DE102024107112A1 - SFP transceiver module for sending and/or receiving an audio signal - Google Patents

Abstract

The invention relates to a small form factor pluggable (SFP) transceiver, SFP transceiver module (1) for transmitting an audio signal between a first electronic device (9) and a second electronic device (9) in at least one signal standard, wherein the SFP transceiver module has a housing (2) in which a first interface (6) for transmitting the audio signal from or to the first electronic device (9), a second interface (5) for transmitting the audio signal from or to the second electronic device (7), an electronic circuit (4) with line drivers, and an integrated circuit (11, 13) for signal conversion between the first (6) and second interface (9) are provided. The SFP transceiver module (1) is characterized in that the audio signal is converted from a first signal standard to a second signal standard between the first interface (6) and the second interface (9).

Description

The invention relates to a small form factor pluggable (SFP) transceiver module for transmitting an audio signal according to claim 1.

Such SFP transceiver modules are already known in a wide variety of designs and are used in the field of network technology and telecommunications in communication systems for the transmission and reception of data signals.

This reveals the DE 102010 001 679 A1 A small form factor pluggable (SFP) optical transceiver module and a method for conducting optical communications. The SFP optical transceiver module includes a transceiver module housing to which a duplex receptacle is attached. The duplex receptacle has a C-shaped opening formed therein for receiving a duplex optical plug to which first and second fiber optic cables are connected. The duplex receptacle has first and second optical ports configured to receive a first ferrule and a second ferrule from the first and second fiber optic cables, respectively. The housing of the optical transceiver module includes an electrical assembly including a printed circuit board, one end of which is configured as a plug end for connecting the printed circuit board to a receptacle of an external communications management system. The printed circuit board includes at least one active optical receive and transmit device. The optical receiving device is configured to generate an electrical data signal in response to a received optical data signal. The optical transmitting device is configured to generate an optical data signal in response to a received electrical data signal.

During signal transmission, SFP transceiver modules serve as converters between optical or electrical signals and differential electrical signals. SFP transceiver modules are equipped with appropriate interfaces or connector types to enable bidirectional conversion between an optical and an electrical signal. For example, an optical signal received by an SFP transceiver module via an LC (Lucent Connector) or an SC (Subscriber Connector) connector can be converted into an electrical signal, such as an LVDS signal, with voltage levels in the low-voltage range, such as a voltage swing of 350 mV at an absolute voltage of approximately 1200 mV, and transmitted by the SFP transceiver module. Likewise, an electrical signal can be converted into a differential electrical signal in an SFP transceiver module. The electrical signal can be input via a BNC (Bayonet Neill Concelman) connector or a so-called mini-BNC connector with a connected coaxial cable. The SFP transceiver module converts the electrical signal into a differential electrical signal.

SFP transceiver modules are increasingly being used to transmit audio signals. Audio signals generated according to the Multichannel Audio Digital Interface Standard (MADI), which is specified by the Audio Engineering Society as the AES10 standard, are fed into transceiver modules via an audio interface and output via an optical or electrical interface, such as a BNC connector. This involves only electrical signal conversion, but no protocol conversion of the signal. Signals generated according to the MADI (AES10) protocol are simply received by the SFP transceiver module via various interfaces or connectors and electrically converted for output via other interfaces or connectors. However, in order to then transmit the audio signals, for example, to networks or to external electronic devices such as computers for processing, a protocol conversion appropriate to the respective receivers is required.

For this purpose, appropriate electronic devices such as interface devices are used in the state of the art. These interface devices then receive a MADI-standardized audio signal via an optical (LC or SC) interface or an electrical (BNC) interface and convert the MADI-formatted audio signal either into an audio signal formatted according to the AES67 standard for transmission over networks or into a signal formatted according to the universal serial bus standard (Universal Serial Bus - USB). It is understood that signal transmission and conversion can be bidirectional, so that AES67-formatted signals received via a network, for example, can be converted into MADI-formatted signals by an interface component and output accordingly.

Transceiver modules are advantageous for bidirectional transmission of audio signals between host components such as digital format converters, mixing consoles, or digital routers and external devices such as computers or network environments. However, this requires additional devices to convert the signals into the signal standards that can be processed by the host components and external devices.

