• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention relates to an optical transceiver configuration device, system and kit. A configuration device includes an optical transceiver jack and a data communications port. An optical transceiver can be received in the jack. The optical transceiver includes non-volatile memory and a transceiver identifier. The transceiver ID can be read from the optical transceiver. A file based at least in part on the transceiver identifier may be provided through the port to a user's computing device. The file is readable through a web browser. The file is configured to display one or more user selectable firmware update options through the user computing device. Selection data relating to a firmware update may be received from the user computing device via the port. A firmware update based at least in part on the selection data can be written to the memory of the optical transceiver.
    公开号:BE1027089B1
    申请号:E20205148
    申请日:2020-03-05
    公开日:2021-02-26
    发明作者:Philippe Bolle
    申请人:Skylane Optics Sa;
    IPC主号:
    专利说明:

    TRANSMITTER CONFIGURATION DEVICE, SYSTEM AND KIT -
    OPTICAL RECEIVER Technical Field The invention relates to the technical field of configuring optical transceivers. Background US 8,566,643 B2 describes a small form factor pluggable control device (SFP). The SFP control device connects to an SFP transceiver and via a USB cable to an FC. The SFP control device uses the PC's default web browser, without an Internet connection, to display details of the SEP transceiver, such as wavelength, description, range, manufacturer, among other information. , according to the program code supplied to the PC via the SFP control device. Both the SEP controller and the SFP transceiver are powered through the PC's USB cable connection. The SFP control device appears on the PC as a memory key.
    The document describes reading from an SEP transceiver, generating readable files through a web browser, and viewing the files through a web browser on a PC. The document in particular learns to do without an Internet connection, A priori, the PC does not need to be configured with dedicated software or files specifically associated with the SFP control device or an SEP transceiver, because these software or files are provided by the SEP control device. The document does not provide for updating firmware data on an SFP transceiver.
    Document US 9 959 110 B2 describes a method of programming an optical transceiver. The optical transceiver has on-board memory storing firmware data and a transceiver ID. A hardware device includes a socket for electrical connection with the optical transceiver, further includes memory storing an identity of the hardware device, and can be electrically connected via USB to a computing device. The identity of the hardware device is read from its memory and provided to a remote provider. After confirming the validity of the identity of the hardware device, the transceiver ID is sent to the provider
    © Remote BE2020 / 5148 to select new firmware data corresponding to the transceiver ID and to download the new firmware data from the remote provider to the storage of the computing device. The new firmware data is retrieved from the storage of the hardware device and written from the hardware device to the memory of the optical transceiver. Wrong firmware data can irreversibly damage an optical transceiver. In particular, this can lead to the use of incorrect user parameters, which in turn can lead to irreversible damage to the optical transceiver. Examples are scratches on optical components of the optical transceiver or hardware failure due to excessive power and / or temperatures exceeding safe limits. ! is of the utmost importance to avoid erroneous firmware data. In the aforementioned document, new firmware data is sent from the remote provider to the computing device, from the computing device to the hardware device, and from the hardware device to the memory of the optical transceiver. Interception of new firmware data on the computing device may occur, corruption of new firmware data by a user may occur, and corrupted firmware data may be written to transceiver memory storage. optical.
    US 7,610,494 B2 describes an optical transceiver which has at least one processor and one memory. The optical transceiver receives encrypted microcode from a source. The optical transceiver can then decrypt the received microcode to create decrypted microcode. The decrypted microcode is then written into memory, where it can be executed by at least one processor to control one or more functions of the optical transceiver. A decryption key may be used which key includes a unique transceiver identifier, such as a transceiver serial number. The optical transceiver is configured to decrypt the microcode. On the optical transceiver, fewer resources are available for other functionalities and / or additional resources are required to activate the decryption functionality, the resources being able to be memory, the computation time on one or more processors, etc. It boils down to a change
    “BE2020 / 5148 linear resource with the amount of optical transceivers, since such a configuration is performed by optical transceiver. Additionally, cryptography tends to use more complex algorithms and / or larger keys, due to the algorithmic progression in solving the discrete logarithm problem, resulting in more resources required overall. The object of the present invention is to solve at least some of the problems mentioned above.
    Summary of the Invention In a first aspect, the present invention provides a configurator for configuring optical transceivers, according to claim 1.
    In a second aspect, the present invention provides a system for an optical transceiver configuration according to claim 18. In a third aspect, the present invention provides a kit for an optical transceiver configuration according to claim 23. The present invention is advantageous because it allows to update and configure an optical transceiver firmware, in particular to write a firmware update to a non-volatile memory of an optical transceiver, via display and user selection of a firmware update option on a user computing device, including through a dedicated user interface. This can be done without the need to install any software! dedicated or files related to optical transceivers on the user's computing device, or can also be done through dedicated software or files, such as a smartphone application. Description of the Figures Figure 1 shows a schematic overview of the data communication of an embodiment according to the present invention. Figure 2 shows a perspective view of an embodiment of a configuration device according to the present invention.
    Figure 3 shows a perspective view of another embodiment of a configuration device according to the present invention.
    Fig. 4A shows a front perspective view of another embodiment of a configuration device according to the present invention. Figure 4B shows a rear perspective view of Figure 4A, Figure 4 © shows a top view of Figure 4A. Figure 4D shows a rear view of Figure 4A. Figure dE shows a right side view of Figure 4A. Figure 4F shows a left side view of Figure 4A.
    Detailed Description of the Invention The present invention relates to an optical transceiver configuration device, system and kit. The invention has been summarized in the corresponding section above. In the following, the invention is described in detail, preferred embodiments are discussed and the invention is illustrated by way of examples.
    Unless defined otherwise, all terms used in the disclosure of the invention, including technical and scientific terms, have the meaning as commonly understood by those skilled in the art to which this invention belongs. As further assistance, definitions of terms are included in order to better understand the teaching of the present invention.
    As used herein, the following terms have the following meanings: The terms "UN =," a "and" the "and" the "as used herein refer to both singular and plural referents, unless otherwise specified by context. By way of example, “a compartment” designates one or more compartments.
    The terms "include", "comprising", "includes" and "consisting of", as used herein, are synonymous with "include", "including", "included" or "contain", "containing>," contains ”and are inclusive or open-ended terms that specify the presence of the following (eg, a component) and do not exclude or exclude the presence of additional unrequited components, functions, elements, organs and steps.
    > BE2020 / 5148 As used here, an "optical transceiver" refers to a device configured to convert an electrical signal into a signal! optical and to convert an optical signal into an electrical signal.
    The optical transceiver includes non-volatile memory and a transceiver identifier.
    Preferably, the optical transceiver includes one or two, or more, ports for inserting an outer end of a fiber optic cable.
    Preferably, the optical transceiver is configured to plug into an outlet of a network device.
