The present disclosure refers to an underwater docking station for cooperating with underwater devices, such as ROVs and AUVs. The underwater docking station is configured to lie on the seabed, optionally in communication with a surface vehicle, such as a boat or a ship, either wired (via a cable connection) or wirelessly.
Underwater vehicles are used for a wide variety of operations that include—but are not limited to inspection/identification, oceanography, survey missions or samples picking. Underwater vehicles may be manned or unmanned. Among the unmanned vehicles, there are ROVs and AUVs. An Autonomous Underwater Vehicle (AUV) is a robot that travels underwater without requiring input from an operator. AUVs constitute part of a larger group of undersea systems known as unmanned underwater vehicles, a classification that includes the mentioned non-autonomous Remotely Operated underwater Vehicles (ROVs)—controlled and powered from the surface by an operator/pilot via an umbilical or using remote control. ROVs are unmanned underwater vehicles connected to a base station, which may be a ship. As mentioned ROVs are connected to the ship by means of cables; this implies that the maximum achievable distance between the ROV and the base station is limited by the length of the cable. AUVs are unmanned underwater vehicles, which are connected to a docking station by means of a wireless communication. Typically, AUVs are propelled through the energy stored in batteries housed in their body. This means that the operative range of an AUV is limited by the capacity of the battery.
This type of underwater vehicles has recently become an attractive alternative for underwater search and exploration since they are cheaper than manned vehicles. Over the past years, there have been abundant attempts to develop underwater vehicles to meet the challenge of exploration and extraction programs in the oceans. Recently, researchers have focused on the development of AUVs for long-term data collection in oceanography and coastal management. The oil and gas industry uses AUVs to make detailed maps of the seafloor before they start building subsea infrastructure; pipelines and sub-sea completions can be installed in the most cost effective manner with minimum disruption to the environment. The AUV allows survey companies to conduct precise surveys of areas where traditional bathymetric surveys would be less effective or too costly. In addition, post-lay pipe surveys are now possible, which includes pipeline inspection. The use of AUVs for pipeline inspection and inspection of underwater man-made structures is becoming more common.
With the adoption of AUV technology becoming more widespread, the limitations of the technology are being explored and addressed. The average AUV charge lasts about 24-hours on an underwater AUV, but sometimes it is necessary to deploy them for the kinds of several day missions that some unmanned systems are equipped to undertake. Like most robots, the unmanned mechanisms contain batteries that require regular recharging. Docking stations that communicate directly with underwater vehicles, guiding them to where they can recharge and transfer data have been developed. Any data the AUV has gathered, such as images of the seabed, could be uploaded to the docking station and transmitted to home base, which could direct new instructions to the robot.
It is known from WO2018109451 a subsea basket or garage for unmanned underwater vehicles or UUVs, especially autonomous underwater vehicles or AUVs. A basket for hosting an AUV on the seabed comprises a hollow open-topped body. The body surrounds a receptacle into which an AUV that enters the body through the open top can dock for protection, recharging, data download and/or data upload for reprogramming. The open top of the body is closed by a lid movable between a closed and an open position. When the lid is open, an AUV can access the receptacle by moving generally horizontally to under the lid before lowering through the open top of the body and into the receptacle for docking. The lid is then closed onto the body over the docked AUV. The lid is supported and moved by telescopic guideposts driven by actuators that extend vertically from the body to lift the lid into the open position and retract vertically to lower the lid into the closed position. In another embodiment, paired posts may be stowed against opposed sloping sides of the body lying compactly against those sides. When deployed, the posts swing into deployed positions in opposite angular directions about respective pivot axes that are parallel to the respective sides of the body; the posts are part of a lifting frame that further comprises a crossbar in two sections. A respective section of the crossbar is attached to each post such that, when deployed, the sections of the crossbar extend oppositely and orthogonally with respect to the associated posts. Pivots between each post and the attached section of the crossbar allow the sections of the crossbar to collapse compactly against the sloping sides of the body when the posts are stowed away. This prior art does not focus on data exchange between the station and the AUV, but rather defines a complex structure to house and protect the AUV during data exchange and power recharging. However, the proposed structure with several moving parts is complex and may not be really effective. Further, the docking station is designed for very specific and dedicated AUVs.
