Millimeter-Wave Multiplexed Wideband Wireless Link Using Rectangular-Coordinate Orthogonal Multiplexing (ROM) Antennas

This paper is the first demonstration of multiplexed wideband data transmission in the millimeter-wave range using rectangular-coordinate orthogonal multiplexing (ROM) antennas. This spatial wireless multiplex communication method can be applied at several hundred GHz for further improvements in the...

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Veröffentlicht in:	Journal of lightwave technology 2021-12, Vol.39 (24), p.7821-7830
Hauptverfasser:	Tomura, Takashi, Hirokawa, Jiro, Ali, Muhsin, Carpintero, Guillermo
Format:	Artikel
Sprache:	eng
Schlagworte:	Antenna arrays Antennas Bandwidths Bit error rate Broadband Cartesian coordinates Channels Crosstalk Data transmission Error analysis Error correction Frequency division multiplexing Low noise Millimeter waves Multiplexing Ports (computers) Radio-over-fiber (RoF) Read only memory real-time multiplex wireless communication rectangular-coordinate orthogonal multiplexing (ROM) Signal processing Spatial multiplex wireless communication waveguide slot array antenna Wideband Wireless communication Wireless communications
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container_issue	24
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container_title	Journal of lightwave technology
container_volume	39
creator	Tomura, Takashi Hirokawa, Jiro Ali, Muhsin Carpintero, Guillermo
description	This paper is the first demonstration of multiplexed wideband data transmission in the millimeter-wave range using rectangular-coordinate orthogonal multiplexing (ROM) antennas. This spatial wireless multiplex communication method can be applied at several hundred GHz for further improvements in the data rate because much wider bandwidth is available and this multiplexing method does not require any signal processing. The multiplexing is achieved through the spatial eigenmodes of a novel antenna based on a rectangular coordinate system and magic-T which eliminates the need for computational signal processing efforts. The aperture distributions of these spatial eigenmodes are designed to have different polarities to avoid crosstalk and operate over a wide bandwidth range. We demonstrate their performance with four eigenmodes, achieving crosstalk between modes below −37.8 dB over a 14.6% relative bandwidth (57-66 GHz). We have introduced these antennas on a photonics-enabled real-time wireless data transmission, transmitting over two channels simultaneously, without any signal processing at the transmitter (multiplex) or the receiver (demultiplex). The two multiplexed channels show a total data rate up to 9.0 Gbps at most (5.875 Gbps and 3.125 Gbps for each channel) limited by the bandwidth of the low noise amplifiers at the receiver. The measured bit error rate (BER) is below the forward error correction (FEC) limit.
doi_str_mv	10.1109/JLT.2021.3093445
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This spatial wireless multiplex communication method can be applied at several hundred GHz for further improvements in the data rate because much wider bandwidth is available and this multiplexing method does not require any signal processing. The multiplexing is achieved through the spatial eigenmodes of a novel antenna based on a rectangular coordinate system and magic-T which eliminates the need for computational signal processing efforts. The aperture distributions of these spatial eigenmodes are designed to have different polarities to avoid crosstalk and operate over a wide bandwidth range. We demonstrate their performance with four eigenmodes, achieving crosstalk between modes below −37.8 dB over a 14.6% relative bandwidth (57-66 GHz). We have introduced these antennas on a photonics-enabled real-time wireless data transmission, transmitting over two channels simultaneously, without any signal processing at the transmitter (multiplex) or the receiver (demultiplex). The two multiplexed channels show a total data rate up to 9.0 Gbps at most (5.875 Gbps and 3.125 Gbps for each channel) limited by the bandwidth of the low noise amplifiers at the receiver. 