Optical line terminal, passive optical network and radio frequency signal transmission method

Abstract

An optical line terminal, a passive optical network and a radio frequency signal transmission method in the communication technical field are provided. The passive optical network comprises: an OLT, an ODN and at least one ONU. The OLT comprises: at least one transmitting unit, which provides one dedicated downstream optical carrier and two dedicated upstream optical carriers for ONU; the two dedicated optical carriers for ONU are configured to carry ONU upstream radio frequency signals; a multiplexing/demultiplexing unit; and at least one receiving unit which obtains the upstream signal from the demultiplexed upstream optical signal. The bandwidth of wireless access network is enhanced, and the design of ONU is simple.

Description

FIELD OF INVENTION

The present disclosure relates to the technical field of network communications, and more particularly to an optical line terminal, a passive optical network and a radio frequency signal transmission method.

BACKGROUND OF THE INVENTION

A Passive Optical Network (PON) is a point-to-multipoint tree network structure. With such characteristics as simple network structure, sharing optical fiber resources, low cost and no need for installing active equipment externally, The PON is recognized as the most promising optical access technology.

At present, in the network based on a PON, the Radio Frequency (RF) signal transmission method is as follows.

The same pair of optical carriers is used between a central office terminal and a plurality of base stations (BS) to transmit RF signals; that is, in a downstream direction, the central office terminal modulates RF signals of different frequencies which need to be transmitted to a plurality of BSs on a same downstream optical carrier through subcarrier multiplexing, the modulated optical signal is transmitted to a plurality of BSs via optical fiber, and the BSs convert the received optical signal to an electrical signal through a Photo Diode (PD). In other words, the optical signal is converted to a RF signal and the RF signal of said BS is obtained by filtering, and then the RF signal obtained through filtering is amplified and transmitted via an antenna; in an upstream direction, a plurality of RF signals of different frequencies which need to be transmitted to the central office terminal by the BSs are modulated on the upstream optical carrier of the same wavelength, and the upstream optical carriers of a plurality of BSs are combined at a Remote Node (RN), and then transmitted to the central office terminal via an optical fiber.

Because a signal after being photoelectrically converted is a RF signal, which may be transmitted directly by a base station, the base station does not need to perform modulation and frequency mixing on the received signal again. Therefore, the base station in the network based on a PON is simplified in comparison with a conventional wireless transmission network.

Nevertheless, the above prior RF signal transmission has at least the following problems:

Optical fiber only serves as a carrier to transparently transmit RF signals in the above RF signal transmission process. Therefore, the large-capacity bandwidth resources of an optical fiber network are not fully used, thereby leading to low bandwidth of a wireless access network.

SUMMARY OF THE INVENTION

An embodiment of the present disclosure provides an optical line terminal, a passive optical network, and a radio frequency signal transmission method, in which the large-capacity bandwidth resources of the optical fiber network are fully used, the bandwidth of the wireless access network is enhanced and the design of an optical network unit (ONU) is simple.

An embodiment of the present disclosure provides an optical line terminal, including: (1) at least one transmitting unit, configured to provide an optical network unit (ONU) with one downstream optical carrier and two upstream optical carriers dedicated for the ONU, wherein the transmitting unit is configured to modulate the downstream radio frequency signal which needs to be transmitted to an ONU on the downstream optical carrier dedicated for the ONU, and after mixing the modulated downstream optical carrier with the two upstream optical carriers dedicated for the ONU, output a downstream optical signal; the two upstream optical carriers dedicated for the ONU are configured to carry upstream radio frequency signals of the ONU; (2) a multiplexing/demultiplexing unit, configured to multiplex through wavelength division downstream optical signals outputted from each transmitting unit and transmit the multiplexed downstream optical signals to an ONU via an optical distribution network (ODN); and wavelength division demultiplex the multiplexed upstream optical wave of each ONU which is transmitted by an ODN, and then output the demultiplexed upstream optical signals; and (3) at least one receiving unit, configured to obtain an upstream signal from the demultiplexed upstream optical signals.

An embodiment of the present disclosure further provides a passive optical network, including an optical line terminal (OLT), an optical distribution network (ODN), and at least one optical network unit (ONU), where the OLT includes: (1) at least one transmitting unit, configured to provide an ONU with one downstream optical carrier and two upstream optical carriers dedicated for the ONU, wherein the transmitting unit is configured to modulate the downstream radio frequency signal which needs to be transmitted to an ONU on the downstream optical carrier dedicated for the ONU, and after mixing the modulated downstream optical carrier with the two upstream optical carriers dedicated for the ONU, output the downstream optical signal; the two upstream optical carriers dedicated for the ONU are configured to carry upstream radio frequency signals of an ONU; (2) a multiplexing/demultiplexing unit, configured to wavelength division multiplex downstream optical signals outputted from each transmitting unit and transmit the multiplexed downstream optical signals to the ONU, via the ODN, and wavelength division demultiplex the multiplexed upstream optical wave of each ONU which is transmitted by the ODN, and then output the demultiplexed upstream optical signals; and (3) at least one receiving unit, configured to obtain an upstream signal from the demultiplexed upstream optical signals.

