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Revision as of 04:12, 22 May 2024
Contents
Project Title
Falcons
Abstract
The Falcon RC car project is the combined efforts of our team to create an autonomously RC Car that avoids all obstacles and follow GPS to reach the destination. Here, we have put in all our experience in software design, hardware design, unit testing, power systems, and mobile application development. Project development started in March of 2024 and ended in May 2024.
Introduction
The project was divided into 4 modules:
- Sensor and Bridge Controller
- Driver Controller
- Geo Controller
- Motor Controller
Driver controller is the master controller that receive inputs from sensor controller and geo controller, and gives output commands to motor controller. The destination coordinate is send from Android application to sensor node via Bluetooth. The app also send a hard start and stop to the car. The car starts only on receiving start signal from the app and stops completely on receiving stop signal from app.
Team Members & Responsibilities
<Team Picture>
Gitlab Project Link - https://gitlab.com/jincyjose491/sjtwo-c[1]
- Sensor
- Link to Gitlab user1
- Link to Gitlab user2
- Motor
- Link to Gitlab user1
- Link to Gitlab user2
- Geographical
- Link to Gitlab user1
- Link to Gitlab user2
- Communication Bridge Controller & LCD
- Link to Gitlab user1
- Link to Gitlab user2
- Android Application
- Link to Gitlab user1
- Link to Gitlab user2
- Testing Team
- Link to Gitlab user1
- Link to Gitlab user2
Schedule
Week# | Start Date | End Date | Task | Status |
---|---|---|---|---|
1 | 02/22/2024 | 02/26/2024 |
|
Completed |
2 | 02/26/2024 | 03/10/2024 |
|
Completed |
3 | 03/10/2024 | 03/12/2024 |
|
Completed |
4 | 03/12/2024 | 03/19/2024 |
|
Completed |
5 | 03/19/2024 | 03/26/2024 |
|
Completed |
6 | 03/26/2024 | 04/02/2024 |
|
completed |
7 | 04/02/2024 | 04/09/2024 |
|
Completed |
8 | 04/09/2024 | 04/16/2024 |
|
Not completed |
9 | 04/16/2024 | 04/23/2024 |
|
Not completed |
10 | 04/23/2024 | 04/30/2024 |
|
Not completed |
11 | 04/30/2024 | 05/07/2024 |
|
Not completed |
Parts List & Cost
Item# | Part Desciption | Vendor | Qty | Cost |
---|---|---|---|---|
1 | RC Car | Traxxas | 1 | $265.00 |
2 | SJ2 boards | CMPE SCE | 4 | $50.00 each |
3 | CAN Transceivers | Adafruit [2] | 4 | $3.95 each |
4 | Ultrasonic sensor | Adafruit [3] | 4 | $114.00 |
5 | GPS PA1616S BREAKOUT | Digikey [4] | 1 | $29.95 |
6 | LSM303AGR ACC COMPASS | Digikey [5] | 1 | $12.50 |
6 | LSM303AGR ACC COMPASS | Digikey [6] | 1 | $12.50 |
7 | LCD Display | Amazon [7] | 1 | $12.99 |
8 | RPM sensor | Traxxas [8] | 1 | $12.00 |
Printed Circuit Board
<Picture and information, including links to your PCB>
CAN Communication
<Talk about your message IDs or communication strategy, such as periodic transmission, MIA management etc.>
Hardware Design
<Show your CAN bus hardware design>
DBC File
<Gitlab link to your DBC file>
VERSION "" NS_ : BA_ BA_DEF_ BA_DEF_DEF_ BA_DEF_DEF_REL_ BA_DEF_REL_ BA_DEF_SGTYPE_ BA_REL_ BA_SGTYPE_ BO_TX_BU_ BU_BO_REL_ BU_EV_REL_ BU_SG_REL_ CAT_ CAT_DEF_ CM_ ENVVAR_DATA_ EV_DATA_ FILTER NS_DESC_ SGTYPE_ SGTYPE_VAL_ SG_MUL_VAL_ SIGTYPE_VALTYPE_ SIG_GROUP_ SIG_TYPE_REF_ SIG_VALTYPE_ VAL_ VAL_TABLE_ BS_: BU_: DBG DRIVER IO MOTOR SENSOR GEO BO_ 100 DRIVER_HEARTBEAT: 1 DRIVER SG_ DRIVER_HEARTBEAT_cmd : 0|8@1+ (1,0) [0|0] "" SENSOR,MOTOR BO_ 10 START_STOP: 1 SENSOR SG_ START_STOP_cmd : 0|8@1+ (1,0) [0|1] "cmd" MOTOR BO_ 200 SENSOR_SONARS: 5 SENSOR SG_ SENSOR_SONARS_left : 0|10@1+ (1,0) [0|500] "cm" DRIVER SG_ SENSOR_SONARS_right : 10|10@1+ (1,0) [0|500] "cm" DRIVER SG_ SENSOR_SONARS_middle : 20|10@1+ (1,0) [0|500] "cm" DRIVER SG_ SENSOR_SONARS_rear : 30|10@1+ (1,0) [0|500] "cm" DRIVER BO_ 210 GEO_STATUS: 8 GEO SG_ GEO_STATUS_COMPASS_HEADING : 0|10@1+ (1,0) [0|359] "Degrees" DRIVER, SENSOR SG_ GEO_STATUS_COMPASS_BEARING : 10|10@1+ (1,0) [0|359] "Degrees" DRIVER, SENSOR SG_ GEO_STATUS_DISTANCE_TO_DESTINATION : 20|16@1+ (0.1,0) [0|1500] "Meters" DRIVER, SENSOR SG_ GEO_STATUS_BEARING_ANGLE_TO_CHKPT : 36|10@1+ (1,0) [0|359] "Degrees" DRIVER, SENSOR SG_ GEO_STATUS_DISTANCE_TO_CHKPT : 46|16@1+ (1,0) [0|1500] "Meters" DRIVER, SENSOR SG_ GEO_STATUS_GPS_LOCK_ACQUIRED : 62|1@1+ (1,0) [0|0] "Boolean" DRIVER, SENSOR BO_ 250 GPS_DESTINATION_LOCATION: 8 SENSOR SG_ GPS_DEST_LATITUDE_SCALED : 0|32@1- (1,0) [-90000000|90000000] "Degrees" GEO SG_ GPS_DEST_LONGITUDE_SCALED : 32|32@1- (1,0) [-180000000|1800000000] "Degrees" GEO BO_ 300 MOTOR_CMD: 2 DRIVER SG_ MOTOR_CMD_steering : 0|8@1- (1,0) [-45|45] "degree" MOTOR SG_ MOTOR_CMD_movement : 8|8@1- (0.1,0) [-10|10] "kph" MOTOR BO_ 400 MOTOR_RPM_SENSOR_DATA: 1 MOTOR SG_ RPM_SPEED: 0|8@1+ (0.1,0) [0|10] "kph" DRIVER, SENSOR BO_ 500 MOTOR_STATUS: 2 MOTOR SG_ MOTOR_STATUS_steering : 0|8@1- (1,0) [-45|45] "degree" DRIVER SG_ MOTOR_STATUS_movement : 8|8@1- (0.1,0) [-6|6] "kph" DRIVER BO_ 510 DBG_DRIVER: 3 DRIVER SG_ driver_intention : 0|8@1+ (1,0) [0|0] "" DBG SG_ driver_steer_direction : 8|8@1+ (1,0) [0|0] "" DBG SG_ driver_drive_direction : 16|8@1+ (1,0) [0|0] "" DBG BO_ 800 DEBUG_GEO_COORDS_CURRENT: 8 GEO SG_ DEBUG_GEO_GPS_CURRENT_LAT_SCALED : 0|32@1- (1,0) [-90000000|90000000] "Degrees" DRIVER, SENSOR SG_ DEBUG_GEO_GPS_CURRENT_LON_SCALED : 32|32@1- (1,0) [-180000000|1800000000] "Degrees" DRIVER, SENSOR BO_ 801 DEBUG_GEO_COORDS_CHKPT: 8 GEO SG_ DEBUG_GEO_GPS_CHKPT_LAT_SCALED : 0|32@1- (1,0) [-90000000|90000000] "Degrees" DRIVER, SENSOR SG_ DEBUG_GEO_GPS_CHKPT_LON_SCALED : 32|32@1- (1,0) [-180000000|1800000000] "Degrees" DRIVER, SENSOR CM_ BU_ DRIVER "The driver controller driving the car"; CM_ BU_ MOTOR "The motor controller of the car"; CM_ BU_ SENSOR "The sensor controller of the car"; CM_ BU_ GEO "The geo controller of the car"; CM_ BO_ 100 "Sync message used to synchronize the controllers"; CM_ SG_ 100 DRIVER_HEARTBEAT_cmd "Heartbeat command from the driver"; BA_DEF_ "BusType" STRING ; BA_DEF_ BO_ "GenMsgCycleTime" INT 0 0; BA_DEF_ SG_ "FieldType" STRING ; BA_DEF_DEF_ "BusType" "CAN"; BA_DEF_DEF_ "FieldType" ""; BA_DEF_DEF_ "GenMsgCycleTime" 0; BA_ "GenMsgCycleTime" BO_ 100 1000; BA_ "GenMsgCycleTime" BO_ 200 50; BA_ "FieldType" SG_ 100 DRIVER_HEARTBEAT_cmd "DRIVER_HEARTBEAT_cmd"; VAL_ 100 DRIVER_HEARTBEAT_cmd 2 "DRIVER_HEARTBEAT_cmd_REBOOT" 1 "DRIVER_HEARTBEAT_cmd_SYNC" 0 "DRIVER_HEARTBEAT_cmd_NOOP" ;
Sensor Controller ECU
GitLab Link :Sensor Controller
Component selection
Selecting the appropriate sensor for an application is crucial. For this project, the sensor needs to be responsive, accurate, capable of operating in outdoor environments, and able to detect obstacles at long ranges. While there are numerous distance measurement options available, we have used MaxBotix (MB1010 LV EZ1) for all the positions. Initially we were thinking to use ultrasonic transducers sensors, but since it needs to have time measurement between the transmitted trigger signal and received echo which was complex software logic, it got ruled out. Maxbotix sensors have easy-to-use output formats and low power consumption of 2 mA for 3v power.
Hardware Design
Sensors are interfaced with combination of GPIO, ADC and other pins of the SJTwo board.
|
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Motor ECU
<Picture and link to Gitlab>
Hardware Design
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Geographical Controller