    The optical transceiver may be a small form factor pluggable optical transceiver (SFP). The optical transceiver can be an enhanced SFP (SFP +), SFP28, SFP56, compact SFP (cSFF), or dual density (SFP-DD) optical transceiver. The optical transceiver may be a small form factor pluggable four-way optical transceiver (QSFP). The optical transceiver can be an enhanced QSFP (QSFP +), QOSFP28, OSFP56, OSFF28 dual density (QSFP28-DD}) or dual density QSFP56 (QSFP56-DD) optical transceiver. The optical transceiver may be a 10 gigabit small form factor (XFP) pluggable optical transceiver. The optical transceiver may be a small octal form factor (OSFP) pluggable optical transceiver. The optical transceiver may be a CG form factor pluggable optical transceiver (CFP). The optical transceiver can be a CFP1, CFP2, CFP4 or CFP8 transceiver. The optical transceiver can also be another optical transceiver.
    Preferably, the non-volatile memory is an electrically erasable programmable read-only memory (EEPROM). Preferably, a memory card in the non-volatile memory is associated with the optical transceiver according to a multi-source agreement (MSA), which is accessible via an inter-integrated circuit interface (12C). Preferably, the optical transceiver is configured for digital diagnostic monitoring (DDM). Preferably, the digital diagnostic monitoring data includes one or more of: temperature, supply voltage, laser bias current, average transmitted power and average received power.
    The digital diagnostic monitoring data may additionally also include other diagnostic features.
    A "remote provider" includes a server.
    A remote provider can include multiple servers.
    A remote provider can be a cloud-based storage and / or computing system comprising multiple servers.
    A server includes one or more processors.
    A remote provider is configured for data communication over a network.
    Preferably a supplier
    > Remote BE2020 / 5148 is configured for data communication via the Internet. A network address can be associated with a remote provider. Non-limiting examples of network addresses are a URL (Uniform Resource Locator) and an IP (Internet Protocol) address. Preferably, the remote provider includes a configuration management database (CMDB). Preferably, the CMDB is defined by the IT infrastructure library (ITIL). In a first aspect, the present invention provides a configuration device for configuring optical transceivers. In a second aspect, the present invention provides a system for configuring optical transceivers, comprising a configuring device according to the first aspect. In a third aspect, the present invention provides a kit for configuring optical transceivers, comprising a first, second and third configurator according to the first aspect. Those skilled in the art will understand that the three aspects of the present invention are therefore interdependent. The explicit reference to a particular aspect can therefore be omitted. Each feature described above and / or below may relate to any aspect of the present invention, even though it has been described in conjunction with a particular aspect of the present invention.
    The configuration device includes an optical transceiver jack and a data communication port. The configurator is configured to receive an optical transceiver in the jack. The configurator is configured to read the transceiver ID from the optical transceiver. The configuration device is preferably configured to read binary files from the memory of the optical transceiver. The configuration device preferably comprises a tangible, non-transient, computer readable storage medium, such as flash memory. The configuration device is preferably configured to extract and save the binary contents of the memory (preferably an EEPROM) of the optical transceiver in a file readable on the storage medium of the configuration device. The configuration device is configured to provide via the port a file based at least in part on the identifier of the transceiver to a user computing device. Preferably, the file is readable through a web browser. Preferably, the file is an HTML file, a txt file or a json file. The file is configured to display one or more user selectable firmware update options through the user computing device. The configuration device is configured to receive selection data relating to a firmware update from the user computing device via the port. The configuration device is configured to write a firmware update based at least in part on the selection data stored in the memory of the optical transceiver. The present invention is advantageous because it allows to update and configure an optical transceiver firmware, in particular to write a firmware update to a non-volatile memory of an optical transceiver, via display and user selection of a firmware update option on a user computing device, including through a dedicated user interface. This can be done without the need to install dedicated software or files related to optical transceivers on the user's computing device, or can also be done through dedicated software or files, such as a smartphone application.
    The configuration device may include one, two, three, four, cing, six, seven, eight, nine, ten, eleven, twelve, thirteen, fourteen, fifteen, sixteen, seventeen, eighteen, nineteen, twenty, twenty-one, twenty-two, twenty-three, twenty-four or more taken for optical transceivers. All outlets can be configured for the same form factor footprint. Different sockets can also be configured for different form factor footprints. Preferably, the configuration device includes an optical transceiver socket.
    Preferably, a socket is configured for the SFP, QSFP or XFP form factors. A socket configured for SEP form factors can also be configured for SFP +, SFP28, SFP56, cSFP and SFP-DD form factors. A socket configured for QSFP form factors can also be configured for QSFP +, QSFP28, OSFP56, QSFP28-DD, QSFP56-DD, and OSFP form factors. Preferably, the port is a male or female USB port. More preferably, the port is a female USB port. Preferably, the port is a micro-USB port. Preferably, the configuration device is configured for data communication with the user computing device via a cable, preferably a USB cable. Preferably, the configuration device is configured to receive power from the user computing device through the port. Preferably, the configuration device includes an optical transceiver socket. A setup device with an optical transceiver socket is advantageous because it is smaller and requires less power. Preferably the
    : BE2020 / 5148 User computing device includes a battery. Preferably, the user computing device is a portable user computing device, more preferably a laptop, tablet, phablet or smartphone, still more preferably a tablet, phabletia or smartphone, and most preferably between all a smartphone. Preferably, the user computing device is configured for data communication with a remote provider. Preferably, the user computing device includes a wireless communication module for data communication with the remote provider via the Internet. Preferably, the wireless communication module is a 3G, 4G, 5G or Wi-Fi module. Preferably, the configuration device is configured to use the user computing device as a tether device. Preferably, the user computing device comprises a display. Preferably, the user computing device comprises a user input device. Preferably, the user computing device comprises a touch screen, which is a screen and a user input device. Preferably, the user computing device comprises a camera. Preferably, the user computing device comprises one or more processors. The system includes the remote provider. The little system! understand the user's Computing device.
    The kit includes a first configuration device according to the first aspect, a second configuration device according to the first aspect, and a third configuration device according to the first aspect, in which each of the first, second and third configuration devices has a socket. optical transceiver. The first configuration device socket is configured for SFP form factors. The second configuration device socket is configured for GSEP form factors. The third configuration device socket is configured for XFP form factors. Preferably, the socket of the first configuration device is also configured for the SFP +, SFP28, SFP56, cSFP and SFP-DD form factors. Preferably, the outlet of the second configuration device is also configured for the QSFP +, QSFP28, GSFP56, OSFP28-DD, QOSFP56-DD and OSFP form factors. The kit may include a fourth configuration device according to the first aspect, wherein the fourth configuration device includes an optical transceiver socket. The optical transceiver jack of the fourth configurator is configured for CFP form factors. Preferably, the socket of the fourth configuration device is also configured for form factors CFP1i, CFP2, CFP4 and CEPS.
    S 7 BE2020 / 5148 The system comprises a configuration device according to the first aspect and a remote provider.