An embodiment of the present disclosure further provides a radio frequency signal transmission method, including:

In the downstream direction: Modulating a downstream radio frequency signal to be transmitted to each optical network unit (ONU) on a downstream optical carrier dedicated for the ONU, mixing the modulated downstream optical carrier for the ONU and two upstream optical carriers dedicated for the ONU, and after multiplexing each mixed downstream optical signal for each wavelength division ONU, transmitting the multiplexed optical signal to the ONU via an optical distribution network (ODN), by an optical line terminal (OLT), wherein the two upstream optical carriers dedicated for the ONU are configured to carry upstream radio frequency signals of the ONU.

In the upstream direction: Receiving the wavelength division multiplexed upstream optical wave of each ONU which is transmitted from an ODN, and demultiplexing the multiplexed upstream optical wavelength division wave, and obtaining the upstream signal from each demultiplexed upstream optical signal, by an OLT.

It can be seen from the description of the above technical solution that, by combining one dedicated downstream optical carrier and two dedicated upstream optical carriers for an ONU, wavelength division multiplexing each combined downstream optical carrier and then transmitting them, on the basis of realizing a colorless ONU, the optical carrier may carry more signals, the large-capacity bandwidth resources of the optical fiber network are fully used, and the bandwidth of the wireless access network is enhanced. Moreover, by modulating the upstream radio frequency signal on the two upstream optical carriers, the power spectrum of a modulation signal is enhanced, the processing procedure of amplifying the upstream optical signal by the ONU is omitted, and the design of the ONU is simple upstream.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram (I) illustrating the configuration of the passive optical network according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram illustrating the frequency relationship among three optical carriers according to an embodiment of the present disclosure;

FIG. 3 is a schematic diagram illustrating a signal spectrum in the combined downstream optical carrier according to an embodiment of the present disclosure;

FIG. 4 is a schematic diagram illustrating the signal spectrum in the wavelength division multiplexed downstream optical carrier according to an embodiment of the present disclosure;

FIG. 5 is a schematic diagram illustrating the signal spectrum in an upstream optical carrier according to an embodiment of the present disclosure; and

FIG. 6 is a schematic diagram (II) illustrating the configuration of the passive optical network according to an embodiment of the present disclosure.

DETAILED DESCRIPTION OF THE EMBODIMENTS

A passive optical network according to an embodiment of the present disclosure is described below.

The passive optical network according to an embodiment of the present disclosure includes: an Optical Line Terminal (OLT), an Optical Distribution Network (ODN), and at least one Optical Network Unit (ONU). Generally, there is a plurality of ONUs. The ONU has dedicated optical carriers; that is, each ONU correspondingly has dedicated optical carriers, one ONU having two dedicated upstream optical carriers and one dedicated downstream optical carrier.

The OLT includes: a transmitting unit, a multiplexing/demultiplexing unit and a receiving unit. There are one or more transmitting units and one or more receiving units. One transmitting unit corresponds to one ONU, and one receiving unit corresponds to one ONU. The number of the transmitting units and the number of the receiving units may be related to that of an ONU.

The process of transmitting, by OLT, the downstream radio frequency signal to a plurality of ONUs is as follows:

Each transmitting unit provides one dedicated downstream optical carrier and two dedicated upstream optical carriers for an ONU corresponding to the transmitting unit. The two dedicated upstream optical carriers for an ONU provided by the transmitting unit are transmitted to the corresponding ONU, and the two dedicated upstream optical carriers for the ONU are configured to carry the upstream radio frequency signal transmitted to an OLT by the ONU; that is, the ONU modulates the upstream radio frequency signal on the upstream optical carriers provided by the transmitting unit of the OLT, and are transmitted to the OLT via an ODN, thereby realizing a colorless ONU.

To ensure that the OLT may accurately detect the upstream optical signal and guarantee the sensitiveness of the receiving unit of the OLT, the two dedicated upstream optical carriers provided by the transmitting unit for one ONU may meet a certain condition, for example, the carrier frequencies of the two dedicated upstream optical carriers provided by the transmitting unit for the ONU are f_c1 and f_c3, then the condition that f_c1 and f_c3 need to meet may be the following condition:

f _c3 −f _c1=2×f_RF—u, where

f_RF—u is the radio-frequency frequency of the upstream radio frequency signal.

The condition met by the two dedicated upstream optical carriers for the ONU may be in other forms, for example, little adjustment could be made to the left part and the right part of the above equation.

The transmitting unit modulates the downstream radio frequency signal transmitted to the ONU on the dedicated downstream optical carrier for the ONU. The modulation may be carrier suppressed double sideband modulation and may be any other existing modulation method, for example, Double Sideband modulation. The modulation method for modulating the downstream radio frequency signal on the downstream optical carrier is not limited in an embodiment of the present disclosure. The radio-frequency frequency of the downstream radio frequency signal may be in waveband of millimeter wave. After the modulation is completed, the transmitting unit combines the modulated downstream optical carrier and the two dedicated upstream optical carriers for the ONU and outputs the combined downstream optical signal.

