Difference between revisions of "S15: Hovercopter"

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== Integration ==
 
== Integration ==
 
Below are pictures of the actual design and integration of the entire system.
 
Below are pictures of the actual design and integration of the entire system.
[[File: S15 146 G1 des1.JPG|250px|left]]
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[[File: S15 146 G1 PowerSensor.JPG|250px|right]]
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[[File: S15 146 G1 des1.JPG|250px]]
[[File: S15 146 G1 emptyframe.JPG|250px|left]]
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[[File: S15 146 G1 PowerSensor.JPG|250px]]
[[File: S15 146 G1 Receiver.JPG|250px|right]]
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[[File: S15 146 G1 emptyframe.JPG|250px]]
[[File: S15 146 G1 final1.JPG|250px|left]]
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[[File: S15 146 G1 Receiver.JPG|250px]]
[[File: S15 146 G1 IMG 2234.JPG|250px|right]]
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[[File: S15 146 G1 final1.JPG|250px]]
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== Testing & Technical Challenges ==
 
== Testing & Technical Challenges ==

Revision as of 06:39, 24 May 2015

Grading Criteria

  • How well is Software & Hardware Design described?
  • How well can this report be used to reproduce this project?
  • Code Quality
  • Overall Report Quality:
    • Software Block Diagrams
    • Hardware Block Diagrams
      Schematic Quality
    • Quality of technical challenges and solutions adopted.

Hovercopter

Abstract

The goal of our project is to design a quadcopter that is capable of self-stabilizing with altitude holding capabilities. The software will use a PID control algorithm to stabilize the motor speeds according to the accelerometer and gyroscope sensor values. The hardware will consist of interfacing the SJSU One board with an Adafruit 10-DOF sensor, remote control receiver, five sonar sensors, an electronic speed controller (ESC), and the four motors. The quadcopter will be able to avoid obstacles using the sonar sensors.

Introduction

Self-stabilization of quadcopters requires that all four rotors are working together to correct themselves according to the gyroscope reading. Our goal for this lab is to get the quadcopter to self-stabilize, and hold its altitude. This is not a simple task. Getting the quadcopter to stabilize on the pitch and roll axis individually is already a huge task alone, but to get them both to hover with both working simultaneously is tough. The flight controller is programmed into the SJSUOne board. Everything ranging from stabilization to remote control is handled on this board. A PID algorithm is used to handle stabilization. This algorithm has been provided and written. Most of our code configuration lied within setting proper normalized values of the remote and to get the proper frequency settings. We spent the bulk of our time finding proper PID coefficients to get the proper stabilization. We have used several different methods including brute force, Ziegler-Nichols, and Cohen-Coon methods.

Objectives

Our objectives include the following:

  • Self-balancing and self-stabilizing system with the ability to pitch forward, pitch backward, roll left, roll right, yaw left, and yaw right.
  • Altitude hold with the use of a sonar sensor and obstacle avoidance with the use of 4 sonar sensors.
  • Clear unobstructed communication from the remote control transmitter to the remote control receiver located on the system.
  • Arm/Disarm
  • Kill switch
  • SD Card logging

Team Members & Responsibilities

  • Arlen Eskandari
  • Jonathon Hongpananon
  • Phillip Tran

Schedule

Week# Start Date End Date Task Status Actual Completion Date
1 4/14/2015 4/20/2015 Correctly route North, South, East, and West pins to their respective motor/ESC wire locations. Start testing and determining a proper P value, then I, then D value. Complete 4/20/15
2 4/21/2015 4/27/2015 Continuation of determining Proportional, Integral, and Derivative values. Complete 4/30/15
3 4/28/2015 5/4/2015 Install sonar sensors for future altitude holding. Use pid tune task which iterates through a range of selected P, I, and D values. This will log the PID output with the respective PID values onto the SD card. We will use Excel to graph the output to determine the smoothest curve with no overdamp/underdamp effect. Complete 5/7/15
4 5/5/2015 5/11/2015 Continuation of PID fine Tuning Complete 5/23/15
5 5/12/2015 5/18/2015 Fix gyroscope sensor readings and tune PID values for yawThrottle. Complete 5/15/15
6 5/19/2015 5/22/2015 Test complete movement consisting of pitch forward, pitch backward, roll right, and roll left. Complete 5/21/15

Parts List & Cost

Give a simple list of the cost of your project broken down by components. Do not write long stories here.

