FR2992505A1 - Communication device for use in e.g. communicating system in motor vehicle, has connection unit transferring first and second signals between black box and antenna, where part of unit induces collection of third signals with cable - Google Patents

Abstract

The device (D) has an antenna (AN) for emitting first signals in a form of waves into a main radio coverage area (Z1) including a part of an electric cable (CE), and/or for receiving second signals in the form of waves to transform the second signal into third signals. A black box (BE) generates the first signals and/or receives the third signals. Connection units (L1, L2) transfer the first and third signals between the black box and the antenna. A part of the connection unit induces a radiation of the first signals and/or a collection of the second signals with the electric cable.

Description

The invention relates to wavelength communications in systems comprising electromechanical systems. The invention relates to wavelength communications in systems comprising electromechanical systems. electric cables with disruptive electromagnetic radiation. Here is meant by "electric cable" a wire element comprising 1 o one or more conductors (or son). Furthermore, in what follows is called "beam" a set of at least two electrical cables. As known to those skilled in the art, certain systems, such as for example certain vehicles, possibly motor vehicles, comprise at least one communication device comprising, firstly, at least one antenna capable of transmitting in the form of waves of the first signals in a radio coverage area (main), and / or receiving second signals in the form of waves to transform them into third signals, and secondly, an electronic box capable of generating the first signals and / or to receive the third signals, and, thirdly, connecting means adapted to transfer the first and third signals between the electronic box and the antenna. Such communication devices are generally intended to exchange data by waves with mobile communicating elements which are momentarily placed in their radio coverage area. By way of example, the communicating element may be a mobile telephone, a portable and communicating computer, a device comprising a communicating smart card, a vehicle electronic key (for "hands-free boot access"), or a communication device in the near field. In some of the aforesaid systems, it may happen that the radio coverage area includes at least a portion of at least one electrical cable that radiates electromagnetically and thus locally constitutes an antenna. There then exists around the radiating electric cable a disturbance zone whose dimensions depend on the amplitude and the frequencies of the current flowing in it. Since this zone of disturbance is at least partly included in the radio coverage area of the communication device, it can disturb or even prevent certain communications with mobile communicating elements because they are momentarily placed in this disturbance zone or when the antenna is placed in the vicinity of this disturbance zone. It is indeed recalled that the intensities of the electromagnetic fields of the waves emitted by the electric beams and the antennas decrease very rapidly, and therefore in the vicinity of electric cables, the intensity of the electromagnetic fields of the waves emitted by the antennas may be small compared to to that of the electromagnetic fields radiated by these electric cables even though the transmitting power of these antennas is large enough to cover the disturbance zone and the current intensities in the electric cables comply with the design rules in force. In other words, near certain electrical cables the signal-to-noise ratio (S / N) of the waves exchanged with a communication device is often too low, which is particularly troublesome for certain wireless applications, such as the detection of a mobile communicating element. Several solutions have been proposed to improve the situation. Thus, it is possible to act on the electric / electronic part of the system by modifying the shape of the signals to reduce the levels of the spectrum in the frequency band of the transmission channels (decrease of the intensity of the current, increase of the time of the eg, raising and lowering of signals, changing periodicity), or modifying the constitution of electric cable bundles (for example by twisting the conductors together or using electromagnetic shielding), or by modifying the electrical cables so that they are entirely outside the radio coverage area. It is also possible to act on the communication device, by modifying the communication protocol used, or by modifying the type of modulation used, or by increasing the transmission power of the antenna, or by modifying the location of the antenna, or by adding additional antennas to better cover the disturbance areas. But some of these solutions are often impossible to implement because they are incompatible with other technical requirements and / or expensive in terms of modification and / or inefficient. The invention therefore aims to provide an alternative inexpensive and easy to implement. It proposes more specifically for this purpose a device 1 o communication by wave, of the type presented in the introductory part, and wherein at least a portion of the connecting means is adapted to induce in the vicinity of a cable