In addition to the above, any underwater vehicle requiring the need of a wireless communication with the docking station faces at least the problem of the limitations for wireless communications in water. Radio frequencies are significantly attenuated in water. Above some hundreds of KHz, in particular, above 1 MHz, attenuation in water raises significantly and any communication is affected by a link budget loss that limits the communication to some meters or less even with relevant transmission power and antenna gains. In particular, above 1 MHz attenuation in seawater raises with a more than linear law from 30 dB/m to reach about 60 dB/m at frequencies of about 10 MHz. Lower frequencies, that lay between the ELF (3-30 Hz) up to the LF (30KHz-300KHz) band, and that include acoustic and/or ultrasonic frequencies, are significantly less attenuated in water.
Exploiting low frequencies for signal transmission implies significant limitations in bandwidth, which may be so reduced that even the voice may have some problem to be transmitted. In practice, with LF frequencies transmissions can take place at some hundreds of meters, while ELF transmissions can be effectively performed at longer distances.
Underwater wireless communication may be performed by means of an optical communication system. Optical communication is affected by water turbidity, and the performance of an effective communication is affected by the type of modulation used for the optical radiation. In any case, it is known that through the optical communications some tens of meters at most can be reached in seawater. Optical communication, due to the high frequency of the carrier(s), provides high bandwidth that allows providing video streaming and/or high-definition images transmission with low latencies.
The Applicant further notices that an effective control of complex underwater vehicles necessitates a predetermined communication structure. An improved docking station appears necessary to allow AUV data collection efficiently, to permit reliable commands exchange, AUVs recharging and control. Further, an easily configurable docking station is desirable for coupling and interaction with different type of underwater devices.
The purpose of the present disclosure is to provide an underwater docking station for communication with one or more underwater devices configured to overcome the aforementioned drawbacks.
One aim of the disclosure is to allow flexibility in submarine communication with a variety of different submarine devices that can be configured and housed in or at the docking station.
A further purpose of the invention is to allow rapid configuration between different operating positions of the docking station to not only accommodate and hold an AUV in place, but also to be able to receive, and (e.g., mechanically) couple and communicate with a ROV, and possibly interact with both devices simultaneously.
A further aim is to allow communication with the underwater device(s) over long distances and/or with sufficient bandwidth and to allow data transfer at high speed (e.g., video data transfer), too.
An auxiliary aim is to provide a docking station that may be easily reconfigured for mechanically and/or communicatively coupling with different AUVs and/or ROVs.
These and further purposes of the present disclosure are obtained by means of an underwater docking station for communication with one or more underwater devices as here disclosed. Several principal aspects of the present disclosure will be hereinafter described. The following aspects can be combined together or with any part of the detailed description, in any suitable form.
In accordance with an independent aspect, an underwater docking station for communication with one or more underwater devices is described comprising:
In accordance with a further independent aspect, an underwater docking station for communication with one or more underwater devices is described comprising:
In a 2nd aspect according to the previous aspects, the actuator (7) is active to move the optical communication module (3) or a portion of the optical communication module (3) to move the optical communication axis (5) between the first and the second operative position.
In a 3rd aspect according to any one of the previous aspects, the coupling arrangement (6) movably mounts the optical communication module (3) to the support structure (2), in particular the actuator (7) being active to the coupling arrangement (6) to move the optical communication axis (5) between the first operative position and the second operative position, in particular the optical communication module (3) being associated to a top portion (2a) of the support structure (2).
In a 4th aspect according to any one of the previous aspects, the optical communication module (3) is configured to communicate on a line of sight along the communication axis (5) with another optical communication module (13) of one of the one or more underwater devices (4) with respective communication axis aligned on the line of sight.
In a 5th aspect according to any one of the previous aspects, the optical communication module (3) is configured to at least rotate along a rotation axis (11) that is transversal, in particular orthogonal, to the communication axis (5).