For example, matrix switchers, which are used to receive and forward signals from multiple audio/video sources such as microphones to multiple audio/video output devices, feature so-called SFP cages on the output side, into which the SFP transceiver modules with their connectors designed for transmitting LVDS signals can be easily inserted. Audio signals, such as MADI-formatted audio signals, are transmitted from a digital format converter or matrix switcher using the SFP transceiver module accommodated in the SFP cage via an optical SC or LC connector or as an electrical signal via a BNC connector to a corresponding separate interface device, where the desired format conversion takes place. In the corresponding interface component, a MADI-standardized audio signal can be converted into a USB-standardized signal or a signal formatted according to the AES67 standard. The signal can then be output via appropriate interfaces such as a USB or RJ45 interface or an RJ45 connector for transmission to a computer, as with the USB-standardized signal, or to a network access point, as with the AES67-formatted signal. This means that for transmission, i.e., receive transmission or transmit transmission, an external interface component is required outside the device acting as the host component, in addition to the inclusion of an SFP transceiver. This is complex to handle and also involves additional costs.

The invention therefore has the object of reducing the number of interfaces used in signal transmission and signal format conversion during transmission and/or reception of an audio signal formatted according to a first standard from a host component to an external application device which is designed to process and/or forward the audio signal in a second standard.

The problem is solved in each case starting from the features specified in the preamble of claim 1 with the characterising features of the same claim.

Accordingly, the invention provides a small form factor pluggable (SFP) transceiver module for transmitting an audio signal between a first electronic device and a second electronic device. The SFP transceiver module has a housing in which a first interface for transmitting the audio signal from or to the first electronic device, a second interface for transmitting the audio signal to or from the second electronic device, an electronic circuit with line drivers, and an integrated circuit for signal conversion or signal adaptation between the first interface and the second interface are provided. The audio signal is transmitted in at least one signal standard.

The transceiver module is characterized in that the SFP transceiver module is designed to convert the audio signal between the first interface and the second interface between a first and a second signal standard or from a first signal standard to a second signal standard and vice versa.

According to the invention, the format conversion or conversion of a bidirectionally transmitted audio signal between two different signal standards and the adaptation of the signal to different input/output interfaces takes place in a single digital signal processing element. Thus, according to the invention, an audio format converter is integrated into an SFP transceiver module. The SFP transceiver module according to the invention performs the signal conversion function of an audio interface.

The invention offers the advantage that bidirectional transmission of an audio signal, including signal format conversion and transmission of the signal via two different interfaces, is significantly simplified by using only one element. A further advantage is the avoidance of signal interference introduced by the eliminated interfaces and the prevention of additional error sources such as poor optical or electrical connections.

Further advantages arise from the subclaims.

One embodiment of the SFP transceiver module according to the invention is characterized by a programmable logic gate array (FPGA) for converting the audio signal between the first and second signal standards, or for converting the audio signal from the first to the second signal standard and vice versa. Thus, a signal received or to be transmitted via the first interface according to the first standard can be converted or converted into a signal constructed according to the second signal standard and to be transmitted or received via the second interface.

In another embodiment of the SFP transceiver module according to the invention, the The first interface is designed as an interface transmitting a low-voltage differential signal (LVDS). Since such an interface is widely used in digital audio technology, the possible applications of the SFP transceiver according to the invention are extensive.

Preferably, the first interface in the SFP transceiver module according to the invention is designed to transmit audio signals formed according to the digital multi-channel audio interface (MADI) protocol (AES10 protocol). The MADI (AES10) protocol is widely used in audio electronics and audio signal transmission technology and allows the transmission of large amounts of data with 64 channels.

In a preferred embodiment of the SFP transceiver module according to the invention, the second interface is an interface designed according to the universal serial bus standard - Universal Serial Bus (USB). This advantageously enables the SFP transceiver according to the invention to be connected to a wide variety of different electronic devices, such as computers, signal processing, and transmission devices.

In a particularly preferred embodiment of the SFP transceiver module according to the invention, the second interface is designed as a USB-C interface. This enables the SFP transceiver according to the invention to connect to the interface standard that is currently becoming increasingly widespread in the fields of computer technology and telecommunications.

In an alternative embodiment of the SFP transceiver module according to the invention, the second interface is designed as an RJ45 interface. This enables the SFP transceiver module according to the invention to be connected to the interface prevalent in telephone and network technology.

Preferably, the second interface of the SFP transceiver module according to the invention is designed for transmitting audio signals according to the AES67 standard. The AES67 standard provides direct access to the network world with data transmission protocols such as the "Transmission Control Protocol/Internet Protocol" TCP/IP or, in the area of wired networks, the Ethernet protocols, and facilitates the transmission of audio signals according to common network protocols.

Furthermore, the second interface can also be configured to transmit audio signals according to the AES67-compatible RAVENNA standard. This provides access to a standard with a bidirectional data transmission volume twenty-four times greater than the MADI standard.