    The remote provider includes a plurality of firmware updates. The remote provider is configured to send a firmware update through the user computing device to the configuration device.
    In a preferred embodiment, the file is configured to retrieve remote firmware update information from the remote provider based at least in part on the identifier of the transceiver.
    In this embodiment, the file is further configured to, upon receipt of a selection of a firmware update option via the user computing device, download selection data including the update. corresponding firmware from the remote provider through the user computing device on the configuration device.
    Preferably, the configuration device comprises a device identifier, the configuration device being configured to generate an authentication key, for authentication vis-à-vis the remote provider, based at least in part on the identifier. device, the transceiver identifier, optionally a user identifier, and optionally a time stamp.
    In a preferred embodiment, the configuration device includes a decryption key and a device identifier.
    In this embodiment, the downloaded firmware update is an encrypted firmware update based at least in part on the device identifier.
    The configuration device is then configured to decrypt the encrypted firmware update downloaded via the decryption key, thereby obtaining the firmware update for writing to the memory of the optical transceiver.
    Alternatively or in addition, the encryption can be based on Pun or more of: a company identifier, a user identifier and the optical transceiver identifier.
    This is advantageous because it allows a firmware update to be retrieved from the remote provider, without a user being able to tamper with the firmware update on an intermediate user computing device.
    This embodiment provides an alternative to US 7,610,494 B2, with the technical advantage of shifting resource requirements / resource usage from the optical transceiver to the optical transceiver.
    +0 2 BE2020 / 5148 configuration device.
    Because one configuration device can be used to configure many optical transceivers, decryption functionality must be provided on one configuration device rather than on each of the many optical transceivers.
    This allows for a simpler design of the optical transceiver.
    It also allows the use of more complex keys and / or encryption algorithms.
    It also allows easy adaptation for secure, on-site and continuous updates of firmware data for a large set of optical transceivers, in the event that an encryption standard is not secure.
    The replacement of software instructions and / or decryption keys on the configuration device, or the complete replacement of the configuration device, can be performed by a trusted provider linked to the remote provider.
    The replacement of an insecure decryption key and / or protocol on an optical transceiver could also be done by a trusted provider, but would have to be done separately for each optical transceiver, and could potentially involve l shipment of each optical transceiver.
    In a preferred embodiment, the remote provider includes an encryption key associated with the device identifier.
    Preferably, the decryption and encryption keys are complementary keys of an asymmetric key pair.
    In this embodiment, the remote provider is configured to encrypt a firmware update via the encryption key associated with the device identifier, thereby obtaining the encrypted firmware update, for sending to the configuring device. via the user's computing device.
    The authentication key can be the decryption key.
    In a preferred embodiment, the configuration device comprises a tangible, non-transient, computer-readable storage medium comprising one OR more firmware updates.
    In this embodiment, the file may include local firmware update information.
    Preferably, the file is configured for, upon receipt of a selection of a firmware update option, preferably a firmware update option corresponding to the local firmware update information, via the user computing device, transferring, via the port, selection data on the selection of the firmware update option to the configuration device.
    & BE2020 / 5148 In a first embodiment, all necessary firmware updates are stored on the storage medium of the configuration device, and the file can be configured to display one or more selectable firmware update options. by the user corresponding to the local firmware update information only. In this embodiment, the configurator does not need to receive a firmware update from the remote provider, although some update events may or may not be logged at the remote provider. See other embodiments relating to the history log below.
    In a second embodiment, the configuration device does not include firmware updates, and the file can be configured to display one or more user-selectable firmware update options corresponding only to user information. remote firmware update.
    In a third embodiment, the configurator includes the storage medium including one or more firmware updates, and the file can be configured to display one or more user-selectable firmware update options. corresponding to the local firmware update information and one or more user-selectable firmware update options corresponding to the remote firmware update information.
    In the third embodiment, the most frequently used firmware updates can be stored on the storage medium of the configuration device, and selected firmware updates which are not present on the storage medium can be stored. downloaded from the remote provider.
    In the third embodiment, a number of the last used firmware updates can be stored on the storage medium, and selected firmware updates which are not present on the storage medium can be downloaded from. from the remote provider, whereby when downloading a firmware update, depending on the storage capacity available on the storage medium, none, one or more of the previously used firmware updates
    +2 a BE2020 / 5148 can be deleted from the storage medium in order to store the downloaded firmware update on the storage medium. In the third embodiment, firmware updates corresponding to a set of firmware update types can be stored on the storage medium. Each firmware update on the storage media includes a version. The local firmware update information includes the versions of the firmware updates corresponding to the bundle. Remote firmware update information includes versions of firmware updates on the remote provider corresponding to the bundle, The file is configured to display one or more user-selectable firmware update options, the file being configured to select an option associated with a type of firmware update based at least in part on a comparison of the corresponding versions based on the functions of the remote and local firmware update information.
    In a preferred embodiment, the file is configured to display an indication of microprogram present in the memory of the optical transceiver. Preferably, the configuration device is configured to read a firmware version from the optical transceiver and generate the file based at least in part on the read firmware version.
    In a preferred embodiment, the configuration device is configured to obtain digital diagnostic monitoring data from the optical transceiver and to send the digital diagnostic monitoring data from the configuration device to the remote provider via the computer device that user.
    In a preferred embodiment, the file is configured to retrieve previous firmware installation data from the remote provider and display previous firmware installation data through the user computing device. Preferably, the file can be configured to display previous firmware installation data. Preferably, the file is configured to display one or more user selectable firmware restore options through the user computing device, with a restore option associated with previously installed firmware. Preferably, the file is configured to display a timeline or roadmap, the timeline or roadmap including a chronological overview of previous firmware installation data.
    In a preferred embodiment, the remote provider includes a history log. The remote provider can be configured to add an update event to the history log including the transceiver ID, an indication of the firmware update, and time information. Preferably, the remote provider is configured to add said update event to the history log when sending selection data including firmware update to the configuration device via the user computing device or when of receiving selection data when selecting the firmware update option. Preferably, the previous firmware installation data is based at least in part on one or more history log update events including the transceiver identifier. In a preferred embodiment, the file is configured to retrieve previous digital diagnostic monitoring data from the remote provider and to display previous digital diagnostic monitoring data through the user computing device. Preferably, the file is configured to display a timeline or roadmap, the timeline or roadmap including a chronological overview of previous digital diagnostic monitoring data. In a preferred embodiment, the history log includes a diagnostic event including the transceiver identifier, digital diagnostic monitoring data, and timing information. Preferably, the remote provider is configured to add a diagnostic event to the history log comprising the transceiver identifier, received digital diagnostic monitoring data, and timing information. Preferably, the foregoing digital diagnostic monitoring data is based at least in part on one or more diagnostic events from the history log including the transceiver identifier. The display via the user computer device of previous firmware installation data and previous digital BE2020 / 5148 diagnostic monitoring data is particularly advantageous, as it allows the deterioration of the performance characteristics of the transmitter to be correlated. - optical receiver with firmware updates.