The multiplexing/demultiplexing unit in the OLT wavelength division multiplexes the combined downstream optical signal outputted by each transmitting unit, and outputs the downstream optical wave wavelength division multiplexed.

The downstream optical wave outputted by the multiplexing/demultiplexing unit is transmitted to the ONU via an ODN, for example, the downstream optical wave outputted by the multiplexing/demultiplexing unit is transmitted to the remote node with the Wavelength Division Demultiplexing function in an ODN via an optical fiber, the downstream optical wave in the optical fiber is demultiplexed to the plurality of combined downstream optical signals by the remote node, and then the demultiplexed downstream optical signals are transmitted to different ONUs.

An ONU receives the combined downstream optical signal transmitted by an ODN, and divides the combined downstream optical signal into two parts. The ONU detects one part of the downstream optical signal (that is to perform photoelectric conversion) to obtain the downstream radio frequency signal in the downstream optical signal after photoelectric conversion. The other part of the downstream optical signal may be configured to carry the upstream radio frequency signal. After the ONU detects the downstream radio frequency signal, the downstream radio frequency signal may be processed with a plurality of methods. For example, the downstream radio frequency signal is transmitted directly via the antenna; or the downstream radio frequency signal is subject to down conversion and the signal after the down conversion is transmitted to a user terminal via a transmission medium such as a copper wire. The specific processing method for the downstream radio frequency signal after an ONU detects the downstream radio frequency signal is not limited in the embodiment of the present disclosure.

The process of transmitting upstream radio frequency signals to an OLT by a plurality of ONUs is as follows.

An ONU directly modulates the upstream radio frequency signal on the other part of the obtained downstream optical signal to generate the upstream optical signal and transmits the upstream optical signal to OLT via ODN. For example, the upstream optical signal is transmitted to the remote note with the Wavelength Division Multiplex function in ODN via optical fiber, and the remote note wavelength division multiplexes the upstream optical signal transmitted from each ONU, and transmits the upstream optical waves wavelength division multiplexed to OLT via optical fiber.

The multiplexing/demultiplexing unit in OLT receives the upstream optical wave transmitted in the optical fiber, wavelength division demultiplexes the upstream optical wave to obtain the upstream optical signal of each ONU and transmits it to the corresponding receiving unit.

After receiving the upstream optical signal transmitted from the multiplexing/demultiplexing unit, the receiving unit in OLT obtains upstream signal from the upstream optical signal. For example, the receiving unit detects the upstream optical signal and performs down conversion on the detected upstream optical signal, thereby obtaining the down-converted upstream signal. The receiving unit may detect the upstream optical signal by adopting the optical heterodyne detection method. Certainly, other existing detection methods may be used to perform the detection, for example, photodiode detection method could be used. The specific realization method for detecting the upstream optical signal by the receiving unit in OLT is not limited in the embodiment of the present disclosure.

In the process of detecting the upstream optical signal by the receiving unit by adopting the optical heterodyne detection method, the receiving unit may take the optical signal emitted by itself as a local oscillator optical signal, and also may take part of the downstream optical carrier provided by the transmitting unit as the local oscillator signal. In the case that the receiving unit takes the downstream optical carrier as the local oscillator signal, the carrier frequency of the downstream optical carrier f_a may meet the following condition:

f _c2 −f _c1 =f _{RF — u} ±f _IF, where

f_IF is an intermediate frequency, f_RF—u is the radio-frequency carrier frequency of the upstream radio frequency signal, and f_c1 is the carrier frequency of one upstream optical carrier of the two dedicated upstream optical carriers for ONU.

The passive optical network according to an embodiment of the present disclosure is described below with reference to FIGS. 1-6.

FIG. 1 is a schematic diagram illustrating the configuration of the passive optical network according to an embodiment of the present disclosure.

It is shown in the passive optical network of FIG. 1 that: OLT, a plurality of ONUs, and RN (remote node) in ODN. OLT is connected with RN via optical fiber, and RN is connected with each ONU via optical fiber. OLT includes a plurality of transmitting units, a plurality of receiving units and one multiplexing/demultiplexing unit (that is MUX and DEMUX in FIG. 1). One transmitting unit corresponds to one ONU and one receiving unit corresponds to one ONU.

The transmitting unit includes a laser group, a mixer, a Mach-Zehnder modulator (MZM) and a combiner, where the laser group is laser module, the mixer is an up conversion module, the MZM is an external modulation module and the combiner is a combining module.

The receiving unit includes a detecting module and a down conversion module. When performing optical heterodyne detection without using the downstream optical carrier as the local oscillator signal, the detecting module may further include: a local oscillator submodule that generates a local oscillator optical signal, and a detecting submodule that performs optical heterodyne detection by using the local oscillator optical signal generated by the local oscillator submodule.