In a 6th aspect according to previous aspect 5, the rotation axis (11) is substantially horizontal in use conditions of the underwater docking station (1).
In a 7th aspect according to any one of the previous aspects, the actuator (7) is configured to rotate the optical communication module (3) to move the optical communication axis (5) between the first operative position and the second operative position.
In a 8th aspect according to any one of the previous aspects, the optical communication axis (5) is movable in a plurality of additional positions in addition to the first operative position and the second operative position, the optical communication module (3) is configured to communicate along additional communication direction in one or more of said additional positions.
In a 9th aspect according to previous aspect 8, the additional communication direction lies in a vertical plane in use condition of the underwater docking station (1).
In a 10th aspect according to any one of the previous aspects, the first communication direction (8) is directed substantially vertically in use condition of the underwater docking station (1), optionally the second communication direction (9) is directed substantially vertically in use condition of the underwater docking station (1), for example the first communication direction (8) is directed upwards and the second communication direction (9) is directed downwards.
In an 11th aspect according to any one of the previous aspects, the control unit (10) is configured to command the actuator (7) exclusively to rotate the optical communication module (3) and move the optical communication axis (5) along a vertical plane in use condition of the underwater docking station (1), in particular, the control unit (10) is configured to rotate over a rotation angle range of at least 90° and in particular of at least 180°.
In a 12th aspect according to any one of the previous aspects, the optical communication module (3) comprises a wireless optical modem.
In a 13th aspect according to any one of the previous aspects, the optical communication module (3) has a maximum communication range of about 60 m.
In a 14th aspect according to any one of the previous aspects, the optical communication module (3) has a data rate of at least 5 Mbit/sec, in particular of at least 9/10 Mbit/sec.
In a 15th aspect according to any one of the previous aspects, the optical communication module (3) is configured for working at least up to a depth of 6000 m.
In a 16th aspect according to any one of the previous aspects, the optical communication module (3) is a bi-directional transceiver.
In a 17th aspect according to any one of the previous aspects, the optical communication module (3) is configured for achieving video data transfer, for example for 4K video data transfer.
In an 18th aspect according to any one of the previous aspects, the support structure (2) comprises a base portion (2a) and a top portion (2b).
In a 19th aspect according to any one of the previous aspects, the support structure (2) is configured for supporting the underwater docking station on the seabed, the underwater docking station being a seabed underwater docking station.
In a 20th aspect according to any one of the previous aspects, the support structure (2) comprises a base portion (2a) including a support plate (12) for resting on the seabed.
In a 21st aspect according to the previous aspect, the support plate (12) has:
In a 22nd aspect according to any one of the previous aspects, the support structure (2), and in particular a base portion (2a) of the support structure, comprises:
In a 23rd aspect according to any one of the previous aspects, the support structure (2) comprises a base portion (2a) and a top portion (2b) and a mechanism (15) interposed between the base portion (2a) and the top portion (2b) to allow moving the base portion (2a) away from the top portion (2b) defining an housing space (16) for receiving the underwater device (4) between the base portion (2a) and the top portion (2b) and to allow reducing or removing the housing space (16) defining a compact configuration of the underwater docking station, in particular the underwater docking station further comprising a reversible actuator active on the mechanism (15) to increase or reduce the housing space (16) by approaching or distancing the base portion (2a) and the top portion (2b).
In a 24th aspect according to the previous aspect, the mechanism (15) comprises at least one scissor mechanism including a first bar and a second bar hinged to each other at a respective intermediate point, in particular the first bar has a fixed portion hinged to the base portion (2a) and a movable portion slidable along the top portion (2b) and the second bar has a fixed hinged to the top portion (2b) and a movable portion slidable along the base portion (2a).
