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EEG Probe Project Grant G. Connell. EEG Probe Project Design Objectives –Investigate BCI for severely handicapped individuals –Use time, frequency, and.

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Presentation on theme: "EEG Probe Project Grant G. Connell. EEG Probe Project Design Objectives –Investigate BCI for severely handicapped individuals –Use time, frequency, and."— Presentation transcript:

1 EEG Probe Project Grant G. Connell

2 EEG Probe Project Design Objectives –Investigate BCI for severely handicapped individuals –Use time, frequency, and phase displays –Use DSP techniques for near real time responses –Use only the mono input to the sound card of a PC for multiple channel displays (start with two channels)

3 EEG Probe Project Design requirements –Some compatibility with Modular EEG H/W Can use analog section with modulator section, +/- 5V operation –Single input (mono to sound card) –Two channel prototype, expandable to 32 channels Reference leg for both channels –Select either SSB, AM, or FM modulation technique Selected AM for frequency stability, better spectrum management than FM –Displays Stripline, Vertical FFT, Vertical Phase, Waterfall Application screen size = 1024 by 768

4 EEG Probe Project System Design (AM Modulation) Freq (Hz) Amplitude 12 kHz 14 kHz16 kHz18 kHz (Carriers) Chan1 Chan2Chan3Chan4 500 Hz

5 EEG Probe Project AM System Design, Processing Chain Sound Card Input (Mono) Channel 1 Bandpass Filter, 16 kHz Channel 2 Bandpass Filter, 18 kHz Channel 1 AM Demod and LP Filter Channel 2 AM Demod and LP Filter Decimate (8x) Prog. Filter, DC Removal Decimate (8x) Prog Filter, DC Removal Channel 1 1024 Byte Buffer & FFT Channel 2 1024 Byte Buffer & FFT Mic. Stripchart Vertical FFT, Phase Vertical FFT, Phase 11025 Hz Sampling Rate 1024 Byte Blocks 1024 Byte Convolutional Filter, 500 Hz BW 1024 Bytes Envelope Detection 128 Bytes 1024 Bytes

6 EEG Probe Project System Design: Displays –Vertical FFT –Vertical Phase –Strip Chart –Waterfall

7 EEG Probe Project Development Environment –Use C,C++ Builder IDE (from Borland) –Third party components (knobs, switches) –Low level sound card drivers –All software developed internally Could use Intel DSP library for open source development

8 Vertical FFT Display, 6 Hz and 12 Hz inputs

9 EEG Probe Project Vertical Phase Display, 2 Hz and 5 Hz

10 Waterfall Display, 6 Hz and 12 Hz inputs

11 RAW FFT Spectrum 3.5 kHz and 4.0 kHz carriers

12 Alpha Bursts, 9 Hz

13 EEG Probe Project First Hardware Protype –Two PC boards Dual channel analog design similar to Modular EEG Dual channel modulator board using low cost ICs, output transformer coupled for isolation from the PC Single supply input (+12 volt) from isolation transformer, converted to +/- 5 volts. –Front panel gain control for each channel –Power supply LEDs

14 EEG Probe Project Hardware Block Diagram XFMR Sum Lo1 AM Mod Lo2 Gain To PC Dual Channel Low Noise Amplifier Board Dual Channel AM Modulator Board Chan 1 DRL Ref Gnd

15 Breadboard Designs New Designs AM Design FM Design

16 Prototype Unit

17 Chassis Layout Power Supply Dual Amp Board Modulator Board

18 EEG Probe Project FM System Design, Processing Chain Sound Card Input (Mono) Channel 1 Bandpass Filter, 14 kHz Channel 2 Bandpass Filter, 19 kHz Channel 1 FM Demod and LP Filter Channel 2 FM Demod and LP Filter Decimate (32x) Prog. Filter, DC Removal Decimate (32x) Prog Filter, DC Removal Channel 1 1024 Byte Buffer & FFT Channel 2 1024 Byte Buffer & FFT Stripchart Vertical FFT, Phase Vertical FFT, Phase 44100 Hz Sampling Rate 1024 Byte Blocks 4096 Byte Convolutional Filter, 500 Hz BW 4096 Bytes Envelope Detection 128 Bytes 1024 Bytes

19 Dual Channel FM Spectrum

20 Dual Channel FM Waveforms

21 Modulation Scheme Comparison AM Modulation –Good spectrum management (1500 Hz per channel) –80 dB dynamic range (2.0 mv to 0.20 uv) –Requires only 3 IC’s plus a transistor per channel (most recent design) –Gain calibration procedure with sound card required –60 dB cross-talk isolation between channels FM Modulation –Limited spectrum management (4 kHz per channel) –80 dB dynamic range (1.5 mv to 0.15 uv) –Requires only 3 IC’s per channel – Gain calibration built-in via H/W and S/W design –60 dB cross-talk isolation between channels

22 EEG Probe Project Prototyped single channel AM modulation unit –Current drain approximately 6.5 ma. @ 9 volts Prototype dual channel FM modulation unit –Current drain approximately 5.75 ma. @ 9 volts –Switched to CMOS version of NE555 IC Prototype dual channel AM modulation unit –Current drain approximately 7.0 ma. @ 9 volts –Switched to simpler AM modulator with better noise performance –Used CMOS version of NE555 IC (ICM7555) All prototypes completed and operational

23 Single Channel AM Unit

24 Dual Channel FM Unit

25 Dual Channel AM Unit

26 EEG Probe Project Current Status –Completing final S/W application AM demodulation design complete FM demodulation design complete Added adjustable LP and BP filters (S/W) –Switched to digital LO (for a two channel system only), used cheaper ICs to generate the local oscillator –Dual channel AM and FM designs completed and prototypes built

27 Software Update EEG Probe software –Added record and playback capability –Near real-time response with IIR digital filters Sound Card Interface to NeuroServer –Converts sound card data to EDF format and interfaces to the NeuroServer –Also converts sound card data to ModEEG format for RS- 232 interfaces, requires Eltima virtual RS-232 driver Both software packages available at the SourceForge web site: –http://openeeg.sourceforge.net/doc/hw/sceeg/

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