CN1719755A - Burst mode optical receiver, system and method - Google Patents

Abstract

A communication system comprising: an optical receiver for receiving the optical signal and converting the optical signal into an electronic signal; a transimpedance amplifier (TIA) for filtering the electrical signal; a Limiting Amplifier (LA) connected to the transimpedance amplifier; an Automatic Threshold Control (ATC) connected to the transimpedance amplifier for providing a reference voltage to the limiting amplifier. The automatic threshold controller further includes a common emitter circuit and an emitter tracking circuit, and the logic high signals (logic high signals) and the logic low signals (logic low signals) in the electronic signals are obtained by comparing with the reference voltage provided by the automatic threshold controller.

Description

Burst mode light receiver, system and method

Technical field

The invention relates to a kind of communication system, refer to a kind of burst mode light receiver, system and method especially.

Background technology

The receiver of light communication system can receive continuous transmission data (being continuous mode) or with the data of burst mode transmission (be a kind of transfer of data of un-encoded, wherein only have in Chuan Shu the data long string 0 or long go here and there 1).Figure lA, Fig. 1 C reach the waveform schematic diagram of transfer of data warp under burst mode at continuous mode, and have a direct current bias voltage (DC offset) respectively.Fig. 1 C, 1D be continuous mode and under burst mode transfer of data through signal through ac filter waveform schematic diagram.The one interchange optical receiver that transmits data serially also can be used in the known communication system.

Can use the direct current optical receiver of burst mode transmission data also can be used in the known communication system.But the required data demodulates program of burst mode transmission can increase the complexity of system and lower the speed of transfer of data.Use in No. 5875050, be described in United States Patent (USP) respectively No. 5025456, No. 5371763, United States Patent (USP) of the example of the known communication system of burst mode transmission data and the United States Patent (USP).When some numerical data signals were received from a data channel (data channel), these signals can be fallen usually translated (degrade) one-tenth analog signal, and has the amplitude of uncertain size and be difficult for transfer characteristic between recognition logic 1 and the logical zero.When logical transition (logic transition) was not easy to identify, noise (noise) and pulse length distortion (pulse width distortion) will influence the performance of system sensitivity (sensitivity) and frequency range (bandwidth).

Therefore, in association area, need a system and a method to solve above-mentioned shortcoming, especially need a burst mode light receiver, system and method, so that overcome degradation (degradation) effect and the noise of burst mode transmission communication system and the effect of waveform distortion that signal takes place when its logical transition of decipher.

Summary of the invention

The object of the present invention is to provide a kind of burst mode light receiver, system and method, can solve because the restriction and the variety of issue that shortcoming causes of correlation technique.

For achieving the above object, a system provided by the invention comprises: an optical receiver, in order to receive the light signal and the light signal be converted to electric signal; One changes impedance amplifier (TIA), in order to the filtering electronic signal; One limiting amplifier (LA) has and changes first input and an automatic Critical Control device (ATC) that is connected with the commentaries on classics impedance amplifier that impedance amplifier is connected, imports so that a reference voltage to second of limiting amplifier to be provided.In addition, automatically the Critical Control device comprises that a common emitter portion and an emitter-base bandgap grading follow portion, and the logic high signal of electric signal and logic low-level signal are with the reference voltage comparison and get.

According to the present invention, a data transmission method comprises: receive the light signal; The convert light signal is an electric signal; The filtering electronic signal; Utilize a common emitter circuit and an emitter-base bandgap grading to follow circuit control one between the high position of electric signal and the critical voltage between the low level; And with respect to critical voltage, logic high signal and logic low-level signal in the decision electric signal.

According to another preferred embodiment of the present invention, one communication system with a passive smooth networking comprises: a burst mode light receiver, be converted to electric signal in order to the light signal of reception burst mode and with the light signal: one changes impedance amplifier, in order to the filtering electronic signal; One limiting amplifier that is connected with this commentaries on classics impedance amplifier; The one automatic Critical Control device that is connected with the commentaries on classics impedance amplifier is in order to provide a reference voltage to limiting amplifier.

