W-Band Millimeter-Wave Vector Signal Generation Based on Precoding-Assisted Random Photonic Frequency Tripling Scheme Enabled by Phase Modulator
We propose W-band photonic millimeter-wave (mm-wave) vector signal generation employing a precoding-assisted random frequency tripling scheme enabled by a single phase modulator cascaded with a wavelength selective switch (WSS). The selected two optical subcarriers from the phase modulator output by...
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2016
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oai:doaj.org-article:2c4d3b545cb44e808b1b3430a3e2252c2021-11-20T00:00:04ZW-Band Millimeter-Wave Vector Signal Generation Based on Precoding-Assisted Random Photonic Frequency Tripling Scheme Enabled by Phase Modulator1943-065510.1109/JPHOT.2016.2535203https://doaj.org/article/2c4d3b545cb44e808b1b3430a3e2252c2016-01-01T00:00:00Zhttps://ieeexplore.ieee.org/document/7420541/https://doaj.org/toc/1943-0655We propose W-band photonic millimeter-wave (mm-wave) vector signal generation employing a precoding-assisted random frequency tripling scheme enabled by a single phase modulator cascaded with a wavelength selective switch (WSS). The selected two optical subcarriers from the phase modulator output by the WSS can have several different kinds of combinations with asymmetrical orders, such as (−3, 0), (−2, 1), (−1, 2), and (0, 3). Employing our proposed precoding-assisted random frequency tripling scheme, we experimentally demonstrate 1/2-Gbd 81-GHz quadrature-phase-shift-keying (QPSK) mm-wave vector signal generation and its wireless delivery over 0.5-m air space distance. We also experimentally demonstrate that the generated mm-wave vector signal based on the minus second-order (−2nd) and first-order (1st) subcarriers, which is equivalent to that based on the minus first-order (−1st) and second-order (2nd) subcarriers, has a better bit-error-ratio (BER) performance than that based on the minus third-order (−3rd) and central (0th) subcarriers, which is equivalent to that based on the 0th and third-order (−3rd) subcarriers, when the phase modulator has a relatively small driving radio-frequency (RF) voltage, whereas an opposite result occurs when the phase modulator has a relatively large driving RF voltage, which is consistent with both our theoretical analysis and numerical simulation.Xinying LiYuming XuJiangnan XiaoJianjun YuIEEEarticlePhotonic millimeter-wave (mm-wave) vector signal generationW-bandrandom frequency triplingprecodingquadrature phase shift keying (QPSK)Applied optics. PhotonicsTA1501-1820Optics. LightQC350-467ENIEEE Photonics Journal, Vol 8, Iss 2, Pp 1-10 (2016) |
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DOAJ |
| collection |
DOAJ |
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EN |
| topic |
Photonic millimeter-wave (mm-wave) vector signal generation W-band random frequency tripling precoding quadrature phase shift keying (QPSK) Applied optics. Photonics TA1501-1820 Optics. Light QC350-467 |
| spellingShingle |
Photonic millimeter-wave (mm-wave) vector signal generation W-band random frequency tripling precoding quadrature phase shift keying (QPSK) Applied optics. Photonics TA1501-1820 Optics. Light QC350-467 Xinying Li Yuming Xu Jiangnan Xiao Jianjun Yu W-Band Millimeter-Wave Vector Signal Generation Based on Precoding-Assisted Random Photonic Frequency Tripling Scheme Enabled by Phase Modulator |
| description |
We propose W-band photonic millimeter-wave (mm-wave) vector signal generation employing a precoding-assisted random frequency tripling scheme enabled by a single phase modulator cascaded with a wavelength selective switch (WSS). The selected two optical subcarriers from the phase modulator output by the WSS can have several different kinds of combinations with asymmetrical orders, such as (−3, 0), (−2, 1), (−1, 2), and (0, 3). Employing our proposed precoding-assisted random frequency tripling scheme, we experimentally demonstrate 1/2-Gbd 81-GHz quadrature-phase-shift-keying (QPSK) mm-wave vector signal generation and its wireless delivery over 0.5-m air space distance. We also experimentally demonstrate that the generated mm-wave vector signal based on the minus second-order (−2nd) and first-order (1st) subcarriers, which is equivalent to that based on the minus first-order (−1st) and second-order (2nd) subcarriers, has a better bit-error-ratio (BER) performance than that based on the minus third-order (−3rd) and central (0th) subcarriers, which is equivalent to that based on the 0th and third-order (−3rd) subcarriers, when the phase modulator has a relatively small driving radio-frequency (RF) voltage, whereas an opposite result occurs when the phase modulator has a relatively large driving RF voltage, which is consistent with both our theoretical analysis and numerical simulation. |
| format |
article |
| author |
Xinying Li Yuming Xu Jiangnan Xiao Jianjun Yu |
| author_facet |
Xinying Li Yuming Xu Jiangnan Xiao Jianjun Yu |
| author_sort |
Xinying Li |
| title |
W-Band Millimeter-Wave Vector Signal Generation Based on Precoding-Assisted Random Photonic Frequency Tripling Scheme Enabled by Phase Modulator |
| title_short |
W-Band Millimeter-Wave Vector Signal Generation Based on Precoding-Assisted Random Photonic Frequency Tripling Scheme Enabled by Phase Modulator |
| title_full |
W-Band Millimeter-Wave Vector Signal Generation Based on Precoding-Assisted Random Photonic Frequency Tripling Scheme Enabled by Phase Modulator |
| title_fullStr |
W-Band Millimeter-Wave Vector Signal Generation Based on Precoding-Assisted Random Photonic Frequency Tripling Scheme Enabled by Phase Modulator |
| title_full_unstemmed |
W-Band Millimeter-Wave Vector Signal Generation Based on Precoding-Assisted Random Photonic Frequency Tripling Scheme Enabled by Phase Modulator |
| title_sort |
w-band millimeter-wave vector signal generation based on precoding-assisted random photonic frequency tripling scheme enabled by phase modulator |
| publisher |
IEEE |
| publishDate |
2016 |
| url |
https://doaj.org/article/2c4d3b545cb44e808b1b3430a3e2252c |
| work_keys_str_mv |
AT xinyingli wbandmillimeterwavevectorsignalgenerationbasedonprecodingassistedrandomphotonicfrequencytriplingschemeenabledbyphasemodulator AT yumingxu wbandmillimeterwavevectorsignalgenerationbasedonprecodingassistedrandomphotonicfrequencytriplingschemeenabledbyphasemodulator AT jiangnanxiao wbandmillimeterwavevectorsignalgenerationbasedonprecodingassistedrandomphotonicfrequencytriplingschemeenabledbyphasemodulator AT jianjunyu wbandmillimeterwavevectorsignalgenerationbasedonprecodingassistedrandomphotonicfrequencytriplingschemeenabledbyphasemodulator |
| _version_ |
1718419825442684928 |