In a 25th aspect according to the previous aspect 23, the mechanism (15) comprises at least two scissor mechanisms, each respectively including a first bar and a second bar hinged to each other at a respective intermediate point, in particular the first bar has a fixed portion hinged to the base portion (2a) and a movable portion slidable along the top portion (2b) and the second bar has a fixed portion hinged to the top portion (2b) and a movable portion slidable along the base portion (2a), for example one first scissor mechanism being on one lateral side of the underwater docking station, and one second scissor mechanism being on an opposite lateral side of the underwater docking station.
In a 26th aspect according to the previous two aspects, the support structure (2), and in particular the base portion (2a), includes a sliding seat (17), the movable portion of one between the first bar and the second bar sliding within the sliding seat (17).
In a 27th aspect according to the previous three aspects, the support structure (2), and in particular the top portion (2b), includes a guide (18), the movable portion of one between the first bar and the second bar sliding over the guide (18).
In a 28th aspect according to the previous five aspects, the reversible actuator comprises a motor and a guide (18) in the form of an endless screw, the motor rotating the endless screw in one or the opposite direction to achieve increasing or reducing the housing space (16).
In a 29th aspect according to the previous aspect, the endless screw is rotatably coupled to the top portion (2a), a threaded head (19) being fixed to a movable portion of a first bar of the mechanism (15), being coupled to and moving over the endless screw.
In a 30th aspect according to any one of the previous aspects, the docking station further comprises a camera (20) associated to the support structure (2) to allow viewing and/or filming of images surrounding the underwater docking station in a field of view.
In a 31st aspect according to the previous aspect, the docking station further comprises a camera actuator (21) active on the camera (20) to move an axis of the field of view between different operative positions having the axis of the field of view of the camera (20) directed along different directions, the control unit (10) being connected to:
In a 32nd aspect according to the previous aspect, the camera (20) is configured to at least rotate along a rotation axis (11) that is transversal, in particular orthogonal, to the axis of the field of view of the camera (20).
In a 33rd aspect according to the previous aspect, the rotation axis (11) is substantially horizontal in use conditions of the underwater docking station (1).
In a 34th aspect according to the previous three aspects, the control unit (10) is configured to command the camera actuator (21) exclusively to rotate the camera (20) and move the axis of the field of view of the camera (20) along a vertical plane in use condition of the underwater docking station (1), in particular, the control unit (10) is configured to rotate over a rotation angle range of at least 90° and in particular of at least 180°.
In a 35th aspect according to any one of the previous aspects, the docking station further comprises one or more LEDs (22) associated to the support structure (2) to allow illuminating the surroundings of the underwater docking station (1), in particular the LEDs being associated to a top portion (2a) of the support structure (2).
In a 36th aspect according to any one of the previous aspects, the docking station further comprises a hydrophone (23) configured to allow a transmission and reception of ultrasonic and/or acoustic signals, the control unit (10) being connected to said hydrophone (23) to manage communication with ultrasonic and/or acoustic signals, in particular the hydrophone (23) being associated to a top portion (2a) of the support structure (2).
In a 37th aspect according to the previous aspect, the transmission of the ultrasonic and/or acoustic signals is a substantially non-directive transmission, the control unit (10) being configured to transmit with the hydrophone (23) when the underwater docking station (1) and the underwater vehicle (4) are at a first distance (D1), and wherein a transmission of optical signals through the optical communication module (3) is a substantially directive transmission, the control unit (10) being configured to transmit with the optical communication module (3) when the underwater docking station (1) and the underwater vehicle (2) are at a second distance (D2), the first distance (D1) being greater than the second distance (D2).
In a 38th aspect according to the previous aspect, the second distance (D2) is lower than 100 m, preferably lower than 80 m, preferably lower than 60 m, optionally the first distance (D1) being lower than 500 m, preferably lower than 300 m, preferably lower than 200 m.
In a 39th aspect according to any one of the previous two aspects, the control unit (10) is configured to:
In a 40th aspect according to any one of the previous four aspects, the communication with ultrasonic and/or acoustic signals has low data transfer rate and the communication with optical signals through the optical communication module (3) has high data transfer rate, the low data transfer rate being lower than the high data transfer rate.