disruptive electromagnetic (electromagnetic) radiation of the first signals in the form of waves and / or a collection of the second signals. The production of such a device is simple and inexpensive. The communication device according to the invention may comprise other characteristics that can be taken separately or in combination, and in particular: in a first embodiment, its connection means may comprise at least a first wired connection interconnecting the housing electronic antenna, and a second wire link connected to the electronic box and comprising a portion located in the vicinity of the electrical cable and adapted to radiate the first signals in the form of waves and / or to collect the second signals; Its electronic box may comprise control means adapted to control the intensity of the first signals injected into the second wired link as a function of the desired dimensions of a secondary radio coverage area which includes at least a portion of the electric cable and a part of the main radio coverage area; In a second embodiment, its connection means may comprise at least a first wired link interconnecting the electronic box to the antenna and comprising a part situated in the vicinity of the electric cable and capable of radiating the first signals in the form of waves and / or collect the second signals; the first wired link may have a type that is selected according to desired dimensions of a secondary radio coverage area that includes at least a portion of the electrical cable and a portion of the main radio coverage area; in a third embodiment, its connection means may comprise at least a first wired link comprising a first part interconnecting the electronic box to the antenna and a second part connected to the first part and comprising a sub-part situated at the the vicinity of the electrical cable and capable of radiating the first signals in the form of waves and / or of collecting the second signals; the first wired link may have a type that is selected according to desired dimensions of a secondary radio coverage area that includes at least a portion of the electrical cable and a portion of the main radio coverage area; in a fourth embodiment, its connection means may comprise, firstly, at least a first wired link interconnecting the electronic unit to the antenna, and secondly, a second wired link connected to the electronic box. and, thirdly, an in-line power line adapter connected to the electrical cable and the second wire link and adapted to integrate the first signals into at least one current flowing in the electrical cable so that the latter radiates them under waveform and / or extracting from the current flowing in the electric cable the third signals which are integrated to it and which result from the collection of the second signals by the electric cable; > the power line adapter in line can be passive or active type; in a fifth embodiment, its connection means may comprise at least a first wired link interconnecting the electronic box to the antenna, and its electronic box may be connected to the electric cable and comprise an on-line power adapter connected to the electrical cable and clean to integrate the first signals in at least one current flowing in the electric cable so that the latter radiates them in the form of waves and / or to extract the current flowing in the electric cable the third signals that are integrated in it and which result from the collection of the second signals by the electric cable; > The power line adapter can be passive or active. The invention also proposes a system, for example arranged in the form of a vehicle, possibly of automobile type, and comprising at least one disruptive electrical cable and at least one communication device of the type of that presented above. Other features and advantages of the invention will appear on examining the detailed description below, and the accompanying drawings, in which: FIG. 1 schematically illustrates, in a view from above, a first embodiment of FIG. a communication device according to the invention installed in a vehicle and having a main radio coverage area including a part of a bundle of disruptive electrical cables, FIG. 2 diagrammatically illustrates, in a view from above, a second embodiment of FIG. a communication device according to the invention installed in a vehicle and comprising a main radio coverage area including a part of a bundle of disruptive electrical cables, FIG. 3 schematically illustrates, in a view from above, a third exemplary embodiment. of a communication device according to the invention installed in a vehicle and comprising a radio coverage area. comprising a part of a bundle of disruptive electrical cables, FIG. 4 schematically illustrates, in a view from above, a fourth embodiment of a communication device according to the invention installed in a vehicle and comprising a coverage area. main radio encompassing a portion of a bundle of disruptive electrical cables, and - Figure 5 schematically illustrates, in a view from above, a fifth embodiment of a communication device according to the invention installed in a vehicle and having a main radio coverage area encompassing part of a disturbing electrical wiring harness The purpose of the invention is to propose a D-wave communication device having a main radio coverage area Z1 intended to equip a system comprising at least