In addition, automatically the Critical Control device comprises that also a common emitter portion and an emitter-base bandgap grading follow portion, and the logic high signal of electric signal and logic low-level signal are with the reference voltage comparison and get.

Characteristics that the present invention is extra and advantage will propose in following execution mode, and to a certain extent can be by obtaining understanding in its narration and the execution mode.Characteristics of the present invention and advantage can be further understood via element in the claim and marriage relation thereof.

Aforesaid summary narration of the present invention and follow-up being described in detail are all exemplary content and only for the usefulness of explaining the present invention, it is unrestricted content of the present invention also.Interest field of the present invention is as the criterion with claim.Accompanying drawing of the present invention is to cooperate content of the present invention and constitute partial content of the present invention, and cooperates narration of the present invention and preferred embodiment of the present invention to illustrate principle of the present invention.

Description of drawings

Figure 1A, Figure 1B, Fig. 1 C and Fig. 1 D are the waveform schematic diagrames of transfer of data under continuous mode and burst mode respectively.

Fig. 2 is a circuit diagram of describing a burst mode light receiver in the system of a preferred embodiment of the present invention.

Fig. 3 one has the transmission system schematic diagram of the burst mode light receiver of a preferred embodiment of the present invention.

Embodiment

For more understanding technology contents of the present invention, be described as follows especially exemplified by preferred embodiment of the present invention.

Fig. 2 is a circuit diagram of describing a burst mode light receiver in the system of a preferred embodiment of the present invention.Fig. 3 one has the transmission system schematic diagram of the burst mode light receiver of a preferred embodiment of the present invention, for example passive smooth networking.(at Fig. 3 is to comprise that with local side (office line terminal, OLT) 300 together show) one changes impedance amplifier 210, a limiting amplifier 220, one control switchs 230 and an automatic Critical Control device 240 to burst mode light receiver 200.Automatically Critical Control device 240 has also comprised transistor 242 and transistor 244, and constitutes a common emitter circuit and a coupled emitter-base bandgap grading is followed circuit.And resistance 246 and resistance 248 are connected with the collection utmost point and the emitter-base bandgap grading of transistor 242 respectively; Resistance 250 and resistance 252 are connected with the collection utmost point and the emitter-base bandgap grading of transistor 244 respectively.Resistance 246 and resistance 250 are connected in a supply voltage (supply voltage), and resistance 248 and resistance 252 is ground connection (ground) then.In addition, optical receiver 200 can be installed on one and has in wavelength divided multiplex (MUX) (WDM) function system.

See also Fig. 3, local side 300 is via a splitter (power splitter) 310, as star-type coupler (star coupler), with a plurality of smooth network unit or ONUs (N1, N2, N3, N4) connection.By an optical fiber cable 320 entrained data is that (time division multipleaccess, mode TDMA) is transmitted between splitter 310 and the local side 300 with the time division multiplexing access.Be transferred to descending (downstream) light signal transmission of ONUs and all can be implemented from local side 300 from up (upstream) light signal transmission that ONUs is transferred to local side 300.Up smooth signal transmission is that optical transmitting set (optical transmitter) and the wavelength divided duplexing equipment from ONUs transmits out, and via fine line 320 transmission of the individual fibers transmission line that is linked to each ONUs, splitter 310 and a common light, and these signals are to transmit via common optical fiber cable 320 with burst mode, and are positioned at optical receiver 200 receptions of local side 300 via another wavelength divided duplexing equipment (not shown).Optical receiver 200 receives from the burst mode signal of ONUs and is converted into electric signal.

