FR3071686A1 - METHOD OF PROCESSING BY A RADIOCOMMUNICATION DEVICE OF A FRAME THAT COMPLIES WITH A BOND LAYER OF THE OSI MODEL - Google Patents

Abstract

The invention relates to a method for processing, by a radio communication device (1), a frame conforming to a link layer of the OSI model, the frame containing useful data, the method comprising a generation (110) from the frame of a radio signal conveying the useful data, in which the radio communication device (1) does not de-encapsulate the frame when the radiocommunication device (1) is not a recipient of the useful data.

Description

FIELD OF THE INVENTION

The present invention relates to a frame processing method and a radio communication device 1 adapted to implement this method.

STATE OF THE ART

A radiocommunication device comprising a protocol stack and a generator of radio signals is known from the state of the art.

In such a device, the protocol stack implemented by the processor is a program which is configured to systematically decapsulate any frame conforming to a link layer having level 2 in the OSI model which it receives, in order to extract from the frame a Protocol Data Unit (PDU) conforming to a layer of the OSI model higher than the link layer.

This extracted protocol data unit is for example a packet conforming to a network layer (level 3 in the OSI model), typically an IP packet; a de-encapsulation is then implemented from the frame received by the device.

This PDU can also be a message or segment in the sense of a transport layer (level 4 in the OSI model), typically a UDP datagram; several de-encapsulations are then implemented successively to recover this message or segment from the frame.

This PDU may ultimately be the payload itself, which may relate to an even higher level layer. An even higher number of decapsulations is then implemented to extract the useful data from the frame received.

The protocol stack then implements at least one re-encapsulation of the PDU in a second frame (the number of encapsulations being identical to the number of de-encapsulations previously implemented by the protocol stack). The radio signal is then generated based on this second frame.

However, these de-encapsulation and then re-encapsulation treatments implemented by the protocol stack are costly in terms of hardware resources.

STATEMENT OF THE INVENTION

An object of the invention is to reduce the material resources used to produce a radio signal from a frame.

This object is achieved by a method of processing, implemented by a radiocommunication device, a frame conforming to a link layer of the OSI model, the frame containing useful data, the method comprising a generation from the frame. a radio signal transporting the useful data, characterized in that the radiocommunication device does not encapsulate the frame when the radiocommunication device is not the recipient of the useful data.

The method may also include the following optional features taken alone or in combination when technically possible.

The method may further comprise decapsulating the frame so as to extract the useful data therefrom, when the radiocommunication device 1 is the recipient of the useful data.

The method may further comprise a reading in the frame a MAC address indicative of a device receiving the useful data, and a comparison of the MAC address read in the frame with a MAC address specific to the radiocommunication device. The decapsulation step is then implemented only when the MAC address read and the MAC address specific to the radiocommunication device are identical.

The method can also comprise a comparison of the MAC address read in the frame with a list of MAC addresses of network equipment with which the radiocommunication device is intended to communicate by radio, the step of generating the radio signal being then implemented only when the MAC address is in the list.

The method can moreover comprise an encapsulation of the frame conforming to the link layer of the OSI model in a radio frame comprising a header, the header comprising a synchronization field allowing the location of the start of the radio frame and / or a length of the frame, the radio signal carrying the radio message.

The frame conforming to the link layer of the OSI model can be a Type II Ethernet frame.

A second aspect of the invention is also proposed, a radiocommunication device comprising:

• an interface for receiving a frame conforming to a link layer of the OSI model, the frame containing useful data previously encapsulated in the frame, • a radio signal generator configured to generate a radio signal containing the useful data from the frame, • at least one processor configured to execute a protocol stack, in which the protocol stack is configured not to encapsulate the frame when the radiocommunication device is not the recipient of the useful data.

The protocol stack can be configured to decapsulate the frame so as to extract the useful data therefrom, when the radiocommunication device is receiving the useful data.

The protocol stack can also be configured for:

• read in the frame a MAC address indicative of a device receiving useful data, and • compare the MAC address read in the frame with a MAC address specific to the radiocommunication device, the de-encapsulation step being implemented only when the MAC address read and the MAC address specific to the radiocommunication device are identical, and / or • compare the MAC address read in the frame with a list of MAC addresses of network equipment with which the radiocommunication device is intended to communicate by radio, the radio signal being generated by the radio signal generator only when the MAC address is in the list.