Qty Description Manufacturer Part Number Total Cost
1 FPV 4-Axis Quadcopter Frame kit w/ Protective Guard UFO $41.00
1 Brushless 25A SimonK 4-in-1 ESC Built-in UBEC Emax 24A*4-UBEC $29.00
4 6045 Carbon Nylon Propellers Gemfan $4.00
1 SJOne Board Preet LPC1758 SJSU Board $80.00
1 9X 9ch Transmitter w/ Module & 8ch Receiver Turnigy TX-9X-M2 $60.00
1 x2204 2300kv Brushless Motors - set of 4 SunnySky SNS-X2204S-KV2300 $63.00
2 4000mAh 3S 30C Lipo Battery Pack Turnigy T4000.3S.30 $22.00
1 50W 5A Balancer Charger Hobbyking ECO6 $19.00
1 4-mm to XT-60 Battery Adaptors - set of 2 Turnigy XT60-HXT4MM $3.00
1 105W 15V/7A DC power supply Hobbyking 9052000023-3 $15.00
1 3.5mm Gold Connectors Polymax $2.00
1 Short Nylon Threaded Spacers $8.00
1 Long Nylon Threaded Spacers $6.00
1 Test Environment Frame for testing Home Depot $15.00
Total Cost (excluding shipping and taxes) $367.00

Design & Implementation

Hardware Design

To make the quadcopter a SJOne board is used on which the flight controller software is developed. This board reads the sensors values and generates the PWM (Pulse Width Modulation) pulses to drive the four motors. In this project four KV2300 Sunnysky brushless servo motors are used. 2300KV means that for each one volt applied to the motor it will produce an RPM of 2300. The battery used in this project is 3cell 11.8V which roughly produces 27k rpm. Each of the motors are capable of lifting 500 grams on full throttle.

These motors are very fast so they draw a lot of current which can’t be provided by SJOne board, so too make the motors to spin the output of the SJOne board is fed into an ESC (Electronic Speed Controller). The EMAX ESC used is capabale of delivering 25 Amperes of continuous current for each motor. Wires to connect the motors to the ESC are 18AWG to be able to support the high current that motors are drawing. The battery is directly connected to the ESC which is used to power the four motors and part of it is also regulated to 5Volts which is used as the power source for other on board electronic systems. A separate power distribution board is designed which provides both 5 and 3.3 volts. The ADAFruit sensor board, along with five sonar sensors, and the remote control receiver which operate with 3.3 Volts receive their supply voltage from this board. The SJSU one board is also connected to this board for its 5Volt supply voltage.

A UFO frame with propellers guard (figure xx) is used for this project. This frame is mainly chosen for safety reasons since the propellers spin very fast and can be dangerous. The ADAFruit sensor board uses the I^2 C bus, so it is connected to SDA2 and SCL2 signals of SJOne board. The remote control receiver is connected to the GPIO pins as follows:

P0.0 RC-Ch1 – Pitch (Ch2. of RC receiver - Grey wire)

P0.1 RC-Ch2 - Roll (Ch1. of RC receiver - White wire)

P0.29 RC-Ch3 - Yaw (Ch4. of RC receiver - Orange wire)

P0.30 RC-Ch4 - Throttle (Ch3. of RC receiver - Yellow wire)

P2.6 RC-Ch5 - Arm/Disarm Gear Switch on RC Remote

The four motors are connected to the PWM enabled GPIO ports of the SJOne board in following order:

P2.0 North Motor

P2.1 South Motor

P2.2 East Motor5

P2.3 West Motor


Figure. 1 Hardware Design

Remote Control Transmitter & Receiver

Figure 2. Remote Controller

The remote control transmitter is responsible for transmitting the desired throttle, pitch, roll, and yaw angles. We chose the FlySky FS-T6 model, which has 6 available channels. The operating frequency is 2.4GHz and the remote comes with many features including a backlit LCD. The channels and their associated operation are :

