EP1597829A2 - System comprising controlled-supply communication module, radio communication assembly, methods and readers - Google Patents

Abstract

The invention relates to a system for controlling a device such as a Bluetooth® communication module (18) having a self-contained power supply source (16). The inventive system comprises a receiving and detecting control unit, whereby the electromagnetic radio waves comply with a voice or data radio communication standard in a radio frequency band, said standard offering at least one function which causes the transmission, in a transmitter according to the standard, of a data packet corresponding to a defined temporal pattern consisting of moments comprising the transmission of a frequency- and/or phase-modulated radiofrequency signal, which are separated by moments comprising no transmission. According to the invention, the defined temporal pattern is transmitted by an electromagnetic generator (6) according to the standard. Moreover, the receiving and detecting unit forms a receiving circuit in the determined radio frequency band and a circuit for detection of an amplitude modulation (ASK) with a detection output. The detector is not sensitive to the frequency and/or phase modulation, the level of the detection output varying when the defined temporal pattern is received and detected. The invention also relates to assemblies, label readers and methods.

Description

 Bluetooth® communication module system with controlled power supply, radio communication system, methods and readers

The invention relates in particular to a Bluetooth® communication module system with controlled power supply as well as a radiocommunication assembly, corresponding operating and implementation methods and readers for electronic labels. It is especially intended to give Bluetooth® functionality to autonomous equipment from the point of view of power supply and over a long period of time. It can in particular be applied in autonomous recorders and wireless sensors.

Self-contained measurement equipment is known intended to record over long periods of time, months or years, certain parameters measured regularly and in particular environmental parameters of the temperature, shock or other type. The recorded measurements are then transferred to a computer system where they can be used. This equipment is used in particular to ensure the traceability and monitoring of materials, the conservation of which may depend on environmental conditions. We know in particular and by way of example an integrated circuit DS 1 61 5 from the company MAXI M® / DALLAS® which comprises memory, an electronic thermometer and a clock and which makes it possible to carry out temperature recordings regularly then transfer them by wired connection to an external computer device. The consumption of this circuit is very low by the use of CMOS type components and a low clock frequency, some kilohertz.

Other measurement equipment uses radio transfer means. However, the latter equipment cannot benefit from the autonomy and / or reduced size of the former because their consumption is much higher, the equipment, to be reactive, before be in permanent reception to be ready to transfer data on each request.

On the other hand, the patent application FR01 / 04659 or its extension PCT / FR02 / 01202 in the name of the present applicant is known to have a Bluetooth® radio module with extended software capacities. This module has a reduced consumption by implementing interrupts regularly waking up the communication or other circuits specific to a given task at a given time. However, even with these means the consumption of the module is too high to be able to hope for sufficient autonomy in a small autonomous device.

Finally, DE 1 00 44 035 discloses a mobile communication system comprising a radio frequency identification label (RFI D tag) making it possible to reactivate an associated means of communication and by EP 1 1 34 905 a sector device, the operation is remote-controlled with a capacity for receiving a different remote control signal during operation or non-operation.

The object of the present invention is in particular to be able to incorporate a Bluetooth® functionality into an autonomous equipment with incorporated power supply and which operates with an autonomy of several months to several years while being of reduced size, that is to say not requiring by a volu minous food. However, a simple addition of a Bluetooth® module to an equipment does not allow these objectives to be achieved because the module in listening mode has a consumption of several mA and therefore a power source with a capacity of several tens would be necessary. ampere hours, assuming that the equipment itself has negligible electrical consumption, to have just sufficient autonomy. Such a power source, in addition to its own cost, has a relatively large volume. ιm îιportant which opposes a miniaturization of the equipment, the electronic circuits being able, them, to be reduced to extremely small sizes.

It is therefore proposed in particular to control the supply of the Bluetooth® module as a function of reception and detection by an independent unit for reception and detection of electromagnetic waves which are emitted by an external electromagnetic generator. The Bluetooth® functionality is provided by a Bluetooth® radio modu, preferably of the type with extended software capacities of the type of the patent applications previously listed. The unit comprises a receiver and a detector with reduced consumption compared to the radio means of the module and is in permanent reception. The typical consumption of the unit is of the order of a few tens of microamps, or even less or zero depending on the degree of sophistication of said unit. The unit is preferably of the radio electronic tag type which detects the generator only at short distance. Since the module in the system is usually not supplied with power, the unit on permanent listening is of very low consumption and the circu it controlled switching power supply of said module being essentially static, the consumption of the system is extremely reduced. Adding the system to autonomous measuring equipment therefore reduces autonomy very little. It is understood that the module has at least one input, possibly at least one output, to be connected to the equipment to which one wishes to add a Bluetooth® functionality. The system being in permanent listening via the reception and detection unit, the reactivity of the system is practically instantaneous for the user, the initialization times of the Bluetooth® module being relatively low of the order of a few tens hundreds of milliseconds. The invention can be implemented with any suitable type of generator to the unit and we will see that it is even possible to use Bluetooth® radio signals to activate the system, the unit receiving and detecting said signals, which avoids having to use a specific generator.

