Line 6: Line 6:
 
Created a list of all things that need to be interfaced with the processor and what kind of interface each one needs:<br>
 
Created a list of all things that need to be interfaced with the processor and what kind of interface each one needs:<br>
  
Interfaces Needed For Processor
+
<b>Interfaces Needed For Processor</b>
  
 
*1)Motor Control -  4 total PWM channels for right motor and left motor plus 2 additional ones to control the turret rotation and barrel pitch. Whether or not a PWM is 100% necessary will need to be discussed with Hong Kong.
 
*1)Motor Control -  4 total PWM channels for right motor and left motor plus 2 additional ones to control the turret rotation and barrel pitch. Whether or not a PWM is 100% necessary will need to be discussed with Hong Kong.
Line 18: Line 18:
 
*7)Fire Cannon (optional) – 1 general purpose IO (output a digital 1, which may need driving to fire)  
 
*7)Fire Cannon (optional) – 1 general purpose IO (output a digital 1, which may need driving to fire)  
 
*8)GPS – (optional) – 2 General purpose IO pins for UART.  
 
*8)GPS – (optional) – 2 General purpose IO pins for UART.  
 
+
<br>
 +
<br>
 +
<b>Sensors</b><br>
 +
*<u>IR Proximity Sensors</u>: The IR sensors selected
  
 
<u>Wireless Transceiver</u><br>
 
<u>Wireless Transceiver</u><br>

Revision as of 09:36, 28 October 2011

Topics from meeting (October 25th)

Attendees: Jason Holmes, Scott Stack, Kin Chin Chua, Chris Romanoff


Created a list of all things that need to be interfaced with the processor and what kind of interface each one needs:

Interfaces Needed For Processor

  • 1)Motor Control - 4 total PWM channels for right motor and left motor plus 2 additional ones to control the turret rotation and barrel pitch. Whether or not a PWM is 100% necessary will need to be discussed with Hong Kong.
  • 2)Wireless Module – 1 SPI/UART/I2C interface to send data and configure the wireless module which will in turn send the data over the internet. The chosen tranceiver can handle all of those interfaces - the one chosen will be based on the required throughput.
  • 3)Camera choices:
    • a)Wireless IP camera – (nothing required for processor)
    • b)Integrated camera – 9 General purpose IO and one I2C interface. Most CMOS cameras have 8 bit parallel output for image data and can be intialized and configured through an I2C interface. So, the board needs 8 general purpose for parallel data input and one for data clock. I2C interface to configure camera.
  • 4)Accelerometer – 3 A/D input (1 for each axis)
  • 5)IR Proximity Sensors – max of 4 A/D converter inputs (one for each sensor)
  • 6)Pushbutton to detect collision – max of 4 general purpose IO (one for each button)
  • 7)Fire Cannon (optional) – 1 general purpose IO (output a digital 1, which may need driving to fire)
  • 8)GPS – (optional) – 2 General purpose IO pins for UART.



Sensors

  • IR Proximity Sensors: The IR sensors selected

Wireless Transceiver
Our choice of camera will impact what kind of bandwidth our wireless transceiver will need to handle . We determined that most image sensor cameras output too much data to be sent usefully over the internet (wireless transceiver can handle a max of 1 Mbit per second UART, but also has a 44MHz clock and SPI - so any reasonable data rate could be handled. A 640x480 color image from one of the cameras we looked at will produce about 16Mbits per second at 30 frames per second.) . We tried to figure out a way to either interface an IP camera to our website or reduce the amount of data coming from a camera. This will have to be done using MJPEG compression.



Back to LRVC Discussions

Alumni Liaison

Basic linear algebra uncovers and clarifies very important geometry and algebra.

Dr. Paul Garrett