Channel 1 - Pitch

Channel 2 - Roll

Channel 3 - Throttle

Channel 4 - Yaw

Channel 5 - N/A

Channel 6 - Arm/Disarm

Motors

Figure 3. Brushless Motors

Brushless motors are perfect for quadcopters because of their superior efficiency. They are much more powerful than conventional brushed motors and less electrical energy is wasted. The fewer mechanical parts result in reduced operational noise and quieter performance. Brushless motors work by producing magnetic fields to produce electric charges. Magnets will attempt to align, thus, causing the motor to spin. A continuous flow on multiple magnets will result in constant spinning depending on the signals sent to the device. Different currents are flowing through different coils making the motor shaft spin. The speed of the spinning motor shaft is controlled by an ESC (electronic speed controller) and is performed by switching the motor coils on or off rapidly at different, but synchronized, times.

Electronic Speed Controller (ESC)

INSERT GENERAL INFORMATION ABOUT ESC HERE

Figure 4. Electronic Speed Control

IMU Sensor

Fig. 5 Inertial Measurement Unit

The IMU (Intertial Measurement Unit) is a sensor that measures the orientation of the quadcopter. This is the device that is used in conjunction with the SJSUOne board to compute proper PID values and for the remote control to request angles for pitch, roll, and yaw. In our case, Y points to the north by default, though we did make some adjustments regarding the orientation.









SJOne Flight Controller

Figure 6. SJSUOne Board

The SJSUOne board is programmed and configured to be the flight controller of the quadcopter. The RC receiver, the sensor, and the ESC are all hooked up to the board. Each of these devices are actively working together and are controlled by the board. The boards’ layout is as follows:

Motor Orientation


No. Pin Motor Orientation
1 2.0 North
2 2.1 South
3 2.2 East
4 2.3 West

RC Inputs


No. Pin Input
1 0.0 Pitch
2 0.1 Roll
3 0.29 Yaw
4 0.30 Throttle
5 2.6 Arm/Disarm

Hardware Interface

Figure 7. PWM Samples

Communication protocols used :

  1. UART - Serial communication and telemetry.
  2. PWM (Pulse Width Modulation) - Decoding remote control signals into pulse signals the ESC's can use to drive the motors
  3. Interrupts - Usage of the GPIO ports on the SJSU One board and the timer API to capture the PPM signals from the remote control transmitter to receiver.

Software Design

Our software utilizes object oriented programming (OOP) concepts. There are many types of "objects" which hold data in our system. For example, mFlightControllerAngles holds the current setpoint angles for all axis, mCurrentAngles holds the current x, y, and z-axis angles, and mMotorValues holds the motor values which will be applied to the motors. There are several different classes which separate the different functions in the system. The lowest level class, MotorControllerIface is an abstract class which contains undefined virtual methods. These virtual methods are defined in inherited classes which will use them. The FlightStabilizer class is responsible for controlling flight parameters using the sensor data and controlling lower-level flight logic. The highest level class, QuadcopterBase, is defined for high-level flight logic such as autonomous GPS flying.

PID Controller

S15 146 G1 PID1.png

PID (proportional, integral, and derivative) is a closed-loop control system that tries to get results closer to the desired setpoint by adjusting the inputs of the system. The PID controller calculates an error, which is the difference between the measured variable and desired setpoint. The PID controller tries to minimizes the error throughout the operation. Our system takes the measured sensor data and compares against expected values (from the remote control) to alter the PWM output which will be applied to the ESC's and motors. The PID controller contains 3 separate parameters - proportional, integral, and derivative. P depends on the present, I on the accumulation of past errors, and D is a prediction of future errors based on the current rate of change. A higher P tries harder to stabilize itself - which can result in overshoot if too high. I attempts to reduce error based on past errors. The longer the error persists, then the more I will attempt to correct itself. Too much I can result in oscillations at lower frequencies. D attempts to dampen the system and prevent fast movements. However, too high of a D will also introduce oscillations.

