Electro-optic field-mapping as a diagnostic tool for microwave circuits and antenna arrays

Whitaker,; Yang, Kiyull; Reano,; Katehi,

doi:10.1109/mwp.2002.1158863

Cited by 2 publications

(1 citation statement)

References 17 publications

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“…The coaxial probes that we have developed for EMC applications have a spatial resolution of 500 µm for monopole and around 1 mm for dipole probes which do not give enough experimental data with microelectronic components [7][8][9][10]. The optical probes can reach a spatial resolution under 100 µm and thus suitable for measuring microelectronic devices [11][12][13]. As a result, to improve the performance of our current near field bench based on passive detection with coaxial probes, and to analyze these interferences, we are currently developing another near-field test bench using optical technology based on the Pockels effect.…”

Section: Introductionmentioning

confidence: 99%

Improvement of Electrical Near-Field Measurements With an Electro-Optic Test Bench

David¹,

Baudry²,

Louis³

2012

PIER B

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Abstract-In this paper, two different kinds of near-field measurement techniques are presented. The first one uses coaxial probes that do not give precise measurements on microelectronic devices. We saw in [1] that the spatial resolution of these probes reaches 500 µm for monopole and is millimetric for dipole probe. The second one is based on the Pockels effect that converts an electromagnetic (EM) field into optical modulation. Our objective is to improve the E x /E y near-field measurement with this second technique. The performance of the electro-optic (EO) probe is compared with dipole probes of 2.5 and 5 mm with the use of simulations and measurements, on a wire above a ground plane and on coupled microstrip lines. At the end, a discussion about the technical limitations of the EO probe is made.

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Section: Introductionmentioning

confidence: 99%

Improvement of Electrical Near-Field Measurements With an Electro-Optic Test Bench

David¹,

Baudry²,

Louis³

2012

PIER B

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EDFA-enhanced sensitivity of RF magneto-optical probe

Mitani¹,

Yamazaki²,

Kishi³

et al.

MWP 2003 Proceedings. International Topical Meeting on Microwave Photonics, 2003.

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EDFA-bsredsensilivit?. enhancement of MO field probe has been invortigated experimentally and theoretically. It was found out that optical pre-nmplifrration provider > 45 dB MO signal amplification and ASE-relaled noise reduction is P key issue. INTRODUCTIONOptical techniques for RF field measurement bared either on the eiectrodpti~ (EO) or magneto-optic (MO) effect have attracted considerable attention recently. This trend has been brought about not only by the advanced EO sampling techniques well developed so far but also by their anractive applications demonstrated for high speed electronic circuits evaluation^ and diagnosis [1]-[5]. In those measuremcnf techniques. their high speed and high spatial resolufion nature arc advantageous while their noninvasivene~s is also noteworthy. However, i t has been highly demanded to improve their sensitivity for many kinds of performance improvements and realization of funher useful and practical applications. Regarding the MO probe scheme, for example. higher spatial resolution, higher response speed. and real time imaging functionalily, etc. are expected to be brought about by sensitivity improvement in the optical detectionSimilar situaiion has been provided also for the EO probe scheme except for the issue of response speed improvement.One should note that preferable enhancement methods for the optical detection sensitivity depend on schsmes of optical measurement sysfcms. Generally, optical measurement schemer can be classified into two. One is the optical sampling and the other is the real wave measurement. A slow pholodetector (PD) is enough for the former while a fast photo-diode is necessary for the latter. An for the rampiing scheme. the input optical pulse energy is an impadant parameter and its improvement is principal ais pointed out in reference IO. On the other hand, an appropriate sensitivity enhancement method should be addressed to lhe Iattec measurement scheme accordingly to lhe esscntid features of fast photo-diodes.However. this important issue has been scarcely dealt with hitheno. In this paper, as described in the followings, we repon on our investigation rewits regarding EDFA-based enhancement of RF MO prove sensitivity.It was confirmed that the signal-to-noire-ratio (SNR) improvement is achievable by a me of an optical amplifier in prior to the PD stage, that is an optical pre-amplifier [ i l l , toðer with the optimization of optical bias for lhe MO modulation. Funhemore, lhe details of the improvement mechanism have been investigated and it war figured out that an MO signal enhancement of 45 dB or higher is available by a standard Er-doped fiber amplifier (EDFA) and dominant RF noise components are given by amplified spontaneour emission (ASE) of EDFAs. Possibility of funher improvement was also examined on the basis of precise system modeling. 11. EXPERIMENTSHere, we explain experiments performed in order to clarify the optimum condition for lhe available best ~en~itivily of our system and the effectiveness of optical pre-amplification. Figu...

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Electro-optic field-mapping as a diagnostic tool for microwave circuits and antenna arrays

Cited by 2 publications

References 17 publications

Improvement of Electrical Near-Field Measurements With an Electro-Optic Test Bench

Improvement of Electrical Near-Field Measurements With an Electro-Optic Test Bench

EDFA-enhanced sensitivity of RF magneto-optical probe

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