Difference between revisions of "Test"

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'''THIS PAGE APPEARS TO BE OUT OF DATE AND SHOULD PROBABLY BE ELIMINATED. See [[RGB Swarm Robot Project]].'''


== Overview ==
The swarm robot project has gone through several phases, with each
phase focusing on different aspects of swarm robotics and the
implementation of the project. This entry focuses on the most recent
phase of the project, covering topics such as, but not limited to,
'''Xbee Interface Extension Boards''', '''LED light boards''', and
'''changes made to the Machine Vision Localization System''', and the
overall conversion to LED boards and a controlled light environment.
These entries help provide insight into setup and specific details to
allow others to replicate or reproduce our results, and to provide
additional information for those working on similar projects or this
project at a later time. Other articles in the '''Swarm Robot
Project''' category focus on topics such as the swarm theory and
algorithms implemented, as well as previous phases of the project, such
as motion control and consensus estimation. You may reach these
articles and others by following the category link at the bottom of
every page, or through this link -
[[:Category:SwarmRobotProject|'''Swarm Robot Project''']].


== Hardware ==


===XBee Interface Extension Board===


{|
====Next Steps====
|
The LED Pattern Board design above needs to be modified in the following parts.
[[Image:XBee_interface_extenstion_board_v1.gif|250px|thumb|alt=Traxmaker
*The hole size for the LEDs has to increase so that it can accomodate the standoff of the LED chosen.
Image of the Previous Xbee Extension Board|Previous Version]]
*The hole size for the switch has to increase so that the switch can be completely inserted through the hole.
| [[Image:IMG 1390-1-.jpg|300px|thumb|alt=Image of an e-Puck with the
*Currently, 10 pos 2mm pitch socket is used to connect the color sensor to the circuit using wires. Instead, the proper header for the color sensor has to be found to connect the color sensor and the circuit more conveniently.
Xbee Extension Board|e-Puck with previous board ]]
|
[[Image:XBee_interface_extenstion_board_v2.gif|vertical|250px|thumb|alt=Traxmaker
Image of the Current Xbee Interface Exension Board|Current Version]]
|
|}


====Previous Version====
==Machine Vision Localization System Modification==
The Machine Vision Localization System takes the real (color) image from the four cameras, and converts it into a grey-scale image. Then, using a threshold set in the machine vision code, the grey-scaled image is divided into black and white, and this black and white image is presented on the machine vision system computer screen. With the current set-up, the white background on the floor is presented as black, and black dot patterns on e-pucks are presented as white patterns. The system recognizes theses white dot patterns and identify e-pucks, and broadcasts the position coordinates to each e-puck via the Xbee Radio. For more information about the theory and operation of the system, look through the [[Machine Vision Localization System]] article.


The previous version of XBee Interface Extension Board, designed by
However, there is a problem with using black dot patterns to identify e-pucks. Since the machine vision system and code use a preset threshold to divide the grey image into black and white, black dot patterns are affected by the background color due to lack of contrast. For instance, if the background is black, or any color besides white, the system would have a difficult time distinguishing the pattern from the background, and possible not capture them at all. In addition, other problems arise from dirt and debris tracked onto the white surface of the floor, resulting in false patterns, further throwing the system.
Michael Hwang.
Its configuration is shown in the figure on the left, with an actual
image of the board mounted on an e-Puck seen in the figure on the
right. This version of XBee Board does not contain a color sensor in
it. Details about this version of XBee Interface Extension Board, such
as parts used and Traxmaker files can be found on the
[[Swarm_Robot_Project_Documentation#Current_Version|Swarm Robot Project
Documentation page]].
<br clear="all">


====Current Version====
A solution is to substitute the black dots with LEDs placed atop the e-pucks, allowing the machine vision system to capture the identification pattern clearly regardless of background color and condition. By adjusting the threshold set in the machine vision code, the system will rely on the contrast of light intensity, minimizing the interference of the operating environment whose light intensity is which is naturally weaker than LEDs'.