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This spatial wireless multiplex communication method can be applied at several hundred GHz for further improvements in the data rate because much wider bandwidth is available and this multiplexing method does not require any signal processing. The multiplexing is achieved through the spatial eigenmodes of a novel antenna based on a rectangular coordinate system and magic-T which eliminates the need for computational signal processing efforts. The aperture distributions of these spatial eigenmodes are designed to have different polarities to avoid crosstalk and operate over a wide bandwidth range. We demonstrate their performance with four eigenmodes, achieving crosstalk between modes below −37.8 dB over a 14.6% relative bandwidth (57-66 GHz). We have introduced these antennas on a photonics-enabled real-time wireless data transmission, transmitting over two channels simultaneously, without any signal processing at the transmitter (multiplex) or the receiver (demultiplex). The two multiplexed channels show a total data rate up to 9.0 Gbps at most (5.875 Gbps and 3.125 Gbps for each channel) limited by the bandwidth of the low noise amplifiers at the receiver. The measured bit error rate (BER) is below the forward error correction (FEC) limit.</description><subject>Antenna arrays</subject><subject>Antennas</subject><subject>Bandwidths</subject><subject>Bit error rate</subject><subject>Broadband</subject><subject>Cartesian coordinates</subject><subject>Channels</subject><subject>Crosstalk</subject><subject>Data transmission</subject><subject>Error analysis</subject><subject>Error correction</subject><subject>Frequency division multiplexing</subject><subject>Low noise</subject><subject>Millimeter waves</subject><subject>Multiplexing</subject><subject>Ports (computers)</subject><subject>Radio-over-fiber (RoF)</subject><subject>Read only memory</subject><subject>real-time multiplex wireless communication</subject><subject>rectangular-coordinate orthogonal multiplexing (ROM)</subject><subject>Signal processing</subject><subject>Spatial multiplex wireless communication</subject><subject>waveguide slot array antenna</subject><subject>Wideband</subject><subject>Wireless communication</subject><subject>Wireless communications</subject><issn>0733-8724</issn><issn>1558-2213</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2021</creationdate><recordtype>article</recordtype><sourceid>ESBDL</sourceid><sourceid>RIE</sourceid><recordid>eNpFkM9LwzAYhoMoOKd3wUvBix46k3xtkh5l-JONwdjYsWTN15nZpTNph_73rmzo6XsPz_vy8RByzeiAMZo9vI9mA045GwDNIEnSE9Jjaapizhmckh6VALGSPDknFyGsKWVJomSP7Ma2quwGG_TxQu8wGrdVY7cVfqOJFtbgUrsueKwwhGhk3Wc0D9atoikWjXarttI-Hta1N9bpBqOJbz7qVe109T_V4XfTyfg-enQNOqfDJTkrdRXw6nj7ZP78NBu-xqPJy9vwcRQXANDEJTcgUqqlFIpSs9SCGsPKTAmVZIURYDjAklMmdQkIWhhpUOtUcIFKSQV9cnvY3fr6q8XQ5Ou69fvnQs4FVWmaMsr3FD1Qha9D8FjmW2832v_kjOad3XxvN-_s5ke7-8rNoWIR8Q_PEqFASfgF8T922w</recordid><startdate>20211215</startdate><enddate>20211215</enddate><creator>Tomura, Takashi</creator><creator>Hirokawa, Jiro</creator><creator>Ali, Muhsin</creator><creator>Carpintero, Guillermo</creator><general>IEEE</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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This spatial wireless multiplex communication method can be applied at several hundred GHz for further improvements in the data rate because much wider bandwidth is available and this multiplexing method does not require any signal processing. The multiplexing is achieved through the spatial eigenmodes of a novel antenna based on a rectangular coordinate system and magic-T which eliminates the need for computational signal processing efforts. The aperture distributions of these spatial eigenmodes are designed to have different polarities to avoid crosstalk and operate over a wide bandwidth range. We demonstrate their performance with four eigenmodes, achieving crosstalk between modes below −37.8 dB over a 14.6% relative bandwidth (57-66 GHz). We have introduced these antennas on a photonics-enabled real-time wireless data transmission, transmitting over two channels simultaneously, without any signal processing at the transmitter (multiplex) or the receiver (demultiplex). 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subjects	Antenna arrays Antennas Bandwidths Bit error rate Broadband Cartesian coordinates Channels Crosstalk Data transmission Error analysis Error correction Frequency division multiplexing Low noise Millimeter waves Multiplexing Ports (computers) Radio-over-fiber (RoF) Read only memory real-time multiplex wireless communication rectangular-coordinate orthogonal multiplexing (ROM) Signal processing Spatial multiplex wireless communication waveguide slot array antenna Wideband Wireless communication Wireless communications
title	Millimeter-Wave Multiplexed Wideband Wireless Link Using Rectangular-Coordinate Orthogonal Multiplexing (ROM) Antennas
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