According to a further non-limiting aspect in combination with any of the previous aspects, an activation of the hydrophone (23) and/or an activation of the optical communication module (3) comprises the control unit (10) configured for measuring and/or electronically calculating a distance between the underwater docking station (1) and the underwater device (4) and the activation of the hydrophone (23), or the transmission of the ultrasonic and/or acoustic signal by means of the hydrophone (23) takes place when the underwater docking station (1) and the underwater device (4) are at a first distance (D1), and the activation of the optical communication module (3) and/or the step of transmission of the optical signal by the optical communication module (3) takes place when the underwater docking station (1) and the underwater device (4) are at a second distance (D2).
According to a further non-limiting aspect in combination with any of the previous aspects, the control unit (10) is configure for adapting and/or configuring the hydrophone (23) in order to allow a transmission and reception of ultrasonic and/or acoustic signals; the hydrophone (23) comprises at least one between a vibrator and/or an amplifier, the vibrator and/or the amplifier being specifically configured to allow the transmission of an ultrasonic and/or acoustic signal, in particular an high power transmission of the ultrasonic and/or acoustic signal.
According to a further non-limiting aspect in combination with any of the previous aspects, the control unit (10) is configured to transmit the ultrasonic and/or acoustic signal by means of the hydrophone (23) and to provide a signal to said vibrator and/or to said amplifier and/or to a piezoelectric transducer of the hydrophone (23).
According to a further non-limiting aspect in combination with any of the previous aspects, the control unit (10) is configured to define a plurality of frequency-spaced transmission channels (Ch1, Ch2, Ch3) of ultrasonic and/or acoustic signal transmission and to transmit the ultrasonic and/or acoustic signal on said plurality of frequency-spaced transmission channels (Ch1, Ch2, Ch3), in particular to transmit simultaneously on said plurality of frequency-spaced transmission channels (Ch1, Ch2, Ch3) optionally to transmit the ultrasonic and/or acoustic signal takes place according to a FSK modulation, or an ASK modulation, or a PSK modulation.
According to a further non-limiting aspect in combination with any of the previous aspects, the ultrasonic and/or acoustic signal comprises a plurality of 0s and 1s and the transmission of the ultrasonic and/or acoustic signal according to the FSK modulation comprises modulating the 0s and the 1s respectively on a first and a second carrier frequency spaced one with respect to the other, said first and second carrier frequencies being spaced of a predefined guard interval.
According to a further non-limiting aspect in combination with any of the previous aspects, the control unit (10) is configured to adapt the predefined guard interval and/or adapt said first and/or second carrier frequency.
According to a further non-limiting aspect in combination with any of the previous aspects, the guard interval is at least 5 kHz or at least 10 kHz.
According to a further non-limiting aspect in combination with any of the previous aspects, the control unit (10) is configured to perform a synchronization of the control and/or of the motion of the underwater device (4) with respect to the underwater docking station (1),
According to a further non-limiting aspect in combination with any of the previous aspects, the control unit (10) is configured to provide the ultrasonic and/or acoustic signal with a noise portion and a payload portion, the control unit (10) is configured to provide underwater noise mitigation, for reducing the noise portion and/or increasing a signal-to-noise ratio of the ultrasonic and/or acoustic signal.
According to a further non-limiting aspect in combination with any of the previous aspects, the underwater noise mitigation (control unit configuration) comprises at least one among:
According to a further non-limiting aspect in combination with any of the previous aspects, the control unit (10) is configured to transmit at least one between said ultrasonic and/or acoustic signal and said optical signal by transmission of a numeric signal, optionally a binary and/or a packet-type numeric signal, comprising a message having a structure including at least one of the fields of the following list: a command type field, containing data relating to the type of command provided to, or received by, the underwater device (4); a payload field, containing data associated to said type of command provided to, or received by, the underwater device (4); a message number identification field; a checksum field.
According to a further non-limiting aspect in combination with any of the previous aspects, the underwater docking station (1) and/or the underwater device (4) comprises at least one position and/or direction sensing element configured to provide indication of a position and/or orientation respectively of the underwater docking station (1) and/or of the underwater device (2).
