FR2968151A1 - Communication device, has management device including demultiplexer for receiving arbitration decision regarding selected query and transmitting decision to secondary communication modules - Google Patents

Abstract

The device (1.0) has a main communication module (1.1) including an arbitration module (1.4) for arbitrating requests transmitted through a communication channel. A management device (1.5) includes a control module for selecting one of the requests received from secondary communication modules (1.3, 2.2) based on priority information about the requests, and a multiplexer for transmitting the selected query and the priority information to the arbitration module. A demultiplexer receives an arbitration decision regarding the selected query and transmits the decision to the secondary modules. Independent claims are also included for the following: (1) a method for managing transmission over a communication channel (2) a computer program for managing transmission over a communication channel (3) a storage device storing a computer program for managing transmission over a communication channel.

Description

The present invention relates to a communication device comprising a main communication module and communication arbitration means on a communication channel, the arbitration means being intended to arbitrate transmission requests on said channel associated with priority information. respective and transmitted by the main module and a single secondary module. The present invention also relates to a transmission management method on a communication channel implemented in this communication device. The present invention also relates to a computer program for implementing the method and storage means storing such a computer program.

In the case where two communication technologies share the same frequency band, interference will occur during competitive transmission attempts on the communication channel. This is the case, for example, when WiFi (registered trademark) technology, based on the IEEE 802.11 specifications for the implementation of wireless local area digital networks, is simultaneously used, and ZigBee (registered trademark) technology, based on IEEE 802.15.4 wireless access control (Wireless Medium Access Control) and Physical Layer (Physical Layer) specifications for low-bit-rate wireless networks with personal dimensions (LR-WPAN or Low Rate Wireless Persona / Area Networks.

Even in the case where the frequency bands are different, interference can also occur due to their location within the same communication device. This is the case, for example, when both ZigBee (registered trademark) technology and General Packet Radio Service (GPRS) general packet radio service technology are used simultaneously.

The "IEEE 802.15.2: Coexistence of Wireless Persona / Area Networks with Other Wireless Devices Operating in Unlicensed Frequency Bands" published August 28, 2003, discusses the management of interference between communication technologies according to IEEE 802.11 specifications and specifications. IEEE 802.15.1 for wireless and physical layer access control for personal wireless networks (WPAN or Wireless Persona / Area Networks), such as Bluetooth (registered trademark) technology. The IEEE 802.15.2 document then proposes a Packet Traffic Arbitration (PTA) packet traffic arbitration mechanism between the technologies according to the IEEE 802.11 specifications and the IEEE 802.15.1 specifications. On this basis, the manufacturers of components conforming to these specifications have developed a mechanism for arbitration of transmissions on the communication channel called "3-wire" (or 3-wire in French). This mechanism defines a main communication module, compliant with IEEE 802.11 specifications, and a secondary communication module, compliant with IEEE 802.15.1 specifications. The secondary module signals to the main module its will to transmit on the communication channel. To do this, the secondary module transmits on a first wire a transmission request on the communication channel, and priority information associated with this request on a second wire. The main module then arbitrates between this request and its own transmission requirements on the communication channel, according to the priority information provided by the secondary module. The main module then transmits its decision to the first module via a third wire. It is from this principle that the term 3-wire is derived. Additional information can be exchanged between the secondary module and the main module. This is called the n-wire mechanism, where n is the number of threads needed to implement the mechanism. However, these communication arbitration mechanisms on the communication channel only work to manage two competing communication modules. However, many components with this limitation are now available on the shelf. In addition, these communication arbitration mechanisms on the communication channel manage only the transmission conflicts on the communication channel by communication modules within the same device. Attempts to transmit over the communication channel by remote devices are not taken into account, and interference may occur. It is desirable to overcome these various disadvantages of the state of the art. In particular, it is desirable to provide a solution that makes it possible to manage transmission conflicts on the communication channel by a greater number of communication modules within the same device, while ensuring operational compatibility with the available components on the same device. shelf, such as for example the components implementing the 3-wire mechanism. It is particularly desirable to provide such a solution which also makes it possible to manage transmission conflicts on the communication channel between remote communication devices.