Geo controller: https://gitlab.com/jincyjose491/sjtwo-c/-/tree/master/projects/geo_controller?ref_type=heads
Navigation in modern systems seamlessly integrates GPS with compass technology to enhance driving experience and safety. GPS provides accurate location data by communicating with satellites, while the compass offers directional orientation of the vehicle. This combination is essential also in the RC car project as it enables the vehicle to autonomously maneuver to a given detsination coordinate. The GPS modules keeps track of the current position of the car, provides the direction that the car should move towards and the compass module keeps track of the direction in which the car is actually heading. Integrating the two modules, an algorithm has been developed as elaborated below to achieve the complete autonomous functionality.
Hardware Design
The Geo controller is interfaced to both the GPS module and the compass modules. Both these modules are powered using stable 3.3V inputs which are derived from the SJ Two boards. The GPS communicates with the board via UART and is connected to the controller at the P4.28 and P4.29, Rx and TX pins respectively. The GPS requires an antenna which is interfaced to the module via a UFL to SMA connector. Though the GPS module houses an led to indicate FIX on GPS lock, the led3 of SJTwo board was used to also show lock acquired after GPS string was received. The compass module communicates with the board via I2C and is connected at P0.10 SDA and P0.11 SCL pins respectively. As part of the hardware design, the compass module was mounted on a separate long pole, away from other interferences. The led1 of SJTwo board was used to indicate a successful comapss read.
<Layout pic>
Software Design
The GPS module provides data in the form of NMEA strings. NMEA (National Marine Electronics Association) is a standard protocol used by GPS receivers to transmit data. These strings contain various pieces of information, such as latitude, longitude, altitude, and time. The data bytes sent from the GPS module through UART are first loaded into a line buffer. The algorithm then parses this buffer to capture the specific $GPGGA strings that includes the correct position, time, and fix status.
Following is the GPS string parsing logic where the lattitude and longitude are retrieved:
static gps_coordinates_t gps_string_to_coordinates(char gps_line[line_buffer_size]) {
gps_coordinates_t coordinates = {0, 0};
char gps_line_copy[line_buffer_size];
strcpy(gps_line_copy, gps_line);
char *token = strtok(gps_line_copy, ",");
int token_count = 0;
char *tokens[6];
while (token != NULL && token_count < 7) {
if (token_count == 2 || token_count == 3 || token_count == 4 || token_count == 5 || token_count == 6) {
tokens[token_count - 2] = token;
}
token = strtok(NULL, ",");
token_count++;
}
// Check GPS Quality indicator value != 0 to see if FIX acquired
if (strtof(tokens[4], NULL)) {
GPS_fix_acquired = true;
coordinates.latitude = strtof(tokens[0], NULL);
char *latitude_dir = tokens[1];
coordinates.longitude = strtof(tokens[2], NULL);
char *longitude_dir = tokens[3];
if (*latitude_dir == 'S')
coordinates.latitude *= -1;
if (*longitude_dir == 'W') {
coordinates.longitude *= -1;
}
}
return coordinates;
}
The compass module required calibration to provide accurate results. This was accomplished using MotionCal software, interfaced with an Arduino. After determining the hard and soft iron offsets, these values were applied in the code to perform software-based compass calibration. The compass heading relative to true north was then calculated based on the mounting direction. Proper register configuration was necessary to initialize the module and read the compass readings accurately.
