Multi-rate variable duty cycle modem for use in an optical communication system
First Claim
1. An optical communication system for transmitting a multi-rate data signal between a transmitter and a receiver, said data signal having a variable data rate, the transmitter comprising:
- an optical source for providing an optical carrier signal;
an encoder for receiving the data signal and encoding the data signal into an encoded data signal, said encoded data signal being encoded based on the data rate of the data signal;
a modulator for receiving the encoded data signal and the optical carrier signal, said modulator modulating the optical carrier signal with the encoded data signal to provide a modulated optical signal, wherein the encoded data signal causes the modulator to vary the duty factor of the modulated optical signal depending on the data rate of the data signal; and
an optical fiber amplifier receiving the modulated optical signal and providing an amplified modulated optical signal for transmission by the transmitter, wherein the fiber amplifier is not using optical power during predetermined times if the data rate of the data signal is below a predetermined full data rate.
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Abstract
An optical communication system (20) is provided for transmitting a multi-rate data signal between a transmitter (22) and a receiver (24) in a power efficient manner. The optical communication system (20) includes an optical source (32) that supplies an optical carrier signal; an encoder (44) that receives and encodes a data signal; an external phase modulator (42) that modulates the optical carrier signal with the encoded data signal, such that the modulator (42) varies the duty factor of the modulated optical signal based on the encoded data signal; and an optically saturated erbium doped fiber amplifier (36) that amplifies the modulated optical signal prior to transmission by the transmitter (22). In accordance with the present invention, the modulation scheme of the optical communication system (20) varies the duty cycle of the modulation to attain power efficiency during periods of low data demand. In an alternative modulation scheme, data bits are encoded using bi-phase mark encoding and are transmitted in variable-length blocks.
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Citations
24 Claims
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1. An optical communication system for transmitting a multi-rate data signal between a transmitter and a receiver, said data signal having a variable data rate, the transmitter comprising:
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an optical source for providing an optical carrier signal;
an encoder for receiving the data signal and encoding the data signal into an encoded data signal, said encoded data signal being encoded based on the data rate of the data signal;
a modulator for receiving the encoded data signal and the optical carrier signal, said modulator modulating the optical carrier signal with the encoded data signal to provide a modulated optical signal, wherein the encoded data signal causes the modulator to vary the duty factor of the modulated optical signal depending on the data rate of the data signal; and
an optical fiber amplifier receiving the modulated optical signal and providing an amplified modulated optical signal for transmission by the transmitter, wherein the fiber amplifier is not using optical power during predetermined times if the data rate of the data signal is below a predetermined full data rate. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12)
a telescope component for receiving the modulated optical signal from the transmitter;
an amplifier for receiving the modulated optical signal and amplifying the modulated optical signal into an amplified modulated optical signal; and
a demodulator for receiving the amplified modulated optical signal and demodulating the amplified modulated optical signal into a data signal and a clock reference signal.
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11. The optical communication system of claim 10 wherein the demodulator further comprises:
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an interferometer for receiving the modulated optical signal and splitting the modulated optical signal into two optical signals, the interferometer having a plurality of selectable delay lines and being operative to pass one of the optical signals over one of the selectable delay lines;
two photodetectors optically connected to the interferometer, each photodetector receiving one of the optical signals and converting the optical signal into a current pulse signal;
a transimpedence amplifier receiving each of the current pulse signals and providing an amplified voltage signal; and
a data recovery unit for receiving the amplified voltage signal and decoding the voltage signal into the data signal and the clock reference signal.
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12. The optical communications system according to claim 1 wherein the optical fiber amplifier operates in an optically saturated average power limited mode for all of the data rates of the data signal.
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13. A method for transmitting a power efficient multi-rate data signal between a transmitter and a receiver in an optical communication system, said data signal having a variable data rate, comprising the steps of:
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receiving a data signal;
encoding the data signal into an encoded data signal based on the data rate of the data signal;
providing an optical carrier signal for transmitting the data signal;
modulating the optical carrier signal with the data rate of the encoded data signal to provide a modulated optical signal;
varying the duty factor of the modulated optical signal based on the encoded data signal; and
amplifying and optically saturating the modulated data signal prior to transmission by the transmitter, wherein amplifying and optically saturating the modulated data signal includes operating a fiber amplifier in optical saturation where the optical amplifier does not use optical power during predetermined times if the data rate of the data signal is below a predetermined full data rate. - View Dependent Claims (14, 15, 16, 17, 18, 19, 20, 21, 22, 23)
receiving the transmitted optical signal at the receiver;
amplifying the transmitted optical signal into an amplified optical signal; and
demodulating the amplified optical signal into a data signal and a clock reference signal.
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23. The method of claim 22 wherein the step of demodulating the amplified optical signal further comprises the steps of:
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splitting the amplified optical signal into two optical signals;
passing at least one of the two optical signals over one of a plurality of selectable delay lines;
combining the two optical signals inteferemetrically to create two new optical signals converting the two new optical signals into a voltage signal; and
decoding the voltage signal into a data signal and a clock reference signal.
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24. A method for transmitting a power efficient multi-rate data signal between a transmitter and a receiver in an optical communication system, said data signal having a variable data rate, comprising the steps of:
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receiving a data signal at an encoder;
encoding the data signal into the encoded data signal, the encoded data signal being indicative of the data rate of the data signal;
providing an optical carrier signal from an optical source to a modulator;
receiving the encoded data signal at the modulator;
modulating the optical carrier signal with the encoded data signal to provide a modulated optical signal;
varying the duty factor of the modulated optical signal by turning on and off the power of the modulator, the duty factor of the modulated optical signal being based on the data rate of the encoded data signal;
amplifying the modulated optical signal using a power average amplifying device, wherein amplifying the modulated optical signal includes operating a fiber amplifier so that the optical amplifier does not use optical power during predetermined times if the data rate of the data signal is below a predetermined full data rate; and
transmitting the amplified modulated optical signal to the receiver, thereby transmitting the data signal in a power efficient manner.
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Specification