1. Electrocardiogram (ECG) application operation – Part A Performed By: Ran Geler Mor Levy Instructor:Moshe Porian Project Duration: 2 Semesters Spring 2012 Final Presentation

2. Contents Introduction Top Architecture Overview Data Flow Components Simulations Performance Problems in developing process Conclusions Part B schedule

3. Introduction The heart is a muscular organ that beats in rhythm to pump blood through the body By analyzing the heart behavior and especially the electrical impulses we can help identify heart diseases and special circumstance that require close monitoring

4. Medical Terms ECG Lead ◦ Bipolar leads ◦ Unipolar leads ◦ Precordial Leads

5. Project Overview

6. Project Goals Portable ECG device based on FPGA Integrating Multi Platforms elements ◦ ECG DB with FPGA Interactive GUI with debugger abilities (Part B) Methodic project

7. Top Architecture

8. What we have achieved: Implementing ECG controller ◦ ECG FSM ◦ Integration with peripheral components. Examination of the Implemented components ◦ Creating tests bench ◦ Mocking TI DB behavior P& R to projects top architecture by Quartus Adding Flash memory support

9. Top Architecture – Data Flow

10. Top Architecture – Frequency Frequency requirements for modules FPGA: Main frequency: 100MHz Rx / Tx Modules @ frequency of 115,200Hz FPGA: Main frequency: 100MHz Rx / Tx Modules @ frequency of 115,200Hz ADS1928R: Main frequency: 2.048MHz SPI-Data Out freq’: >110KHz ADS1928R: Main frequency: 2.048MHz SPI-Data Out freq’: >110KHz MATLAB GUI: Rx / Tx Via UART interface @ frequency of 115,200Hz MATLAB GUI: Rx / Tx Via UART interface @ frequency of 115,200Hz Flash Memory: Main frequency: 100MHz Flash Memory: Main frequency: 100MHz

11. Core microarchitecture 512Bytes Data Rate: 100MHz Data Rate: >110KHz

12. Core Architecture ECG FSM FIFO Command & Aux Regs Wishbone Master & Slave SPI Core

13. ECG FSM Controls the flow of data between the host and the DB Three Main chain of actions: ◦ Read Data ◦ Read Registers ◦ Write Registers

14. ECG FSM - Graph

15. FIFO at ECG Controller 1 st Command 2 nd Command Additional Data Operation Commands (ex: RDATAC, Rreg, Wreg, Standby, Reset, ect’..) Optional: Second Byte for (Rreg, Wreg) and sample interval for RDATAC command. Data for commands FIFO Size: 512 Bytes. Stores Instruction and Sampled data. Data structure on Instruction case:

16. SPI The SPI Interface frequency: At 24bit resolution per 8 Electrodes and 500 Samples per Sec: Active at low. i.e. CS = ‘0’

17. Flash Component FLASH Flash Controller Flash FSM Flash FSM RAM Reset en WBS Flash Component 256Byte

18. Flash Component - Flash One sample (24bit res. per 8 Electrodes) = 27Byte. Lets assume sample rate of 500 SPS Flash size = 4MB Therefore we can sample for 5min.

19. Flash Component – Flash client Technical Demands: Common FLASH Interface protocol (CFI) Wishbone Interface Performs Read, Write, Reset and Erase transactions Initiative read on power-on Contains a timeout algorithm Generic: adaptable to different FLASH sizes and clock frequencies. BUS Wishbone CFI

20. ADS1298R ECG DB Texas Instruments Card Arrived to the High Speed Digital Systems Lab

21. ADS1298R ECG DB Future acquisitions of probes and electrodes Connection of the DB to the FPGA

22. Test Methodologies Operation of the ECG Controller: ◦ Checking that states change are at time ◦ Checking control signals & data signals between units ◦ Non existing commands NOTE: When a transaction is executed the wishbone “stall” signal is raised to ‘High’, So other requests will remain pending at the Rx Wishbone Master.

23. ECG Controller TB Data Flow We have implemented a special closed component for Testing.

24. DB mocking We have implemented a component that is imitating the TI DB behavior.

25. ADS1298R ECG DB

26. Simulations – Read Transaction example Top Architecture Wave. Rx Transaction SPI Flash

27. Simulations – Read Transaction example SPI Transaction

28. Simulations – Read Transaction example Flash transaction

29. Simulations – Read Transaction example FIFO Usage

30. Quartus Simulations General Layout

31. Quartus Simulations Max Frequency

32. Quartus Simulations Top Arc Synthesis summary

33. Problems in developing process Meet timings requirements of the TI Evaluation board. Keep the projects specifications and requirements while adding more logic to the top arch. Debug and testing of the whole implemented logic.

34. Conclusions We learned a lot about the developing process & the importance of good planning a head The importance of working organized How much good documentation of previous project is important

35. Schedule – Part B Designing The GUI interface (off line) Planning the GUI methodsBuilding GUI using Matlab Test & Debug 1w 3w 1w

36. Schedule – Part B Cont. Project book completion Semester B -Final Presentation 1w