===Compatibility Problem of Original Code with LEDs===
With the original code implementation, the system could not recognize LED patterns on e-puck; it only recognizes white patterns on the screen, which are black patterns in the reality. This problem can be simply fixed with modifying code to make the system capture LED patterns and present them as white patterns on the screen. The change of program will be shown in the next section. With this change, the system now makes LED patterns white dot patterns on the screen, so it can recognize them and identify e-pucks.


The upgraded version of XBee Interface Extension Board. It is designed
===Change from Original Code===
by Michael Hwang. This version has a color sensor circuit built in. The
In '''main.cpp''' in VisionTracking project, the code has been changed in
details of the color sensor circuit can be found in the color sensor
section below.


The RTS flow control line on the XBee is connected to the sel3 line of
<pre>
the e-puck. Although the CTS line is not connected to the sel2 pin in
Line 48:
this board design, it can be easily connected with a jumper.


This new version of XBee Interface Extension Board design was actually
cvThreshold(greyImage[camerai], thresholdedImage[camerai], threshold, 255, '''CV_THRESH_BINARY_INV''');
built and implemented on the e-puck # 3. In order to see if there is
any working problem in this board design, it is first tested with the
other e-puck which uses the previous XBee Boards.


The e-puck # 3 upgraded with the new XBee board did not show any
to
problem in communicating with other e-pucks. According to the goal
defined, all e-pucks, including e-puck # 3, locate themselves to the
desired location.
<br clear="all">
=====Color Sensor Circuit=====
{|
| [[Image:color_sensor_circuit_diagram_v1_R.gif|300px|thumb|Red Color
Sensor Circuit]]
| [[Image:color_sensor_circuit_diagram_v1_G.gif|315px|thumb|Green Color
Sensor Circuit]]
| [[Image:color_sensor_circuit_diagram_v1_B.gif|300px|thumb|Blue Color
Sensor Circuit]]
|}


As you may draw from the circuit diagrams above, as each photodiode
cvThreshold(greyImage[camerai], thresholdedImage[camerai], threshold, 255, '''CV_THRESH_BINARY''');
receives light, a certain amount of current start to flow through the
</pre>
photodiodes and generates a voltage across R<sub>1</sub> = 680K. Each
photodiode is designed to detect the certain range of wavelength of the
light, and the amount of current flowing through the photodiodes is
determined according to the amount of the corresponding light to each
photodiode. The op-amp (LMC6484) takes the voltage generated across
R<sub>1</sub> as the input signal, amplifying it by a ratio particular
to the circuit. This ratio is also known as gain, and is defined by
resistance of the potentiometer. The now amplified output is then sent
to the analog digital converter, which on the e-Puck had been used as
the X,Y, and Z axis accelerometers. This convenient, as each
accelerometer axis can be used as a channel for the color sensors three
colors. The converted signal can then be used to measure the response
of the color sensor to light. The corresponding equation for the
circuits illustrated above are as follows:


<math>|V_o| = |V_i * \frac{R_2}{R_{pot}}|</math>
and


*R<sub>pot</sub> = resistance of the potentiometer (shown in the
<pre>
diagram)
Line 735:
*R<sub>2</sub> = 100K (shown in the diagram)
*V<sub>i</sub> = voltage across R<sub>1</sub> = 680K, which the op-amp
takes as an input
*V<sub>o</sub> = output signal amplified from the op-amp


The gain of the color sensor circuits is approximately 20. Thus, the
cvThreshold(grey, thresholded_image, threshold, 255, CV_THRESH_BINARY_INV);
input voltage, V<sub>i</sub>, is amplified to be 20V<sub>i</sub>, which
is V<sub>o</sub>. As mentioned above, the gain can be adjusted properly
by controlling the resistance of the potentiometer.


As shown in the circuit diagram on the left, the siganl from the red
to
photodiode goes into the pin #5, and the amplified signal is sent out
through the pin # 7. Similarly, the signal from the green photodiode
goes into the pin #3 and it is sent out from pin #1 while the signal
from the blue photodiode goes into the pin #12, and it is sent out from
pin #14.