The invention relates to a communication device comprising a main communication module and communication arbitration means on a communication channel, said arbitration means being intended to arbitrate transmission requests on said channel associated with priority information. respective and transmitted by said main module and a single secondary communication module, the communication device being such that it comprises a plurality of secondary communication modules and a priority access management device to said channel comprising: - means of receiving, from said secondary communication modules, transmission requests on the communication channel associated with respective priority information; means for selecting one of the requests received competitively by the reception means, as a function of their priority information; Means for transmitting to said arbitration means the selected request and the associated priority information; means for receiving, from said arbitration means, an arbitration decision as to the selected request and for transmitting said arbitration decision to the secondary module having transmitted said selected request. Thus, it is possible to manage transmission conflicts on the communication channel by more than two communication modules within the same device, while ensuring operational compatibility with the components available on the shelf. According to a particular embodiment, said arbitration means are included in the same integrated circuit as the main communication module. According to a particular embodiment, the management device further comprises means for transmitting, to each secondary module having transmitted a request other than the selected request, a transmission refusal information on the communication channel. Thus, it is possible to use a shelf component integrating both an interface with the communication channel and the arbitration means, such as a 3-wire compatible WLAN component. According to a particular embodiment, the communication device comprises a processor comprising means for emulating the behavior of a secondary communication module, on the basis of information relating to communications implemented by at least one external device communication device. Thus, it is possible to manage transmission conflicts on the communication channel between remote communication devices. According to a particular embodiment, a first of the secondary communication modules comprises a Zigbee-type communication interface and a second one of the secondary communication modules comprises a Bluetooth-type communication interface. According to a particular embodiment, one of the secondary communication modules comprises a Zigbee type communication interface, and said priority management device is included in the same integrated circuit as this secondary communication module. The invention also relates to a transmission management method on a communication channel, implemented in a communication device comprising a main communication module and communication arbitration means on a communication channel, said arbitration means being intended to arbitrate transmission requests on said channel associated with respective priority information and transmitted by said main module and a single secondary communication module, the communication device comprising a plurality of secondary communication modules and a communication management device; access priority to said channel, the method being such that said management device performs the following steps of: receiving, from said secondary communication modules, transmission requests on the communication channel associated with respective priority information; selecting one of the requests received competitively by the reception means, according to their priority information. transmitting to said arbitration means the selected request and the associated priority information; receiving, on behalf of said arbitration means, an arbitration decision concerning the selected request; and - transmitting said arbitration decision to the secondary module having transmitted said selected request. The invention also relates to a computer program, which can be stored on a medium and / or downloaded from a communication network, in order to be read by a computer system or a processor. This computer program includes instructions for implementing the method mentioned above, when said program is executed by a computer system or a processor. The invention also relates to storage means comprising such a computer program. The characteristics of the invention mentioned above, as well as others, will emerge more clearly on reading the following description of an exemplary embodiment, said description being given in relation to the attached drawings, among which: Fig. 1 schematically illustrates a communication device, according to a first embodiment; FIG. 2 schematically illustrates a communication device, according to a second embodiment; FIG. 3 schematically illustrates a first embodiment of priority management device of the communication device; FIG. 4 schematically illustrates a second embodiment of priority management device of the communication device; FIG. 5 schematically illustrates an algorithm implemented by the priority management device of the communication device; FIG. 6 schematically illustrates a communication device, according to a third embodiment; FIG. 7 schematically illustrates a communication device, according to a fourth embodiment; FIG. 8 schematically illustrates an algorithm implemented by a communication device processor, according to the fourth embodiment. Fig. 1 schematically illustrates a communication device, according to a first embodiment. A communication device 1.0 comprises a main communication module 1.1 comprising, for example, a communication interface according to the WiFi (registered trademark) technology. The main module 1.1 comprises arbitration means 1.4 adapted to receive transmission requests on the communication channel from a single secondary communication module, in addition to those of the main module 1.1. These queries are received via a link or thread 1.9. In association with these requests are transmitted, via a link or wire 1.10, respective priority information. An arbitration is then performed between this request and the transmission requirements on the communication channel specific to the main module 1.1, according to the priority information associated with the request. If the main module 1.1 must perform a transmission on the communication channel of higher priority than that of the received request, a decision of refusal of transmission on the communication channel is transmitted via a link or thread 1.11. Otherwise, a transmission acceptance decision on the communication channel is transmitted via the link or wire 1.11. In 3-wire type systems, the signals transmitted on the link or wire 1.9 are commonly called BT ACTIVE, those transmitted on the link or wire 1.10 are commonly known as BT PRIORITY and those transmitted on the link or wire 1.11 are commonly referred to as WLAN. ACTIVE. This is because 3-wire systems are typically intended to be used to manage the coexistence of Bluetooth (registered trademark) and WLAN technologies.