    In a preferred embodiment, the user-selectable firmware update option (s) may include a cancel option including an indication of the firmware present in the optical transceiver memory. Preferably, the option of canceling is associated with leaving the firmware currently present in the memory of the optical transceiver unchanged. Those skilled in the art will understand that, based at least in part on the transceiver identifier, the remote provider can extract from the history log the firmware data currently present in the transceiver memory. .
    In a preferred embodiment, the optical transceiver comprises a bar code including information about the transceiver identifier. Previous firmware installation data and / or previous digital diagnostic monitoring data from an optical transceiver can be obtained without the involvement of a configuration device. They can also be obtained with the intervention of a configuration device. An image of the bar code can be captured through the camera of a second user computing device, the name being said aforementioned user computing device or another user computing device. The transceiver identifier can be obtained based at least in part on the captured image and sent to the remote provider. For this purpose, the bar code may include remote provider information in addition to the information on the transceiver identifier. Previous firmware installation data and / or previous digital diagnostic monitoring data based at least in part on the transceiver ID and history log of the remote provider can be received from the remote provider on the second user input device. A chronological overview based at least in part on previous firmware installation data and / or previous digital diagnostic monitoring data received can then be displayed on a screen of the second user input device.
    In a preferred embodiment, the configurator comprises a longitudinal direction, the configurator being elongated in the direction
    > BE2020 / 5148 longitudinal. The plug and port are positioned along the longitudinal direction at opposite outer ends of the configuration device. Preferably, the plug and port are configured for insertion along the longitudinal direction.
    In a preferred embodiment, the configuration device comprises a middle portion between the outer ends. The median part comprises a median perimeter perpendicular to the longitudinal direction. Each of the outer ends includes a perimeter perpendicular to the longitudinal direction which is greater than the median perimeter. This is advantageous for gripping and holding the configuration device, for example manually or via an elastic band, without obstructing the grip and port of the configuration device. In a preferred embodiment, the configurator comprises a total length in the longitudinal direction of at most 12cm, preferably at most 10cm, more preferably at most 8cm, still more preferably at most. more than 7 cm and most preferably not more than 6.5 cm. Preferably, the configurator comprises a total width along a width direction perpendicular to the longitudinal direction of at most 4 cm, more preferably at most 3.6 cm, and still more preferably at most. 3.2 om. Preferably, the configurator comprises a thickness along a depth direction perpendicular to the longitudinal directions and a width of at most 4 em, more preferably at most 3.6 em, still more preferably at most. 3.2 em, even more preferably at most 2.8 cm, most preferably at most 2.4 cm. In a preferred embodiment, the configuration device comprises a printed circuit board (PCB). The socket and port are connected to the printed circuit board. The configuration device may include an outer case configured to hold the printed circuit board in a fixed relative position (relative to the outer case) without screws. The PCB may include edges, depressions and / or holes, whereby the outer casing is configured to clamp the edges, depressions and / or holes of the printed circuit board, thereby maintaining the printed circuit board in a tight fit. fixed relative position.
    In a preferred embodiment, the configuration device (100) comprising a first housing (110), a second housing (120) and a connection means (130) between the first housing (110) and the second housing (120) .
    > BE2020 / 5148 In a preferred embodiment, the first housing (110) comprises a body (111), in which the body (111) may or may not be suitable for being held in the hand with an ergonomic design in the hand. 'mind. Said ergonomic design may or may not include rounding the edges, providing a narrowed section on the body (111), and adding an additional layer on the body {111} such as an anti-slip layer. The first housing (110) further includes an optical transceiver socket (114) and an end portion (131) of the link means (130). Said socket (114) may or may not be suitably configured to receive an optical transceiver comprising an SEP form factor, QSFP form factor, XFP form factor and / or other form factors. Said socket (114) may or may not be configured to receive other types of transceivers. Said socket (114) may or may not be configured to accommodate other devices. The first housing (110) may or may not further include indicator means (115), configured to indicate the status of the configuration device (100) during a configuration process. Said indicating means (115) may or may not include light, LED light, screen, and / or other indicating means. Said indicating means {115} may or may not follow an indication system to indicate the state of a configuration process.
    In a preferred embodiment, the second housing (120) includes a body (121), wherein the body (121) may or may not be suitable for being held in the hand with an ergonomic design in mind. Said ergonomic design may or may not include rounding the edges, providing a narrowed section on the body (121), and adding an additional layer on the body (121) such as an anti-slip layer. The second housing (120) further includes a data communication port (124) and an end portion {132} of the link means (130). Said port (124) is configured to communicate with a user computing device. Said port (124) may or may not be a commonly used means of communication comprising a USB connector, a mini USB connector, a micro USB connector, a USB type c connector, an Apple 30 pin connector, an Apple Lightning connector, and / or other connectors. Said port (124) may or may not be a male or female end of a connector. Correspondingly, the desired user computing device may or may not be a female or male end of the same type of connector. Said port (124) may or may not
    ‘BE2020 / 5148 communicating with a user computing device via a means of wireless communication. Said port (124) may or may not communicate with a user computing device by any suitable means.
    In a preferred embodiment, the connecting means (130) comprises a body (133) between the first end part (131) and the second end part (132). The body (133) may or may not be adjustable in length depending on market demand or user demand. The body (133) may or may not be flexible. The body (133) may or may not be enveloped by one or more layers comprising a protective layer, an anti-slip layer, a rigid layer and / or other layers. The two end portions (131, 132} may or may not be enveloped by one or more layers comprising a protective layer, an anti-slip layer, a rigid layer and / or other layers. (130) enables communication between the first housing (110) and the second housing (120). Said communication comprising data communication, power communication or communication by other means. the configuration device (200) comprises a housing (201). Said housing (201) may or may not be a cuboid housing, a cylindrical housing, a cubic housing, and / or a regularly shaped housing, and / or a irregularly shaped casing. Said casing (201) may or may not contain an ergonomic design for a better user experience. Said configurator (200) is suitable to be hermetically attached to a mobile phone; therefore , the size of said configuration device (200) will be adapted to this use. Said housing (201) is preferably 66 mm in length, 25 mm in width and 15.2 mm in thickness. In a preferred embodiment, said configuration device (200) may or may not include indicator means (211), configured to indicate the state of the configuration device (100) during a configuration process. Said indicating means (211) may or may not include light, LED light, screen, and / or other indicating means. Said indicating means (211) may or may not follow an indication system to indicate the state of a configuration process.
    ia BE2020 / 5148 In a preferred embodiment, said configuration device (200) comprises an optical transceiver socket {241}. Said socket {241} may or may not be suitably configured to receive an optical transceiver comprising an SFP form factor, QSFP form factor, XFP form factor and / or other form factors.