An ONU includes a Photo Diode (PD) and an electro-absorption modulator (EAM), where PD is the receiving module and EAM is the modulation module.

The process of transmitting the downstream radio frequency signal shown in FIG. 1 is as follows.

The laser group in each transmitting unit transmits for its corresponding ONU one dedicated downstream optical carrier of the ONU and two dedicated upstream optical carriers. The carrier frequencies of the three optical carriers are set to be f_c1, f_c2 and f_c3, where the optical carrier with the carrier frequency being f_c2 is taken as the downstream optical carrier, configured to carry the downstream radio frequency signal; the optical carriers with carrier frequencies being f_c1 and f_c3 are taken as upstream optical carriers, configured to be down assigned to ONU so as to carry the upstream radio frequency signal. In the case that the receiving unit in OLT performs optical heterodyne detection by adopting the downstream optical carrier as the local oscillator signal, the frequency relationship among the three optical carriers is as shown in FIG. 2.

In FIG. 2, f_RF—u is the radio-frequency carrier frequency of the upstream radio frequency signal, for example, f_RF—u may be 60 GHz; f_RF—d is the radio-frequency carrier frequency of the downstream radio frequency signal, for example, f_RF—d may be 40 GHz; and f_IF is an intermediate frequency, for example, f_IF may be 5 GHz.

The condition that the carrier frequencies f_c1, f_c2 and f_c3 of the three optical carriers need to meet may be the following condition:

f _c3 −f _c1=2×f_RF—u

f _c2 −f _c1 =f _{RF — u} ±f _IF, where

f_RF—u is the radio-frequency carrier frequency of the upstream radio frequency signal, and f_IF is the intermediate frequency.

The equation f_c3−f_c1=2×f_RF—u ensures that after the upstream signal carried on f_RF—u is double-sideband modulated on the two upstream optical carriers f_c1 and f_c3 at an ONU, the right sideband signal spectrum of the carrier f_c1 and the left sideband signal spectrum of the carrier f_c3 are superposed at the middle point between the two upstream optical carriers, thereby enhancing the power spectrum of the modulated upstream optical signal; the equation f_c2−f_c1=f_RF—u±f_IF ensures that the spectrum of downstream optical carrier f_c2 is positioned at the left side/the right side of the modulated upstream radio frequency signal spectrum with the spacing being equal to the frequency of an intermediate frequency signal, for example, the spacing is 5 GHz so that when the upstream optical wave is transmitted to an OLT, the upstream optical wave may be coherently mixed with part of the downstream carrier f_c2 to perform optical heterodyne detection in order to obtain the upstream signal. Due to the reasons such as the modulation method adopted by an ONU, the signal detected by an OLT may be an intermediate frequency signal other than a radio frequency signal. Therefore, in an embodiment of the present disclosure, the signal detected by an OLT is general called an upstream signal.

The dedicated downstream optical carrier for an ONU transmitted by the laser is transmitted to the MZM module and an Rx module (Rx module is optical heterodyne detection in FIG. 1) each, where the Rx module is the detecting module. The two upstream optical carriers of an ONU transmitted by the laser are transmitted to the combiner.

The mixer mixes the downstream data for an ONU and the radio frequency carrier with the radio-frequency frequency being in waveband of millimeter wave (for example, the radio-frequency frequency may be 40 GHz) to obtain the downstream radio frequency signal of an ONU and transmit the downstream radio frequency signal to an MZM.

The MZM modulates the downstream radio frequency signal transmitted from the mixer on the downstream optical carrier with the carrier frequency being f_c2 which is transmitted from the laser, by using the Carrier Supressed Double Sideband Modulation method, and transmits the modulated downstream optical carrier to the combiner.

The modulated downstream optical carrier and the two upstream optical carriers with carrier frequencies being f_c1 and f_c3 are combined at the combiner to generate the downstream optical signal. The combiner transmits the downstream optical signal to the MUX. The signal spectrum of the downstream optical signal combined by the combiner is as shown in FIG. 3. In FIG. 3, the shaded area is the signal spectrum in the combined downstream optical signal.

An MUX multiplexes by wavelength division the combined downstream optical signal transmitted from each combiner, and then transmits the downstream optical wave multiplexed by wavelength division to an RN via optical fiber. Dedicated upstream/downstream optical carriers for different ONUs may adopt different optical wavelengths. The signal spectrum in the downstream optical waves multiplexed by wavelength division is as shown in FIG. 4.

An RN has the function of multiplexing/demultiplexing. In this embodiment, if the spacing between the two upstream optical carriers with carrier frequencies being f_c1 and f_c3 is 120 GHz, RN may select and use a wavelength division apparatus with 400 GHz channel spacing.

The RN receives the downstream optical wave transmitted from an OLT in optical fiber, and demultiplexes out the upstream optical carriers and modulated downstream optical carrier belonging to each ONU from the downstream optical wave. RN transmits the upstream optical carriers and the modulated downstream optical carrier belonging to each ONU to each ONU by the distributed optical fiber connected with each ONU. The upstream optical carriers and the modulated downstream optical carrier constitute downstream optical signal.