The module 1.1 is therefore said to be principal in the sense that it is directly connected, or even includes, these arbitration means 1.4 transmissions on the communication channel. When it comprises these arbitration means 1.4, it decides whether or not to grant another communication module to transmit on the communication channel. This other module is then said secondary in that it is not master, but is slave, of the decision. Preferably, the arbitration means 1.4 are included in the same integrated circuit as the main communication module, but can also be implemented in a separate integrated circuit. The communication device 1.0 further comprises a first secondary module 1.2 and a second secondary communication module 1.3. The first secondary module 1.2 comprises for example a communication interface according to Zigbee technology (registered trademark). The second secondary module 1.3 comprises, for example, a communication interface according to Bluetooth (registered trademark) technology. In an alternative embodiment, the second secondary module 1.3 is made by a processor comprising means for emulating the behavior of such a secondary communication module, so as to prohibit any transmission, over the communication channel, by any module of Communication of the communication device 1.0. Such a processor emulating the behavior of a secondary communication module is more fully described below in relation to FIGS. 7 and 8. The communication device 1.0 may comprise a larger number of secondary communication modules.

The communication device 1.0 further comprises a device 1.5 for managing access priority to the communication channel. In FIG. 1, the priority management device 1.5 is included in the same integrated circuit as the secondary communication module comprising the communication interface according to the Zigbee (registered trademark) technology.

The priority management device 1.5 receives, via a link or wire 1.6, transmission requests on the communication channel transmitted by the second secondary module 1.3. The priority management device 1.5 receives, via a link or wire 1.7, priority information respectively associated with these requests. The priority management device 1.5 also receives, internally to the integrated circuit, requests from the Zigbee (registered trademark) secondary communication module and associated priority information respectively. If such requests come to it concurrently, the priority management device 1.5 selects one of these concurrent requests, based on the priority information. The request of highest priority is then transmitted to the arbitration means 1.4 by means of the link or wire 1.9 and the associated priority information is transmitted to him via the link 1.10 link or wire. If the requests do not reach him in a concurrent way, the priority management device 1.5 transmits each of these requests and his priority information associated with the arbitration means 1.4.

The priority management device 1.5 receives, via the link or thread 1.11, a decision as to the request transmitted via the link or wire 1.9 and transmits it to the secondary module concerned. If the secondary module concerned is the secondary module 1.3, the priority management device 1.5 transmits this decision via a link or wire 1.8. Otherwise, the priority management device 1.5 transmits the decision, internally to the integrated circuit, to the Zigbee (registered trademark) secondary communication module. It should therefore be noted that the priority management device 1.5 does not make a transmission authorization decision on the communication channel by the secondary communication modules. This function is in fact carried out by the arbitration means 1.4.