    Said socket (241) may or may not be configured to receive other types of transceivers.
    Said socket {241} may or may not be configured to receive other devices.
    In a preferred embodiment, said configuration device (200) comprises a first communication port.
    Said port (231) is configured to communicate with a user computing device.
    Said port (231) may or may not be a commonly used means of communication comprising a USB connector, a mini USB connector, a micro USB connector, a USB type c connector, an Apple 30 pin connector, an Apple Lightning connector, and / or other connectors.
    Said port (231) may or may not be a male or female end of a connector.
    Correspondingly, the desired user computing device may or may not be a female or male end of the same type of connector.
    Said port {231} may or may not communicate with a user computing device via a wireless communication medium.
    Said port (231) may or may not communicate with a user computing device by any suitable means.
    In a preferred embodiment, said configuration device (200) comprises a second communication port.
    Said port (251) is configured to communicate with a user computing device.
    Said port (251) may or may not be a commonly used means of communication comprising a USB connector, a mini USB connector, a micro USB connector, a USB type c connector, an Apple 30 pin connector, an Apple Lightning connector, and / or other connectors.
    Said port (251) may or may not be a male or female end of a connector.
    Correspondingly, the desired user computing device may or may not be a female or male end of the same type of connector.
    Said port {251} may or may not communicate with a user computing device via a wireless communication medium.
    Said port (251) may or may not communicate with a user computing device by any suitable means.
    in 19 BE2020 / 5148 In a preferred embodiment, said first communication port (231) and a second communication port (251) may or may not be the same type of communication medium, preferably different types of communication medium. communication. Said first communication port (231) and second communication port (251) may or may not be both male or female connectors, preferably a male connector and a female connector. In a preferred embodiment, said configuration device (200) may or may not include a third or more communication port. Said port is configured to communicate with a user computing device. Said port may or may not be a commonly used means of communication comprising a USB connector, a mini USB connector, a micro USB connector, a CG-type USB connector, a 30-pin Apple connector, an Apple Lightning connector, and / or other connectors. Said port may or may not be a male or female end of a connector. Correspondingly, the desired user computing device may or may not be a female or male end of the same type of connector. Said port may or may not communicate with a user's computing device via a wireless communication medium. Said port may or may not communicate with a user computing device by any suitable means.
    In a preferred embodiment, said third or more communication port may or may not be the same type of communication means as the first and / or second communication port. Said third or more communication port may or may not be a male or female connector.
    In a preferred embodiment, said communication port (231, 251) and said socket (241) may or may not be close to each other, such that when an external device (transceiver , user computing device) is connected to a port (231, 251) or outlet (241), it does not interfere with the use of another port (251, 231) or outlet (241 ). In a preferred embodiment, a male connector (251) should not be placed near the socket (241), so that the male connector (251) and the socket (241) cannot be used at the same time. time. In a preferred embodiment, the communication port (231, 251) and the receptacle (241) are located on different surfaces of the housing (201). In a more preferred embodiment, the plug (241) is in a position orthogonal to the position of a communication port (251), preferably a male connector (251).
    a BE2020 / 5148 In a preferred embodiment, the data communication port is removably connected to the second housing.
    In another preferred embodiment, the removable data communication port is also interchangeable.
    Such an interchangeable connector allows connection of the second housing with various communication ports known in the art.
    Preferably, said communication port is one of: a male USB-A connector, a male USB-B connector, a male USB-C connector, a male mini-USB connector, a male micro-USB connector, a male connector USB 3 male, one LIGHTNING® male connector, one THUNDERBOLT® male connector, etc.
    These communication ports are widely used and available.
    Preferably, one or more of the communication ports mentioned above are provided in the kit according to the invention.
    In a preferred embodiment, the data communication port is removably magnetically connected to the second housing.
    In another preferred embodiment, the removable data communication port includes a magnetic connection surface for removable connection with a complementary magnetic receiving surface provided on the second housing.
    The magnetic connection surface and the magnetic receiving surface can be configured to exert a coupling force between said data communication port and said second housing in either of two rotational orientations.
    This configuration provides a quick connect interface on the configuration device for the data communication port.
    Such magnetic communication ports can also be cut with rotational symmetry such that a 180 degree rotation of a port part, either clockwise or counterclockwise, produces an identical connection, thus eliminating the need to check alignment when connecting.
    According to a preferred embodiment, the magnetic connection surface is round or elliptical.
    The magnetic connection surface may or may not be one of: rectangular, triangular, or trapezoidal.
    The magnetic connection surface may or may not be located around the removable data communications port.
    According to one embodiment, the removable communication port comprises a magnetic ring configured to come to be housed around the port. ideally, the complementary magnetic receiving surface provided on the second housing has a shape complementary to the magnetic connection surface.
    pe BE2020 / 5148 The invention is further described by the following non-limiting examples which illustrate the invention in more detail and are not intended to limit, nor should they be interpreted to limit the scope of the invention. Examples Example 1: First Embodiment Fig. 1 shows a schematic overview of the data communication of an embodiment according to the present invention. A remote provider (1), a smartphone (2), a configurator (3) and an optical transceiver (4) are presented. The optical transceiver includes an EEPROM, transceiver serial number, and bar code. The bar code includes information about the serial number of the transceiver. The configuration device (3) includes a device identifier, a socket for the optical transceiver, a female micro-USB port and an authentication key. The smariphone includes one or more processors, a battery, a touch screen, a female USB port, a wireless communication module for data communication with the remote provider via the Internet, and a camera. The remote provider includes a history log including update events and diagnostic events. The optical transceiver (4) is plugged into the configuration device socket (3). The configuration device (3) is connected to the smartphone (2) via a USB cable.
    The serial number of the transceiver is read (43) by the configuration device. A File, such as an html file, based at least in part on the serial number of the transceiver, is generated by the configuration device and transferred (32) from the configuration device to the smartphone. The file is translated and viewed, preferably via a web browser, on the smartphone. While reading the file, remote firmware update information based at least in part on the serial number of the transceiver is requested (21) and received (12) from the remote provider. The remote firmware update information includes a user-selectable cancel option including information about the firmware present in the optical transceiver memory, based on the history log of the remote provider and the 'transceiver identifier, in order to leave the firmware in the memory of the transceiver-
    Da ve BE2020 / 5148 optical receiver unchanged. The remote firmware update information further includes one or more user selectable update options. A page is displayed, preferably via the web browser, on the smartphone, the page including the user selectable cancel option and the user selectable update option (s). Upon receipt of a user selection of an update option via the user computing device, selection data including the firmware update corresponding to the selected update option is requested (21) and received (12) from the remote provider and uploaded (23) to the configuration device. An update event including the transceiver identifier, an indication of the firmware update, and time information is added to the history log of the remote provider. The firmware update of the selection data is written (34) to the memory of the optical transceiver by the configuration device.