DESCRIPTION OF THE FIGURES

Other characteristics, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and not limiting, and which should be read with reference to the appended drawings in which:

• Figure 1 schematically shows a radiocommunication device according to an embodiment of the invention.

• Figure 2 is a flow diagram of steps of a frame processing method according to an embodiment of the invention.

In all of the figures, similar elements bear identical references.

DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION

With reference to FIG. 1, a radiocommunication device 1 comprises an interface 2 for receiving useful data, at least one memory 4, at least one processor 6, and a generator 8 of radio signals.

The radiocommunication device 1 is for example intended to be on board an aircraft, and to act as an interface between a local network of the aircraft and a radio communication network between the aircraft and a ground station.

The data reception interface 2 is configured to receive frames, these frames belonging to the link layer of the OSI model (level 2 layer).

The reception interface 2 can thus be an Ethernet interface, comprising at least one input port in RJ45 format.

The memory 4 comprises at least one (volatile) buffer memory is configured to temporarily store data received via the input interface and / or produced by the processor 6. The buffer memory is for example of RAM type.

The memory 4 also comprises at least one non-volatile memory for storing data persistently (HDD, SSD, Flash, etc.).

The radiocommunication device 1 has its own MAC address. This MAC address makes it possible to identify the radiocommunication device 1 as a receiver of frames in a network (typically the local network of the aircraft in which the device 1 is on board). The MAC address of the radiocommunication device 1 is stored in the non-volatile memory.

A list of predetermined MAC addresses (different from the MAC address of the radiocommunication device 1) is also stored in the non-volatile memory. These predetermined MAC addresses are those of network equipment known in advance authorized to receive directly or indirectly by radio useful data from the radiocommunication device 1.

The processor 6 is configured to execute an operating system allowing the timing of software tasks in real time.

The operating system includes a network communication protocol stack, which is configured to implement encapsulations and de-encapsulations of protocol data units (PDUs). The protocol stack uses the OSI model.

The protocol stack is in particular configured to process frames received by the input interface of the radiocommunication device 1 or stored in the buffer memory 4.

The protocol stack is configured to be able to read the MAC addresses stored in the non-volatile memory.

The operating system also includes (or cooperates with) other application programs, such as a web server.

The signal generator 8 is configured to be able to process data supplied by the protocol stack.

The signal generator 8 comprises for example an antenna for transmitting radio signals.

With reference to the flowchart represented in FIG. 2, the radiocommunication device 1 implements a method comprising the following steps, when a frame, that is to say a protocol data unit conforming to a link layer (level 2 in the OSI model), is received by the input interface 2.

The frame is for example a type II Ethernet frame, the length of which ranges from 60 to 1518 bytes.

In a manner known in itself, the frame contains a header and useful data encapsulated in the frame. This payload is a protocol data unit conforming to a layer of level 3 or higher, typically at least one IP packet itself comprising at least one UDP datagram.

The header of the received frame contains a MAC address indicative of a device receiving the frame, hereinafter simply referred to as the destination MAC address.

The protocol stack reads the header of the frame (step 102) and more precisely the destination MAC address.

The protocol stack compares the destination MAC address with the addresses stored in the non-volatile memory (step 104).

In particular, the protocol stack compares during step 104 the destination MAC address with the MAC address of the radiocommunication device 1.

If the destination MAC address and the MAC address of the radiocommunication device 1 are identical, the radiocommunication device 1 itself is the recipient of the useful data. In this case, the protocol stack implements a de-encapsulation of the frame or a series of de-encapsulations on the basis of the frame, so as to extract the useful data contained in the frame (step 106). By way of example, this useful data can be intended to be used by one of the applications executed by the communication device 1, such as the web server.

If the destination MAC address and the MAC address of the radiocommunication device 1 are different, the protocol stack does not de-encapsulate the Ethernet frame or subsequent re-encapsulation to obtain an Ethernet frame again. In fact, the useful data is not intended to be used by the radiocommunication device 1 in this case. This saves unnecessary processing within the radiocommunication device 1.