Fig. 2 schematically illustrates the communication device 1.0, according to a second embodiment. The embodiment of FIG. 2 differs from that of FIG. 1 in that the priority management device 1.5 is not included in the same integrated circuit as a secondary communication module. The communication device 1.0 comprises a secondary communication module 2.2 interfaced with the priority management device 1.5 via links or wires 2.3, 2.4 and 2.5. The link or wire 2.3 makes it possible to transmit transmission requests over the communication channel, the link or wire 2.4 that of priority information and the link or wire 2.5 that of the decisions taken by the arbitration means 1.4. According to the embodiment of FIG. 2, the secondary module 1.3 includes a Bluetooth communication interface (registered trademark); the secondary module 2.2 comprises a Zigbee communication interface (registered trademark) or corresponds to a processor comprising means for emulating the behavior of a secondary communication module. Fig. 3 schematically illustrates a first embodiment of the priority management device 1.5, the functions of which are thus implemented in hardware form by a dedicated machine or component, such as an FPGA (Field-Programmable Gate Array in English or Programmable Gate Matrix on Field in French) or an ASIC (Application-Specific Integrated Circuit or Application Specific Integrated Circuit). The priority management device 1.5 comprises a module 3.1 for managing priority and selecting transmission requests on the communication channel. This module 3.1 receives priority information from three secondary communication modules via links 3.4, 3.5 and 3.6. The queries associated with this priority information are respectively received by the priority management device 1.5 via links or wires 3.7, 3.8 and 3.9. The decisions concerning these requests are respectively transmitted via links or wires 3.10, 3.11 and 3.12. The priority management device 1.5 comprises a multiplexer 3.2 whose inputs are the links or wires 3.7, 3.8 and 3.9, and the output is the link or wire 1.10. I1 further comprises a demultiplexer 3.3 whose input is the link 1.11 and the outputs are the links or wires 3.10, 3.11 and 3.12. The module 3.1 performs a selection of a request among the competing requests received by the multiplexer 3.2, according to the priority information received via the links 3.4, 3.5 and 3.6. The module 3.1 then controls the multiplexer 3.2 by means of a control link 3.13 so that the selected query is pointed to the link 1.10. The module 3.1 also transmits, via the link 1.9, the priority information associated with the selected request. In addition, the module 3.1 controls the demultiplexer 3.3 by means of a control link 3.14 so that the decision taken by the arbitration means 1.4 is directed to the link 3.10, 3.11 or 3.12 concerned. Fig. 4 schematically illustrates a second embodiment of the priority management device 1.5, whose functions are thus implemented in software form by executing a set of instructions by a programmable machine, such as a DSP (Digital Signal Processor). of Digital Signal Processing in French), a microcontroller or a processor. The priority management device 1.5 comprises, connected by a communication bus 4.1: a processor, microprocessor, microcontroller (noted μc) or CPU (Central Processing Unit in English) 4.2; - Random Access Memory RAM (Random Access Memory in French) 4.3; a ROM (Read Only Memory in English or Memory Read Only in French) 4.4; a storage medium reader 4.5, such as a SD (Secure Digital Card) card reader; interface means 4.6 with the main communication module 1.1; interface means 4.7 with secondary communication modules. The processor 4.2 is capable of executing instructions loaded into the RAM 4.3 from the ROM 4.4, an external memory (not shown), a storage medium, such as an SD card or the like, or a communication network. When the communication device 1.0 is turned on, the processor 4.2 is able to read instructions from RAM 4.3 and execute them. These instructions form a computer program. This computer program causes the implementation, by the processor 4.2, of the algorithm described below in relation with FIG. 5. FIG. 5 schematically illustrates an algorithm implemented by the priority management device 1.5.