    An image of the barcode is captured via the smartphone camera. The transceiver serial number is obtained at least in part from the captured image and sent to the remote provider. Historical data based at least in part on the transceiver serial number and the history log is received from the remote provider. A chronological overview based at least in part on historical data and including firmware update information and digital diagnostic monitoring information is displayed on the touchscreen of the smariphone.
    Example 2: Second Embodiment Figure 2 shows a perspective view of an embodiment of a configuration device (3) according to the present invention. The second embodiment may or may not be linked to the first embodiment.
    The configuration device includes an optical transceiver socket (6) and a female micro-USB port (7). The configuration device includes a longitudinal direction. The configurator is elongated in the longitudinal direction. The plug and port are positioned along the longitudinal direction at opposite outer ends of the configuration device. The plug and port are configured for insertion along the longitudinal direction. The configurator has a total length in the longitudinal direction
    Pr BE2020 / 5148 of about 64 mm, a total width in a width direction perpendicular to the longitudinal direction of about 30 mm, and a total thickness in a depth direction perpendicular to the width and longitudinal directions of about 20 mm . The configuration device comprises a middle part (11) located between the outer ends (10). The configuration device comprises a housing (8), and a gripping device (9), such as rubber, is disposed at the middle part. The middle part comprises (a cross section comprising) a middle perimeter perpendicular to the longitudinal direction. Each of the outer ends includes (a cross section including) a perimeter perpendicular to the longitudinal direction which is greater than the median perimeter. Example 3: Third Embodiment Fig. 3 shows a preferred embodiment of the configuration device according to the present invention. The configuration device (100) comprising a first housing (110), a second housing (120) and a connection means (130) between the first housing and the second housing.
    The first housing (110) comprises an elongated body (111), in which the elongated body (111) is rounded at the edges, making it suitable for being held in the hand. Said elongated body (111) has a narrowed section in the middle part, and the elongated body (111) is enveloped by an anti-slip layer, which is suitable for hand holding with ergonomic design in mind. The first housing (110) further includes two flat ends (112, 113), wherein the first flat end (112) includes an optical transceiver socket (114) and the second flat end (113) includes a portion. end (131) of the connecting means (130). Said socket (114) is suitably configured to receive an optical transceiver comprising an SFP form factor, a QSFP form factor, and an XFP form factor. The first flat end (112) further includes an LED light indicator (115), configured to indicate the status of the configuration device {100} during a configuration process. The system of light signals (115) and their corresponding information are shown in the following table: Color of light Frequency Configuration status LED
    PC BE2020 / 5148 Verl / Flashing Red Update of the nT ee Pas (ee I The second housing (120) includes an elongated body (121), in which the elongated body (121) is rounded at the edges, which makes it makes it suitable for being held in the hand. The second housing (120) further includes two flat ends (122, 123), wherein the first flat end (122) includes a data communication port (124) and the second end plate (113) comprises an end portion (132) of the link means (130) Said port (124) is a male USB connector, configured to communicate with a user computing device having a female USB connector.
    The connecting means (130) includes an elongate body (133) between the first end portion (131} and the second end portion (132). The elongate body (133) is adjustable in length according to demand. The elongated body (133) is flexible. The elongated body (133) is completely enveloped by a protective layer. Both end portions (131, 132} are completely enveloped by a protective layer and a rigid layer. Said connecting means (130) enables communication between the first housing (110) and the second housing (120). Said communication comprising data communication, power communication or communication by other means Said connecting means {130} is a cable.
    This embodiment allows configuration in a situation where the configurator (1003 and the user's computing device are not positioned in close proximity to each other. This embodiment also allows greater freedom for operating the optical transceiver and configuration device (100), particularly in a small space where operation is limited by dimensions. This embodiment includes a male USB connector which is suitable for immediately connecting to the Most user computing devices, such as laptops and desktops.
    Example 4: Fourth Embodiment Figures 4A-4F show a preferred embodiment of the configuration device according to the present invention. The configurator (200) comprises a cuboid housing (201), said cuboid housing (201) comprising an upper surface (210), a lower surface (220), a left surface (230), a right surface (240). , a front surface (250) and a rear surface (260). The cuboid housing (291) is rounded at all edges and all surfaces (210, 220, 230, 240, 250, 260) are flat. The length of the cuboid housing (201), namely from the left surface (230) to the right surface (240), is 66 mm. The width of the cuboid housing (201), namely from the front surface (250) to the rear surface (260), is 25 mm. The thickness of the cuboid housing (201), namely from the upper surface (210) to the lower surface (220), is 15.2 mm.
    The top surface (210) includes an LED indicator light (211), configured to indicate the status of the configuration device (200) during a configuration process. The system of light signals (211) and their corresponding information are shown in the following table: Light color Frequency Configuration status an (ET Green / Red Flashing Updating the OT tee CDs Co The left surface (230) includes a opening for a female USB connector (231) The opening for said female USB connector is 19 mm long and 9 mm wide.
    The straight surface (240) includes an opening for an optical transceiver socket (241}, said socket (241} being suitably configured to receive an optical transceiver comprising an SFP form factor, a form factor QSFP, and an XFP form factor. The aperture for said socket
    Da a BE2020 / 5148 (241) is 14mm long and 9mm wide.
    The opening on the left surface (230) and the opening on the right surface (240) are aligned with each other in the width, i.e. in the dimension from the top surface (210) to the surface lower (220). The two openings are closer to the bottom surface (220). The front surface (250) includes a male USB Type-C connector (251), wherein said connector (251) is strictly in the middle between the left surface (230) and the right surface (240), but said connector (251) is closer to the top surface (210). Said connector (251) is also removable from the cuboid housing (201). A magnetic mating surface is provided on the rear side of the male USB Type C connector (251). A complementary magnetic receiving surface is provided on the cuboid housing (201). Such a removable configuration allows for an interchangeable data communication port.
    For example, the type © USB male connector (251) can be replaced by a male Lighining® connector, thus allowing connection to different types and brands of devices.
    When configuring an optical transceiver, a single communications port (231, 251) is connected to a user computing device.
    The USB Type-C connector (251), USB connector (231), and jack (241) are located on different surfaces oriented in different directions, and thus, when a user computing device and an optical transceiver are connected to the configuration device (200), they do not interfere with each other.
    This embodiment allows the configuration device (200) to be connected to a user computing device through the type © USB connector (251), such as an android phone.
    This embodiment also allows the configuration device (200) to be connected to a user computing device through the female USB connector (2313, such as a laptop or desktop computer.
    For combined use, this allows the user to switch between user computing devices with different types of connectors without modifying the configuration device (200) with appropriate connectors.
    Namely, when a user first configures an optical transceiver by an android phone with a female USB type C connector, the configuration device (200) can be connected to the android phone via the USB type C connector ( 251). Then, when the user configures the same or another optical transceiver through a laptop computer equipped with a male USB connector, the
    © BE2020 / 5148 configuration device {200) can be connected to the portable ordinaleur via the USB connector (231). This embodiment covers most types of devices on the market.