Following is the compass register settings for proper initialization:
void compass__init() {
i2c__initialize(current_i2c, i2c_baudrate_hz, clock__get_peripheral_clock_hz(), &binary_semaphore_struct,
&mutex_struct);
uint8_t ctrl_reg1_value = 0x8C;
uint8_t ctrl_reg2_value = 0x02;
uint8_t ctrl_reg3_value = 0x10;
i2c__write_single(current_i2c, magnetometer_write, MAGNETOMETER_CTRL_REG1, ctrl_reg1_value);
i2c__write_single(current_i2c, magnetometer_write, MAGNETOMETER_CTRL_REG2, ctrl_reg2_value);
i2c__write_single(current_i2c, magnetometer_write, MAGNETOMETER_CTRL_REG3, ctrl_reg3_value);
}
Checkpoint Algorithm
The checkpoint algorithm finds the nearest checkpoint coordinate based on the current location among a series of checkpoints, considering also the distance to destination coordinates. Initially, it calculates the distance between the current location and the destination. Then, it iterates through each checkpoint, finding the distance from the current location to the checkpoint and from the checkpoint to the destination. If both distances are less than the minimum distance to the destination found so far, it updates the minimum distance and sets the next checkpoint accordingly. Finally, it returns the coordinates of the closest checkpoint considering the destination. This ensures proper navigation by selecting the most relevant checkpoint.
gps_coordinates_t find_closest_checkpoint_coordinate(gps_coordinates_t current_coordinate,
gps_coordinates_t destination_coordinate) {
float min_distance_to_destination =
coordinates__get_distance_to_destination(current_coordinate.latitude, current_coordinate.longitude,
destination_coordinate.latitude, destination_coordinate.longitude);
gps_coordinates_t next_checkpoint = destination_coordinate;
for (uint8_t index = 0; index < max_checkpoints; index++) {
float distance_to_waypoint =
coordinates__get_distance_to_destination(current_coordinate.latitude, current_coordinate.longitude,
checkpoints[index].latitude, checkpoints[index].longitude);
float distance_from_waypoint_to_destination =
coordinates__get_distance_to_destination(checkpoints[index].latitude, checkpoints[index].longitude,
destination_coordinate.latitude, destination_coordinate.longitude);
if (distance_to_waypoint < min_distance_to_destination &&
distance_from_waypoint_to_destination < min_distance_to_destination) {
min_distance_to_destination = distance_to_waypoint;
next_checkpoint = checkpoints[index];
}
}
return next_checkpoint;
}
Technical Challenges
As the geo logic came as the final step in the project, it could only be tested thoroughly after all other modules performed reliably. Several issues were identified and resolved on the geo controller side:
- Problem: The compass was giving unreliable values and not pointing to true north.
- Solution: The compass needed to be calibrated for the environment in which it was used, especially with the motor running.
- Problem: The compass was giving a fixed range of values 170-250 dgrees, instead of the full 0-359 range, despite repeated calibrations.
- Solution: The register configurations had to be updated. Specifically, the block data update needed to be set, and offset cancellation had to be enabled.
- Problem: The GPS was giving no parsed outputs.
- Solution: The issue was traced back to soldering errors. The TX and RX wires were not swapped correctly; the TX of the board needed to connect to the RX of the GPS module, and vice versa.
- Problem: GPS was not acquiring stable lock inspite of testing it in open space and having the antenna connected.
- Solution: A button cell was added to the GPS module in the slot (rear side) provided in the module which enabled it to acquire locks faster.
- Problem: GPS parsing was incorrect and not returning proper data.
- Solution: The line buffer size was increased, and it was ensured that a lock was obtained before reading the data.