Implementation

System Initialization

  1. Get the sensor inputs
  2. Update the flight sensor system data
  3. Update flying logic
  4. Run PID loop
  5. If timing is skewed, light up LED and increment TimingSkewedCount.
  6. If armed, apply motor values. Otherwise, apply value 0 to motors.

Remote Control Signal Decoding

  1. Initialize ports for interrupt on rising and falling edges of inputs.
  2. On rising edge of signal, start timer capture.
  3. On falling edge of signal, stop timer capture.
  4. Pulse width = stop - start

Get normalized values of decoded remote control pulse width signals

  1. If throttle, scale from 0 to +100 for 0% to 100% by using a scaling factor and subtracting factor. Apply value to throttle of flight parameters.
  2. Else, scale from -45 degrees to +45 degrees by using a separate scaling factor and subtracting factor. Apply values for requested flight angles.
  3. Set limits and noise margins for robustness.

Integration

Below are pictures of the actual design and integration of the entire system.

S15 146 G1 des1.JPG S15 146 G1 PowerSensor.JPG S15 146 G1 emptyframe.JPG S15 146 G1 Receiver.JPG S15 146 G1 final1.JPG S15 146 G1 IMG 2234.JPG

Testing & Technical Challenges

Issue #1

Issue: We first had inconsistent motor/propeller spinning. They were not spinning with normal behavior so we traced it back to the values that are applied to the motor from the remote control signals. The values decoded from the remote controls signals were incorrect. The ESC"s accept PWM servo pulses upon calibration and we initially had the SJSU One board outputting PWM duty cycle signals to the ESC. We reworked the remote control decoding functions to correct PWM pulses ranging from 1ms to 2ms wide pulses.

Result: The result was smooth operation of motors/propellers when throttle was applied from the remote control to the SJSU One board.

Issue #2

Issue: During the week of 4/24/15 to 4/29/15, we had remote control transmitter issues. It started out with random spikes in throttle pulse widths. We fixed the random spikes by adding control in our software, but eventually the throttle had no response. Change in the joystick would have no effect on the actual pulse width received from the receiver.

Result: Our solution was to order a different brand, especially not the Turnigy 9x. We opted for the FlySky FS-T6 remote control transmitter. So far, it has better response, light up display, and ability to adjust throttle curve which the Turnigy didn't have. Another issue that we have faced though, is the channel that we want our roll to be on does no work, instead, we have replaced the yaw channel with roll as a temporary fix.

Conclusion

We have learned many valuable things from this project. Besides team-work and process planning, we learned many things that can be applied to future work. Before this project, we had no experience with remote control PWM signal processing, PID feedback control, or flying with devices. This project has expanded our tool-set because we broadened our experience with real-world applications. Also, we learned that PID tuning is not just a simple plug and play process. Majority of the time spent on the project was devoted towards PID tuning. You can have a set of PID coefficient gains that are optimal for a smooth or aggressive flight and you won't know how it actually reacts until you start flying it. For example, we made a test-bed rig for tuning on 1 axis at a time and were able to log many different sets of PID values that seemed suitable for flying. Actually flying it on its own is a completely different story. Three different axis running plus outside disturbances such as wind and turbulence will have an affect on the real-time operation and flying. Another important thing we learned from this project is signal processing. We learned how to encode and decode signals from one form to another. What we have ultimately learned from this project is that planning and testing phases are crucial for a project, especially a quadcopter, to run well. Without a doubt, we will continue to utilize knowledge from this project towards other future projects.

Project Video

Initial testing of P values : https://www.youtube.com/watch?v=IqSVVo5YJBs&feature=youtu.be

Second stage of testing with P, I, and D values : https://www.youtube.com/watch?v=PpRCZm-XeGI

Initial flight testing : https://www.youtube.com/watch?v=7N-rQDqYn_8

Project Source Code

References

Acknowledgement

Any acknowledgement that you may wish to provide can be included here.

References Used

http://www.rctoys.com/pr/2009/05/25/all-about-brushless-motors-what-you-need-to-know/

http://blog.oscarliang.net/quadcopter-pid-explained-tuning/