Especially as shown in Figure 2, automatically the common emitter circuit in the Critical Control device 240 comprise have base stage, the transistor 242 of the collection utmost point and emitter-base bandgap grading, resistance 246 and 248, and and resistance 248 electric capacity 254 arranged side by side.The base stage of transistor 242 is to be connected with the negative output S-that changes impedance amplifier via resistance 256 in the common emitter circuit.Emitter-base bandgap grading in the automatic Critical Control device 240 is followed circuit and is comprised transistor 244, resistance 250 and the resistance 252 that has base stage, collects the utmost point and emitter-base bandgap grading, and the base stage of transistor 244 is connected with the collection utmost point and the electric capacity 254 of transistor 242.One direct current voltage source is connected in the PIN type diode 260 of a combining optical element, so that optical signal is converted to electric signal, for example one has the PIN type diode 260 that is series at the output of changeing impedance amplifier 210.The output S+ that changes impedance amplifier is connected via the limiting amplifier 220 that electric capacity 262 and one has a computing amplifier comparator (operational amplifier comparator), and the output S-of commentaries on classics impedance amplifier is connected with automatic Critical Control device 240 via resistance 256.Automatically the output of Critical Control device 240 is connected with limiting amplifier 220 and control switch 230 via electric capacity 264 and electric capacity 266 respectively, and control switch 230 is promptly accumulated voltage in electric capacity 266.Control switch 230 also comprises an operational amplifier 268.When signal was imported, control switch 230 was just opened limiting amplifier 220; And when not having the signal input, control switch 230 just cuts out limiting amplifier 220, to prevent voltage oscillation (voltageoscillation) and signal distortion (signal distortion) limiting amplifier is caused adverse effect.On the other hand, as control switch and a clock pulse (clock) and a data recovery circuit (data recoverycircuit, CDR) (phase-lock loop (phase lock loop for example, PLL) or delay-locked loop (delay lock loop, when DLL)) being connected, the function of (data recovery) replied system's time pulse signal in the may command optical receiver 200 (system clock signal) and data by control switch.

When a burst mode light receiver 200 receives the light signal via optical fiber cable 320 from ONUs after, PIN type diode 260 can be converted to electric signal with the light signal, and now changeing the output signal that impedance amplifier 210 is converted to low noise, and output signal S+ and output signal S-offer limiting amplifier 220 and automatic Critical Control device 240 respectively.When receiving burst mode light signal, via the output S-that changes impedance amplifier 210, it is also roughly identical with the voltage that changes impedance amplifier 210 output S-up to its voltage to 254 chargings of the electric capacity in the circuit that optical receiver 210 drives common emitter circuits, and emitter-base bandgap grading is followed circuit and can be prevented electric capacity 254 overcharge (overcharging).Therefore, emitter-base bandgap grading follow that circuit helps to slow down since the continuity high-frequency signals of optical receiver 200 input cause to the electric capacity adverse influence of charging.

Therefore, Critical Control device 240 is connected with the negative output S-that changes impedance amplifier and provides a critical voltage (threshold voltage) that is fit to supply to judge that the logic state of the electric signal representative that is converted by the light signal is 1 or 0 automatically.Automatically Critical Control device 240 is via second input of electric capacity 264 output one critical values (threshold value) to limiting amplifier 220.Limiting amplifier 220 can be selected suitable susceptibility and have magnitude of voltage 5mV or above signal so that only amplify.This critical value can be as a reference voltage of limiting amplifier 220 negative inputs, so that logical one and the logical zero of logic identification from the signal that changes impedance amplifier 210 and the transmission via electric capacity 262.Automatic Critical Control device 240 has guarantees that critical value can approach to import the intensity median of changeing impedance amplifier 210 signals, so that prevent the pulse length distortion of generation when logic output (logic output).

Preferred embodiment of the present invention can comprise a kind of data transmission method, and comprises that receiving light signal, convert light signal is electric signal, filtering electronic signal, utilizes common emitter circuit and emitter-base bandgap grading to follow circuit control one to determine logic high signal and logic low-level signal in the electric signal between the high position of electric signal and the critical voltage between the low level and based on this critical voltage.In addition, the method can be applicable to one and has with burst mode and transmit in the system at passive smooth networking of light signal.When the light signal was sent to optical receiver, the light signal can be the light signal of wavelength divided multiplex (MUX) (wavelength divisionmultiplexed).When the electric capacity in the common emitter circuit was recharged, control switch can prevent that electric capacity from being overcharged.