In a step 5.1, the priority management device 1.5 receives transmission requests on the communication channel from secondary communication modules, and receives respectively associated priority information. In a next step 5.2, the priority management device 1.5 selects a request from the requests received during step 5.1. If requests are concurrently received, the Priority Management Device 1.5 selects the request with the highest associated priority. If these concurrently received requests have the same priority level, the priority management device 1.5 may perform an arbitrary selection among these requests. If the requests are received in a non-concurrent manner, the priority management device 1.5 selects each of these requests. In a next step 5.3, the priority management device 1.5 transmits each selected request, and its associated priority information, to the arbitration means 1.4 of the main module 1.1. The priority management device 1.5 thus provides the arbitration means 1.4 with a candidate wishing to transmit on the communication channel; arbitration means 1.4 to decide whether to actually allow a transmission by the secondary module that issued this request. In a next step 5.4, the priority management device 1.5 can transmit, to each secondary module that has transmitted a request other than the selected request, transmission refusal information on the communication channel. In this step, the priority management device 1.5 does not make a decision as to actually authorize transmission over the communication channel. It selects only a candidate according to the priority of the requests it receives, the decision being taken by the arbitration means 1.4. Each secondary module having transmitted a request other than the selected request is not candidate, following the selection made by the priority management device 1.5, to transmit on the communication channel. In a subsequent step 5.5, the priority management device 1.5 receives the decision taken by the arbitration means 1.4 as to the selected request. In a subsequent step 5.6, the priority management device 1.5 transmits this decision to the secondary module having transmitted this request. Fig. 6 schematically illustrates the communication device 1.0, according to a third embodiment.

The communication device 1.0 comprises a 6.1 processor and a USB type dongle 6.0, that is to say having an interface compliant with Universal Serial Bus Universal Serial Bus (USB) specifications. The processor 6.1 and the key 6.0 are interconnected via a USB type bus 6.4.

The USB key 6.0 comprises the main module 1.1 and a secondary communication module 6.3, which are interconnected via the links or wires 1.9, 1.10 and 1.11. The secondary module 6.3 comprises the priority management device 1.5. The USB key 6.0 further includes a 6.2 conversion module interfaced with the USB bus 6.4. The conversion module 6.2 converts the data from the USB bus 6.4, and addressed to the main module 1.1, in data compatible with the format supported by a link 6.5 connecting the conversion module 6.2 and the main module 1.1; and vice versa. The conversion module 6.2 converts the data from the USB bus 6.4, and addressed to the secondary module 6.3, in data compatible with the format supported by a link 6.6 connecting the conversion module 6.2 and the secondary module 6.3; and vice versa. The data exchanged on links 6.5 and 6.6 are typically data to be transmitted over the communication channel, configuration and status data. For example, links 6.5 and 6.6 are compatible with Universal Universal Asynchronous Receiver Transmitter (UART) as well as Serial Peripheral Interface (Serial Peripheral Interface) serial device interface specifications. In addition, the conversion module 6.2 demultiplexes data from the USB bus 6.4 to extract the communication request 6.7 transmission signals on the communication channel, and associated priority information 6.8, from the processor 6.1 and transmit them to the 1.5 priority management device. The conversion module 6.2 also performs data multiplexing for the USB bus 6.4 to insert the decision signals 6.9 generated by the arbitration module 1.4 and relayed by the priority management device 1.5. These signals are for example exchanged by the conversion module 6.2 via General Purpose Input-Ouput (GPIO) general purpose I / O interfaces.

