FR2976144A1 - METHOD FOR COMMUNICATIONS BETWEEN RADIO DEVICES OF IDENTICAL OR DIFFERENT TECHNOLOGIES - Google Patents

Abstract

The invention relates to a communication method between a radio transmitter and a radio receiver. This method comprises a step in which said radio transmitter, said first transmitter (A), sends at least one information to said receiver (B) by means of predetermined variations of at least one baseband parameter of the radio signal transmitted by said first transmitter (A) and received by said receiver (B). Application to the mutual management of the exploitation of radio resources between self-configurable devices.

Description

The invention relates to the field of radio communications, in particular (but not exclusively) those that use ISM frequency bands (Industrial, Scientific and Medical). More specifically, the invention relates to the mutual management of resources between transmitting or receiving devices operating in frequency bands accessible to a plurality of radio technologies.

It is recalled that the ISM frequency bands were originally reserved internationally for the use of radiofrequencies (RF) for industrial, scientific and medical purposes, such as microwave ovens. household microwaves (operating at 2.45 GHz) and medical diathermy machines - and not for communications purposes. The radio frequencies in the ISM bands have subsequently been used for communications purposes, despite the fact that such devices may experience interference from non-communicating sources of electromagnetic energy. Since the emissions from these devices can create electromagnetic interference and disrupt radio communications using the same frequencies, the use of these devices has been limited to certain frequency bands. Thus, a frequency band, known as the "Citizen's Band", adjacent to an ISM band, has been allocated to the United States since 1958. Many other countries later adopted FCC regulations ("Federal"). Communications Commission) of the United States, which has enabled the use of this technology in all industrialized countries. These regulations therefore allow civilian exploitation of free access radio spectra. 2 ISM bands have been defined by the ITU-R (the ITU-R is the International Telecommunication Union (ITU) sector responsible for radio communications) in sections 5.138, 5.150 and 5.280 of the Radio Regulations. The use in some countries of the bands designated in these sections may differ due to variations in the national radio regulations. Because communication devices using ISM tapes must tolerate interference from other ISM equipment, these radio bands are normally reserved for use in unlicensed operations, such as Wireless Sensor Networks in 868 tape. MHz, 915 MHz and 2,450 GHz, the local area network (LAN), and battery telephones in the 915 MHz, 2,450 GHz and 5,800 GHz bands; wireless LAN devices include Bluetooth (2,450 GHz), HIPERLAN (5,800 GHz), Wi-Fi (2,450 GHz and 5,800 GHz), and ZigBee (915 MHz and 2,450 GHz). ISM tapes are also widely used for RFID ("RadioFrequency Identification") applications, such as biometric passports and contactless chips, the most commonly used frequency band for this purpose being the 13.56 MHz band in accordance with the ISO / IEC 14443. Wireless LANs and battery-powered telephones may also use frequency bands other than ISM bands, but such uses require country-by-country approval. DECT phones use an allocated spectrum (which is different in Europe and North America), which is outside the ISM bands. Despite the fact that these additional bands are outside the official ITU-R ISM bands, it is sometimes incorrectly said that these additional frequency bands are also ISM bands because they are used for same types of low power personal communications. It should also be noted that several brands of radio control equipment use the 2.4 GHz band for the low-power remote control of toys, such as cars and miniature planes.

Note that, while the present invention is applicable to the ISM bands described above, it can also advantageously be applied to certain radio devices (for example "femtocells", which serve as basic elements for residential or residential uses). company) operating in licensed frequency bands.

In the context of the present invention, it will be said that systems containing different technology communications apparatus are "heterogeneous (communications) systems". In such a system, a communications device must, in theory, be tolerant of interference caused by potential licensed users for the same frequency band, and, in addition, operate itself with sufficient power low to avoid causing interference to licensed users; for example, the 915 MHz radio band should not be used in countries that use the GSM-900 band for mobile phones.

However, it is found in practice that, in heterogeneous systems, the interferences between communicating devices of different technologies are often troublesome and substantially alter the SINR (initials of the words "Signal to Interference-plus-Noise Ratio" meaning "Signal to Interference Ratio" more Noise "). In the case of certain self-configurable devices, that is to say capable of changing transmission or reception frequency according to predetermined criteria, it could be envisaged, in the event of annoying interference, to solve this problem by sending them an appropriate signal. But given that we consider interferences between devices of different technologies, these devices are not designed to communicate with each other. Two solutions to this problem can be envisaged. A first solution would be to allow all radio devices concerned to be compatible with the various radio technologies implemented. It goes without saying that such a solution implies considerable complexity and cost for these devices. A second solution would be to set up, in each heterogeneous system, a central control device. Such a central device should ideally include means for: 1) decoding signaling messages from all transmitters belonging to the heterogeneous system; 2) to calculate, based on predetermined criteria (for example, priority for a particular technology in terms of SINR), the optimal network configuration on the basis of the information received from all the devices belonging to the heterogeneous system; and 3) encode and send to each respective transmitter, in its respective technology, a respective message to enable it to configure itself.