Output Pins
cvThreshold(grey, thresholded_image, threshold, 255, CV_THRESH_BINARY);
*Pin #7 - Amplified Red photodiode signal
</pre>
*Pin #1 - Amplified Green photodiode signal
*Pin #14 - Amplified Blue photodiode signal


=====Parts used=====
Also, in '''global_vars.h''',
Parts used in both the previous version and the new version of XBee
Interface Extension Board
*2x 10 pos. 2 mm pitch socket (Digikey S5751-10-ND)
*LE-33 low dropout voltage regulator (Digikey 497-4258-1-ND)
*2.2uF tantalum capacitor (Digikey 399-3536-ND)
*2x Samtec BTE-020-02-L-D-A (Order directly from Samtec)
*0.1"header pins for RTS and CTS pins (you can also use wire for a
permanent connection)
*2x 0.1" jumpers for connecting RTS and CTS pins if you used header
pins(Digikey S9000-ND)


Additional parts for new version of XBee Interface Extension Board
<pre>
*3x 100K resistors
Line 65:
*3x 680K resistors
*3x 10K potentiometer
*3x 5pF capacitor
*1x RGB color sensor (Order directly from HAMAMATSU, part#:s9032-02,
[http://jp.hamamatsu.com/resources/products/ssd/pdf/s9032-02_kspd1067e03.pdf
Datasheet])
*1x High impedence op-amp LMC6484


=====Future modifications=====
double threshold = 75; //black/white threshold
As mentioned in the overview, the black dot patterns of e-pucks are
replaced with new LED patterns by implementing LED pattern board at the
top of each e-puck. Thus, in order for the color sensor to collect data
properly, it is necessary to move the color sensor from the XBee
Interface Extension Board to the LED pattern board so that nothing will
block the color sensor. All other components for the color sensor
circuit remains in the XBee Interface Extension Board and only the
color sensor will be place in the LED pattern board. We can use a
jumper to connect the color sensor placed at the LED pattern board to
the color sensor circuit place in the XBee Interface Extension Board.
The datails of this LED pattern Board will be presented at the section
below.
----


===LED Pattern Board===
to
[[Image:LED_pattern_board.gif|left|thumb]]
This new LED pattern board is introduced for the Swarm Robot Project.
Currently, the unique black dot pattern of each e-puck was used for
the machine vision system to recognize each e-puck. However, this black
dot pattern requires a white background in order for the machine vision
system to recognize e-pucks. The new LED pattern board uses LEDs with
the proper brightness, instead of the black dot pattern. By doing so,
the machine vision system can now recoginize e-pucks on any background.
The reason why this LED pattern is recognized on any background will be
presented briefly in the Code section below. In addition, in order to
apply this LED pattern to the machine vision system, we made a
modification in code. This modification will also be presented in the
Code Section below. The PCB file can be downloaded here:
[[Media:LED_Pattern_Board.pcb]]
<br clear="all">
====LED Pattern Board Design====
This LED Pattern Board is created using Traxmaker. This LED Board
design can be downloaded here:
Although we replaced the black dots with LEDs, we maintain each pattern
of dots. The horizontal distance and the vertical distance between the
two adjacent LEDs are both 0.8 inch. In order to reduce power
consumption of the e-puck battery, we implement a seperate pair of AAA
batteries to supply power to the LEDs. This LED board can be turned on
and off by the switch.
The milicandela rating of the LEDs used is 4850 mcd. In addition, this
LED has diffused lens style. The reason to choose this LED is that it
has a proper brightness and power consumption, and it is diffused so
that the machine vision system can capture this LED in any places.The
resistor used are 68.7 ohm.


