Optical communication using duobinary modulation
First Claim
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1. A device, comprising:
- a plurality of analog signal mixers to respectively produce a plurality of analog modulation control signals that respectively carry a plurality of data channels, each analog signal mixer configured to receive and mix a data channel encoded as a duobinary encoded signal and a local oscillator signal at a local oscillator frequency different from local oscillator frequencies received by other analog signal mixers to produce a corresponding analog modulation control signal; and
an optical modulator to receive an input CW laser beam at an optical carrier frequency and to modulate the input CW laser beam in response to the analog modulation control signals to produce an optical output beam which comprises a plurality of different optical subcarriers at optical subcarrier frequencies different from the optical carrier frequency and respectively related to the local oscillator frequencies of the local oscillator signals, wherein each optical subcarrier carries a baseband signal comprising information of a corresponding data channel of the data channels so that the different optical subcarriers carry baseband signals corresponding to the plurality of data channels, respectively, andwherein the optical modulator is an optical Mach-Zehnder modulator which comprises;
an optical splitter which splits the input CW laser beam into a first optical carrier beam and a second optical carrier beam, both at the optical carrier frequency;
a first AC phase modulator to apply the analog modulation control signals with a 90-degree phase shift between two analog modulation control signals adjacent in frequency to modulate the first optical carrier beam to produce a first modulated optical signal;
a second AC phase modulator to apply the analog modulation control signals with a 90-degree phase shift between two analog modulation control signals adjacent in frequency to modulate the second optical carrier beam to produce a second modulated optical signal, each analog modulation control signal in the first AC phase modulator being phase shifted by 90 degrees relative to each corresponding analog modulation control signal in the second AC phase modulator;
first and second DC phase modulators to modulate the first and the second optical signals, respectively, and configured to modulate an optical carrier component at the optical carrier frequency of the first modulated optical signal to be phase shifted by 90 degrees relative to an optical carrier component at the optical carrier frequency of the second modulated optical signal; and
an optical combiner which combines the first and second modulated optical signals to form the output optical beam carrying the plurality of data channels, wherein each data channel is carried by only one of the different optical subcarriers and the optical subcarrier frequencies are different from the optical carrier frequency by amounts corresponding to the local oscillator frequencies of the local oscillator signals.
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Abstract
Optical techniques, devices and systems for combining duobinary modulation and optical subcarrier multiplexing in optical communication applications. An analog mixer is used to mix a duobinary signal for a data channel and a local oscillator signal to produce a modulation control signal for controlling the subsequent optical subcarrier multiplexing modulation. Various optical subcarrier multiplexing modulation techniques may be used including optical single sideband modulators and optical double sideband modulators.
155 Citations
13 Claims
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1. A device, comprising:
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a plurality of analog signal mixers to respectively produce a plurality of analog modulation control signals that respectively carry a plurality of data channels, each analog signal mixer configured to receive and mix a data channel encoded as a duobinary encoded signal and a local oscillator signal at a local oscillator frequency different from local oscillator frequencies received by other analog signal mixers to produce a corresponding analog modulation control signal; and an optical modulator to receive an input CW laser beam at an optical carrier frequency and to modulate the input CW laser beam in response to the analog modulation control signals to produce an optical output beam which comprises a plurality of different optical subcarriers at optical subcarrier frequencies different from the optical carrier frequency and respectively related to the local oscillator frequencies of the local oscillator signals, wherein each optical subcarrier carries a baseband signal comprising information of a corresponding data channel of the data channels so that the different optical subcarriers carry baseband signals corresponding to the plurality of data channels, respectively, and wherein the optical modulator is an optical Mach-Zehnder modulator which comprises; an optical splitter which splits the input CW laser beam into a first optical carrier beam and a second optical carrier beam, both at the optical carrier frequency; a first AC phase modulator to apply the analog modulation control signals with a 90-degree phase shift between two analog modulation control signals adjacent in frequency to modulate the first optical