Communication Bridge Controller & LCD
<Picture and link to Gitlab>
Hardware Design
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Driver Node
Gitlab Link: https://gitlab.com/jincyjose491/sjtwo-c/-/tree/master/projects/driver?ref_type=heads
Hardware Design
Driver node gives the interconnection between input and output. It receives input from geo node and sensor node and give commands to the motor node. The only hardware driver has is the LCD display and CAN transceiver. The LCD display used is a SunFounder IIC I2C TWI Serial 2004 20x4 LCD Module and is interfaced through an I2C bus through the I2C2 port. The module used and pin connections for LCD is shown below.
|
Software Design
Driver has more software and less hardware. For navigation, there are two algorithms - obstacle avoidance and GPS navigation. Obstacle avoidance has precedence over GPS navigation. In case of any obstacle, car avoids obstacle. In other cases, it follows the path from geo node input. When the destination is reached, car slows down and stops.
Different debug signals were added to check the logic when car was working. This helped in corrected undesired behavior of car taking turns without obstacle, stopping without reason, etc. The debug values used and their indications are shown in below table.
|
Obstacle Avoidance
The obstacle avoidance code is written in the form of a truth table that has 4 bit input and one bit output. Inputs are four sensor values and output the motor commands. Bases on changes in sensor values, the motor command also changes. The logic that worked for us is given below
|
For GPS navigation the angle difference between heading and bearing is calculated and motor turn commands are generated based on this. Heading gives the current position in angle with respect to north. Bearing gives the angle to destination with respect to north. The logic that worked for our hardware is given below:
|
Technical Challenges
Since driver comes as the interconnect between all other nodes, the driver logic could be verified by outside testing only when we had stable input from geo and sensor node and motor nodes working as expected for given PWM. Unit testing can help in building of logic. But for actual test, we have to make sure all inputs are reliable. This can be verified with debug messages on bluetooth, CAN messages on busmaster, LCD display or LED indicators. The verification or debugging should be done in same frequency as which driver is processing.
- Problem: LCD was not displaying anything.
- Solution: Initially tried with 3.3V supply, then 5V supply and finally added level shifter to I2C pins. But the issue was slave address given in the datasheet was wrong. I got the correct slave address from web serial. After this was corrected, LCD worked well with 3.3V.
- Problem: LCD flickered a lot when everything was connected together.
- Solution: We initially connected all 5V supplies to a single 5V source. This included servo motor also. And it was causing the flicker. So, we powered up servo and rpm from ESC, all other sensors were powered separately from power bank and the issue was solved. This problem could have been avoided if more reports were read on how to power everything up.
- Problem: Driver gave a reverse signal for one clock cycle when there was no obstacle.
- Solution: Sensors gave random value for just one clock cycle and this caused driver to generate reverse command. After sensor inputs were corrected and made stable, the problem was solved.
- Problem: Driver not able to correct turning commands to motor even after sensing obstacle on side. This happened in the clock cycle when there was obstacle on all three side and it took reverse.
- Solution: We gave steps in angle changes in size of 5. Instead of direct 45 degree turn, car always turned in steps. So even though it sensed obstacle step sized turn angles took long clock cycles. So I finally reverted back to simple code logic of 45 degree turn and obstacle avoidance started working perfectly.
- Problem: We thought driver was giving wrong commands to sensor values that was there on app.
- Solution: Sensor values were updated at 1 Hz. Driver was working at 10Hz which is 10 times faster than what we see on app. So incorrect sensor value for just one cycle was not displayed. Finally debugged it in a hard way from all debugging sources listed above.
Mobile Application
<Picture and link to Gitlab>
Hardware Design
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Conclusion
<Organized summary of the project>
<What did you learn?>
Project Video
Project Source Code
Advise for Future Students
- Make sure you have a clear idea on how to power up every modules in the project. This require careful distribution of power across the boards, sensors, motors. Connect everything together in the initial stage to see if entire module can work well when connected together. Doing this at an early stage helps to understand how to correctly power up everything. Again, you'll get an idea on which all modules should/should not be connected together, which module require additional power source, etc. from previous reports. Most of your problems could be solved from previous year reports. Don't limit yourself to 2-3 reports. Read more.. It'll be useful.
- Try to interface everything and see if communication is reliable between the nodes. Do this early so that you can work on project requirements.
- Find out your motor PWM for forward, neutral and reverse as soon as you get the car. You can save time here.
- Simplify the wire connections to save time when you meet. When we met in the initial few weeks, most of the time was spent on connecting everything from scratch and figuring out why something is not working.
- Get good quality hardware so that you don't have to invest more time here.
Acknowledgement
We would like to thank our instructor, Preet, for all his efforts in our class and all motivation and guidance lifelong. We have learnt so much about unit testing, C coding, software-hardware integration, team work, git and documentation, all because of Preet.
We also have to acknowledge all the teams who came before us, their reports helped us a lot.