As mentioned in the XBee Interface Extension Board section, the color
double threshold = 200; //black/white threshold
sensor has to be moved to this LED pattern board from the XBee
</pre>
Interface Extension Board so that nothing blocks the sensor. Thus, as
you can see in the Figure on the left, the color sensor is place at the
front, and each photodiode is connected to the 10 pin header. This
header connects the color sensor on the LED pattern board to the
remaining part of color sensor circuit on the XBee Interface Extension
Board.


====Parts used====
As change '''''CV_THRESH_BINARY_INV''''' in both line 48 and 735 to '''''CV_THRESH_BINARY''''' and adjust the value of threshold from '''''75''''' to '''''200''''', the system now clearly presents LED patterns as white dot patterns on the screen, so it can identify e-pucks according to LED patterns.
*3x LED (Digikey 516-1697-ND): Some e-pucks require 4 LEDs since they
have a pattern composed of 4 dots
*3x 68.7 ohm resistors : Some e-pucks require 4 resistors since they
have 4 LEDs
*2x AAA Battery Holder (Digikey 2466K-ND)
*1x Switch (Digikey CKN1068-ND)
*1x RGB color sensor (Order directly from HAMAMATSU, part#:s9032-02)
*1x 10 pos. 2 mm pitch socket (Digikey S5751-10-ND)


====Tests====
===Further Threshold Testing===

The threshold value of ''200'' is determined to be good enough for the test inside. With various conditions, however, the threshold value can, or should, be changed more properly. In addition, the results for different range of threshold under the same test condition is presented below:
=====LED Distance vs Color Sensor Signal=====
Tests need be done in order to note the affect of the LED light on the
color sensor due to potential interference. The first experiment
performed is designed to see how much interference will be caused as
the distance between the LED and the color sensor changes.

'''Setup and Results'''

1. A white LED is used in this experiment because the white LED will
cover the entire wavelengh ranges of the visible light. The experiment
with the white LED can yield a general result, while the experiment
with the colored LEDs will yield more specific result focused on the
interference between the certain photodiode and the certain color.
*LED: 18950 mcd (millicandela), digikey part number:
C503B-WAN-CABBB151-ND

2. The experiment was performed under the two conditions; with the
ambient light and without the ambient light.

3. The LED and the color sensor were placed at the same plane, and both
are facing upward.

4. Distance between the color sensor and the LED is increased by 0.25
inch each time from 1 inch to 2.5 inch.

5. The amplified output, V<sub>o</sub> as shown in the circuit diagram
above, of each photodiode is measured.

With Ambient light
[[Image:Distance_vs_output_with_room_light.gif|450px|left|thumb]]
*Unit: Volt, V


{| class="wikitable" border="3"
{| class="wikitable" border="3"
|+'''Threshold range'''
|+'''Distance vs Amplified Output'''
|-
|-
! Range !! Result
! Distance !! R !! G !! B
|-
|-
| No LED|| 1 || 1.4 || 0.469
| 0 - 94 || System cannot caputure LED patterns at all; whole screen is white.
|-
|-
| 1 inch || 1.259 || 1.716 || 0.832
| 95 - 170 || System can recognize the pattern but it is unstable, since most of background becomes white.
|-
|-
| 1.25 inch || 1.185 || 1.619 || 0.757
| 171 - 252 || System cleary captures and recognizes LED patterns.
|-
|-
| 1.5 inch || 1.135 || 1.529 || 0.669
| 253|| System can recognize the pattern but it is unstable since pattern is too small; stronger intensity is required.
|-
|-
| 1.75 inch || 1.097 || 1.503 || 0.613
| 254 - 255 || System cannot caputure LED patterns at all; whole screen is black.
|-
| 2 inch || 1.086 || 1.481 || 0.589
|-
| 2.25 inch || 1.071 || 1.47 || 0.563
|-
| 2.5 inch || 1.06 || 1.453 || 0.546
|}
|}
<br clear="all">
Without the Ambient Light
[[Image:Distance_vs_output_without_room_light.jpg|450px|left|thumb]]
*Unit: Volt, V