The invention uses available functionalities of radio transmission equipment according to standards in order to be able to activate an equipment, which can in particular be a Bluetooth® module, by means of a simplified and low consumption reception and detection unit. compared to what a receiver, detector (and downstream circuits required) operating according to the standard is normally. The reception and detection unit is intended to receive and detect radio signals of some functions (in practice one) coming from radio-transmission equipment according to a standard, the unit being concerned only with amplitude variations over time radio signals in the entire frequency band of the standard and without having the possibility of decoding the function if the function requires decoding according to the standard.

The invention therefore relates to a system for controlling equipment by radio electromagnetic waves, the system comprising a reception and detection unit independent of control of the equipment, the radio electromagnetic waves being according to a radiocommunication standard for voice or data. in a radio frequency band, the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a pattern of defined temporal structure comprising moments of emission of a signal rad io-frequency modulated in frequency and / or phase separated by moments of absence of emission.

According to the invention, the pattern of defined temporal structure is emitted by an electromagnetic generator according to the standard and external to the system and the reception and detection unit is a reception circuit, in the band of determined radio frequency, and amplitude modulation detection (ASK) with a detection output, the detector not being sensitive to frequency and / or phase modulation, the level of the detection output toggling when the pattern of defined time structure is received and detected. In various embodiments of the invention, the following means can be used alone or in any technically conceivable combination, are used:

- the standard is chosen from the BLU ETOOTH®, Wi-Fi® or GSM / GPRS® protocols and, in the case of the BLU ETOOTH® standard, the radio frequency band is the ISM band 2.4GHz to 2.48G Hz , the function is an identification function and the data packet is an identity packet pattern (I D_packet), and in the case of the GSM / G PRS® standard, the function is a connection establishment function and the data packet is a random access channel (RACH) packet pattern,

- in the case of the Wi -Fi® standard, the function is a function of identification and / or establishment of connection according to the available functions,

- the equipment is an electrical device, in particular a lighting lamp, a motor for actuating a mechanism, etc.

- the equipment is an electronic device and in particular measurement equipment of the wireless recorder and / or sensor type,

- the equipment is an electronic transmitter / receiver device according to the standard, - the detection output of the reception and detection unit is connected to a decoding device making it possible to determine output states as a function of a repetition according to temporal modalities determined by switching sequences of the detection output of the unit, (the time is therefore repeated repeatedly according to a temporally determined pattern function causing in the transmitter according to the standard, the transmission of a data packet corresponding to a pattern of defined temporal structure so that the detection output has such a temporally determined pattern which can be recognized by the decoding device, the pattern temporally determined can correspond to alphanumeric signs, instructions, data ... which allows in particular a data transmission)

- the decoding device is integrated into the equipment,

- the decoding device is separate from the equipment and from the reception and detection unit, - the decoding device is integrated into the reception and detection unit,

the system is intended for switching the electrical power supply to the equipment and that the detection output of the reception and detection unit is connected to a control input of a controlled power supply switching circuit. equipment so that when the detection output switches, the equipment is supplied,

- the controlled supply switching circuit includes at least one passive device for switching the supply,

the passive device is an electromagnetic relay, the controlled supply switching circuit includes at least one active device for switching the supply,

the switching control circuit further comprises voltage regulation means,

the active device is a power transistor, the controlled supply switching circuit comprises at least one power MOS transistor with control gate ensuring the switching of the supply,

- the equipment is a Bluetooth® communication module comprising an autonomous power source, the communication being with controlled supply, the unit of reception and detection of electromagnetic waves is according to the amplitude modulation (ASK) for detection of an identity packet (I D_Packet) of type DAC or IAC emitted by the generator external electromagnetic according to the BLUETOOTH® standard, the detection output of the reception and detection unit being connected to the control input of the controlled switching power supply circuit so that, when the radio electromagnetic wave of the function transmission of identification packet (I D_packet) is received and detected by the unit, the Bluetooth® communication module is powered by the autonomous power source,