As an alternative to transmitting audio signals according to the AES67 standard, the second interface can be designed to transmit audio signals according to the Audio Video Bridging (AVB) standard and/or the Media-integrated local network (MILAN) standard.

In a further embodiment of the SFP transceiver according to the invention, the second interface is designed to transmit audio signals according to the Digital Audio Network Through Ethernet (DANTE) standard.

Advantageously, the SFP transceiver module according to the invention is electrically powered by the first electronic device via the first interface. This simplifies the use of the SFP transceiver module because no external power supply is required.

In a particularly preferred embodiment of the SFP transceiver module according to the invention, the first interface is intended for connecting the SFP transceiver module to an SFP cage of a host component, and the second interface is intended for connecting the SFP transceiver module to an electronic device, such as a computer. By accommodating the first interface in an SFP cage of the host component, this is then referred to in technical circles as an internal interface, and the second interface as an external interface for connecting to an external device.

• Figur eine Ausführungsform eines erfindungsgemäßen SFP-Transceivermoduls.

The invention is explained in more detail below using a non-limiting embodiment in conjunction with an accompanying drawing, some of which is highly simplified and not to scale. It shows:

• Figure shows an embodiment of an SFP transceiver module according to the invention.

An SFP transceiver module according to the invention, identified in the figure as a whole by reference numeral 1, has a substantially rectangular housing 2 that corresponds to the usual specification INF-8074i for such modules. Accordingly, the SFP transceiver module 1 can be plugged into a so-called SFP cage 4, which is mounted in a connection section of a host component 5 as the first electronic device is provided. The first electronic device can be embodied as a digital format converter or a digital crossbar and the like. At a first longitudinal end of the housing 2a, a first interface 6 is provided, which is designed to transmit LVDS signals and is referred to below as an LVDS connector. At a second longitudinal end 2b of the SFP transceiver module 1, opposite the first longitudinal end 2a, a second interface embodied as a USB-C socket 9 is provided on a printed circuit board 7 (PCB). The LVDS connector 6 is also an integral part of the printed circuit board 7. A computer 11, for example, can be connected to the USB-C socket 9 via a corresponding USB cable 10 for further processing and/or forwarding the signal sent by the SFP transceiver module 1.

After the SFP transceiver module 1 has been preferably inserted into the SFP cage 4 (shown only very schematically) of the first electronic device embodied as the host component 5, an audio signal formatted according to a first signal standard embodied as the MADI (AES10) standard is input into the SFP transceiver module 1 via the first interface, embodied as an LVDS connector 6. The audio signal formatted according to a first signal standard is converted or converted in the SFP transceiver module 1 into an audio signal formatted according to a second signal standard embodied as the USB signal standard. The signal is sent from the SFP transceiver module 1 in the second signal standard via the USB cable 10 to the computer 11.

The SFP transceiver module 1 is designed for bidirectional transmission and reception. Accordingly, the signal transmission between the computer 11 and the host component 5 can occur in the opposite direction to the one just described.

A programmable logic gate array (FPGA) 12 is provided on the circuit board 7 to convert the USB signal to be sent or received by the SFP transceiver module 1 via the USB-C socket 9 into a signal formatted according to the MADI (AES10) protocol, to be received or output via the LVDS connector 6. Furthermore, an integrated circuit 14 is configured for encoding or decoding the signal in the USB-C standard. In addition, the electrical circuit board 7 includes line drivers and a voltage regulator for generating the required supply voltages from the voltage signal present at the cage 4 of the host component 5.

In a further embodiment of the SFP transceiver module according to the invention (not shown), an RJ45 socket is provided instead of the USB-C socket 9, via which a network cable can be connected, thus enabling a connection of the SFP transceiver module to a network and the network devices connected to it. In this embodiment of the SFP transceiver module according to the invention, a programmable logic gate array (FPGA) for converting or converting a network transmission signal constructed according to the AES67 standard, to be received or transmitted via the RJ45 socket, into a signal constructed according to the MADI (AES10) standard is provided on the circuit board 7 instead of the USB-FPGA. Likewise, the integrated circuit 14 for adapting the signal between the LVDS connector 6 and the USB-C interface 9 is replaced by an integrated circuit for adapting or converting the signal between the LVDS connector 6 and the RJ45 socket. It goes without saying that the circuit board 7 as a whole is adapted to the corresponding signal format conversion. Thus, the line drivers according to the SFP transceiver module 1 must also be adapted to the corresponding signal format conversion.

In a further embodiment of the SFP transceiver module according to the invention, which is also not illustrated in the drawing, the USB socket 9 of the SFP transceiver module 1 is replaced as a second interface by an interface for transmitting audio signals according to the RAVENNA standard.