one CE 1 o radiating electrical cable and located at least partly in this region. main radio coverage area Zl. In the following, we consider, by way of non-limiting example, that the system is a vehicle, possibly of automotive type. But the invention is not limited to this type of system. It concerns in fact any type of system comprising electric cables capable of defining at least one disturbance zone for at least one wave communication device, and in particular terrestrial or maritime (or fluvial) or aeronautical vehicles, satellites, rockets, communicating electronic equipment (such as computers, possibly portable), and buildings, spaces and facilities, public or private. FIGS. 1 to 5 show schematically a part of a system comprising electrical cables CE which are at least partly included in a main radio coverage area Z1 of a wave communication device D according to the invention. It will be noted that what differentiates the devices (wave communication) D of FIGS. 1 to 5 from one another are their embodiments. These electric cables CE radiate electromagnetically, because they carry electric currents, and therefore induce around them a disturbance zone ZP which is at least partially included in the main radio coverage area Z1. As illustrated in these FIGS. 1 to 5, a device (wave communication) D, according to the invention, comprises at least one electronic box BE, at least one antenna AN, and link means Lj . Note that in the non-limiting examples illustrated device D comprises only one antenna AN coupled to a single electronic control unit BE. But an electronic box can be coupled to several (at least two) antennas each having their own main radio coverage area. Each antenna AN is arranged to emit as waves first signals in its main radio coverage area Z1, and / or to receive second signals in the form of waves to transform them into third signals. Each electronic control unit BE is arranged to generate first signals to be transmitted in the form of waves by an associated antenna AN and / or to receive third signals transmitted by an associated AN antenna via the connecting means Lj and resulting from the transformation of second received signals in the form of waves. In a vehicle, such an electronic control unit BE may, for example, be a computer called BSI ("Intelligent Service Enclosure"), for example responsible for controlling power relays, or a BSM ("Motor Servitude Enclosure") for example, to control the power electronics and lighting under the hood of a car. It will be noted that the communications between an electronic box BE and a mobile communicating element EM can be done by any radio frequency communication standard known to those skilled in the art and whatever the frequency band (for example 125 KHz or 433 GHz ), and for example by WiFi (possibly very short range (or WiFi-SD ("Short Distance"))) or WiMAX or Bluetooth or by near field communication (or NFC ("Near Field Communication")). The connecting means Lj are not only able to transfer the aforementioned first and third signals between the electronic control unit BE and the antenna AN, but also to induce in the vicinity of the electric cable (s) CE, thanks to the at least one of their parts, wave radiation of the first signals which are issued from the electronic control unit BE and / or a collection of the second signals from the third signals emitted by a mobile communicating element EM temporarily located in the zone of main radio coverage Zl. It will be understood that the invention is particularly useful, although not limitatively, when the mobile communicating element EM is temporarily located in the disturbance zone ZP and that the antenna AN transmits thereto second signals (by means of waves). or when the antenna AN is located in the zone of disturbance ZP and the mobile communicating element EM is temporarily located in the main radio coverage area Z1 and transmits second signals (by waves) to the AN antenna. As mentioned above, several embodiments can be envisaged for the device D. Five of these non-limiting embodiments are respectively illustrated in FIGS. 1 to 5. In a first embodiment illustrated in FIG. connecting means Lj comprise at least a first wired link L1 and at least a second wired link L2. The first wired link L1 interconnects the electronic box BE to the antenna AN and thus allows a transfer of the first signals to be transmitted and / or the third signals received. The second wire link L2 is connected to the electronic box BE and comprises a portion PL which is situated in the vicinity of one (at least) of the electric cables CE and arranged so as to radiate the first signals in the form of waves and / or to collect the second signals emitted by a mobile communicating element EM. It will be understood that at least the portion PL of the second wired link L2 is arranged to behave as a transmitting and / or receiving antenna associated with a secondary radio coverage zone Z2 located at least partially in the zone. ZP disturbance and at least partially encompassed by the main radio coverage area Z1. For this purpose, the part PL may be constituted by a radiating electrical cable which may be preceded in the direction of the electronic box BE by another part which is either like (radiant) or different from it (non-radiating). These two parts can extend one another or constitute two electrical cables connected to one another.