In a 41st aspect according to any one of the previous aspects, a top portion (2a) of the support structure is substantially flat and configured to receive in support an underwater device (4).
In a 42nd aspect according to any one of the previous aspects, the docking station further comprises a wireless recharge module configured to couple to a corresponding wireless recharge module of the underwater device (4) to charge a battery of the underwater device (4).
In a 43rd aspect according to the previous aspect, the wireless recharge module is configured to recharge the battery of the underwater device (4) if the corresponding wireless recharge module of the underwater device is at a distance from the wireless recharge module of less than 0.5 m, in particular when the underwater device (4) is in a housing space (16) of the support structure (2).
In a 44th aspect according to any one of the previous aspects, the docking station further comprises a battery associated to the support structure (2) to provide electric power to the control unit (10), to the optical communication module (3) and to the actuator (7).
In a 45th aspect according to the previous aspect, the battery of the underwater docking station is rechargeable, e.g., wirelessly, through the one or more underwater devices (4) that provides electric power.
In the subsequent detailed description, a preferred embodiment of the underwater docking station according to the present disclosure will be presented. The detailed description refers to the annexed figures; a brief description thereof is here presented.
The underwater docking station 1 comprises a support structure 2 that defines the frame containing the ‘operative’ elements of the docking station 1 further allowing the station 1 itself to rest on the seabed. The support structure 2 includes a base portion 2a and a top portion 2b interconnected one another.
The portion 2a includes a support plate 12 that is substantially flat for resting on the seabed; the support plate may have any suitable overall dimension, however a length of less than 1 m (for example a length of about 825 mm) and a width of less than 1 m (for example a width of about 625 mm) may be recommended to keep the overall volume sufficiently reduced. The support plate 12 may be rectangular with a ratio of sides between 0.5 and 1 (width/length).
As apparent from the figures (for example
As shown in
Further, the support plate 12 shows a guide 14 in the form of a vertical bar starting from the housing space entrance and heading backwards towards the back of the station; the guide 14 is designed for guiding the underwater device 4 when received by the underwater docking station 1 in the housing space 16 (e.g., avoids that the underwater device 4 hits the scissor mechanism 15 and promotes a correct relative positioning of the underwater device 4 with respect to the docking station, for example for recharging purposes and/or for data exchange as below described in more detail). Obviously, the underwater device 4 has a corresponding seat that receives the emerging guide 14. It is clear that, in an alternative construction, the support plate 12 may include a seat and the underwater device 4 have the emerging guide.
In addition, the support plate 12 shows a locking mechanism 15a, such as one or more projections emerging from the plate 12, for allowing the underwater device 4 to lock to the underwater docking station 1, for example by means of corresponding clamps.
Notably, the support plate 12 may be substituted with a different plate having guide 14 and/or locking mechanism 15a dedicated to a different types/positions of corresponding seat and/or clamps of another underwater device 4.
Going back to the scissor mechanism 15 between the top portion and the base portion, the compact configuration is shown in the lateral view of
In order to automatically switch between the configuration of
Differently, the second bar has a fixed portion hinged to the top portion 2b and a movable portion slidable along the base portion 2a. The base portion 2a includes a sliding seat 17 and a pin of the movable portion of the second bar slides within the sliding seat 17 during movement between the open and the closed positions.