In yet another embodiment of the SFP transceiver module according to the invention, the second interface is an interface suitable for transmitting audio signals according to the Audio Video Bridging (AVB) standard.

Yet another embodiment of the inventive SFP transceiver module has a second interface via which Media-Integrated Local Network (MILAN)-standardized signals can be received and transmitted. The first interface of the embodiments of the inventive SFP transceiver module not shown is, as in the illustrated embodiment, designed as an LVDS connector, via which MADI (AES10)-standardized audio signals can be transmitted or received.

In a further embodiment of the SFP transceiver module according to the invention, which is also not illustrated in the drawing, the USB socket 9 of the SFP transceiver module 1 can be replaced as a second interface by an interface to Transmission of audio signals according to the network-based SoundGrid protocol from Waves.

Finally, the second interface of the SFP transceiver module can be designed to transmit audio signals according to the Digital Audio Network Through Ethernet (DANTE) standard.

It is understood that in the latter embodiments of the SFP transceiver module according to the invention, the integrated circuits for adapting or converting the signal between the LVDS connector 6 and the respective second interface are adapted accordingly. Likewise, a programmable logic gate array (FPGA) for converting a MADI (AES10) signal into a RAVENNA, AVB, MILAN, SoundGrid, and/or DANTE signal is provided. Likewise, the line drivers and the like are selected to match the respective required signal format conversions.

LIST OF REFERENCE SYMBOLS (part of the description)

1

SFP transceiver module

2

Housing

2a

first longitudinal end of the housing 2

2b

second longitudinal end of the housing 2

4

electronic circuit

5

first electronic device

6

first interface

7

printed circuit board

9

second interface

10

USB cable

11

second electronic device

12

programmable logic gate arrangement

14

integrated circuit

QUOTES CONTAINED IN THE DESCRIPTION

This list of documents submitted by the applicant was generated automatically and is included solely for the convenience of the reader. This list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010 001 679 A1 [0003]

Claims (12)

Small form factor transceiver module (1) - small form factor pluggable (SFP) transceiver, SFP transceiver module (1) - for transmitting an audio signal between a first electronic device (5) and a second electronic device (11) in at least one signal standard, comprising a housing (2) in which a first interface (6) for transmitting the audio signal from or to the first electronic device (9), a second interface (9) for transmitting the audio signal to or from the second electronic device (11), an electronic circuit (4) with line drivers and an integrated circuit (14) for signal conversion between the first interface (6) and the second interface (9) are provided, characterized in that the SFP transceiver module (1) is designed to convert the audio signal between the first interface (6) and the second interface (9) between a first signal standard and a second signal standard. SFP transceiver module (1) to Claim 1 , characterized by a programmable logic gate arrangement (12) - Field-Programmable Gate Array (FPGA) - for converting the audio signal between the first and second signal standards. SFP transceiver module (1) to Claim 1 or 2 , characterized in that the first interface (6) is designed as an interface transmitting a differential low-voltage signal - Low Voltage Differential Signal (LVDS). SFP transceiver module (1) according to one of the Claims 1 until 3 , characterized in that the first interface (6) is designed to transmit audio signals formed according to the digital multi-channel audio interface - Multi-channel Audio Digital Interface (MADI) - protocol, AES10 protocol). SFP transceiver module (1) according to one of the Claims 1 until 4 , characterized in that the second interface (9) is designed as an interface transmitting a signal formatted according to the universal serial bus standard - Universal Serial Bus (USB). SFP transceiver module (1) according to one of the Claims 1 until 4 , characterized in that the second interface is designed as an RJ45 interface. SFP transceiver module (1) according to one of the Claims 1 until 4 and 6 , characterized in that the second interface is designed to transmit audio signals formatted according to the AES67 standard. SFP transceiver module (1) according to one of the Claims 1 until 4 , 6 and 7 , characterized in that the second interface is designed to transmit audio signals according to the RAVENNA standard. SFP transceiver module (1) according to one of the Claims 1 until 4 , characterized in that the second interface is designed to transmit audio signals according to the Audio Video Bridging (AVB) standard. SFP transceiver module (1) according to one of the Claims 1 until 4 , characterized in that the second interface is designed to transmit audio signals according to the Media-integrated local network (MILAN) standard. SFP transceiver module (1) according to one of the Claims 1 until 4 , characterized in that the second interface is designed to transmit audio signals according to the Digital Audio Network Through Ethernet (DANTE) standard. SFP transceiver module (1) according to one of the Claims 1 until 11 , characterized in that the SFP transceiver module (1) is electrically supplied by the first electronic device (5) via the first interface (6).