The present invention is enclosed in the area of gigabit passive optical network line terminals (GPON-OLT), particularly in the field of small form-factor pluggable (SFP) modules.
Gigabit-capable Passive Optical Network (GPON) have been widely spread among operators allowing the distribution of high bandwidth, large coverage and providing high efficiency to deliver broadband. Based on International Telecommunication Union - Telecommunication Standardization Sector (ITU-T) G.984.x - GPON-OLTs commonly use SFP transceiver hosts equipped with SFPs in a single fiber bidirectional SC connector configuration for carrying out the transmission and reception of the passive optical network (PON) data.
Current GPON SFP optical transceiver modules employ a single fiber bidirectional SC connector, limiting the port density on the GPON-OLT, where a single SFP transceiver host equipped with a SFP is adapted to feed a GPON, limiting the number of users connected to said host and thereby limiting also its density.
The present invention addresses the above problem.
The present invention relates to a dual GPON Small Form-Factor Pluggable (DGPONSFP) optical module, projected to provide connection to two SC optical fiber connectors, and to be incorporated in any state of the art GPON-OLT.
Due to the set of particular technical features that characterizes the DGPONSFP optical module developed, it is not only possible to duplicate the number of users connected to the same SFP transceiver host’s cage - that is, for the same cage space it allows to double the density of transceiver - but also allows transmitting and receiving two GPON channels in a single SFP optical transceiver.
Erro! A origem da referência não foi encontrada. is a schematic diagram of the DGPONSFP optical module developed, according to certain aspects of the invention. The numerical references represent:
Erro! A origem da referência não foi encontrada. is a schematic diagram of the DGPONSFP module’s control unit, according to certain aspects of the invention. The numerical references represent:
Erro! A origem da referência não foi encontrada. is a diagram of the DGPONSFP’s module contact assignment of the high-speed electrical interface to the SFP transceiver host in order to support the dual GPON, according to certain aspects of the invention.
The module contact assignment is defined as:
Erro! A origem da referência não foi encontrada. is a view of the case of the DGPONSFP’s optical module developed with a dual SC connector for integrating two GPON-OLT channels, according to certain aspects of the invention. The numerical references represent:
Erro! A origem da referência não foi encontrada. is an exploded view of the case and internal components of the DGPONSFP optical module developed with a dual SC connector, according to certain aspects of the invention. The numerical references represent:
The following detailed description has references to the figures. Parts which are common in different figures have been referred to using the same numbers. Also, the following detailed description does not limit the scope of the disclosure.
The present invention relates to a DGPONSFP optical module comprising a dual SC connector, projected to be connected in a SFP transceiver host, allowing it to operate as a dual GPON transmitter and receiver.
According to the main embodiment of the invention, the DGPONSFP optical module (10) is comprised by at least two bidirectional optical subassemblies - BOSAs - (110), a control unit (111) comprising connection and processing means adapted to drive and control said BOSAs (110) and a high-speed electrical interface - HSEI - (112) adapted to provide connection to the SFP transceiver host, in order to feed several Optical Network Units. These elements comprising the DGPONSFP optical module (10) are housed in a case (113) which is to be installed inside the SFP transceiver host cage of an GPON-OLT.
Erro! A origem da referência não foi encontrada. illustrated the block diagram of an exemplary embodiment of the DGPONSFP optical module (10) of the invention. It is comprised by the case (113) housing two BOSAs (110) for GPON-OLT connection, the control unit (111) and the high-speed electrical interface (112).