Fig. 7 schematically illustrates the communication device 1.0, according to a fourth embodiment. The communication device 1.0 comprises a processor 7.1, the main communication module 1.1 and the arbitration means 1.4. The arbitration means 1.4 are preferentially included in the main module 1.1. The processor 7.1 is interconnected to the main module 1.1 via the links or wires 1.9, 1.10 and 1.11. To do this, GPIO interfaces of the processor 7.1 can be used. The processor 7.1 comprises emulation means 7.2 of the behavior of a secondary communication module vis-à-vis the arbitration means 1.4, so as to prohibit any transmission by the main module 1.1 on the communication channel. Preferably, this emulation is performed on the basis of information relating to at least one transmission to be performed by at least one device external to the communication device 1.0. This external device may be under the control of the processor 7.1 and be located on the same equipment as the communication device 1.0. This external device can also be located on a remote device. The processor 7.1 is able to predict the times at which the external device transmits on the communication channel. Thanks to the knowledge of these moments, the processor 7.1 makes it possible to limit the interference on the communication channel by sending a request on the link or wire 1.9. The processor 7.1 thus has a secondary communication module behavior: it transmits transmission requests on the communication channel, although it is not itself a transmitter on this channel. It then makes it possible to prevent the communication device 1.0 from transmitting on the communication channel, while a transmission by an external device is provided. By thus simulating a transmission on the channel, it makes it possible to limit the interference for data intended to be received by the communication device 1.0 via the communication channel. In order to be able to predict these times, the processor 7.1 may, for example, register the services using the communication channel. For example, these services require periodic communications. The processor 7.1 can then construct a description table of these services and use it to trigger the emulation means 7.2 of the behavior of a secondary module. To perform this service census, the processor 7.1 communicates at the application level with any other device with which it shares the communication channel. He may obtain from this other device information regarding the communications provided by his services. It can for example obtain from this other device information as to the periodicity of the planned communications, their duration, their priority level and the type of service with which they are associated. It is possible to take into account, in determining the duration of a planned communication, the fact that it requires or not acquits. The processor 7.1 can obtain the information of periodicity of the communications associated with the services identified by requesting this information from devices implementing these services. This information can be stored in non-volatile memory by the devices concerned. This information can also be obtained by the processor 7.1 by learning, by analyzing signals or data exchanged on the communication channel. The priority information exchanged between modules can be defined according to application characteristics. According to a first example, priority levels can be defined according to energy consumption constraints of the devices involved by each service. The communications of a very energy-constrained device, for example powered by batteries or by battery, can then be considered as priority over those of a less energy-constrained device, for example mains-powered. This can limit energy costs related to transmission failures and data retransmissions. In a second example, the communications of a service relating to the security of a home can be considered as priority over those of a heating management service in a home automation system. According to a third example, the communications of a real-time service, such as voice data communications or communications of the association phase of the Bluetooth (registered trademark) technology, can be considered as priority over those of a non-real-time service. Combinations of these application features and / or other application features may be considered to define the priority level of transmission over the communication channel. FIG. 8 diagrammatically illustrates an algorithm implemented by the processor 7.1 of the communication device 1.0, according to the fourth embodiment described above in relation to FIG. 7.

All or part of the algorithm described below can be implemented in software form by executing a set of instructions by a programmable machine, such as a DSP or a microcontroller, or be implemented in hardware form by a machine or a dedicated component, such as an FPGA or an ASIC.

In a step 8.1, the processor 7.1 obtains temporal information as to the transmission of data by other devices having access to the communication channel. In a next step 8.2, the processor 7.1 detects time events relating to the information obtained in step 8.1. For example, the processor 7.1 maintains a table of services that are active via the communication channel, this table including information as to the instant of the next communication for each service. The processor 7.1 compares this communication instant information with the value contained in an incrementing register according to the timing of a clock of the communication device 1.0. When one of these communication time information matches the value of the register, the communication takes place on the communication channel. The processor 7.1 then updates the service table to take into account the next communication of the service concerned.

In a next step 8.3, the processor 7.1 transmits to the main module 1.1 transmission requests on the communication channel and preferably associated priority information. The processor 7.1 thus emulates the behavior of a secondary communication module vis-à-vis the arbitration means 1.4, so as to prohibit transmission by the main module 1.1 on the communication channel. Preferably, this emulation is performed on the basis of the time events detected in step 8.2 and temporal information, such as communication times, obtained in step 8.1. The processor 7.1 receives in return the decision of the arbitration means 1.4 as to the request. If it receives, from the arbitration means, a decision of refusal of transmission on the communication channel, because of the priority level of its request, the processor 7.1 can expect interference with the communication provided by the table of services. This communication will have to be renewed. Take a first example that the communication device 1.0 has a main module 1.1 with a WiFi interface (registered trademark). The processor 7.1 has the knowledge that at a time t0, a remote ZigBee (registered trademark) sensor will transmit. It then transmits just before time t0 a transmission request on the communication channel via the link or wire 1.9. It also transmits, via the link or wire 1.10, the priority information associated with the service to which the transmission by the remote sensor corresponds. The arbitration means 1.4 may suspend transmissions via the WiFi interface (registered trademark) to leave the free communication channel for the remote sensor to transmit. Let us take a second example according to which the communication device 1.0 has a main module 1.1 comprising a WiFi interface (registered trademark), and has the architecture described above in relation to FIG. 6. The 6.1 processor implements an activity monitoring mechanism on the USB bus 6.4, which can be shared with other devices than the USB 6.0 key. When the processor 6.1 detects, or provides, a bottleneck in the USB bus 6.4, it emulates the behavior of a communication module vis-à-vis the arbitration means 1.4, so as to limit transmissions , or even prohibit any transmission, by at least one of the communication modules 1.1 and 6.3 on the communication channel. By doing this, the processor 6.1 makes it possible to release the constraints on the USB bus 6.4. Thus, the emulation performed by the processor 6.1 makes it possible to manage conflicts of access to resources internal to the communication device and shared between the transmission process on the communication channel and at least one other process of the communication device.

