Near-field scanning systems are by far the most compact alternatives for antenna pattern measurement. Yet, conventional near-field scanning systems have substantial downsides. These systems involve metallic radiators that act as receivers for picking up the near field of the antenna under test (AUT). Such metallic pick-up antennas cannot get close to the AUT since they would perturb its near fields. They also limit the operational bandwidth of the system, and their accuracy degrades significantly at lower frequency bands. Sophisticated software tools are often used in conjunction with these systems to de-embed and minimize various errors due to their specific architectures and configurations.
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[[Image:NEOWEB7.png|thumb|550px|Modulating the polarization state of an optical beam passing through an electro-optic crystal.]]
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[[Image:NEOWEB9.png|thumb|550px|Modulating the polarization state of an optical beam passing through an electro-optic crystal.]]
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In short, with NeoScan, you get a compact portable self-contained system that characterizes your antenna system from the very near fields to the very far fields without requiring considerable real estate. NeoScan is particularly useful for phase characterization and calibration large antenna arrays.
[[Image:NEOWEB7.png|thumb|450px|Modulating the polarization state of an optical beam passing through an electro-optic crystal.]]
[[Image:NEOWEB8.png|thumb|450px|Modulating the polarization state of an optical beam passing through an electro-optic crystal.]]
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[[Image:NEOWEB9.png|thumb|450px|Modulating the polarization state of an optical beam passing through an electro-optic crystal.]]
[[Image:NEOWEB10.png|thumb|450px|Modulating the polarization state of an optical beam passing through an electro-optic crystal.]]