{| class="wikitable" border="3"
|+'''Distance vs Amplified Output'''
|-
! Distance !! R !! G !! B
|-
| No LED|| 0.028 || 0.025 || 0.019
|-
| 1 inch || 0.244 || 0.221 || 0.223
|-
| 1.25 inch || 0.195 || 0.166 || 0.143
|-
| 1.5 inch || 0.162 || 0.123 || 0.097
|-
| 1.75 inch || 0.130 || 0.097 || 0.069
|-
| 2 inch || 0.102 || 0.077 || 0.054
|-
| 2.25 inch || 0.087 || 0.064 || 0.045
|-
| 2.5 inch || 0.073 || 0.056 || 0.039
|}
<br clear="all">
As you can see in the two graphs above, the color sensor is affected by
the light from the LED. The color sensor is most affectd by the LED
when the LED is closest to it. As the distance between the LED and the
color sensor increases, the interference decreases. When the color
sensor is most affected by the LED under the presence of the room
light, the output increases up to 25.9%, 22.6%, and 43.6 % of the
original output. As the LED is 2.5 inch away from the color sensor, the
output becomes very close to the original value.
In this experiment, we see that the lights from LEDs can affect the
color sensor. However, we used much brighter LED in this experiment
than the ones we use in the LED pattern board. The brightness of the
LED used in the experiment is 4 times larger than the ones in the LED
pattern board. Thus, more experiment with the LEDs used in the LED
pattern board is required.


=====LED Angle vs Color Sensor Signal=====
An e-puck was fitted with a LED pattern board and then tested with the machine vision localization system. With the changes implemented, the machine vision localization system did not show any problems, showing the ability to capture and locate the e-puck located in anywhere in the field of vision of the cameras. In addition, the vision system was able to capture and locate the e-puck as it moved. There was no loss of positional accuracy as compared to previous implementations of identification systems. The recognition of the e-puck by the machine vision localization system displayed the stability of the LED boards with the vision system, further supporting their implementation for further experiments.


The second experiment is designed to see how much interference will be
===Additional Considerations===
caused as the angle between LED and color sensor changes. Different
While there do not need to be any additional changes to the set up of the machine vision localization system, there may be additional considerations for further development. One such consideration is the 'background', or floor material, of the setup. With the modified machine vision code, light intensity is what is picked up and filtered by the system, thus rendering the LEDs from the e-pucks to be the only tracked objects. However, with more advanced set ups, such as one featuring light that is projected onto the background, this may present a problem with the machine vision system picking up reflected light. More testing has to be done with modifying the machine vision system threshold to see if there is an ideal threshold to accommodate this setup. Another option may be to use a non-reflective or matte surface for the background.
from the first experiment, V<sub>i</sub>, the voltage before amplified,
is mesured since amplified output, V<sub>o</sub>, easily reaches to the
maximum.


'''Setup and Results'''
Another consideration involves the hardware of the setup, or the themselves. The cameras are equipped with the Logitech software which automatically adjusts the exposure and light contrast settings to correct for poor lighting and setup conditions. However, this leads to issues as with increased exposure (due to light blocking set up) and bright LEDs results in blurry or blobby images received. The machine vision localization system cannot read these images, and as a result cannot track the e-pucks. One potential solution may be to adjust the threshold of the vision system. Other solutions may be to use less intense or bright LEDs, or increase the background lighting of the setup, for instance with upward casting lights.


1. A white LED is used again in this experiment with the same reason
=='''Conclusion'''==
above for the first experiment.
*LED: 18950 mcd, Digikey part number: C503B-WAN-CABBB151-ND


2. The experiment was performed under the two conditions; with the
The new XBee Interface Extension Board design was tested, and we found out that it does not have any problem. In addition, the black dot pattern of the e-pucks are upgraded to LED patterns. The advantage of this improvement is that the machine vision system can recoginize each e-puck no matter where the e-pucks are located. The color of the background also does not affect the vision system. However, we had to move the color sensor to the LED pattern board since the LED pattern board will block the sensor if the sensor is located in the XBee Interface Extension Board. Thus, we now consider the light interference between the LEDs and the color sensor. In the light interference test, we found out that the color sensor is affected by the light from LED. However, since we used much brighter LEDs in our light interference test than the LEDs used for the LED pattern board, we have to do more experiment on this in order to have more accurate interference data.
ambient light and without the ambient light.