Claims (9)

CLAIMS1) Communication device (1.0) comprising a main communication module (1.1) and arbitration means (1.4) for transmissions over a communication channel, said arbitration means being intended to arbitrate transmission requests on said channel associated with respective priority information and transmitted by said main module and a single secondary communication module, characterized in that it comprises a plurality (1.3, 2.2) secondary communication modules and a device (1.5) for prioritizing access to said channel comprising: - means (3.1, 3.2) receiving, from said secondary communication modules, transmission requests on the communication channel associated with respective priority information; means (3.1, 3.13) for selecting one of the requests received in a concurrent manner by the reception means, as a function of their priority information; means (3.1, 3.2) for transmitting to said arbitration means the selected request and the associated priority information; means (3.3, 3.14) for receiving, from said arbitration means, an arbitration decision as to the selected request and for transmitting said arbitration decision to the secondary module having transmitted said selected request; . 2) Communication device according to claim 1, characterized in that said arbitration means are included in the same integrated circuit as the main communication module 25. 3) Communication device according to any one of claims 1 and 2, characterized in that the management device further comprises transmission means, each secondary module having transmitted a request other than the selected query, information of refusal of transmission on the communication channel. 4) Communication device according to any one of claims 1 to 3, characterized in that it comprises a processor (6.1) comprisingemulsion means (7.2) of the behavior of a secondary communication module, on the basis of information relating to communications implemented by at least one device external to said communication device. 5) A communication device according to any one of claims 1 to 4, characterized in that a first among the secondary communication modules comprises a Zigbee type of communication interface and a second one of the secondary communication modules comprises an interface of Bluetooth type communication. 6) Communication device according to any one of claims 1 to 5, characterized in that one of the secondary communication modules comprises a Zigbee type of communication interface, and in that said priority management device is included in the same integrated circuit (1.2) as this secondary communication module. 7) Transmission management method on a communication channel, implemented in a communication device (1.0) comprising a main communication module (1.1) and means (1.4) for arbitration of transmissions on a communication channel, said arbitration means being intended to arbitrate transmission requests on said channel associated with respective priority information and transmitted by said main module and a single secondary communication module, characterized in that, the communication device comprising a plurality ( 1.3, 2.2) of secondary communication modules and a device (1.5) for prioritizing access to said channel, said management device performs the following steps of: reception (5.1), from said secondary communication modules, of transmission requests on the communication channel associated with respective priority information; selecting (5.2) one of the requests received competitively by the reception means, as a function of their priority information. transmitting (5.3) to said arbitration means the selected request and the associated priority information; Receiving, (5.5) from said arbitration means an arbitration decision as to the selected request; and - transmitting (5.6) said arbitration decision to the secondary module having transmitted said selected request. 8) Computer program, characterized in that it comprises instructions for implementing, by a communication device, the method according to claim 7, when said program is executed by a processor of said device. 9) storage means, characterized in that they store a computer program comprising instructions for implementing, by a communication device, the method of claim 7, when said program is executed by a processor of said device. 15