Each BOSA (110) is composed by a laser working on GPON downstream wavelength at 2.5 Gbit/s and a burst mode receiver working on GPON upstream wavelength at 1.25 Gbit/s. The BOSA (110) further includes an SC ferrule to allow the connection to an SC optical fiber connector. In the particular embodiment of the DGPONSFP module (10) developed as illustrated in
The control unit (111) is shown in Erro! A origem da referência não foi encontrada., and is adapted to control the two BOSAs (110). For that purpose, the control unit (111) comprises a modulation sub-unit (210) and a microcontroller (220), besides the required circuit electronics that comprises resistors, capacitors, power supply (230) and ferrite bead. The modulation sub-unit (210) comprises laser drivers and limiting amplifiers adapted to drive and modulate the lasers and to amplify the electrical signals from the burst mode receiver of each BOSA (110). The microcontroller (220) is configured to control the modulation sub-units (210) and to communicate with the SFP transceiver host through the HSEI (112). The microcontroller (210) is also configured to control the BOSAs power supplies (230). In one embodiment, the two BOSAs (110) are connected to the control unit (111) through a flex printed circuit board (114). More particularly, each BOSA (110) is connected to the modulation sub-unit (210) of the control unit (111), and in particular to the respective laser driver and limiting amplifier, by means of the flexible printed circuit board (114), in order to guarantee the electronic performance. In another embodiment, the control unit (111) is mounted in a printed circuit board (115) containing all the necessary electrical connections between the different elements in order to control and drive the BOSAs (110).
The HSEI (112) is configured to provide a high-speed interconnection to the SFP transceiver host, in order to transmit electrical signals that were transformed by the DGPONSFP optical module (10) from the PON data received. Similarly, the DGPONSFP optical module (10) may receive electrical signals from SFP transceiver host via said port connector, in order to be transformed to optical signals and sent to a fiber network via optical connection.
For the purpose of that connection with the SFP transceiver host, the HSEI (112) comprises a port connector including a plurality of connection pins. In a particular embodiment, the port connector of the HSEI (112) is provided with a specific contact assignment, in order to ensure adaptability and compatibility with the state of the art SFP transceiver hosts. In accordance with a particular embodiment of the HSEI (112),
Erro! A origem da referência não foi encontrada. illustrates the mechanical case (113) design of the DGPONSFP optical module (10) developed. It assumes a standard size inside a cage assembly: height rear (410), width rear (420) and length of transceiver outside of cage to rear (430), following the Transceiver Multisource Agreement - MSA - in order to fit on a standard SFP Cage Assembly of the SFP transceiver host. The DGPONSFP optical module (10) dimensions outside of the cage MSA, in order to fit two SC connectors, assume a specific front length (440) of 31.8 mm, front width (450) of 16.8 mm, front height (460) of 13.5 mm and a BOSA ferrule distance (470) of 7.35 mm.
The DGPONSFP optical module comprises a case (113) which includes two SC BOSA supports (550) and a case spacer (560) adapted to accommodate the installation of the two BOSAs (110). Additionally, and as shown in
The DGPONSFP optical module mechanical parts, (510), (520), (530), (540), (560) are made from several types of metallic materials as zinc alloys, zamak 2, zamak 3 or aluminium. The SC BOSA supports (550) are manufactured in plastic or metal.
The physical geometry of the DGPONSFP optical module (10) developed is to be such that it may fit within the receptacle case of a conventional GPON-OLT transceiver.
The DGPONSFP optical module (10) developed may be one of multiple DGPONSFP optical modules (10) incorporated into SFP transceiver hosts of a GPON-OLT. In certain embodiments, inserting a DGPONSFP optical module (10) into a SFP transceiver host configured to operate with conventional GPON SFP optical modules, may result in the DGPONSFP optical module (10) be only able to establish a single optical connection. Similarly, adding a conventional GPON SFP optical modules to a SFP transceiver host configured to operate with a DGPONSFP optical module may limit the transceiver to only a single optical GPON connection.
As will be clear to one skilled in the art, the present invention should not be limited to the embodiments described herein, and a number of changes are possible which remain within the scope of the present invention.
Of course, the preferred embodiments shown above are combinable, in the different possible forms, being herein avoided the repetition all such combinations.
Number | Date | Country | Kind |
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116279 | Apr 2020 | PT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2021/052998 | 4/12/2021 | WO |