But, again, it goes without saying that such a solution is both complex and expensive. The present invention therefore relates to a communication method between a radio transmitter and a radio receiver. Said method is remarkable in that it comprises a step during which said radio transmitter, said first transmitter, sends at least one piece of information to said receiver by means of predetermined variations of at least one baseband parameter of the transmitted radio signal. by said first transmitter and received by said receiver. Indeed, the authors of the present invention have realized that a radio receiver is generally able to identify certain baseband parameters of the radio equipment located in its environment. For example, the transmit power (average or instantaneous), the modulation scheme (amplitude, frequency, phase, and so on), the size (number of states) of the modulation constellation, and the Transmission timing are baseband parameters (which, for convenience of language, will be referred to below as "physical parameters") that can be easily identified. Thus, even when a receiver receives a message using a different technology and the receiver can not understand by decoding the digital stream, it is nevertheless possible, following a prior convention, to use predetermined variations in the band parameters. basis for transmitting information. This type of communication will be referred to below as "strategic communications" because it presupposes a degree of competition and negotiation between various radio devices operating in the same frequency band. Unlike conventional standards, which specify certain resources (such as time slots or frequency bands) dedicated to certain signals, there is no strategic communication of radio resource dedicated to signaling.

The message according to the invention is encoded via the "physical parameters" of transmission, that is to say, for example, by means of modulation, power, choice of channels, or transmission timing. As a result, the use of strategic communications in a self-configurable radio network entails only a small additional cost for the network operator.

It should be noted that strategic communications in self-configurable radio networks are not intended to replace existing communications systems, but rather to provide new means of communication; these means are particularly advantageous in the case of radio devices using different technologies (but able to operate in the same frequency band), which, in the prior art, could not communicate directly with each other; but it will be noted that these means of communication also make it possible, in a simple and inexpensive way, to enrich the range of information transmitted between radio devices of the same technology.

It will be understood that this is a choice of management of a communications network, insofar as the exchange of information according to the invention may eventually lead to a temporary decrease in the throughput of certain elements of the network. However, in many situations, we will be able to agree in order to benefit from an improvement in overall performance over the long term. According to particular features, said method then comprises a step during which said receiver transmits said information to a radio transmitter, said second transmitter, autoconfigurable.

Thanks to these arrangements, it is possible to cause said second transmitter to modify at least one parameter of its radio transmission, so as to satisfy the "general interest" of the communications system, particularly at the level of radio receivers whose quality of the received signal would suffer. (for example because of annoying interference) of the transmission of the second transmitter before said radio parameter modification. Correlatively, the invention relates to a communications system. Said communications system is remarkable in that it comprises at least one radio transmitter, said first transmitter, able to send, and a radio receiver capable of receiving, at least one information associated with predetermined variations of at least one parameter of baseband of a radio signal that can be transmitted by said first transmitter and received by said receiver. According to particular features, said communications system further comprises a radio transmitter, said second radio transmitter, self-configurable, said receiver being able to transmit to said second radio transmitter, and the second radio transmitter being able to receive, said at least one information. The invention also relates to a computer program downloadable from a communication network and / or stored on a computer readable medium and / or executable by a microprocessor. This computer program is notable in that it includes instructions for performing the steps of any of the communication methods succinctly set forth above, when executed on a computer.

The advantages offered by this computer program are essentially the same as those offered by said methods. Other aspects and advantages of the invention will appear on reading the detailed description below of particular embodiments, given by way of non-limiting examples.

As mentioned above, the present invention introduces the notion of "strategic communications": these communications are able to exchange a certain number of messages from an "alphabet", each element of the alphabet corresponding to a sequence of change ( s) transmission parameters. The size of the alphabet is a function of the number of available transmission configurations that satisfy the Quality of Service (QoS) required for all communications. For example, suppose that a transmitter can be decoded reliably by a set of receivers when it transmits by means of n different transmission configurations. Suppose further that all receivers can identify the baseband configuration of this transmitter during M time slots, and that the transmission of a message is distributed over these M time slots. The transmitter can, under these conditions, send to the receivers nM different messages.

Two examples of transmission of information according to the invention (which, in the particular case where the transmitter and receiver devices operate according to the same technology, can be added to the information transmitted in a conventional manner): 1) an uninterrupted radio transmission during N> 0 symbol periods is associated with an information constituted by the bit 1, and the uninterrupted absence of transmission during N symbol periods is associated with information consisting of the bit 0; or 2) a BPSK radio transmission (initials of the words "Binary Phase-Shift Keying" meaning "Binary Phase Modulation") during N> 0 symbol periods is associated with a bit 1 information, and a radio transmission in QAM (initials of the words "Quadrature Amplitude Modulation" meaning "Quadrature Amplitude Modulation") with 4 states during N symbol periods is associated with information consisting of the bit 0. In these two examples, a radio transmission during M - N symbol periods, where M> 1, allows the transmission according to the invention of M information bits. An example of a method implementing the communications system according to the invention will now be given. In step S1, a Wi-Fi communication is in progress between an AT transmitter (for example, a "box") and an AR receiver (for example, a laptop). In step S2, any cause (for example, an intrusion into a private property comprising said communications system) triggers an alarm within an associated alarm system, said alarm system comprising a BT transmitter and an alarm system. BR receiver operating in ZigBee, said BR receiver being able to relay the alarm or to apply predetermined remedies in response to this cause of alarm.