    Some obvious alternatives to this embodiment would be a dual combination of a group of connectors including a USB connector, a mini USB connector, a micro USB connector, a © type USB connector, an Apple 30 pin connector, an Apple Lightning connector. , and each type of connector comprising a male and female end.
    权利要求:
    Claims (37)
    [1]
    1. Configuration device for an optical transceiver configuration, comprising an optical transceiver socket and a data communication port, in which the configuration device is configured to: - receive an optical transceiver in the socket, the optical transceiver comprising non-volatile memory and a transceiver identifier; - read the transceiver identifier from the optical transceiver, and preferably read binary files in the memory of the optical transceiver; - provide, vla port, a file based at least in part on the transceiver identifier to a user computing device, the file being readable through a web browser, the file being configured to display one or more options updating user selectable firmware via the user computing device; - receive, via the port, selection data of a firmware update from the user's computing device; el - write a firmware update based at least in part on the selection data to the memory of the optical transceiver.
    [2]
    2. Configuration device according to preceding claim 1, wherein the file is configured to retrieve remote firmware update information from a remote provider based at least in part on the issuer identifier. receiver, wherein the file is further configured to, upon receipt of a selection of a firmware update option via the user computing device, download selection data including the corresponding firmware update from the remote provider through the user computing device on the configuration device.
    [3]
    3. Configuration device according to preceding claim 2, in which the configuration device comprises a device identifier, in which the configuration device is configured to generate an authentication key based at least in part on the identifier of the device. device,
    Da> BE2020 / 5148 of the transceiver identifier, possibly a user identifier, and possibly a time stamp.
    [4]
    4. Configuration device according to any one of the preceding claims 2 and 3, wherein! the configuration device comprises a decryption key and a device identifier, wherein said downloaded firmware update is an encrypted firmware update based at least in part on the device identifier, wherein the configuration device is configured to decrypt the encrypted firmware update downloaded via the decryption key, thereby obtaining the firmware update.
    [5]
    The configuration device according to any one of the preceding claims, wherein the configuration device comprises a tangible, non-transient, computer-readable storage medium comprising one or more firmware updates, wherein the file comprises data. local firmware update information.
    [6]
    The configuration device according to the preceding claim 5, wherein the file is configured to, upon receipt of a selection of a firmware update option via the user computing device, forward, via the port. , selection data on the selection of the firmware update option, to the configuration device.
    [7]
    A configuration device according to any preceding claim, wherein the file is configured to display an indication of the firmware present in the memory of the optical transceiver.
    [8]
    A configuration device according to any preceding claim, wherein the file is configured to retrieve previous firmware installation data from a remote vendor and to display previous firmware installation data through the. user computing device.
    [9]
    9. A configuration device according to any one of the preceding claims, wherein the file is configured to retrieve previous digital diagnostic monitoring data from a remote provider BE2020 / 5148 and to display the diagnostic monitoring data. previous digital data via the user's computing device.
    [10]
    10. A configuration device according to any preceding claim, wherein the configuration device is configured to obtain digital diagnostic monitoring data from the optical transceiver and to send the digital diagnostic monitoring data. from the configuration device to a remote provider via the user computing device.
    [11]
    11. Configuration device according to claim 1, in which the file is an html file.
    [12]
    A configuration device according to any preceding claim, wherein the socket is configured for SFP, QSFP or XFP form factors.
    [13]
    13. A configuration device according to any preceding claim, wherein the port is a male or female USB port, preferably a female USB port, more preferably a female micro-USB port.
    [14]
    14. A configurator according to any preceding claim, wherein the configurator comprises a longitudinal direction, wherein the configurator is elongated in the longitudinal direction, wherein the plug and port are positioned in the direction. longitudinal at opposite outer ends of the configuration device, preferably in which the plug and port are configured for insertion in the longitudinal direction.
    [15]
    15. Configuration device according to the preceding claim 14, in which the configuration device comprises a middle part between the outer ends, wherein the middle part comprises a median perimeter perpendicular to the longitudinal direction, in which each of the outer ends comprises a perimeter perpendicular to the longitudinal direction which is greater than the median perimeter.
    > BE2020 / 5148
    [16]
    16. A configurator according to any one of the preceding claims 14 and 15, wherein the configurator comprises an overall length in the longitudinal direction of at most 12 cm, preferably at most 10 cm, more preferably d. 'at most 8 cm.
    [17]
    A configuration device according to any one of the preceding claims 14 to 16, wherein the configuration device comprises a printed circuit board, in which the socket and the port are fixed to the printed circuit board, in which the device The configuration includes an outer housing configured to contain the printed circuit board in a fixed relative position without screws.
    [18]
    18. An optical transceiver configuration system, comprising a configuration device according to any one of the preceding claims, wherein the system further comprises a remote provider comprising a plurality of firmware updates, in which the provider is referred. remote is configured to send a firmware update through a user computing device to the configuration device.
    [19]
    19. System according to the preceding claim 18, comprising a configuration device according to the preceding claim 2, in which the remote provider comprises a history log, in which the remote provider is configured to add an update event to the log. 'history including the transceiver identifier, an indication of the firmware update and time information, preferably when sending the selection data including the firmware update to the configuration device via the user computing device.
    [20]
    20. The system of preceding claim 19, wherein the history log includes a diagnostic event comprising a transceiver identifier, digital diagnostic monitoring data, and timing information.
    [21]
    21.5 System according to the preceding claim 20, comprising a configuration device according to the preceding claim 10, in which the remote provider is configured to add a diagnostic event to this BE2020 / 5148 to the history log comprising the transmitter identifier. receiver, received digital diagnostic monitoring data and time information.
    [22]
    22, System according to any one of the preceding claims 18 to 21, comprising a configuration device according to the preceding claim 4, in which the remote provider comprises an encryption key associated with the device identifier, preferably in the current key. decryption and encryption are complementary keys of an asymmetric key pair, in which the remote provider is configured to encrypt a firmware update through the encryption key associated with the device ID, thereby obtaining the update. encrypted firmware update.
    [23]
    # 3. An optical transceiver configuration kit comprising: - a first configuration device according to any one of the preceding claims 1 to 17, in which the first configuration device comprises an optical transceiver socket, the socket being configured for SEP form factors; - a second configuration device according to any one of the preceding claims 1 to 17, in which the second configuration device comprises an optical transceiver socket, the socket being configured for GSFP form factors; - a third configuration device according to any one of the preceding claims 1 to 17, wherein the third configuration device comprises an optical transceiver socket, the socket being configured for XEP form factors.