An ONU receives the upstream optical carriers and the modulated downstream optical carrier transmitted from an RN, and divides the received downstream optical signal into two parts and provides the two parts for a PD and an EAM separately. The PD may detect one part of the received downstream optical signal to obtain the downstream radio frequency signal carried on the downstream optical carrier. Then the PD outputs the detected downstream radio frequency signal, which may be transmitted directly via an antenna after processes such as filtering and amplification.

The process of transmitting the upstream radio frequency signal in FIG. 1 is as follows.

An EAM modulates the other part of the received downstream optical signal. Since an OLT modulates the downstream radio frequency signal by adopting the carrier suppressed double sideband modulation method, the downstream optical carrier for modulating the downstream radio frequency signal is suppressed. Therefore, an ONU may directly modulate the upstream radio frequency signal on the other part of the downstream optical signal, which is equivalent to the fact that the ONU modulates the upstream radio frequency signal on the combined two upstream optical carriers. The ONU modulates the upstream radio frequency signal on the downstream optical signal to generate the upstream optical signal and then output the upstream optical signal.

The signal spectrum in the upstream optical carriers modulated by EAM is as shown in FIG. 5. In FIG. 5, the spectrum of the white part is the signal spectrum in the modulated upstream optical carriers.

The upstream optical carrier modulated by EAM, which is the upstream optical signal, is transmitted to RN via optical fiber. RN wavelength division multiplexes the upstream optical signal of each ONU to obtain the upstream optical wave, and transmit it to the OLT via optical fiber.

The OLT receives the upstream optical wave wavelength division multiplexed and transmitted via optical fiber, and the DEMUX in OLT wavelength division demultiplexes the upstream optical wave to obtain the modulated upstream optical carrier of each ONU, that is the upstream optical signal. The DEMUX transmits the modulated upstream optical carrier of each ONU to the receiving unit corresponding to the ONU.

The detecting module in the receiving unit performs optical heterodyne detection to the modulated upstream optical carrier by using part of the downstream optical carrier transmitted by the corresponding transmitting module; that is, the detecting module takes the part of the downstream optical carrier with carrier frequency f_c2 transmitted by the transmitting module as the local oscillator optical signal, the local oscillator optical signal is coherently mixed with the modulated upstream optical carrier transmitted from DEMUX, and then the mixed signal is subject to optical heterodyne detection to obtain the upstream signal carried on the intermediate frequency band f_IF, and to output the upstream signal.

When the detecting module in the receiving unit includes a local oscillator submodule and a detecting submodule, the local oscillator optical signal provided for the detecting submodule may be the optical signal transmitted by the local oscillator submodule. The detecting submodule in the detecting module performs optical heterodyne detection to the upstream optical signal transmitted from DEMUX by using the local oscillator signal provided by the local oscillator submodule, to obtain the upstream signal and output it.

The down conversion module performs down conversion on the upstream signal transmitted by the detecting module to obtain an upstream baseband signal.

The passive optical network according to an embodiment of the present disclosure may be converted into the passive optical network as shown in FIG. 6 by slight change.

The passive optical network in FIG. 6 is same as that shown in FIG. 1 basically, with the difference that an ONU may include a PD, an EAM and a down conversion module at ONU. That is, the down conversion module may perform down conversion on the downstream radio frequency signal detected by the PD, and the downstream signal subjected to down conversion is transmitted to the user terminal in wired way such as a copper wire. In addition, the passive optical network may further include an ONU unit in a Wavelength Division Multiplex (WDN) PON, and the OLT shall include a transmitting unit and a receiving unit in WDM PON. A multi-wavelength optical signal in a WDM PON and the optical wave signal in the embodiment of the present disclosure are transmitted in a shared optical fiber via the multiplexing/demultiplexing module in an OLT and WDM device of the RN wavelength division node multiplexing. The units are existing units, so the procedure of processing the upstream signal and the downstream signal by them is not explained in detail here. The passive optical network in FIG. 6 may realize wireless business and wired business simultaneously.

It may be seen from the description on the above passive optical network that the passive optical network according to an embodiment of the present disclosure may be a hybrid passive optical network composed of a WDM PON and a Radio over Fiber (RoF) network. The transmitting unit in the OLT according to an embodiment of the present disclosure provides dedicated optical carrier for each ONU and combines the upstream and downstream optical carriers dedicated for an ONU. The multiplexing/demultiplexing unit in the OLT wavelength division multiplexes the combined downstream optical signal of each ONU so that the downstream optical wave wavelength division multiplexed may carry more signals, thereby making full use of the large-capacity bandwidth resources of the optical fiber network and enhancing the bandwidth of the wireless access network. Moreover, the modulation of the upstream radio frequency signal on the two optical carriers enhances the power spectrum of the modulation signal, and improves the detection sensitivity of the receiving unit of the OLT on the upstream signal. The receiving unit of the OLT further improves the detection sensitivity on the upstream signal by adopting the optical heterodyne technology. Therefore, there does not need to use an amplifying module at an ONU, thereby making the design of an ONU simple.