carrier beam to produce a first modulated optical signal; a second AC phase modulator to apply the analog modulation control signals with a 90-degree phase shift between two analog modulation control signals adjacent in frequency to modulate the second optical carrier beam to produce a second modulated optical signal, each analog modulation control signal in the first AC phase modulator being phase shifted by 90 degrees relative to each corresponding analog modulation control signal in the second AC phase modulator; first and second DC phase modulators to modulate the first and the second optical signals, respectively, and configured to modulate an optical carrier component at the optical carrier frequency of the first modulated optical signal to be phase shifted by 90 degrees relative to an optical carrier component at the optical carrier frequency of the second modulated optical signal; and an optical combiner which combines the first and second modulated optical signals to form the output optical beam carrying the plurality of data channels, wherein each data channel is carried by only one of the different optical subcarriers and the optical subcarrier frequencies are different from the optical carrier frequency by amounts corresponding to the local oscillator frequencies of the local oscillator signals. - View Dependent Claims (2, 3, 4)
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5. A device, comprising:
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a plurality of analog signal mixers to respectively produce a plurality of analog modulation control signals that respectively carry a plurality of data channels, each analog signal mixer configured to receive and mix a data channel encoded as a duobinary encoded signal and a local oscillator signal at a local oscillator frequency different from local oscillator frequencies received by other analog signal mixers to produce a corresponding analog modulation control signal; and an optical modulator to receive an input CW laser beam at an optical carrier frequency and to modulate the input CW laser beam in response to the analog modulation control signals to produce an optical output beam which comprises a plurality of different optical subcarriers at optical subcarrier frequencies different from the optical carrier frequency and respectively related to the local oscillator frequencies of the local oscillator signals, wherein each optical subcarrier carries a baseband signal comprising information of a corresponding data channel of the data channels so that the different optical subcarriers carry baseband signals corresponding to the plurality of data channels, respectively, wherein the optical modulator is an optical double sideband modulator and comprises; an optical carrier modulator to modulate the input CW laser beam to produce an optical beam having first and second carrier frequencies on two opposite sides of the optical carrier frequency; an optical splitter which splits the optical beam into a first optical beam and a second optical beam; a first optical filter to filter the first optical beam to transmit light at the first optical carrier frequency as a first optical carrier beam while rejecting light at the second carrier frequency and the optical carrier frequency; a second optical filter to filter the second optical beam to transmit light at the second optical carrier frequency as a second optical carrier beam while rejecting light at the first carrier frequency and the optical carrier frequency; a first optical Mach-Zehnder modulator to apply the analog modulation control signals and a DC bias to two optical modulation paths to cause a 180-degree phase shift between the optical modulation paths and to produce a first output optical signal which carries the plurality of different optical subcarriers at optical subcarrier frequencies at both sides o of the first optical carrier frequency and different from the first optical carrier frequency by amounts corresponding to the local oscillator frequencies of the local oscillator signals and in which light at the first optical carrier frequency is suppressed; a second optical Mach-Zehnder modulator to apply the analog modulation control signals and a DC bias to two optical modulation paths to cause a 180-degree phase shift between the optical modulation paths and to produce a second output optical signal which carries the plurality of different optical subcarriers at optical subcarrier frequencies at both sides of the second optical carrier frequency and different from the second optical carrier frequency by amounts corresponding to the local oscillator frequencies of the local oscillator signals and in which light at the second optical carrier frequency is suppressed; an optical combiner to combine the first and second output optical signals into a single combined beam; and an optical filtering device to filter the single combined beam to transmit optical subcarriers at frequencies between the first optical subcarrier and the second optical carrier frequency while rejecting other optical subcarriers to produce the optical output beam. - View Dependent Claims (6, 7, 8, 9, 10, 11)
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12. A method, comprising:
