Photonic Bandwidth Compression Front End for Digital Oscilloscopes

Photonic Bandwidth Compression Front End for Digital Oscilloscopes

Time-stretch photonic analog-to-digital converter (ADC) technology is used to make an optical front end that compresses radio-frequency (RF) bandwidth before input to a digital oscilloscope. To operate a time-stretch ADC in a continuous-time mode for bandwidth compression, the optical signal on whic...

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Veröffentlicht in:Journal of lightwave technology 2009-11, Vol.27 (22), p.5073-5077
Hauptverfasser: Chou, J., Conway, J.A., Sefler, G.A., Valley, G.C., Jalali, B.
Format: Artikel
Sprache:eng
Schlagworte:
Aerospace electronics
Analog-digital conversion, digital-analog conversion, pcm coding
Analog-to-digial conversion (ADC)
Applied sciences
Bandwidth
Channels
Circuit properties
Compressing
Digital
Digitization
Electric, optical and optoelectronic circuits
Electronics
Exact sciences and technology
Information, signal and communications theory
Integrated optics. Optical fibers and wave guides
Interleaved codes
Laboratories
microwave photonics
optical analog link
Optical and optoelectronic circuits
Optical modulation
Optical signal processing
Optical telecommunications
Oscilloscopes
photonic assisted ADC
photonic time stretch
Photonics
Radio frequencies
Radio frequency
RF signals
Signal and communications theory
Systems, networks and services of telecommunications
Telecommunications
Telecommunications and information theory
Temporal logic
Transmission and modulation (techniques and equipments)
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Beschreibung
Zusammenfassung:Time-stretch photonic analog-to-digital converter (ADC) technology is used to make an optical front end that compresses radio-frequency (RF) bandwidth before input to a digital oscilloscope. To operate a time-stretch ADC in a continuous-time mode for bandwidth compression, the optical signal on which the RF is modulated must be segmented and demultiplexed. We demonstrate both spectral and temporal methods for overlapping the channels. Using the temporal method, we obtain a compression ratio of 3 with four channels. Mating this optical front end with a state-of-the-art four-channel digital oscilloscope with an input bandwidth of 16 GHz and a sampling rate of 50 GS/s gives a digitizer with 150 GS/s and an input bandwidth of 48 GHz. We digitize RF signals up to 45 GHz and obtain effective number of bits (ENOB) ~ 2.8 with single channels and ~ 2.5 with multiple channels, both measured over the 48-GHz instantaneous bandwidth of our system.
ISSN:0733-8724
1558-2213
DOI:10.1109/JLT.2009.2030519