As such, the hybrid passive optical network according to an embodiment of the present disclosure not only makes full use of respective advantage of the two networks, but also ensures that the technical features of the two networks to support each other, and the technical effect that both the two networks cannot achieve is obtained. Therefore, the hybrid optical network according to an embodiment of the present disclosure is a passive optical network with wide access bandwidth and low construction cost.

The OLT provided according to an embodiment of the present disclosure is described below.

The OLT provided according to an embodiment of the present disclosure includes: a plurality of transmitting units, a plurality of receiving units and one multiplexing/demultiplexing unit. One transmitting unit corresponds to one ONU and one receiving unit corresponds to one ONU.

The transmitting unit includes a laser module, an up conversion module, an external modulation module and a combining module. The receiving unit includes a detecting module and a down conversion module. When performing optical heterodyne detection without using the downstream optical carrier as the local oscillator signal, the detecting module may further include: a local oscillator submodule that generates a local oscillator optical signal, and a detecting submodule that performs optical heterodyne detection by using the local oscillator optical signal generated by the local oscillator submodule.

The operation performed by each module refers to the description of the above passive optical module, and is not repeatedly described herein.

The radio frequency signal transmission method provided according to an embodiment of the present disclosure is described below.

The process of transmitting the downstream radio frequency signal is as follows.

An OLT provides one downstream optical carrier and two upstream optical carriers with respect to each ONU. The carrier frequencies of the three optical carriers are set to be f_c1, f_c2 and f_c3, where the optical carrier with the carrier frequency f_c2 is taken as the downstream optical carrier, configured to carry the downstream radio frequency signal; the optical carriers with carrier frequencies f_c1 and f_c3 are taken as upstream optical carriers, configured to be assigned to an ONU so as to carry the upstream radio frequency signal. The condition that the above f_c1 and f_c3 need to meet may be the condition as follows:

f _c3 −f _c1=2×f_RF—u, where

f_RF—u is the radio-frequency frequency of the upstream radio frequency signal.

In the case that the OLT performs optical heterodyne detection by adopting the downstream optical carrier as the local oscillator signal, the condition that f_c2 needs to meet may be the condition as follows:

f _c2 −f _c1 =f _{RF — u} ±f _IF, where

f_RF—u is the radio-frequency carrier frequency of the upstream radio frequency signal, and f_IF is an intermediate frequency.

The OLT mixes the downstream data for each ONU and the radio frequency carrier with the radio-frequency frequency being in waveband of millimeter wave (for example, the radio-frequency frequency may be 40 GHz) to obtain the downstream radio frequency signal for each ONU. The OLT modulates the downstream radio frequency signal for each ONU on the downstream optical carrier provided by the OLT for each ONU by using the carrier suppressed double sideband modulation method. For example, The OLT modulates the downstream radio frequency signal for each ONU on the downstream optical carrier with the carrier frequency of f_c2 for the ONU. Dedicated upstream/downstream optical carriers for different ONUs may adopt different wavelengths.

The OLT combines the modulated downstream optical carrier for each ONU and the corresponding upstream optical carriers to generate the downstream optical signal for each ONU. The OLT wavelength division multiplexes the downstream optical signal for each ONU to generate downstream optical wave. Sequentially, the OLT transmits the downstream optical wave wavelength division multiplexed to an RN via optical fiber.

An RN has the function of multiplexing/demultiplexing. In this embodiment, if the spacing between the two upstream optical carriers with carrier frequencies being f_c1 and f_c3 is 120 GHz, the RN may select and use a wavelength division apparatus with channel spacing being 400 GHz.

The RN receives the downstream optical wave transmitted from the OLT in optical fiber, and demultiplexes out the upstream optical carriers and modulated downstream optical carrier belonging to each ONU from the downstream optical wave. RN transmits the upstream optical carriers and the modulated downstream optical carrier belonging to each ONU to each ONU through the distributed optical fiber connected with each ONU. The upstream optical carriers and the modulated downstream optical carrier consists downstream optical signal.

An ONU receives the upstream optical carriers and the modulated downstream optical carrier transmitted from the RN, divides the received downstream optical signal into two parts, where one part of the downstream optical signal is used to detect the downstream radio frequency signal to obtain the downstream radio frequency signal carried on the downstream optical carrier, and the other part of the downstream optical signal is configured to modulate the upstream radio frequency signal. The ONU may detect the downstream radio frequency signal by adopting detection methods such as photodiode detection. After detecting the downstream radio frequency signal, the ONU may process the downstream radio frequency signal with various methods; for example, the downstream radio frequency signal may be transmitted directly via the antenna after being filtered and amplified; or the downstream radio frequency signal is subject to down conversion and the down converted signal is transmitted to the user terminal via a transmission medium such as a copper wire. The specific processing method for the downstream radio frequency signal after an ONU detects the downstream radio frequency signal is not limited in the embodiment of present disclosure.

