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导波光学 Photonic Analog-to-Digital Conversion

导波光学 Photonic Analog-to-Digital Conversion. 班级: B1203491 学 号: 1120349012 姓名:钱阿权. C ontent. Limits in Electronic ADCs How to solve in photonic approach ? Principles of Photonic ADC Advantages of the A/D scheme Discussion. Limits in Electronic ADCs. sample-and-hold. A/D conversion.

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导波光学 Photonic Analog-to-Digital Conversion

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  1. 导波光学Photonic Analog-to-Digital Conversion 班级:B1203491 学号:1120349012 姓名:钱阿权

  2. Content • Limits in Electronic ADCs • How to solvein photonic approach? • Principles of Photonic ADC • Advantages of the A/D scheme • Discussion

  3. Limits in Electronic ADCs • sample-and-hold • A/D conversion • quantization The ENOB describe the possible maximum resolution that can be achieved for a physical ADC with the meaningful number.

  4. Limits in Electronic ADCs

  5. Limits in Electronic ADCs Three mechanisms (thermal noise, timing jitter, and comparator ambiguity) limiting the performance of an ADC.

  6. Limits in Electronic ADCs The conventional sample-interleaved analog-to-digital converter architecture.

  7. Limits in Electronic ADCs Conceptual block diagram for a time-stretched analog-to-digital converter.

  8. Limits in Electronic ADCs Conceptual block diagram of time-stretched analog to digital converter array

  9. How to solvein photonic approach?

  10. How to solvein photonic approach? What makes these developments especially exciting is that with the recent progress made in silicon photonic and electronic-photonic integration technologies

  11. Principles of Photonic ADC Layout of the photonic ADC

  12. Principles of Photonic ADC • It is a photonic sampling and electronic quantizing ADC, with electronics performing the critical function of digitizing the modulated pulses, which electronics can do best at high resolutions. • At the post-processing stage, the samples captured in different wavelength channels are interleaved and distortion-compensated to obtain the final digital representation of the RF signal.

  13. Principles of Photonic ADC • With this approach to sampling, the aperture jitter is determined by the timing jitter of the mode-locked lasers, which can be extremely low , thus eliminating the problem of aperture jitter. • The scheme with N channels reduces the required analog bandwidth of photo detectors and electronic ADCs in proportion to N, which means that the comparator ambiguity becomes a non-issue.

  14. Advantages of the A/D scheme • The latest developments in silicon photonics and electronic-photonic integration technology make it possible to integrate the whole A/D system on a silicon chip. • a vision for the photonic ADC implemented as a single electronic-photonic silicon chip

  15. Advantages of the A/D scheme

  16. Discussion • The photonic sampling is capable of strongly reducing the role of the two fundamental limitations in ADCs: aperture jitter and comparator ambiguity. • If the currently observed low levels of timing jitter in mode-locked lasers can be translated into effective bits, one will be able to digitize signals of up to THz bandwidth with more than 10 ENOB.

  17. Discussion • Together with silicon photonics as the integration platform finally a practical, cheap, integrated solution for photonic ADCs has arrived, that might surpass its completely electronic counterpart by potentially more than three orders of magnitude in achievable resolution-bandwidth product.

  18. Thanks!

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