    [24]
    24. Configuration device for the configuration of an optical transceiver, comprising a first housing, a second housing and a connection means between the first housing and the second housing; wherein the first housing includes an optical transceiver socket: wherein the second housing includes a data communications port, the port being configured to communicate with a user computing device; wherein the connecting means allows communication between the first box and the second box.
    an> BE2020 / 5148
    [25]
    25. The configuration device of claim 24, wherein the outlet is configured for any one, and preferably more than one, SFP, QSFP and XFP form factors.
    [26]
    26. A configuration device according to any one of claims 24 and 25, wherein the data communication port is a male USB connector.
    [27]
    27. A configuration device according to any one of claims 24 to 26, wherein the connecting means is a data cable.
    [28]
    28. A configuration device according to any one of claims 1 to 17 and according to any one of claims 24 to 27.
    [29]
    29. A configuration device for configuring an optical transceiver, comprising a housing, an optical transceiver jack, and at least one data communication port; wherein the data communication port is configured to communicate with a user computing device, wherein the data communication port is rigidly connected with respect to the housing.
    [30]
    30. A configuration device according to claim 29, wherein the device comprises a transceiver direction for inserting an optical transceiver into the optical transceiver socket, wherein the communication port of data protrudes from the housing in a direction substantially perpendicular to the transceiver direction.
    [31]
    31. A configuration device according to any one of claims 23 and 30, wherein the data communication port is rigidly attached to the housing.
    a BE2020 / 5148
    [32]
    32. A configuration device according to any one of claims 29 to 31, wherein! the data communication port is a male USB connector, preferably a micro USB connector.
    [33]
    33. A configuration device according to any one of claims 29 to 32, wherein the socket is configured for any one, and preferably more than one, SFP, QSFP and XFP form factors.
    [34]
    34. A configuration device according to any one of claims 29 to 33, further comprising one or more data communication ports.
    [35]
    35. A configuration device according to any one of claims 29 to 34, wherein the data communication port is removably connected to the second housing, preferably wherein said communication port is one of: a USB connector -A male, a male USB-B connector, a male USB-C connector, a male mini-USB connector, a male micro-USB connector, a male USB 3 connector, a male Lightning® connector, or a male THUNDERBOLT® connector.
    [36]
    36. A configuration device according to claim 35, wherein the removable data communication port comprises a magnetic connection surface capable of removably connecting with a complementary magnetic receiving surface provided on the second housing.
    [37]
    37. A configuration device according to any one of claims 1 to 17 and according to any one of claims 29 to 36.
    类似技术:
    公开号 | 公开日 | 专利标题
    EP2487452B1|2014-01-08|Instrument for measuring dimensions with an interface, and corresponding interface
    BE1027089B1|2021-02-26|OPTICAL TRANSCEIVER CONFIGURATION DEVICE, SYSTEM AND KIT
    EP2193626A2|2010-06-09|Secure communication between an electronic label and a reader
    WO2015049180A1|2015-04-09|Accessory for mobile apparatus comprising means of communication by luminous signals of li-fi type
    FR3011373A1|2015-04-03|PORTABLE LISTENING TERMINAL HIGH PERSONALIZED HARDNESS
    EP2795475B1|2016-01-20|Data exchange and storage device
    FR2948797A1|2011-02-04|MOBILE TELEPHONY AND NFC COMMUNICATION
    EP2813088A1|2014-12-17|System for reading digital content and corresponding method of reading
    WO2016016283A1|2016-02-04|Management unit for a communication device
    FR2994048A1|2014-01-31|Method for personalization of e.g. SIM card placed in mobile phone or sales package in shop, involves transmitting subscription profile from personalization device to module, and not providing communication unit in contact with near field
    EP2602956A1|2013-06-12|Method for customising a security element engaging with a telecommunications terminal and corresponding system
    EP3016172B1|2019-06-12|Portable power-supply device
    FR2976375A1|2012-12-14|Universal serial bus stick for data transmission, has connector unit allowing exchange of data frames between front universal serial bus male connector and rear universal serial bus female connector or encryption unit
    EP2073544A1|2009-06-24|System, portable object and terminal for decoding encoded audio and/or video data
    EP3526946A1|2019-08-21|Encryption method, decryption method, device and corresponding computer program
    EP3288153B1|2020-02-05|Electric supply for substitution by electric induction via a probe
    FR2976376A1|2012-12-14|USB ASSEMBLY WITH IMPROVED USB KEY
    WO2013029954A1|2013-03-07|Onboard system for supervising a machine from a portable terminal
    EP3663945A1|2020-06-10|Connectable electronic module comprising secured clusters of elements
    EP3813330A1|2021-04-28|Methods and devices for pairing
    FR3102322A1|2021-04-23|Communication technique between an application implementing a service and a server
    FR3112901A1|2022-01-28|Device for securing a connection of a connector end piece with an additional receiver of a mobile device
    FR3063408A1|2018-08-31|METHOD FOR ELECTRONIC COUPLING OF A MOBILE TERMINAL WITH A CONFIGURED HOUSING FOR RECEIVING THE MOBILE TERMINAL, DEVICE AND HOUSING THEREFOR
    WO2018130763A1|2018-07-19|Usb peripheral connected via wifi
    FR3093572A1|2020-09-11|PORTABLE, AUTONOMOUS AND SECURE MICRO SERVER FOR COLLABORATION BETWEEN DIFFERENT USERS
    同族专利:
    公开号 | 公开日
    WO2020177917A1|2020-09-10|
    BE1027087A1|2020-09-29|
    BE1027087B1|2020-10-05|
    BE1027089A1|2020-09-29|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20060093371A1|2004-10-29|2006-05-04|Hahin Jayne C|Transaction for transceiver firmware download|
    US20060147178A1|2004-12-30|2006-07-06|Ekkizogloy Luke M|Access key enabled update of an optical transceiver|
    WO2016081906A1|2014-11-20|2016-05-26|Oe Solutions America, Inc.|Method and apparatus for controlling, monitoring, and communicating with tunable optical devices and subassemblies|
    DE102016115546A1|2016-08-22|2018-02-22|Flexoptix GmbH|Transceiver interface, system with at least one transceiver interface and method with a transceiver interface|
    US7610494B2|2004-12-30|2009-10-27|Finisar Corporation|Encrypted microcode update of an optical transceiver|
    US8566643B2|2010-02-04|2013-10-22|Hubbell Incorporated|Small form factor pluggable checking device for reading from and determining type of inserted SFP transceiver module or other optical device|
    WO2015183182A1|2014-05-28|2015-12-03|Starview International Pte Ltd|Optical transceiver device and method|
    法律状态:
    2021-04-23| FG| Patent granted|Effective date: 20210226 |
    优先权:
    申请号 | 申请日 | 专利标题
    BE20195133A|BE1027087B1|2019-03-05|2019-03-05|OPTICAL TRANSCEIVER CONFIGURATION DEVICE, SYSTEM AND KIT|
    PCT/EP2019/087192|WO2020177917A1|2019-03-05|2019-12-31|Optical transceiver configuration device, system and kit|
    [返回顶部]