The process of transmitting the upstream radio frequency signal is as follows.

An ONU performs modulation of the upstream radio frequency signal on the other part of the received downstream optical signal. In the even that the OLT modulates the downstream radio frequency signal by adopting the carrier suppressed double sideband modulation method, the downstream optical carrier is suppressed. At this time, the ONU may directly modulate the upstream radio frequency signal on the other part of the downstream optical signal; that is, the ONU modulates the upstream radio frequency signal on the combined two upstream optical carriers. The ONU modulates the upstream radio frequency signal on the downstream optical signal to generate the upstream optical signal and transmits the upstream optical signal to an RN via optical fiber.

An RN multiplexes the upstream optical signal of each ONU to obtain upstream optical wavelength division wave, the optical wave is transmitted to the OLT via optical fiber.

The OLT receives the upstream optical wave wavelength division multiplexed transmitted via optical fiber, and wavelength division demultiplexes the upstream optical wave, to obtain the upstream optical signal of each ONU. Subsequently, the OLT performs optical heterodyne detection on the upstream optical signal of each ONU by using the downstream optical carrier provided for each ONU; that is, the OLT uses part of the downstream optical carrier with carrier frequency being f_c2 for each ONU as a local oscillator optical signal, the local oscillator optical signal of each ONU is mixed with the upstream optical signal of each ONU coherently, and the upstream signal of each ONU carried on the intermediate frequency band f_IF is obtained through optical heterodyne detection. It is certain that the OLT may also use the optical signal emitted by itself as the local oscillator signal to perform optical heterodyne detection on the upstream optical signal.

The OLT may perform down conversion on the detected upstream signal to obtain the upstream baseband signal.

It may be seen from the above description on the radio frequency transmission that the OLT according to an embodiment of the present disclosure provides the dedicated optical carriers for each ONU, and combines the dedicated upstream and downstream optical carriers for an ONU, and wavelength division multiplexes the combined downstream optical signal for each ONU, so that the downstream optical wave wavelength division multiplexed can carry more signals, thereby making full use of the large-capacity bandwidth resources of the optical fiber network and enhancing the bandwidth of the wireless access network. In addition, the modulation of the upstream radio frequency signal on the two upstream optical carriers enhances the power spectrum of the modulation signal, and improves the detection sensitivity of the OLT on the upstream signal. The OLT further improves the detection sensitivity on the upstream signal by adopting the optical heterodyne technology. Therefore, an amplifying module at an ONU does not need to be used, thereby making the design of an ONU simple.

Although the present disclosure is described through embodiments, persons skilled in the art know that there are a lot of variations and changes without departing from the scope of the present disclosure. The claims of the application document of the present disclosure include such variations and changes.

Claims

1. An optical line terminal, comprising: at least one transmitting unit, configured to provide an optical network unit (ONU) with one downstream optical carrier and two upstream optical carriers dedicated for the ONU, to modulate a downstream radio frequency signal to the ONU on the downstream optical carrier dedicated for the ONU, to combine the modulated downstream optical carrier with the two upstream optical carriers dedicated for the ONU, and to output a downstream optical signal; wherein the two upstream optical carriers dedicated for the ONU are configured to carry upstream radio frequency signals of the ONU;a multiplexing/demultiplexing unit, configured to multiplex through wavelength division downstream optical signals outputted from each of the at least one transmitting unit and to transmit the multiplexed downstream optical signals to an ONU via an optical distribution network (ODN); and to demultiplex through wavelength division the multiplexed upstream optical wave of each ONU transmitted by an ODN, and output the demultiplexed upstream optical signals; andat least one receiving unit, configured to obtain an upstream signal from the demultiplexed upstream optical signals.

2. The optical line terminal according to claim 1, wherein the transmitting unit comprises: a laser module, configured to provide one downstream optical carrier and two upstream optical carriers dedicated for an ONU;an up conversion module, configured to mix the downstream data transmitted to an ONU and the radio frequency carrier whose the radio-frequency frequency is in waveband of millimeter wave, and obtain the downstream radio frequency signal for an ONU;an external modulation module, configured to modulate the downstream radio frequency signal for an ONU on the downstream optical carrier dedicated for the ONU through carrier suppressed double sideband modulation, and output the modulated downstream radio frequency signal; anda combining module, configured to combine the two upstream optical carriers for an ONU and the downstream optical carrier outputted from the external modulation module, and output the combined downstream optical signal.

3. The optical line terminal according to claim 1, wherein the receiving unit comprises: a detecting module, configured to perform optical heterodyne detection on the upstream optical signal of an ONU and output the detected upstream signal; anda down conversion module, configured to perform down conversion on the detected upstream signal and obtain an upstream baseband signal.