Note that the PL part could itself be extended in series or star by one or more other parts, intended to radiate in one or more other radio coverage areas of a device D, possibly via at least one link load and / or amplification means. The first wired link L1 may be a radiating or non-radiating electrical cable. It will be noted, as shown in non-limiting manner in FIG. 1, that the electronic control unit BE may optionally comprise control means MC arranged to control the intensity of the first signals that are injected into the second wired connection L2 according to the desired dimensions. the Z2 secondary radio coverage area. It is recalled that the larger the dimensions of the secondary radio coverage area Z2, the greater the intensity of the first signals injected into the second wired link L2. These control means MC may be arranged in the form of passive or active electronic circuits, with or without fixed or variable amplification. In a second embodiment illustrated in FIG. 2, the connection means Lj comprise at least a first wire link L1.

This first wired link L1 interconnects the electronic box BE to the antenna AN and comprises a portion PL which is located in the vicinity of one (at least) of the electric cables CE and which is arranged to radiate the first signals in form. and / or to collect the second signals emitted by a mobile communicating element EM.

It will be understood that at least the portion PL of the first wired link L1 is arranged to behave as a transmitting and / or receiving antenna associated with a secondary radio coverage area Z2 located at least partially in the ZP disturbance and at least partially encompassed by the main radio coverage area Zl. For this purpose, the PL part may be constituted by a non-twisted and unshielded electrical cable which may be preceded towards the electronic control unit BE and extended in the direction of the antenna AN by two other parts which are either like it (radiating) , different from her (not radiant). These three parts can extend one another or constitute three electrical cables connected to one another. The first wired link L1, and in particular its portion PL, may have a type which is chosen according to the desired dimensions of the secondary radio coverage area Z2 offered by its radiant PL part and which includes at least a part of the CE electrical cable (s) and part of the main radio coverage area Zl. In a third embodiment illustrated in FIG. 3, the connection means Lj comprise at least a first wired link L1. This first wired link L1 comprises a first portion Lia which interconnects the electronic box BE to the antenna AN, and a second part L1 b which is connected to the first part Lia and which comprises a subpart PL situated in the vicinity of the at least one of the electric cables CE and arranged to radiate the first signals in the form of waves and / or to collect the second signals emitted by a mobile communicating element EM. The second part L1b may, for example, be connected to the first part Lia by means of a splice EP or a power divider with or without an amplifier. It will be understood that at least the subpart PL of the first portion L1a of the first wired link L1 is arranged to behave as a transmitting and / or receiving antenna associated with a secondary radio coverage area. Z2 located at least partially in the ZP disturbance zone and at least partially encompassed by the main radio coverage zone Z1. For this purpose, the subpart PL may be constituted by a non-twisted and unshielded electrical cable which may be preceded in the direction of the control unit BE by another sub-part which is either like it (radiating) or different from she (not radiant). These two sub-parts may extend one another or constitute two electrical cables 30 connected to one another. It should be noted that the subpart PL may itself be extended in series or star by one or more other parts intended to radiate in one or more other radio coverage areas of a device D, possibly via at least one load link and / or amplification means. The first wired link L1, and in particular its sub-part PL, may have a type which is chosen as a function of the desired dimensions of the secondary radio coverage zone Z2 offered by its radiating sub-part PL and which includes at least one part of the CE electrical cable (s) and part of the main radio coverage area Zl. In a fourth embodiment illustrated in FIG. 4, the connection means Lj comprise at least a first wired link L1, at least a second wired link L2, and an AC line power line adapter. The first wired link L1 interconnects the electronic box BE to the antenna AN and thus allows a transfer of the first signals to be transmitted and / or the third signals received. The second wired link L2 is connected to the electronic control unit BE and coupled to at least one of the electric cables CE via the AC line power line adapter. The AC line carrier adapter is adapted to integrate the first signals to be emitted into the current flowing in each CE electrical cable to which it is connected, so that the latter (AC) radiates them in the form of waves, and and / or to extract from the current flowing in each electrical cable CE to which it is connected the third signals which are integrated with it and which result from the collection of the second signals by this electric cable CE in its secondary radio coverage area Z2. It is recalled that the technique of line carrier currents (or CPL) operates not only in transmission, but also in reception (at least when it is passive type). It is also recalled that the CPL technique can be applied to one or more wires (or conductors) of the same electrical cable CE. The first wired link L1 may be a radiating or non-radiating electrical cable.

It will be understood that each electrical cable CE which is coupled to the AC line power line adapter is used here as a transmitting and / or receiving antenna at least in a part PL 'which is radiating in a zone of secondary radio coverage Z2 located at least partially in the ZP disturbance zone and at least partially encompassed by the main radio coverage area Z1. The second wired link L2 may be dedicated or constituted by a portion of an electric cable CE.

It should be noted that this AC line power adapter can be either passive type or active type. In a fifth embodiment illustrated in FIG. 5, the connection means Lj comprise at least a first wire link L1, and the electronic box BE comprises an AC line power line adapter. The first wired link L1 interconnects the electronic box BE to the antenna AN and thus allows a transfer of the first signals to be transmitted and / or the third signals received. The line AC power line adapter is connected to at least one of the electric cables CE which reach the level of the electronic box BE and is arranged to integrate the first signals to be emitted into the current flowing in each cable which it is connected, so that the latter (AC) radiates them in the form of waves, and / or to extract from the current flowing in each electrical cable CE to which it is connected the third signals which are integrated to it and which result from the collection of the second signals by this electric cable CE in its secondary radio coverage area Z2. The electrical cable CE which reaches the electronic box BE and which is coupled to the power line adapter AC line is for example the one that is responsible for supplying power to the electronic control unit BE.

But it could also be an output cable for supplying one or more electrical components via the electronic control unit BE, or an output cable for controlling or controlling one or more electrical components via the electronic control unit BE, or an input cable for controlling a switch of the electronic control unit BE, for example. A new function (transport and radiation of signals) is thus conferred on at least one existing electrical cable CE in the system under consideration. The first wired link L1 may be a radiating or non-radiating electrical cable.

