S13: Solar Panel Tracker

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Revision as of 05:47, 22 May 2013 by Matt s13 (talk | contribs) (Design & Implementation)

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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.

Solar Panel Tracker

Abstract

The objective of this project is to create a solar panel that tracks the sun. The project will consist of two stepper motors that control the position of the solar panels by using the photo resistors to detect the sun location.

Objectives & Introduction

Solar Panel Sun tracker uses the inputted voltage from photo resistors in order to adjust the position of the solar panel. The project uses and Analog to digital converter. The servo motors are controlled using a pulse; this controls the position of various angles. The servo uses in this project is a standard servo which can only position between 0 and 180 degrees.

The project required the following objectives to be accomplished:

  • Read the voltage from photo resistors
  • Control servo to move from 0 to 180 degrees
  • Compute the location which has the greatest light intensity
  • Determine algorithm to convert digital value into servo position


Team Members & Responsibilities

  • Arturo Montoya
    • Light Sensors (PWM driver) , Servo motor(ADC driver) , and Matrix (Spi driver)
  • Matthew Balhorn
    • FreeRTOS Software Design

Schedule

WeekPlanned TasksStatus

1

  • Order parts
  • Completed

2

  • Look over datasheet(s)
  • Test Servos
  • Design System Logics
  • Completed
  • Completed
  • Completed

3

  • Test Light-sensing circuit
  • Create System Schematics
  • Code Servo Task
  • Create Structure Design (Autodesk Inventor)
  • Completed
  • Completed
  • Completed
  • Completed

4

  • Code Light-sensing Task
  • Build/Machine Structure
  • Code Glue Logics (Directional Logic)
  • Completed
  • Completed
  • Completed

5

  • Integrate system
  • Test System
  • Project report
  • Completed
  • Completed
  • Completed

6

  • Finalize project
  • Finalize report
  • Completed
  • Completed

Parts List & Cost


Part QuuantityCostLink
LPC 1758 SJSU Dev Board 1 $60
180 Degree Servo 2 $25
Solar Panel 1 $15
LED Matrix 1 $25
Resistors 4 $.25
Photoresistors 4 $1.50
Jumper wires(x50) 1 $15
Servo belt 2 $2

Design & Implementation

Hardware Design

Structure Design

The structure of the Solar Panel Tracker consists of a 'base' servo to rotate the solar cell to a position in a 180 degree arch, and a 'top' servo which tilts the 'arm' which holds the solar cell and a photoresistor circuit. A second photoresistor circuit, used for the base direction logic, is located on top of the structure and angled in the same direction of the base rotational range. The base servo rotates the structure using servo belts and pulleys which move the structure resting on an old computer fan bearing. This provides for a smooth rotation.

Light Sensor

The Solar Panel Sun Tracker consists of the following hardware:

  • Resistors
  • Photo resistors

This section is responsible for interpreting the voltage of the photo resistors. The diagram below shows the circuit needed in order to get a voltage division of the two photo resistors. This voltage divider consists of two resistors on each side of the voltage divider output (ADC pin). When the top photo resistor has a greater resistance then the bottom resistor the voltage output will drop. When they both have the same resistance will hold in the middle.


CmpE146 S13 SPT LightSensorConnection.png
Figure 1: LightSensorConnection


Servo Motor

The servo section consists of the following hardware:

  • Servo Motors / Servo Belts
  • Solar Panel

This section is responsible for positioning the solar panels perpendicular to the light source. The panel is mounted to a frame that pivots according to the top servo. In order to perform a full scan the top servo motor was mounted on pivoting bases that is controlled by the second motor. The diagram below describes the complete setup in order to properly track the sun from sun rise to sun set.

CmpE146 S13 SPT SJOneBoardSchematic.png
Figure 2: SjOneInterface

Hardware Interface

CmpE146 S13 SPT SjOneInterface.png
Figure 2: SjOneInterface


SJSU Dev Board Pin Destination PinDescription
PWM1.4(p1.23) Servo Base Control Set pivot
PWM1.5(p1.24) Servo Top Control Set pivot
AD0.4(p1.30) Light Sensor Base Analog Input
AD0.5(p1.31) Light Sensor Top Analog Input

Pulse Width Modulation

PWM, or Pulse Width Modulation, was used to control the two 180 degree positional servos. The servos required a 50 Hz (20 ms) duty cycle, and the duration of the high duty cycle (in milliseconds) would control the position to move to. Typically, the valid high duty cycles are between 1.0 and 2.0 milliseconds, with 1.0 representing '0 degrees', 1.5 representing '90 degrees' and 2.0 representing '180 degrees.' However, we found that the valid duty cycle range was larger, ranging from [INSERT FULL RANGE]. Knowing this, we expanded the range of the duty cycle and converted the range into a degree range with the change_direction_with_Degree() function. The servos were connected to a 5V power supply and were controlled by PWM1-4(P1.23)and PWM1-5(P1.24).