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receiving a plurality of data channels encoded as duobinary encoded signals; using a plurality of analog signal mixers to respectively mix the plurality of data channels and a plurality of local oscillator signals at respectively different local oscillator frequencies to produce a plurality of analog modulation control signals that respectively carry the plurality of data channels; and receiving an input CW laser beam at an optical carrier frequency; using an optical splitter to split the input CW laser beam into a first optical carrier beam and a second optical carrier beam, both at the optical carrier frequency; applying the plurality of analog modulation control signals with a 90-degree phase shift between two analog modulation control signals adjacent in frequency to modulate the first and second optical carrier beam to produce respectively a first and second modulated optical signal, each analog modulation control signal applied to the first optical carrier beam being phase shifted by 90 degrees relative to each corresponding analog modulation control signal applied to the second optical carrier beam; modulating an optical carrier component at the optical carrier frequency of the first modulated optical signal to be phase shifted by 90 degrees relative to an optical carrier component at the optical carrier frequency of the second modulated optical signal; and using an optical combiner to combine the first and second modulated optical signals to form an output optical beam carrying the plurality of data channels, wherein; the optical output beam comprises a plurality of different optical subcarriers at optical subcarrier frequencies different from the optical carrier frequency and respectively related to the local oscillator frequencies of the local oscillator signals, each optical subcarrier carries a baseband signal comprising information of a corresponding data channel of the data channels so that the different optical subcarriers carry baseband signals corresponding to the plurality of data channels, respectively, and each data channel is carried by only one of the different optical subcarriers and the optical subcarrier frequencies are different from the optical carrier frequency by amounts corresponding to the local oscillator frequencies of the local oscillator signals.
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13. A method, comprising:
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receiving a plurality of data channels encoded as duobinary encoded signals; using a plurality of analog signal mixers to respectively mix the plurality of data channels and a plurality of local oscillator signals at respectively different local oscillator frequencies to produce a plurality of analog modulation control signals that respectively carry the plurality of data channels; receiving an input CW laser beam at an optical carrier frequency; modulating the input CW laser beam to produce an optical beam having first and second carrier frequencies on two opposite sides of the optical carrier frequency; using an optical splitter to split the optical beam into a first optical beam and a second optical beam; filtering the first optical beam to transmit light at the first optical carrier frequency as a first optical carrier beam while rejecting light at the second carrier frequency and the optical carrier frequency; filtering the second optical beam to transmit light at the second optical carrier frequency as a second optical carrier beam while rejecting light at the first carrier frequency and the optical carrier frequency; applying the analog modulation control signals and a DC bias to two optical modulation paths to cause a 180-degree phase shift between the optical modulation paths and to produce a first output optical signal which carries the plurality of different optical subcarriers at optical subcarrier frequencies at both sides of the first optical carrier frequency and different from the first optical carrier frequency by amounts corresponding to the local oscillator frequencies of the local oscillator signals and in which light at the first optical carrier frequency is suppressed; applying the analog modulation control signals and a DC bias to two other optical modulation paths to cause a 180-degree phase shift between the optical modulation paths and to produce a second output optical signal which carries the plurality of different optical subcarriers at optical subcarrier frequencies at both sides of the second optical carrier frequency and different from the second optical carrier frequency by amounts corresponding to the local oscillator frequencies of the local oscillator signals and in which light at the second optical carrier frequency is suppressed; using an optical combiner to combine the first and second output optical signals into a single combined beam; and filtering the single combined beam to transmit optical subcarriers at frequencies between the first optical subcarrier and the second optical carrier frequency while rejecting other optical subcarriers to produce an optical output beam comprising a plurality of different optical subcarriers at optical subcarrier frequencies different from the optical carrier frequency and respectively related to the local oscillator frequencies of the local oscillator signals, wherein each optical subcarrier carries a baseband signal comprising information of a corresponding data channel of the data channels so that the different optical subcarriers carry baseband signals corresponding to the plurality of data channels, respectively.
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Specification