- the reception and detection unit is a passive electronic label, the supply of the label being provided by the electromagnetic generator, the electromagnetic waves of the electromagnetic generator being used for supplying the label, - the reception and detection unit is an active electronic label, the label being supplied by an independent power supply to the equipment,

- the active electronic label includes a periodic activation means allowing the reception and detection unit to operate according to a periodic repetition of standby for a duration T1 followed by listening to a duration of time TO in order to reduce consumption,

the periodic activation means furthermore allows the reception of a transmission of a radio frequency signal in the frequency band to cause for a determined time the reduction of the duration of standby or the disappearance of the standby,

- T1> TO,

- the minimum possible values of times T1 and TO are determined as a function of the defined temporal structure pattern,

- times T1 and / or TO are constant, - times T1 and / or TO have random durations,

- the determined time of reduction of the duration of standby or disappearance of standby is greater than or equal to the sum of the time separating two successive transmissions of a pattern of defined structure and the duration of a pattern of defined temporal structure,

the controlled supply switching circuit further comprises a delay means activatable by the control input and making it possible to maintain the supply of said equipment for a predetermined hold time after an end of detection of the electromagnetic wave, l the supply of the equipment being cut off at the end of the predetermined holding time whether or not there have been new detections during the holding time,

the controlled supply switching circuit further comprises a delay means activatable by the control input and making it possible to maintain the supply of said equipment for a predetermined initial holding time after an end of detection of the electromagnetic wave , the power supply to the equipment being cut off at the end of the predetermined hold time in the absence of new detection during the hold, the detection of the electromagnetic wave during the hold causing the continuation of the hold during the detection and holding for the predetermined holding time at the end of the detection,

the equipment comprises a supply control output connected to a second control input for the controlled supply switching circuit, the equipment thus being able to directly control its supply once supplied following the detection of electromagnetic waves,

the system includes a watchdog for monitoring the supply, the controlled supply switching circuit comprising the time delay means activatable by the command input with detection of the electromagnetic wave during the hold time causing the continuation of the hold for a new predetermined hold time, the delay means is also activatable by the second command input of the controlled circuit of switching of power supply, said second input being active on a transition, the equipment having to regularly send said transitions to its power control output in order to maintain its power supply,

- the activatable delay means is replaced by a logic flip-flop with at least one R / S function and with:

- an arming input (S),

- a disarming input (R), the arming input being connected to the detector output and the disarming input being connected to the power control output. The invention also relates to a method of operating a system with a control module for equipment by radio electromagnetic waves, the system comprising a reception and detection unit independent of the equipment, the radio electromagnetic waves being according to a standard for radiocommunication of voice or data in a radio frequency band, the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a time structure pattern defined comprising moments of emission of a radio frequency signal modulated in frequency and / or phase separated by moments of absence of emission.

According to the method, with a system having one or more of the preceding characteristics, the pattern of temporal structure defined by an electromagnetic generator according to the standard and external to the system is transmitted and a reception and detection unit is implemented. control which is a circuit for receiving, in the determined radio frequency band, and for detecting an amplitude modulation (ASK) with a detection output, the detector not being sensitive to frequency modulation and / or phase, the level of the detection output toggles when the pattern of defined time structure is received and detected.

The method of the invention can be applied according to all the operational methods that can be envisaged in relation to one or more of the previously listed material means of the system, and, in particular in a variant of the method, an equipment is implemented which is a module of Bluetooth® communication with autonomous power source, and that the power supply of the module is controlled according to the reception and detection of electromagnetic waves emitted by the electromagnetic generator according to the Bluetooth® standard with a controlled switching circuit supply of said communication module comprising a control input, the detection output having been connected to the control input of the controlled supply switching circuit so that when the detection output switches, the Bluetooth® communication module is powered, the external generator operating in the ISM 2.4 GHz radio frequency band at 2.48G Hz with a function which is an identification function and a data packet which is an identity packet pattern (I D_packet).

The invention also relates to a radiocommunication assembly comprising at least one system for controlling equipment by radio electromagnetic waves and at least one electromagnetic generator physically independent of the system, the system comprising a reception and detection unit for control independent of the equipment, the electromagnetic radio waves being according to a radiocommunication standard for voice or data in a determined radio frequency band, the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a pattern of defined temporal structure comprising moments of emission of a radio-frequency signal modulated in frequency and / or phase separated by moments no transmission, in which the assembly includes a system according to one or more of the characteristics listed above, the command reception and detection unit being a reception circuit, in the determined radio frequency band, and detection of an amplitude modulation (ASK) with a detection output, the detector is not sensitive to frequency and / or phase modulation, the level of the detection output toggles when the pattern of defined time structure is received and detected, and in that the time structure pattern is emitted by an electromagnetic generator according to the standard.