By properly actuating the motor and synchronizing the two scissor mechanism 15, it is possible to configure the underwater docking station between the configuration of
The top portion 2a of the support structure is substantially flat and designed to receive in support another underwater device 4, for example a ROV (see
The top portion 2a usually houses a battery associated to the support structure 2 to provide electric power to various components here after described such as a control unit 10, an optical communication module 3, an acoustic communication module (hydrophones 23), a camera 20, LEDs 22 and the respective actuators. The battery of the underwater docking station is rechargeable, e.g., wirelessly, through the one or more underwater devices 4 that provides electric power. Indeed, the ROV shown in
Notably, the support structure 2 further houses a wireless recharge module configured to couple to a corresponding wireless recharge module of the underwater device 4 to charge a battery of the underwater device 4. In this regard, electric power recharge is in the reverse direction, namely towards the underwater device 4, which in this case may be an AUV that has no power connection to the surface vehicle. The wireless recharge module is configured to recharge the battery of the underwater device 4 if the corresponding wireless recharge module of the underwater device is at a distance from the wireless recharge module of less than 0.5 m, in particular when the underwater device 4 is correctly positioned in the housing space 16 of the support structure 2. The recharge module of the underwater device 4 could be used both to receive electric power from e.g., a ROV, and to provide electric power to e.g., an AUV as mentioned.
As visible from
The top portion 2a also houses a camera 20 placed in correspondence of the front panel. The camera 20 is connected to the control unit 10 and allows viewing and/or filming of images surrounding the underwater docking station; the camera has a certain field of view and the collected data may be stored in a memory connected to the control unit 10. As visible in
As it is visible from
The optical communication module 3 comprises a wireless optical modem that in the specific embodiment has a maximum communication range of about 60 m. Of course, maximum distance is affected by water turbidity and environment noise. The optical communication module 3 has a data rate of at least 5 Mbit/sec, in particular of at least 9/10 Mbit/sec and is configured for working at least up to a depth of 6000 m. The optical communication module 3 is a bi-directional transceiver and is configured for achieving video data transfer, for example for 4K video data transfer.
In general terms, the optical communication module 3 is used for transmitting and receiving data at high data rate with good bandwidth using optical signals. For the purposes of the present disclosure, with “optical signal” shall be intended a signal within the range of visible light—about in the [380-750] nm range—and/or in the range of the infrared light—about in the [700-1000] nm range—and/or in the range of the ultraviolet light—about in the range [10-380] nm range. The clause “and/or” is provided since in an embodiment the bandwidth of the optical signal may be so broad to cover at least two or three among the ranges of the visible light, the infrared light, the ultraviolet light.
A coupling arrangement 6 is used to mount the optical communication module 3 to the support structure 2 in order to allow a relative movement between the optical communication module 3 and the support structure. The movement is used to properly orient the communication axis 5 and therefore the line of sight of the optical module. An actuator 7 is shown in
As mentioned, an AUV may be housed in the housing space 16 below the top portion 2a (see
Differently, when a ROV is positioned on top of the support structure 2 as shown in
The control unit 10 is connected to the optical communication module 3 to manage the communication with said one or more underwater devices 4, and to the actuator 7 to drive the optical communication axis 5 (by moving the optical communication module 3 or a portion thereof) to the first operative position or to the second operative position. The optical communication module 3 rotates along a rotation axis 11 that is transversal, in particular orthogonal, to the communication axis 5. As visible form the figures, the rotation axis 11 is substantially horizontal in use conditions of the underwater docking station 1, and therefore the actuator 7 is configured to (exclusively) rotate the optical communication module 3 to move the optical communication axis 5 between the first operative position and the second operative position so that any communication directions lie in a vertical plane. In particular, the control unit 10 is configured to rotate over a rotation angle range of at least 90° and more in detail of at least 180°.
Clearly, the optical communication axis 5 is movable to a plurality of additional positions in addition to the first operative position and the second operative position, and the optical communication module 3 is configured to communicate along additional communication directions in one or more of said additional positions. For example, in the configuration of FIG. 1, the communication axis 5 is horizontal and any underwater device 4 placed in front of (and in line of sight with) the docking station may communicate in the shown position of the module 3.