3. In this experiment, the distance between LED and color sensor is
kept constant, 1 inch.


4. Angle between LED and color sensor is increased by 15
[[Category:SwarmRobotProject]]

Latest revision as of 15:25, 17 April 2010

THIS PAGE APPEARS TO BE OUT OF DATE AND SHOULD PROBABLY BE ELIMINATED. See RGB Swarm Robot Project.

Overview

The swarm robot project has gone through several phases, with each phase focusing on different aspects of swarm robotics and the implementation of the project. This entry focuses on the most recent phase of the project, covering topics such as, but not limited to, Xbee Interface Extension Boards, LED light boards, and changes made to the Machine Vision Localization System, and the overall conversion to LED boards and a controlled light environment. These entries help provide insight into setup and specific details to allow others to replicate or reproduce our results, and to provide additional information for those working on similar projects or this project at a later time. Other articles in the Swarm Robot Project category focus on topics such as the swarm theory and algorithms implemented, as well as previous phases of the project, such as motion control and consensus estimation. You may reach these articles and others by following the category link at the bottom of every page, or through this link - Swarm Robot Project.

Hardware

XBee Interface Extension Board

Previous Version
e-Puck with previous board
Current Version

Previous Version

The previous version of XBee Interface Extension Board, designed by Michael Hwang. Its configuration is shown in the figure on the left, with an actual image of the board mounted on an e-Puck seen in the figure on the right. This version of XBee Board does not contain a color sensor in it. Details about this version of XBee Interface Extension Board, such as parts used and Traxmaker files can be found on the Swarm Robot Project Documentation page.

Current Version

The upgraded version of XBee Interface Extension Board. It is designed by Michael Hwang. This version has a color sensor circuit built in. The details of the color sensor circuit can be found in the color sensor section below.

The RTS flow control line on the XBee is connected to the sel3 line of the e-puck. Although the CTS line is not connected to the sel2 pin in this board design, it can be easily connected with a jumper.

This new version of XBee Interface Extension Board design was actually built and implemented on the e-puck # 3. In order to see if there is any working problem in this board design, it is first tested with the other e-puck which uses the previous XBee Boards.

The e-puck # 3 upgraded with the new XBee board did not show any problem in communicating with other e-pucks. According to the goal defined, all e-pucks, including e-puck # 3, locate themselves to the desired location.

Color Sensor Circuit
Red Color Sensor Circuit
Green Color Sensor Circuit
Blue Color Sensor Circuit

As you may draw from the circuit diagrams above, as each photodiode receives light, a certain amount of current start to flow through the photodiodes and generates a voltage across R1 = 680K. Each photodiode is designed to detect the certain range of wavelength of the light, and the amount of current flowing through the photodiodes is determined according to the amount of the corresponding light to each photodiode. The op-amp (LMC6484) takes the voltage generated across R1 as the input signal, amplifying it by a ratio particular to the circuit. This ratio is also known as gain, and is defined by resistance of the potentiometer. The now amplified output is then sent to the analog digital converter, which on the e-Puck had been used as the X,Y, and Z axis accelerometers. This convenient, as each accelerometer axis can be used as a channel for the color sensors three colors. The converted signal can then be used to measure the response of the color sensor to light. The corresponding equation for the circuits illustrated above are as follows:

  • Rpot = resistance of the potentiometer (shown in the

diagram)

  • R2 = 100K (shown in the diagram)
  • Vi = voltage across R1 = 680K, which the op-amp

takes as an input

  • Vo = output signal amplified from the op-amp

The gain of the color sensor circuits is approximately 20. Thus, the input voltage, Vi, is amplified to be 20Vi, which is Vo. As mentioned above, the gain can be adjusted properly by controlling the resistance of the potentiometer.