In various modes of implementation of the set:

- the unit for receiving and detecting electromagnetic waves is an electronic label and the generator is an electronic label reader,

- the equipment is a Bluetooth® communication module comprising an autonomous power source, the communication module being with controlled power supply, the system being intended for switching the power supply of the communication module and the detection output of the label being connected to a control input of a controlled circuit for switching the power supply of the communication module so that when the detection output switches, the communication module is supplied, and in that the reader electronic label also includes a Bluetooth® radio communication device that can communicate with a basic stati on and the system module,

- the equipment is a Bluetooth® communication module comprising an autonomous power source, the communication module being with controlled supply, the system being intended for switching the power supply of the communication module and the detection output of the label being connected to a control input of a controlled circuit for switching the power supply of the communication module so that when the detection output switches, the communication module is supplied, and in that the electromagnetic generator of the electronic label reader operates in the radio frequency band ISM 2.4 GHz to 2.48 GHz with a function which is an identification function and a packet which is an identity packet pattern (I D_packet). The invention also relates to a method for implementing the above radiocommunication assembly in which in:

- a first phase, the electronic tag reader is activated in order to generate electromagnetic waves allowing the reception and detection unit to control the supply of the Bluetooth® module and supply the said module,

- a second phase, at least one data exchange is carried out between the Bluetooth® module and the Bluetooth® radiocommunication device of the electronic tag reader, - in a third phase, the Bluetooth® module controls the cutting of its own power supply.

The invention finally relates to a first electronic tag reader for generation of radio electromagnetic waves intended for the control of a system comprising a receiving unit and control detection independent of the equipment, the radio electromagnetic waves being according to u ne standard for radio communication of voice or data in a determined radio frequency band, the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a structural pattern time defined comprising moments of emission of a radio frequency signal modulated in frequency and / or phase separated by moments of absence of emission, in which the system is according to one or more of the corresponding characteristics previously listed of the system , where the reception and detection unit is a circuit for receiving, in the determined radio frequency band, and for detecting an amplitude modulation (ASK) with a detection output, the detector not being sensitive to the frequency and / or phase modulation, the level of the detection output toggling when the pattern of defined time structure is received and detected, said reception and detection unit being an electronic tag and the pattern of defined time structure being transmitted by the electromagnetic generator of the label reader according to the standard, the label reader further comprising a Bluetooth® radio communication device can communicate the reader with a base station and the system module.

Finally, the invention relates to a second electronic tag reader for generating radio electromagnetic waves intended for controlling a system comprising a reception and detection unit independent of the equipment, the electromagnetic waves being radio according to a standard for radiocommunication of voice or data in a radio frequency band, the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a pattern of defined time structure comprising moments of emission of a radio frequency signal modulated in frequency and / or phase separated by moments of absence of emission, in which the system is according to one or more of the corresponding characteristics listed above of the system, where the command reception and detection unit is a reception circuit, in the determined radio frequency band, e t detection of amplitude modulation (ASK) with a detection output, the detector not being sensitive to frequency and / or phase modulation, the level of the detection output toggles when the defined time structure pattern is received and detected , and the reception and detection unit is an electronic label intended to receive and detect electromagnetic waves according to the Bluetooth® standard, and the electronic label reader comprises an electromagnetic generator which is a radiocommunication device emitting according to the standard Bluetooth®, the radio frequency band being the ISM band 2.4GHz to 2.48GHz, the function being an identification function and the data packet being an identity packet pattern (I D_packet).

According to another mode of presentation of the invention which relates more particularly to an application with Bluetooth® communication module, the invention relates to a system with Bluetooth® communication module comprising at least:

- an autonomous power source,

- the Bluetooth® communication module.