In step S3, the receiver AR observes a reduction of the SINR, caused by interference with the radio signal emitted by the transmitter BT, and informs the transmitter AT using conventional means. In step S4, the transmitter AT varies, in a predetermined manner and during a predetermined transmission time, at least one baseband parameter in the transmitted Wi-Fi signal. In step S5, the receiver BR (although unable to decode the Wi-Fi signal) observes these variations of said parameter, and informs the transmitter BT using conventional means.

In step S6, the transmitter BT changes its transmission frequency of the alarm signal ZigBee, preferably after having warned the receiver BR and, if necessary, other receivers ZigBee: thus, the SINR of the Wi-Fi signal received by the receiver AR is advantageously restored.

Optionally, it may further be provided that the transmitter BT sends, by means of a predetermined variation of a baseband parameter of the ZigBee signal, an acknowledgment to the receiver AR for retransmission to the transmitter AT (indeed, it could be expected that in the absence of acknowledgment for a predetermined waiting period, the transmitter AT repeats step S4). As an example, an application of the invention has been provided for the management of interference, that is to say, more generally, the coordination of access to a common resource (selection channel, transmission power adjustment, and so on). It is important to note, however, that many other applications of the invention are possible, such as: - the exchange of information for the improvement of a service, for example the cooperative refinement of the measurement of a variable in a sensor network; or - the sharing of experience, for example the method of learning a self-configurable radio device, newly installed in a network, on the basis of the observation of the signals transmitted by the other devices of the network.

As indicated above, the present invention also relates to a computer system implementing the communications method described above. This computer system conventionally comprises a central processing unit controlling signals by a memory, as well as an input unit and an output unit.

In addition, this computer system can be used to execute a computer program comprising instructions for carrying out the communications method according to the invention. Indeed, the invention also relates to a downloadable computer program from a communication network comprising instructions for executing the steps of a communications method according to the invention, when it is executed on a computer. This computer program may be stored on a computer readable medium and may be executable by a microprocessor. This program can use any programming language, and present itself as source code, object code, or intermediate code between source code and object code, in a partially compiled form or in any other desirable form. The invention also relates to an information carrier, irremovable, or partially or completely removable, readable by a computer, and comprising instructions of a computer program as mentioned above. The information carrier may be any entity or device capable of storing the program. For example, the medium may comprise storage means, such as a ROM, for example a CD ROM or a microelectronic circuit ROM, or a magnetic recording medium, for example a USB flash drive ("USB flash drive"). in English) or a hard drive. On the other hand, the information medium may be a transmissible medium such as an electrical or optical signal, which may be conveyed via an electrical or optical cable, by radio or by other means. The computer program according to the invention can in particular be downloaded to an Internet type network. As a variant, the information carrier may be an integrated circuit in which the computer program is incorporated, the circuit being adapted to execute or to be used in the execution of the method according to the invention.

Claims (8)

REVENDICATIONS1. A method of communication between a radio transmitter and a radio receiver, characterized in that it comprises a step during which said radio transmitter, said first transmitter (AT), sends at least one information to said receiver (BR) by means of variations predetermined ones of at least one baseband parameter of the radio signal transmitted by said first transmitter (AT) and received by said receiver (BR). 2. A method of communications according to claim 1, characterized in that it then comprises a step in which said receiver (BR) transmits said information to a radio transmitter, said second transmitter (BT), self-configurable. The communication method according to claim 1 or claim 2, characterized in that said baseband parameter is an element, or an association of elements, of the set comprising the instantaneous power, the average power, the pattern. modulation, the size of the constellation, the duration of transmission, and the timing of transmission. 4. Communications system, characterized in that it comprises at least one radio transmitter, said first transmitter (AT), able to send, and a radio receiver (BR) able to receive, at least one information associated with predetermined variations at least one baseband parameter of a radio signal that can be transmitted by said first transmitter (AT) and received by said receiver (BR). 5. Communications system according to claim 4, characterized in that it further comprises a radio transmitter, said second radio transmitter (BT), self-configurable, and in that said receiver (BR) is adapted to transmit to said second radio transmitter (BT), and the second radio transmitter (BT) is adapted to receive, said at least one information. The communications system of claim 4 or claim 5, characterized in that said baseband parameter is an element, or an association of elements, of the set including instantaneous power, average power, pattern modulation, the size of the constellation, the duration of transmission, and the timing of transmission. An immovable, or partially or totally removable data storage medium, comprising computer program code instructions for performing the steps of a communications method according to any one of claims 1 to 3. 8. Computer program downloadable from a communication network and / or stored on a computer-readable medium and / or executable by a microprocessor, characterized in that it comprises instructions for the execution of the steps of a method of communications according to any one of claims 1 to 3 when executed on a computer.