It will be understood that each electrical cable CE which is coupled to the AC line power line adapter is used here as a transmitting and / or receiving antenna at least in a part PL 'which is radiating in a zone of secondary radio coverage Z2 located at least partially in the ZP disturbance zone and at least partially encompassed by the main radio coverage area Z1. As in the previous embodiment, the power line adapter CPL can be either passive type or active type. It will be noted that in all the embodiments, apart from the second (FIG. 2), the (sub) part PL ensuring the radiation may be extended in series or in a star by one or more other (sub) parts, possibly of different types, and intended to radiate in one or more other radio coverage areas of a communication device D, possibly via at least one connecting load and / or amplification means and / or an adapter of carrying currents. line. The invention offers several advantages, among which: a simple, inexpensive and imposing few modifications, the integration of the control unit in a computer for managing the power supply of the supply network of the system considered. , in order to use some of its power supply outputs to carry the signals to be transmitted and / or received in almost any location of the electrical architecture, - a significant decrease in the power emitted by each antenna 25 for to cover the disturbance zones where the resulting electromagnetic field is too weak in relation to the disturbing electromagnetic field which is radiated by a bundle of electrical cables, - the possibility of locally increasing the size of the main radio coverage area of an antenna by through each secondary radio coverage area.

Claims (10)

REVENDICATIONS1. Wavelet communication device (D) for a system comprising at least one radiating electric cable (CE), said device (D) comprising at least one antenna (AN) able to emit in the form of waves first signals in a main radio coverage area (Z1) encompassing at least a portion of said electric cable (CE), and / or receiving second wave signals to transform them into the third signals, an electronic control unit (BE) suitable for generating said first signals and / or receiving said third signals, and connecting means (Lj) adapted to transfer said first and third signals between said electronic box (BE) and said antenna (AN), characterized in that a part at least one of said connecting means (Lj) is capable of inducing in the vicinity of said electric cable (CE) a radiation of said first signals in the form of waves and / or a collection of said second signals. 2. Device according to claim 1, characterized in that said connecting means (Lj) comprise at least a first wire link (L1) interconnecting said electronic box (BE) to said antenna (AN), and a second wire link ( L2) connected to said electronic box (BE) and comprising a portion located in the vicinity of said electric cable (CE) and adapted to radiate said first signals in the form of waves and / or to collect said second signals. 3. Device according to claim 2, characterized in that said electronic box (BE) comprises control means (MC) adapted to control the intensity of said first signals injected into said second wire connection (L2) according to desired dimensions a secondary radio coverage area (Z2) encompassing at least a portion of said electrical cable (CE) and a portion of said main radio coverage area (Z1). 30 4. Device according to claim 1, characterized in that said connecting means (Lj) comprise at least a first wire link (L1) interconnecting said electronic box (BE) to said antenna (AN) and comprising a portion located in the vicinity of said electric cable (CE) and suitable for radiating said first waveform signals and / or for collecting said second signals. 5. Device according to claim 1, characterized in that said connecting means (Lj) comprise at least a first wire link (L1) having a first portion (Lia) interconnecting said electronic box (BE) to said antenna (AN) and a second portion (L1b) connected to said first portion (Lia) and including a sub-portion located adjacent said electrical cable (CE) and adapted to radiate said first waveform signals and / or to collect said second signals. 6. Device according to one of claims 4 and 5, characterized in that said first wire link (L1) has a type selected according to desired dimensions of a secondary radio coverage area (Z2) encompassing at least a portion of said electric cable (CE) and a part of said main radio coverage area (Z1). 7. Device according to claim 1, characterized in that said connecting means (Lj) comprise at least a first wire link (L1) interconnecting said electronic box (BE) to said antenna (AN), a second wire link (L2) connected to said electronic box (BE), and an in-line power line adapter (AC) connected to said electric cable (CE) and said second wire link (L2) and adapted to integrate said first signals into at least one current flowing in said electric cable (CE) so that the latter (CE) radiates them in the form of waves and / or to extract from said current flowing in said electric cable (CE) said third signals integrated in said current and resulting from the collection of said second signals by said electric cable (CE). 8. Device according to claim 1, characterized in that said connecting means (Lj) comprise at least a first wire link (L1) interconnecting said electronic box (BE) to said antenna (AN), and in that said electronic box (BE) is connected to said electrical cable (CE) and comprises an in-line power-line adapter (AC) connected to said electric cable (CE) and adapted to integrate said first signals into at least one current flowing in said electric cable (CE) in order for the latter (CE) to radiate them in the form of waves and / or to extract from said current flowing in said electric cable (CE) said third signals integrated in said current and resulting from the collection of said second signals by said electric cable (CE). 9. Device according to one of claims 7 and 8, characterized in that said in-line carrier adapter (AC) is passive or active type. 10. Vehicle comprising at least one electrical cable (CE), characterized in that it further comprises at least one communication device (D) according to one of the preceding claims.