Furthermore, during step 104, the protocol stack compares the destination MAC address with a list of predetermined MAC addresses (different from the MAC address of the radiocommunication device 1). These predetermined MAC addresses are those of network equipment known in advance authorized to receive directly or indirectly by radio useful data from the radiocommunication device 1.

If the MAC address contained in the frame is not found in the list, the frame is not processed, but discarded.

If the MAC address contained in the frame is found in the list, the protocol stack in this case encapsulates the frame in a radio frame comprising a radio header (step 108). This is the only encapsulation implemented by the protocol stack if the destination MAC address and the MAC address of the radiocommunication device 1 are different.

The radio header includes a synchronization field for locating the start of the radio frame.

The radio header also comprises a length of the frame which has been received by the reception interface 2 and then encapsulated in the radio frame. Adding this length information to the radio header is advantageous because it is not always available at the same position in an Ethernet frame due to the different protocols that can be supported.

In an exemplary embodiment, the radio header is 10 bytes, the synchronization field is 8 bytes and the length of the Ethernet frame is coded on 2 bytes. Consequently, the radio frame obtained at the end of the encapsulation step has a length ranging from 70 to 1528 bytes.

The protocol stack then transmits the radio message to the signal generator 8.

The signal generator 8 generates a radio signal carrying the radio signal it has received (step 110).

When the radiocommunication device 1 is on board an aircraft, the radio signal is for example transmitted by the antenna, with the aim of being received by a ground station (step 112) whose MAC address is referenced in the list above.

Claims (10)

1. A method of processing, by a radiocommunication device (1), a frame conforming to a link layer of the OSI model, the frame containing useful data, the method comprising a generation (110) from the frame d 'a radio signal carrying the useful data, characterized in that the radiocommunication device (1) does not decapsulate the frame when the radiocommunication device (1) is not the recipient of the useful data. 2. Method according to claim 1, further comprising a de-encapsulation (106) of the frame so as to extract the useful data therefrom, when the radiocommunication device 1 is receiving the useful data. 3. Method according to claim 2, comprising steps of: • reading (102) in the frame of a MAC address indicative of a device receiving useful data, • comparison (104) of the MAC address read in the frame with a MAC address specific to the radiocommunication device (1), the decapsulation step being implemented only when the MAC address read and the MAC address specific to the radiocommunication device are identical. 4. Method according to one of claims 1 to 3, further comprising the steps of: • reading (102) in the frame of a MAC address indicative of a device receiving useful data, • comparison (104) of the MAC address read in the frame with a list of MAC addresses of network equipment with which the radiocommunication device is intended to communicate by radio, the step of generating the radio signal being implemented only when the MAC address is in the list. 5. Method according to one of claims 1 to 4, comprising an encapsulation (108) of the frame conforming to the link layer of the OSI model in a radio frame comprising a header, the header comprising a synchronization field allowing identification from the start of the radio frame and / or a length of the frame, the radio signal carrying the radio message. 6. Method according to one of claims 1 to 5, wherein the frame conforming to the link layer of the OSI model is a type II Ethernet frame. 7. Radiocommunication device (1) comprising: • a reception interface (2) of a frame conforming to a link layer of the OSI model, the frame containing useful data previously encapsulated in the frame, • a radio signal generator (8) configured to generate a radio signal containing the useful data from the frame, • at least one processor (6) configured to execute a protocol stack, the radiocommunication device being characterized in that the protocol stack is configured not to encapsulate the frame when the radiocommunication device ( 1) is not the recipient of the useful data. 8. Device according to claim 7, in which the protocol stack is configured to decapsulate the frame so as to extract the useful data therefrom, when the radiocommunication device (1) is the recipient of the useful data. 9. Device according to claim 8, in which the protocol stack is configured for: • read in the frame a MAC address indicative of a device receiving useful data, and • compare the MAC address read in the frame with a MAC address specific to the radiocommunication device (1), the de-encapsulation step being implemented works only when the MAC address read and the MAC address specific to the radiocommunication device are identical. 10. Device according to one of claims 7 to 9, in which the protocol stack is configured for: • read in the frame a MAC address indicative of a device receiving useful data, • compare the MAC address read in the frame with a list of MAC addresses of network equipment with which the radiocommunication device is intended to communicate by radio, the radio signal being generated by the radio signal generator (8) only when the MAC address is in the list.