4. The optical line terminal according to claim 3, wherein the detecting module uses part of the downstream optical carrier provided by the transmitting unit as a local oscillator signal, and performs the optical heterodyne detection on the upstream optical signal of an ONU by using the local oscillator signal; the carrier frequency of the downstream optical carrier is fc2, which meets the condition: fc2−fc1=fRF—u±fIF; wherein fIF is an intermediate frequency, fRF—u is the radio frequency carrier frequency of the upstream radio frequency signal, and fc1 is the carrier frequency of one upstream optical carrier of the two upstream optical carriers dedicated for the ONU.

5. The optical line terminal according to claim 1, wherein the carrier frequencies of the two upstream optical carriers provided for the ONU by the transmitting unit are fc1 and fc3, which meet the condition fc3−fc1=2×fRF—u, wherein fRF—u is the radio-frequency frequency of the upstream radio frequency signal.

6. A passive optical network, comprising an optical line terminal (OLT), an optical distribution network (ODN) and, at least one optical network unit (ONU), configured to implement a method comprising: in the downstream direction:modulating a downstream radio frequency signal to be transmitted to each optical network unit (ONU) on a downstream optical carrier dedicated for the ONU, combining the modulated downstream optical carrier for the ONU and two upstream optical carriers dedicated for the ONU, multiplexing each combined downstream optical signal for each wavelength division ONU, and transmitting the multiplexed optical signal to the ONU via an optical distribution network (ODN), by an optical line terminal (OLT);wherein the two upstream optical carriers dedicated for the ONU carry upstream radio frequency signals of the ONU;in the upstream direction:receiving the wavelength division multiplexed upstream optical wave of each ONU which is transmitted from an ODN, and demultiplexing the multiplexed upstream optical wavelength division wave, and obtaining the upstream signal from each demultiplexed upstream optical signal, by an OLT.

7. (canceled)

8. (canceled)

9. A radio frequency signal transmission method, comprising: in the downstream direction:modulating a downstream radio frequency signal to be transmitted to each optical network unit (ONU) on a downstream optical carrier dedicated for the ONU, combining the modulated downstream optical carrier for the ONU and two upstream optical carriers dedicated for the ONU, multiplexing each combined downstream optical signal for each wavelength division ONU, and transmitting the multiplexed optical signal to the ONU via an optical distribution network (ODN), by an optical line terminal (OLT);wherein the two upstream optical carriers dedicated for the ONU carry upstream radio frequency signals of the ONU;in the upstream direction:receiving the wavelength division multiplexed upstream optical wave of each ONU which is transmitted from an ODN, and demultiplexing the multiplexed upstream optical wavelength division wave, and obtaining the upstream signal from each demultiplexed upstream optical signal, by an OLT.

10. The method according to claim 9, wherein the downstream radio frequency signal in the method comprises the downstream radio frequency signal for an ONU obtained by mixing the downstream data to be transmitted to an ONU and the radio frequency carrier whose the radio-frequency frequency is in waveband of millimeter wave.

11. The method according to claim 9, wherein modulating the downstream radio frequency signal for the ONU on the downstream optical carrier dedicated for the ONU comprises: modulating the downstream radio frequency signal for an ONU on the downstream optical carrier dedicated for the ONU by carrier suppressed double sideband modulation.

12. The method according to claim 9, wherein obtaining the upstream signal comprises: performing optical heterodyne detection on the upstream optical signal transmitted via an ODN by an ONU to obtain the upstream signal, and performing down conversion on the obtained upstream signal to obtain the upstream baseband signal, by the OLT.

13. The method according to claim 12, wherein performing optical heterodyne detection on the upstream optical signal transmitted via an ODN by an ONU, by the OLT comprises: using part of the downstream optical carrier dedicated for an ONU as the local oscillator optical signal, and performing optical heterodyne detection on the upstream optical signal of an ONU by using the local oscillator signal, by the OLT, whereinthe carrier frequency of the downstream optical carrier is fc2, and fc2 meets the condition that fc2—fc1=fRF—u±fIF, whereinfIF is an intermediate frequency, fRF—u is the radio frequency carrier frequency of the upstream radio frequency signal, and fc1 is the carrier frequency of one upstream optical carrier of the two upstream optical carriers dedicated for an ONU.

14. The method according to claim 9, wherein the carrier frequencies of the two upstream optical carriers dedicated for the ONU are fc1 and fc3, which meet the condition fc3−fc1=2×fRF—u, wherein fRF—u is the radio-frequency frequency of the upstream radio frequency signal.

15. The optical line terminal according to claim 3, wherein the detecting module comprises: a local oscillator submodule, configured to generate a local oscillator optical signal; anda detecting submodule, configured to perform optical heterodyne detection on the upstream optical signal of an ONU by using the local oscillator optical signal generated by the local oscillator submodule, and output the detected upstream signal.

16. The method according to claim 12, wherein performing optical heterodyne detection comprises: generating a local oscillator optical signal, and performing optical heterodyne detection on the upstream optical signal of an ONU by using the generated local oscillator signal, by the OLT.