As shown in the circuit diagram on the left, the siganl from the red photodiode goes into the pin #5, and the amplified signal is sent out through the pin # 7. Similarly, the signal from the green photodiode goes into the pin #3 and it is sent out from pin #1 while the signal from the blue photodiode goes into the pin #12, and it is sent out from pin #14.

Output Pins

  • Pin #7 - Amplified Red photodiode signal
  • Pin #1 - Amplified Green photodiode signal
  • Pin #14 - Amplified Blue photodiode signal
Parts used

Parts used in both the previous version and the new version of XBee Interface Extension Board

  • 2x 10 pos. 2 mm pitch socket (Digikey S5751-10-ND)
  • LE-33 low dropout voltage regulator (Digikey 497-4258-1-ND)
  • 2.2uF tantalum capacitor (Digikey 399-3536-ND)
  • 2x Samtec BTE-020-02-L-D-A (Order directly from Samtec)
  • 0.1"header pins for RTS and CTS pins (you can also use wire for a

permanent connection)

  • 2x 0.1" jumpers for connecting RTS and CTS pins if you used header

pins(Digikey S9000-ND)

Additional parts for new version of XBee Interface Extension Board

  • 3x 100K resistors
  • 3x 680K resistors
  • 3x 10K potentiometer
  • 3x 5pF capacitor
  • 1x RGB color sensor (Order directly from HAMAMATSU, part#:s9032-02,

[http://jp.hamamatsu.com/resources/products/ssd/pdf/s9032-02_kspd1067e03.pdf Datasheet])

  • 1x High impedence op-amp LMC6484
Future modifications

As mentioned in the overview, the black dot patterns of e-pucks are replaced with new LED patterns by implementing LED pattern board at the top of each e-puck. Thus, in order for the color sensor to collect data properly, it is necessary to move the color sensor from the XBee Interface Extension Board to the LED pattern board so that nothing will block the color sensor. All other components for the color sensor circuit remains in the XBee Interface Extension Board and only the color sensor will be place in the LED pattern board. We can use a jumper to connect the color sensor placed at the LED pattern board to the color sensor circuit place in the XBee Interface Extension Board. The datails of this LED pattern Board will be presented at the section below.


LED Pattern Board

LED pattern board.gif

This new LED pattern board is introduced for the Swarm Robot Project. Currently, the unique black dot pattern of each e-puck was used for the machine vision system to recognize each e-puck. However, this black dot pattern requires a white background in order for the machine vision system to recognize e-pucks. The new LED pattern board uses LEDs with the proper brightness, instead of the black dot pattern. By doing so, the machine vision system can now recoginize e-pucks on any background. The reason why this LED pattern is recognized on any background will be presented briefly in the Code section below. In addition, in order to apply this LED pattern to the machine vision system, we made a modification in code. This modification will also be presented in the Code Section below. The PCB file can be downloaded here: Media:LED_Pattern_Board.pcb

LED Pattern Board Design

This LED Pattern Board is created using Traxmaker. This LED Board design can be downloaded here: Although we replaced the black dots with LEDs, we maintain each pattern of dots. The horizontal distance and the vertical distance between the two adjacent LEDs are both 0.8 inch. In order to reduce power consumption of the e-puck battery, we implement a seperate pair of AAA batteries to supply power to the LEDs. This LED board can be turned on and off by the switch. The milicandela rating of the LEDs used is 4850 mcd. In addition, this LED has diffused lens style. The reason to choose this LED is that it has a proper brightness and power consumption, and it is diffused so that the machine vision system can capture this LED in any places.The resistor used are 68.7 ohm.

As mentioned in the XBee Interface Extension Board section, the color sensor has to be moved to this LED pattern board from the XBee Interface Extension Board so that nothing blocks the sensor. Thus, as you can see in the Figure on the left, the color sensor is place at the front, and each photodiode is connected to the 10 pin header. This header connects the color sensor on the LED pattern board to the remaining part of color sensor circuit on the XBee Interface Extension Board.

