The present invention relates to a radio equipment automatic redundant architecture.
In the field of telecommunications it is known the use of Distributed antenna systems (DAS) for providing wireless service within a geographic area or structure.
DAS is a network of spatially separated Remote antenna Heads (RH), connected to a series of Base Stations (BS) through a series of Points Of Interface (POI) and a Combining-Splitting (CS) section.
It is also known the need to use a Point of Interface network which is redundant in order to recover the service as soon as a failure occurs.
The main aim of the present invention is to provide a radio equipment automatic redundant architecture with an inner dynamic redundant network that activates in case of failure.
Another object of the present invention is to provide a radio equipment automatic redundant architecture, which allows to minimize the number of hop to link all the Point of Interface units.
The above-mentioned objects are achieved by the present radio equipment automatic redundant architecture according to the features of claim 1.
Other characteristics and advantages of the present invention will become better evident from the description of a preferred, but not exclusive embodiments of a radio equipment automatic redundant architecture, illustrated by way of an indicative but non-limitating example in the accompanying Figures, in which:
With particular reference to such illustrations, globally indicated with reference RE is a radio equipment automatic redundant architecture.
Particularly, with reference to the specific embodiment of the invention disclosed and showed in the figures, the radio equipment RE is constituted by a Point of Interface (POI) network feeding a Distributed Antenna System (DAS).
With reference to the specific embodiment showed in
Specifically, the embodiment showed in the Figures and disclosed below relates to a Radio Equipment RE defined according to the Common Public Radio Interface (CPRI) standard.
However, the invention can be applied to different type of radio equipment.
Particularly, it is not excluded the use of the Radio Equipment RE according to the invention in different types of interfaces implementing a Master/Slave architecture.
For example, the radio equipment RE can be of the type of a Remote Radio Head (RRH).
The radio equipment RE automatic redundant architecture according to the invention comprises a plurality of Point of Interface units each provided with:
Usefully, each Point of Interface unit may comprise a plurality of Master ports M able to forward the link incoming in said Slave port S.
Furthermore, each Point of Interface unit may comprise a plurality of Redundant ports R with same Slave port S capabilities.
With reference to the example showed in
Each Point of Interface unit POI1, POI2 and POI3 has two Master ports M for forwarding the link incoming in the Slave port S and a single Redundant port R.
However, the use of different configurations with a different number of Master ports M or Redundant ports R is not excluded.
The radio equipment RE comprises a first Point of Interface unit POI1 provided with a Slave port S connected to a corresponding first Master port of a radio base station BTS (or a similar device).
Particularly, according to the possible embodiment of the invention illustrated in
However, it is not excluded the connection to different Master ports of different devices. For example, the Slave port S is also connectable to a server port or to other radio equipment Master port.
Furthermore, with reference to the example showed in
The second Point of Interface unit POI2 has the Redundant port R connected to a corresponding second Master port CPRI3 of said radio base station BTS.
The two Master ports M of the second Point of Interface unit POI2 are connected respectively to the Redundant port R of the first Point of Interface unit POI1 and to the Redundant port R of the third Point of Interface unit POI3. The method (automatic rules) for the management of the radio equipment RE according to the invention is disclosed below and an example of dynamic recovery in case of Main link failure is illustrated in
The method comprises, for each of said Point of Interface units POI1, POI2, POI3, at least a step of detecting the presence/absence of an input link on the slave port S.
In case of detection of the presence of an input link on the slave port S, the method comprises a step of forwarding the link incoming in the Slave port S on the Master ports M. In this condition the Redundant port R is switched off.
In case of detection of the absence of an input link on the slave port S, after a proper timeout, the method comprises the following steps:
If a redundant CPRI link isn't available on the redundant port R, the method comprises a step of activating, after a proper timeout, the Slave port S, in order to check if a CPRI link is available.
In such a configuration the Slave ports S and the Master ports M are active and the Redundant ports R are inactive.
In this case, the Slave port S of the first Point of Interface POI1 does not detect a CPRI link then (after a proper timeout) the Master ports M of the first Point of Interface POI1 are switched off to propagate the unavailability of the CPRI link to the next Points of Interface POI2 and POI3.
The Redundant port R of the second Point of Interface POI2 is activated to check if a redundant CPRI link is available. When the Redundant port R detects a redundant CPRI link on the Master port CPRI3, then the CPRI link is relaunched on Master ports M of the second Point of Interface POI2. The CPRI link is then propagated to the third Point of Interface POI3.
As a further example,
In practice it has been observed that the described invention achieves the intended purposes.
Thanks to the described radio equipment port assignment and radio equipment automatic rule it is always possible to create a fully-interconnected POI network that:
Particularly, in case of single point of failure at any point of the system then the system will automatically reconfigure.
In case of multiple point of failure, the impact on the system availability is minimized thanks to the fully-interconnected network and the part of the network that is “out of service”, thanks to proper timeout, is able to switch between two status of stability and recover the service as soon as the first failure recovers.
Number | Date | Country | Kind |
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102017000006409 | Jan 2017 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2018/050340 | 1/19/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/134777 | 7/26/2018 | WO | A |
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20210152207 A1 | May 2021 | US |