146ServoPWM.png

Analog-to-Digital-Converter

ADC, or Analog-to-Digital-Converter, was used to convert the analog photoresistor circuit voltage into a digital value for processing. The pins ADC-4 and ADC-5 were used in the system, each connected to the output of one of the photoresistor circuits. The raw value was tough to work with, so a conversion to a more manageable range of values was implemented in higher level code.

Software Design

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Our software design centered on using two tasks to pass data used to track the sun. One task was a Light Sensor task, which is used to load data into the Queue, destined for the other task, a Servo Motor task. The Servo Motor task then calls a function to change the servo position. In order to support the tasks, and bridge the gap between them and the drivers, the LightSensors.cpp and ServoMotor.cpp source files were created.

CmpE146 S13 SPT FreeRTOS.png
Figure 2: FreeRTOS


CmpE146 S13 SPT SoftwareFlowchart.png
Figure : Flowchart of the Software Design

Implementation

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CmpE146 S13 SPT SjOneIO.png
Figure 2: Pins used for ADC and PWM
CmpE146 S13 SPT SJOneBoardPWMblockDiagram.png
Figure 2: FreeRTOS

Light sensor Logic

The LightSensors.cpp file contains the functions that the Light-sensing task calls. These functions are getDirection(), which reads the referenced Analog-to-Digital Converter pin (ADC-4 or ADC-5), and returns a value which is the new change in direction for the respective servo motor (Top or Base). The getDirection() function reads the ADC pin value and uses it to decide which direction the servo should move towards, and returns either a positive degreeChange, a negative degreeChange, or a 0 for no change. For this project, we decided to use 5 degrees as the degree change. The getDirection() function can be seen below:

146getDirectionBaseCodeSnippet.png

Servo motor Logic

The ServoMotors.cpp file contains the change_direction_withDegree() function, which updates the PWM Match Register for the given PWM signal and the degree. This function takes the degree value, ensures that it is within range, then converts it into milliseconds so it can be written to the respective Match Register, using the PWMUpdateMR() function defined in the PWM driver file. We used the definitions Max_degree, Servo_Width, Servo_Start, and freq_ms, whose values may need to be changed if a different servo motor is used. Max_degree is the farthest degree available to the servo motor (180), freq_ms is the duty cycle (20 ms), and the Servo_Width and Servo_Start are derived from the duty cycle thresholds (in ms) mapped to the degree range (0 - 180) of the servo motor.

146changeDirectionCodeSnippet.png

Light-sensing Task

The Light-sensing task was very simple. To keep it this way, all of the 'heavy lifting' was completed in lower level code in the LightSensors.cpp file. Therefore, the only function that the Light-sensing task needs to use is the getDirection() function. However, there is a small amount of code to prevent the degree values from going out of range (0-180 degrees). The task reads the getDirection() values for both the top and base servo motors, which have valid values of negative five (-5), zero (0), or positive five (5). These values are added to the current positional value to obtain updated values to pass to the Servo Motor task through the Queue.

Servo Task

The Servo Task is even simpler. It takes the top and base positional values from the Queue, then passes the value to the servo motors using the change_direction_withDegree() function, which is defined in the ServoMotors.cpp file.

CmpE146 S13 SPT ServoTask.png

Testing & Technical Challenges

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Servo Motor Mounting challenge

Initially, the base servo was mounted directly to the base, holding up the other servo, solar cell, etc. The base was unsteady and had a risk of damaging the servo. To fix this, the top servo, solar cell, etc. were mounted on an old computer fan bearing. The base servo motor was moved off to the side, with 2 belts and pulleys used to translate the rotation to the structure on the base.

Servo Motors Testing

We tested the Servo motors by sending an increasing range of active duty cycle time until the full range was found. Normally, servo motors have an active duty cycle range of 1.0 ms to 2.0 ms. Our servo motors had an actual range of 0.2 ms to 3.3 ms. Once we found this range, we had no problems with the servo motors.

Photoresistor Circuit Testing

We tested the photoresistor circuit by connecting it to an ADC pin and monitoring the digital values. Varying amounts of light were given to the circuit and appropriate changes in values were observed. For example, when the photoresistor connected to 5V receives more light than the other photoresistor(connected to ground), the voltage to the ADC pin drops. A corresponding drop in value was observed with the digital value. The same comparison was true with a spike in voltage and the spike in digital value, when the other photoresistor receives more light.

Integrated Testing

We tested the system after full integration by using a flashlight as a simulated sun. The Solar Panel Tracker correctly adjusted for every sun movement.

Conclusion

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Project Video

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Project Source Code

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References

Acknowledgement

Preet Kang

Dr. Haluk Ozemek

References Used

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Appendix

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