Difference between revisions of "Project1: Implement algorithm using microphone array"

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==PC Implementation - Work in groups of 2==
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*'''Download''' [[media:RoboticSensing.FL14.zip|RoboticSensing.zip]] and extract to your Home Directory. Double-Click on  RoboticSensing\MicSourceLocator.lvproj to open LabVIEW Project
*Start with this [[media:MicSourceLocator.zip|simulation model]] of the 4 microphones. Extract to your Home Directory and run MicSourceLocator.vi. This can be the starting point for your application.
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[[File:MicSourceLocatorProject-2.jpg|MicSourceLocator Project]]
**Source Localization
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*'''Description''' of [[Description of RoboticSensing.lvproj| MicSourceLocator.lvproj]]
***Compute angle of arrival for each pair
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*'''Double-Click on My Computer->MicSourceLocator.lvproj.''' and open My Computer -> MicSourceLocator-Array.vi. This is the starting point for your application. In the end, your VI should look like [[media:MicSourceLocatorSolution.jpg|this]]. Pay attention to the drawing on the Simulator.vi front panel to see the definition of the microphone indices.
***Compute source location by computing the intersection of the 2 lines given (x,y,theta) of each pair
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*'''Part A: Simulation'''
***Compute all possible intersections (Web)
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**Create ComputeAngle subVI to compute the angle of arrival from the delay and the microphone pair geometry.
**Bandpass signal on all channels
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**Create ComputeIntersection subVI that computes the triangulation equation to estimate the source location. Use Functions -> Mathematics -> Script & Formula -> MathScript Node if you can use Matlab syntax. Use the Formula Node for Java/C syntax. Trap the case where theta is 90 degrees and set the tangent to 1,000,000 instead of infinity.
**Spectrogram
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**Create FindCCPeak subVI to compute the relative delay between the microphone pairs. Instantiate this into your while loop. Make sure to use the Error Cluster. You will use this same vi on the robot and you might run out of memory on that platform.
**Store previous buffer and do level detection to handly an Asynchronous Source
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**Create Web subVi that computes all of the possible triangulations. Use your ComputeAngle and ComputeIntersection subVIs.
*Test with microphone array [[Media:Microphone_Array_Connections.pdf‎ |microphone array]]
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**Plot the results of the Web and the Source Location estimate on an XY graph. Also, plot the simulated source location and the microphone locations. To add additional traces to the XY graph, you need to use Functions -> Express -> Signal Manip -> Merge Signals instead of Build Array ([[media:XYPlot.vi|XY Plot example]])
 
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**Initially, verify that your triangulation works for a rotation of 0. Once that is working, set the rotations to +/- 45 degress and verify that also.
==Robot Implementation - Work in groups of 2==
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*'''Part B: Hardware'''
Projects for smaller groups:
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**'''Test''' with the 4 microphone array [[Media:Microphone_Array_Connections.pdf‎ |microphone array]]. Connect the line out from the PC to a speaker and generate a chirp on the sound card using Chirp2SoundCard.vi from the zip file.
*Compute angle of arrival on Robot platform
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**In the DAQ Assistant, make sure the Analog Inputs (Voltage) are from the USB-6212, differential, +/- 1 V, Continuous Samples, Samples to Read = 50k, Rate(Hz) = 50K. Make sure you wire the Stop control into the DAQ Assistant
*PC to Robot communication using Shared Variable
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<!-- **'''Test''' with "Real Simulated Data", use RealSimData.vi from the zip file to troubleshoot.-->
*Robot position control (x,y,theta)
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**'''When everything is working''', clean up your block diagram and modularize your code so it looks like the solution. This will make porting your code to the robot easier.
*Main PC Controller to compute source location from 5 robots
 
** Manual Position
 
** Automated controller
 
*Robot/FPGA implementation of Cross Correlation
 
*Thin client communication to Robot
 
 
 
==System Integration - Everybody==
 
*Get all of the individual pieces to work together on all 5 robots
 

Latest revision as of 19:21, 24 September 2014

  • Download RoboticSensing.zip and extract to your Home Directory. Double-Click on RoboticSensing\MicSourceLocator.lvproj to open LabVIEW Project

MicSourceLocator Project

  • Description of MicSourceLocator.lvproj
  • Double-Click on My Computer->MicSourceLocator.lvproj. and open My Computer -> MicSourceLocator-Array.vi. This is the starting point for your application. In the end, your VI should look like this. Pay attention to the drawing on the Simulator.vi front panel to see the definition of the microphone indices.
  • Part A: Simulation
    • Create ComputeAngle subVI to compute the angle of arrival from the delay and the microphone pair geometry.
    • Create ComputeIntersection subVI that computes the triangulation equation to estimate the source location. Use Functions -> Mathematics -> Script & Formula -> MathScript Node if you can use Matlab syntax. Use the Formula Node for Java/C syntax. Trap the case where theta is 90 degrees and set the tangent to 1,000,000 instead of infinity.
    • Create FindCCPeak subVI to compute the relative delay between the microphone pairs. Instantiate this into your while loop. Make sure to use the Error Cluster. You will use this same vi on the robot and you might run out of memory on that platform.
    • Create Web subVi that computes all of the possible triangulations. Use your ComputeAngle and ComputeIntersection subVIs.
    • Plot the results of the Web and the Source Location estimate on an XY graph. Also, plot the simulated source location and the microphone locations. To add additional traces to the XY graph, you need to use Functions -> Express -> Signal Manip -> Merge Signals instead of Build Array (XY Plot example)
    • Initially, verify that your triangulation works for a rotation of 0. Once that is working, set the rotations to +/- 45 degress and verify that also.
  • Part B: Hardware
    • Test with the 4 microphone array microphone array. Connect the line out from the PC to a speaker and generate a chirp on the sound card using Chirp2SoundCard.vi from the zip file.
    • In the DAQ Assistant, make sure the Analog Inputs (Voltage) are from the USB-6212, differential, +/- 1 V, Continuous Samples, Samples to Read = 50k, Rate(Hz) = 50K. Make sure you wire the Stop control into the DAQ Assistant
    • When everything is working, clean up your block diagram and modularize your code so it looks like the solution. This will make porting your code to the robot easier.