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PC Based Spectrum Analyzer

PC Based Spectrum Analyzer. Phase III. May03-10. Client: Teradyne Inc. Faculty Advisor: Dr. DJ Chen. Michael Cain Paul Heil Eric Rasmussen Aung Thuya. April 29, 2003. Acknowledgements. The team would like to thank: Teradyne Steve Miller Dr. Degang Chen. Presentation Outline.

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PC Based Spectrum Analyzer

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  1. PC Based Spectrum Analyzer Phase III May03-10 Client: Teradyne Inc. Faculty Advisor: Dr. DJ Chen Michael Cain Paul Heil Eric Rasmussen Aung Thuya April 29, 2003

  2. Acknowledgements • The team would like to thank: • Teradyne • Steve Miller • Dr. Degang Chen

  3. Presentation Outline Problem Statement Operating Environment Intended Use and Users Assumptions and Limitations End Product Accomplishments Approaches Research Design Implementation Testing Resources and Schedules Closing Materials

  4. List of Definitions DAC – digital to analog converter DC offset – DC voltage in an AC signal FPGA – field programmable gate array Spectrum analyzer – measures magnitude of signal harmonics THD – total harmonic distortion

  5. Problem Statement Amplifier for PC Based Spectrum Analyzer • 100MHz high gain, low noise, low distortion • Programmable DC offset and frequency response calibration

  6. Problem Statement (cont’d.) DC — 1kHz Input +/- 5 volts 6, 20, 40, 60 +/- 10 volts 0.05 dB < - 105 dB Total 1.5 nV/rtHz Input Voltage Available Max Output Freq Response Harmonic > 1kHz - 20 kHz +/- 5 volts 6, 20, 40, 60 +/- 10 volts 0.05 dB < - 95 dB 1.5 nV/rtHz Frequency Range Gain Settings Voltage Flatness Distortion Noise > 20kHz - 100kHz +/- 2.5 volts 6, 20, 40 +/- 5 volts 0.10 dB < -85 dB 2.5 nV/rtHz Range (Volts) (dB) (Volts) (dB) (dB) (nV/rtHz) > 100kHz - 1MHz +/- 2.5 volts 6, 20, 40 +/- 5 volts 0.10 dB < - 80 dB 3.5 nV/rtHz > 1MHz - 10MHz +/- 2.5 volts 6, 20, 40 +/- 5 volts 0.10 dB < - 70 dB 3.5 nV/rtHz > 10MHz - 20MHz +/- 2.5 volts 6, 20 +/- 5 volts 0.10 dB < -65 dB 3.5 nV/rtHz > 20MHz - 50MHz +/- 1.0 volts 6, 20 +/- 2.0 volts 0.10 dB < -50 dB 5.0 nV/rtHz > 50MHz - 100MHz +/- 1.0 volts 6, 20 +/- 2.0 volts 0.10 dB < -40 dB 5.0 nV/rtHz

  7. Operating Environment Normal lab conditions Low humidity, room temperature

  8. Intended Users and Uses Users will be Teradyne test engineers Use will be preamplifier for PC Based spectrum analyzer

  9. Assumptions • Users • Teradyne test engineers are familiar with the operation of a spectrum analyzer • Requirements • Specifications are attainable • Financial Budget • Teradyne will cover project costs

  10. Limitations • Hardware • Noise and distortion trade-off • Must have a stable configuration • Software • Simulation software limitations • Technical Knowledge • No experience with PC board fabrication

  11. End Product • The end product will consist of the following deliverables: • Analog amplifier design with embedded digital controls • Software for the embedded digital controls • Design and user documentation

  12. Present Accomplishments • Research – 100% completed • Analog amplifier design – 100% completed • Digital controls – 100% completed • Software controls – 100% completed • Simulations – 100% completed • Fabrication – 0% completed • Testing – 0% completed

  13. Approaches Considered and Used • Amplifier Topology • Low noise amplifier (LNA) • Operational amplifier in resistive feedback

  14. Approaches Considered and Used (cont’d.) • DC Offset Correction • Clocked ping-pong structure • Offset voltage referral • Successive approximation scheme

  15. Approaches Considered and Used (cont’d.) • Frequency Response Calibration • Automatic • Manual

  16. Project Definition Activities • Project scope was changed to a paper design • Occurred after design was submitted for fabrication • Will be completed by future team

  17. Research Activities • Amplifier Topologies • Operational Amplifiers • DACs • FPGAs • Digital Potentiometers • Comparators

  18. Design Activities Amplifier Design

  19. Design Activities (cont’d.)

  20. Design Activities (cont’d.)

  21. Design Activities (cont’d.) DC offset correction

  22. Design Activities (cont’d.) Frequency response calibration

  23. Design Activities (cont’d.)

  24. Implementation Activities Implementation was not necessary

  25. Testing Activities PSpice simulations for analog design Verilog simulations for digital state machine

  26. Other Significant Activities User manual Estimated performance analysis Design vault on CD

  27. Resource Requirements Personal Effort

  28. Resource Requirements (cont’d.) Item Team Hours Other Hours Cost Board Fabrication 0 0 $0 Components 0 0 $0 Project Poster 10 0 $48 Total 10 0 $48 Total Cost

  29. Schedule Project Schedule

  30. Project Evaluation • Schematic level implementation – fully met • Simulations – fully met • Fabrication – not attempted • Testing – not attempted

  31. Commercialization • Only one will be fabricated for testing purposes • Will be a part of Teradyne’s Integra J750 • Cost of J750 starts at $99,000

  32. Recommendations for Future Work • Meet low noise requirement • Make frequency response calibration automatic • Fabricate board • Complete testing

  33. Lessons Learned • Set up weekly meetings with client and team • Do not procrastinate • Make sure design tools are adequate • Do not be too optimistic with scheduling • Do not be too elaborate with complicated designs

  34. Risk and Risk Management • Losing a team member • No available times for meetings • Parts ordered on time • Sending design to fabrication on time

  35. Closing Summary Learned a lot about amplifier topologies Team skills improved Useful information passed to next group

  36. Questions?

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