Parts used

  • 3x LED (Digikey 516-1697-ND): Some e-pucks require 4 LEDs since they

have a pattern composed of 4 dots

  • 3x 68.7 ohm resistors : Some e-pucks require 4 resistors since they

have 4 LEDs

  • 2x AAA Battery Holder (Digikey 2466K-ND)
  • 1x Switch (Digikey CKN1068-ND)
  • 1x RGB color sensor (Order directly from HAMAMATSU, part#:s9032-02)
  • 1x 10 pos. 2 mm pitch socket (Digikey S5751-10-ND)

Tests

LED Distance vs Color Sensor Signal

Tests need be done in order to note the affect of the LED light on the color sensor due to potential interference. The first experiment performed is designed to see how much interference will be caused as the distance between the LED and the color sensor changes.

Setup and Results

1. A white LED is used in this experiment because the white LED will cover the entire wavelengh ranges of the visible light. The experiment with the white LED can yield a general result, while the experiment with the colored LEDs will yield more specific result focused on the interference between the certain photodiode and the certain color.

  • LED: 18950 mcd (millicandela), digikey part number:

C503B-WAN-CABBB151-ND

2. The experiment was performed under the two conditions; with the ambient light and without the ambient light.

3. The LED and the color sensor were placed at the same plane, and both are facing upward.

4. Distance between the color sensor and the LED is increased by 0.25 inch each time from 1 inch to 2.5 inch.

5. The amplified output, Vo as shown in the circuit diagram above, of each photodiode is measured.

With Ambient light

Distance vs output with room light.gif
  • Unit: Volt, V
Distance vs Amplified Output
Distance R G B
No LED 1 1.4 0.469
1 inch 1.259 1.716 0.832
1.25 inch 1.185 1.619 0.757
1.5 inch 1.135 1.529 0.669
1.75 inch 1.097 1.503 0.613
2 inch 1.086 1.481 0.589
2.25 inch 1.071 1.47 0.563
2.5 inch 1.06 1.453 0.546


Without the Ambient Light

Distance vs output without room light.jpg
  • Unit: Volt, V
Distance vs Amplified Output
Distance R G B
No LED 0.028 0.025 0.019
1 inch 0.244 0.221 0.223
1.25 inch 0.195 0.166 0.143
1.5 inch 0.162 0.123 0.097
1.75 inch 0.130 0.097 0.069
2 inch 0.102 0.077 0.054
2.25 inch 0.087 0.064 0.045
2.5 inch 0.073 0.056 0.039


As you can see in the two graphs above, the color sensor is affected by the light from the LED. The color sensor is most affectd by the LED when the LED is closest to it. As the distance between the LED and the color sensor increases, the interference decreases. When the color sensor is most affected by the LED under the presence of the room light, the output increases up to 25.9%, 22.6%, and 43.6 % of the original output. As the LED is 2.5 inch away from the color sensor, the output becomes very close to the original value. In this experiment, we see that the lights from LEDs can affect the color sensor. However, we used much brighter LED in this experiment than the ones we use in the LED pattern board. The brightness of the LED used in the experiment is 4 times larger than the ones in the LED pattern board. Thus, more experiment with the LEDs used in the LED pattern board is required.

LED Angle vs Color Sensor Signal

The second experiment is designed to see how much interference will be caused as the angle between LED and color sensor changes. Different from the first experiment, Vi, the voltage before amplified, is mesured since amplified output, Vo, easily reaches to the maximum.

Setup and Results

1. A white LED is used again in this experiment with the same reason above for the first experiment.

  • LED: 18950 mcd, Digikey part number: C503B-WAN-CABBB151-ND

2. The experiment was performed under the two conditions; with the ambient light and without the ambient light.

3. In this experiment, the distance between LED and color sensor is kept constant, 1 inch.

4. Angle between LED and color sensor is increased by 15