BR/>
 

Latest revision as of 14:40, 15 July 2016

This project is about a large team getting a car to self-drive to a selected destination. This involves working with an RTOS running on a low power processor and various different processor boards working together over a CAN bus.

   
Self-Drive Car Block Diagram

Gitlab

Create a "master" Gitlab project that contains sub-folders of each project OR a Gitlab project that contains different "master" branches for each controller. Please provide me the access (Gitlab username: preet) to your master project so I can peek at all of your source code when needed. The Gitlab will track your commit history so I would also know how much work each person or team is contributing.

The folder structure should be:

  • TeamX_CmpE_Fall2015
    Sensor
    IO
    <other controller projects>

Parts

Controllers

Given below are the controllers, their duties, and the number of people involved. It is possible that one team gets done with their part, but that doesn't mean your job is done. If you are done, help others. If you are done, and the primary objective is met (the car can self-drive), then add more features. There are many things you can do, and the 16-week semester definitely won't provide an opportunity to sit and relax. Get up and learn!.

Controllers
Sensor Controller

(2 members)

  • Interfaced to front and rear vision.
    Consider Sonar, and/or IR sensors with long distance vision
  • Sensors must be "filtered" and must provide reliable "vision"
  • Provide additional sensor inputs:
    Provide battery voltage, and % charge remaining
    Light sensor reading
    Tilt (angle of the car)
Motor and I/O Controller

(2 members)

  • Interfaced to motor control system of the car
    Provide a means to steer, and drive the car
  • Provide feedback of the speed using a wheel encoder or speed sensor
  • Provide an LCD screen to report car status
    Errors and communication status
    Sensor values
  • Buttons to start and stop the car
  • Button hard-coded to set a specific destination
  • Provide means to turn on/off the headlights (etc).
Communication Bridge + Android

(2 members)

  • Provide means to communicate and display status on an Android/iPhone device
  • Allow a user to see sensor values, car speed (etc)
  • Allow a user to select a destination from Google Earth
Geographical Controller

(2 members)

  • Interface to a 5Hz or faster GPS
  • Interface to a compass
  • Allow a GPS coordinate to be "set"
    Based on the set coordinate, calculate, and provide CAN data regarding
    the current heading, and the desired heading to reach the destination
  • This unit needs to compute the "heading degree" to reach the destination
Central Controller

(2 members)

  • This is the primary unit that communicates with every controller to drive the car
  • This unit shall also turn on headlights (etc), and be the "brain" of the car
  • Upon a detection of a "Start" condition, work with different controllers to drive the car
    Motor Controller and Geographical Controller to drive the car to destination
    Avoid obstacles on the way to the destination
    Add features once you finish the primary goal

Communication

Each controller shall provide a means to communicate with the other controllers. Before you read any further, it requires that you have deep knowledge of the CAN bus. CAN is a BROADCAST communication bus, and the controller or message with the highest priority shall pick a lower CAN message ID.

Recommended CAN Message ID format

We can split the 11-bit CAN message ID into 2 portions, one that dictates the priority of the message (message type), and the other that dictates the priority of the controller. For example, the airbag sensor ECU should use lowest controller ID and lowest message type.

The split of message ID can also help filter out unwanted messages from arriving into your microcontroller as the CAN peripheral of the microcontroller will filter out the unwanted data. For example, you can choose to accept all messages from the sensor controller, while making sure you receive no messages from the motor controller. In particular, your CAN hardware filter needs a single EXTENDED GROUP filter.

CAN Communication Protocol (11-bit CAN ID)
Reserved bit Source Controller Message type
1-bit : B10 6-bit : B9:B4 4-bit : B3:B0

DBC Format

DBC format is a well known format to describe the format of a CAN message. This is essentially the schema of the data that is communicated over the CAN bus. Please view the linked DBC Format article for details before reading further.

How will communication work?

After startup, begin to send your data messages at the desired periodic rates using the periodic scheduler as listed below in the example. Whichever controller wants to listen to your periodic message shall intercept your message and use it for its needs. You can have global variables for the CAN data messages, and tasks should update the data within these messages.

Features

The first feature to develop is the self-drive capability and everything else comes later. While some people in the team may be focusing on delivering this primary feature, other members can focus on other things such as automatic headlights, variable speed settings through Android interface etc. If your product team fails, then just like it would happen in the industry, you will get laid off, and I will see you again in the course ;(

Quick and Easy Features

These features are mandatory, just to help you debug faster.

  • Each controller shall display its version information at startup, for example:
    printf("Vesion: %s %s\n", __DATE__, __TIME__);
  • Each controller shall use the 2-digit LED display to display meaningful info
    Maybe Geo Controller can display # of feet to destination
    Central controller can display number of CAN messages received per second.
  • Each controller shall use the 4-LED lights for some indication
    LED0 should be lit if an error happens (common to everyone)
    Each LED should be labeled about what it means (maybe with a label maker?)

Robustness

Your project is one project as a whole. So if it doesn't work, do not blame it on "hey, their controller crashed". If a controller crashes it will restart, and you will have live with missing data messages. So your code should be robust, and self-recover from any crashed event or any brief power disruptions.

Likewise, if you send a message, and it fails (in case the other controller is down), your CAN bus may go to abnormal state and turn off. In this condition, all of your messages will fail, and you will have to handle this. I recommend the following:

  • In 1Hz periodic callback, check if the Bus if OFF, and simply reset it
  • Do not reset it in the CAN ISR callback from bus-off since a bad controller can continuously cause errors without the delay of 1Hz

Startup Tests

Since we rely on multiple controllers, it is critical to be able to test each controller quickly, reliably, and easily. So here is a startup test the Central Controller must process upon each boot:

  • Central controller sends a message requesting boot information from each controller
  • Central controller checks responses after about 100 ms:
    Each controller must have responded
    Each controller's boot code (normal, abnormal) should be validated.

Considerations

You should consider and design your software for all of these events:

  • Where is the kill switch?
  • Can you remotely shut down the car in 3 seconds?
  • If your controller goes down, will it fully recover to "last known configuration"?
  • If critical sensor data stops coming, how will you stop the car?
  • How can you quickly discover one or more controllers reaching an error state?
  • Log the data on the SD card as much as possible.
    If something wrong happens, you need to know what happened.
    Each controller must log its "startup" time, to debug when a controller crashes and restarts

Grade

Your grade is relative. The best team earns the best grade. Remember than three out of three features working 100% is far better than nine out of ten features working. Focus on less features, with highest quality.

Sample Code


Part 1: Basic structure and CAN initialization

/************** periodic_callbacks.cpp ************/
#include "can.h"

bool period_init(void)
{
    /* Initialize CAN Bus and set the acceptance filter(s) */
    CAN_init(can1, 100, 10, 10, NULL, NULL);

    /* TODO Initialize acceptance filters */
    CAN_reset_bus(can1);
    
    return true;
}


Part 2: Periodic Parsing Task

Only one FreeRTOS periodic function should be responsible to receive CAN messages (while any task can send a CAN message). This receiving task should "route" the incoming messages to the appropriate "consumers" in your code.

See the DBC Format article for more sample code related to handling the received messages over the CAN bus.

void period_100Hz(void)
{
    can_msg_t msg;
        // Process all messages that arrived in the last 10ms
        while (CAN_rx(can1, &msg, 0)) 
        {
            /* TODO: Call auto generated code from DBC parser to parse the message */
        }
}