For having the people of general knowledge in field of the present invention, other embodiment of the present invention can be by understanding easily in the content of this specification and the execution mode.Only for the usefulness of explanation, right application content of the present invention is to be as the criterion with the claim of applying for for content of this specification and example.

Claims (20)

1. A system comprising: an optical receiver for receiving an optical signal and converting the optical signal into an electronic signal; a transimpedance amplifier to filter the electronic signal; a limiting amplifier having a first input connected to the transimpedance amplifier; and an automatic threshold controller connected to the transimpedance amplifier and providing a reference voltage to a second input of the limiting amplifier; Wherein the automatic threshold controller also includes a common emitter part and an emitter follower part; a logic high signal and a logic low signal of the electronic signal are compared with the reference voltage. 2. The system of claim 1, wherein the optical receiver further comprises: a grounded DC voltage source; A photodiode is connected with the voltage source and converts the light signal into the electronic signal. 3. The system of claim 1, wherein the common emitter part is connected to a negative output of the transimpedance amplifier and the limiting amplifier is connected to an output of the emitter follower part. 4. The system of claim 3, further comprising a passive optical network transmitting the optical signal in a burst mode. 5. The system according to claim 1, further comprising a control switch connected with an output of the common emitter part and the second input of the limiting amplifier, the control switch is used for receiving The electronic signal correspondingly switches the limiting amplifier. 6. The system of claim 1, wherein the optical receiver further comprises a switch having an operational amplifier and a DC voltage source connected to a reference voltage, and the operational amplifier is connected to the limiting the second input of the amplifier and the DC voltage source. 7. The system according to claim 1, further comprising a splitter for receiving a signal from an optical network unit and a common fiber optic cable connected to the splitter for transmitting the optical signal to the light receiver. 8. The system of claim 1, wherein the common emitter portion comprises a common emitter circuit having a bipolar transistor having a base, a collector and an emitter And the base is connected with a resistor connected in series with a negative output of the transimpedance amplifier. 9. The system of claim 1, wherein the emitter follower comprises an emitter follower circuit having a bipolar transistor having a base, a collector and an emitter and the base is connected to the common emitter part. 10. The system according to claim 1, further comprising an optical network unit and a wavelength division multiplexer for multiplexing the optical signal. 11. A data transmission method, comprising the following steps: Receive a light signal; Convert the optical signal to an electronic signal: filter the electronic signal; using a common emitter circuit and an emitter follower circuit to control a threshold voltage between high and low levels of the electronic signal; and Relative to the threshold voltage, a logic high signal and a logic low signal in the electronic signal are determined. 12. The method of claim 11, further comprising a step of amplifying and low-pass filtering the electronic signal. 13. The method of claim 11, further comprising a step of transmitting the optical signal in a burst mode. 14. The method of claim 11, further comprising a step of charging a capacitor of the common emitter circuit. 15. The method of claim 14, further comprising the step of providing a control switch to prevent overcharging of a capacitor. 16. A communication system having a passive optical network comprising: a burst mode optical receiver for receiving a burst mode optical signal and converting the optical signal into an electronic signal; a transimpedance amplifier to filter the electronic signal; a limiting amplifier connected to the transimpedance amplifier: and an automatic threshold controller connected to the transimpedance amplifier and providing a reference voltage to the limiting amplifier; Wherein the automatic threshold controller also includes a common emitter part and an emitter follower part; a logic high signal and a logic low signal of the electronic signal are compared with the reference voltage. 17. The system of claim 16, wherein the optical receiver further comprises a photodiode for converting the optical signal into the electronic signal. 18. The system according to claim 16, further comprising a control switch connected with an output of the common emitter part and the second input of the limiting amplifier, the control switch is used to determine whether to receive The electronic signal correspondingly switches the limiting amplifier. 19. The system of claim 16, wherein the common emitter portion comprises a common emitter circuit having a bipolar transistor having a base, a collector and an emitter And the base is connected with a resistor connected in series with a negative output of the transimpedance amplifier. 20. The system of claim 16, wherein the emitter follower comprises an emitter follower circuit having a bipolar transistor having a base, a collector and an emitter and the base is connected to the common emitter part.

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