NR-BD-RIS on LEO satellites breaks channel reciprocity to support simultaneous multi-user full-duplex beams, yielding higher DL/UL sum-rates than conventional RIS with less frequent reconfiguration.
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Mobile THz wireless links cannot achieve high bandwidths while staying in the far field without unrealistic transmit power, unlike stationary THz or sub-6 GHz/mmWave systems.
Closed-form expressions for near-field boundary distances are derived for misaligned mmWave and THz antenna arrays across array-to-array and array-to-point setups with linear and planar arrays.
citing papers explorer
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Enabling Full-Duplex LEO Satellite Systems with Non-Reciprocal BD-RIS-Assisted Beamforming
NR-BD-RIS on LEO satellites breaks channel reciprocity to support simultaneous multi-user full-duplex beams, yielding higher DL/UL sum-rates than conventional RIS with less frequent reconfiguration.
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User Mobility Demands Near-Field Communications in Terahertz Band Wireless Networks Beyond 6G
Mobile THz wireless links cannot achieve high bandwidths while staying in the far field without unrealistic transmit power, unlike stationary THz or sub-6 GHz/mmWave systems.
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Near-field Boundary Distance in mmWave and THz Communications with Misaligned Antenna Arrays
Closed-form expressions for near-field boundary distances are derived for misaligned mmWave and THz antenna arrays across array-to-array and array-to-point setups with linear and planar arrays.