Further, to the above optical communication system, the docking station is further provided with an acoustic communication module. Since the optical module 3 allows for good data transfer rate, but requires line of sight and proximity, the applicant has implemented a second communication module that uses acoustic and/or ultrasound signals. This system may communicate at greater distances than the optical system and does not require line of sight. However, the data transfer is much reduced. Therefore, the acoustic module is mainly used for exchanging commands, while the optical for important and large data transfer (e.g., video files). The combination of an optical communication and of a ultrasonic and/or acoustic communication between the base station 1 and the underwater device 4 allows to exchange high-bandwidth data using the optical signal and to obtain long communication distances, even if at a lower bandwidth, using the ultrasonic and/or acoustic signal, in particular without requesting complex and/or delicate transmitters differing from a differently configured or adapted hydrophone. The ultrasonic and/or acoustic communication and the optical communication constitute two distinct logic channels for allowing a communication between the base station and underwater device 4. The fact that the operative connection of the base station 1 with the underwater device 4 takes place through two logic channels of communication operating at frequencies significantly different each other allows to guarantee that some noise sources that may affect one logic channel do not interfere with the other logic channel; in some embodiments those two logic channels may be used simultaneously for redundancy—especially for redundancy of control—thereby achieving an increase of reliability of communication.
For the purposes of the present disclosure, with “ultrasonic signal” shall be intended a signal whose frequency is higher than 20 kHz, preferably comprised in the interval [20-200] KHz.
For the purposes of the present disclosure, with “acoustic signal” shall be intended a signal whose frequency is equal or lower than 20 kHz, preferably comprised in the interval [0.01-20] kHz, more preferably in the interval [0.02-20] KHz.
It is noted that the ultrasonic and/or acoustic signal is so defined since in an embodiment its bandwidth may be located between the frequency range of the ultrasonic signals and the frequency range of the acoustic signals, or the plurality of carriers of the channels of the signal may be located between the frequency range of the ultrasonic signals and the frequency range of the acoustic signals.
The Applicant actually notices that according to IEEE Communications Magazine, January 2009 “Underwater Acoustic Communication Channels: Propagation Models and Statistical Characterization”, by Milica Stojanovic, Northeastern University, and James Preisig, Woods Hole Oceanographic Institution, the power spectral density of the ambient noise in an underwater environment, at least due to the wind and shipping activity has a minimum substantially located between 20 KHz and 150 kHz, more in particular between 30 kHz and 110 kHz. Thus, in a preferred, non-limiting, embodiment, the frequency range for the ultrasonic and/or acoustic signal may be located in the [20-150] KHz range, preferably in the [30-110] kHz range.
In this regard, the underwater docking station comprises one or more hydrophones 23 associated to the top portion 2a of the support structure 2 and configured to allow a transmission and reception of ultrasonic and/or acoustic signals. The control unit 10 is connected to the hydrophones 23 to manage communication with ultrasonic and/or acoustic signals. Since the transmission of the ultrasonic and/or acoustic signals is a substantially non-directive transmission, the control unit 10 transmits using the hydrophone 23 when the underwater docking station 1 and the underwater vehicle 4 are at more than a first distance D1 (e.g., between 50 m and 500 m or more). Since the transmission of optical signals through the optical communication module 3 is a substantially directive transmission, the control unit 10 transmits with the optical communication module 3 when the underwater docking station 1 and the underwater device 4 are at a second distance D2 (e.g., between 0 m and 60 m). Notably, the first distance D1 is greater than the second distance D2.
In order to properly work, the control unit 10 is configured to receive or determine a distance between the underwater docking station 1 and the underwater device 4, and select a communication using either the hydrophone 23 or the optical communication module 3 based on said calculated or received distance.
Albeit this shall not be considered limiting, in an embodiment the body of the hydrophone 23 is substantially elongated, and defines a main direction of extension that defines substantially a pointing direction or axis of the hydrophone. The hydrophone 23 is specifically configured to operate in a full-duplex communication environment, i.e. wherein simultaneous reception and transmission takes place.
The invention is not limited to the annexed figures. For such reason, the reference numbers provided in the annexed claims are provided for the sole purpose of increasing the intelligibility of the claim, and shall not be construed as limiting.
It is finally clear that several adaptations and additions can be provided to the object of the invention without for this departing from the scope of protection provided by the annexed claims.
Number | Date | Country | Kind |
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102021000022478 | Aug 2021 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2022/020060 | 8/19/2022 | WO |