According to the invention according to this other modality, the module is with controlled power supply, the system further comprising:

- a controlled power supply switching circuit of said communication module with a control input,

a unit for receiving and detecting electromagnetic waves emitted by an external electromagnetic generator, the unit being independent of the module and comprising a detection output, the detection output being connected to the control input of the controlled switching circuit power supply so that when the electromagnetic wave is detected by the unit, the Bluetooth® communication module is supplied. In various embodiments of the invention presented according to this other modality, the following means can be used alone or in any technically conceivable combination, are used (these means can also be used in the invention in its generality such as previously presented):

the controlled supply switching circuit comprises at least one passive device for switching the supply,

- the passive device is an electromagnetic relay,

the controlled supply switching circuit includes at least one active device for switching the supply,

the switching control circuit further comprises voltage regulation means,

- the active device is a power transistor,

the controlled supply switching circuit comprises at least one power MOS transistor with control gate ensuring the switching of the supply,

the electromagnetic wave reception and detection unit detects in a specific reception range any wave whose level of the electromagnetic field is greater than a predetermined level,

(the specific term corresponds to a reception band according to a particular standard)

the unit for receiving and detecting electromagnetic waves further comprises means for detecting a particular electromagnetic wave, the particular electromagnetic wave is a wave according to the Bluetooth® standard,

the unit for receiving and detecting electromagnetic waves further comprises means for detecting a particular electromagnetic wave, the particular electromagnetic wave being a wave according to the Bluetooth® standard and all-or-nothing modulation of identity package (ID_Packet) of DAC or IAC type,

- the means of detecting the particular electromagnetic wave with all or nothing modulation by identity packet (ID_Packet) of DAC or IAC type according to the Bluetooth® standard comprises a modulation counter and a delayed counter reset circuit including the delay is reset by a modulation, so that the detection output does not switch over until after reception of a predetermined number of all-or-nothing modulations of identity packet (ID_Packet), each separated from the next by a time less than delay,

- the reception and detection unit is of the radio electronic tag (“TAG”) type with detection output,

- the electronic label is passive, the unit being supplied by the external electromagnetic generator, the electromagnetic waves from the generator being used to supply the label,

- the electronic label is active, the unit being supplied by the power source,

the controlled supply switching circuit further comprises a delay means activatable by the control input and making it possible to maintain the supply of said module for a predetermined hold time after an end of detection of the electromagnetic wave, l the module supply being cut off at the end of the predetermined hold time whether or not there have been new detections during the hold time,

the controlled supply switching circuit further comprises a delay means activatable by the control input and making it possible to maintain the supply of said module for a predetermined initial holding time after an end of detection of the electromagnetic wave, the module supply being cut off at the end of the predetermined hold time in the absence of new detection during the maintenance, the detection of the electromagnetic wave during the maintenance causing the continuation of the maintenance during the detection and the maintenance during the predetermined maintenance time at the end of the detection, - the time delay means is a capacity arranged on the control gate of a power MOS transistor ensuring the switching (or regulation) of the power supply,

- the timing means is a timed monostable circuit,

- the new predetermined hold time is equal to the predetermined initial hold time,

- the new predetermined hold time is greater than the predetermined initial hold time,

- the new predetermined hold time is less than the predetermined initial hold time,

- the module includes a power control output (or forcing) connected to a second control input of the controlled power switching circuit, the module can thus directly control its power once powered after the detection of electromagnetic waves ,

the controlled supply switching circuit includes a delay means which can be activated by the second control input,

- the controlled supply switching circuit includes a single activatable delay means,

- the system comprises a watchdog for monitoring the supply, the controlled supply switching circuit comprising the delay means which can be activated by the control input with detection of the electromagnetic wave during the provocative holding time continuation of the hold for a new predetermined hold time, the delay means can also be activated by the second control input of the circu it controlled switching of power supply, said second input being active on a transition, the module having to regularly send said transitions to its power control output in order to maintain its power supply,

- the activatable delay means is replaced by a logic flip-flop with at least one R / S function and with:

- an arming input (S),

- a disarming input (R), the arming input being connected to the detector output and the disarming input being connected to the power control output, - the power source is electrochemical of the battery type or drums,

the module also comprises an inhibition output intended to allow the inactivation of the detection output of the unit,

- the module is connected to at least one sensor,

- the sensor is chosen from temperature, pressure, humidity, sound, brightness, vibration sensors,

the sensor comprises an independent recording means with memorization of measurements in a memory, the module being able to read the said memory when it is powered,

- the module is connected to an electrically (re) programmable memory, - the module includes an electrical control output of an external electrical device,

- the module includes an electronic communication output with an external electronic device,

- the command or communication output for the external device is isolated by photo-coupler. The invention according to this other modality also relates to a method of operating a system with a Bluetooth® communication module with an autonomous power source in which the supply of the module is controlled and a system is implemented according to the one or more of the preceding claims with: a controlled power supply switching circuit of said communication module with a control input,

a unit for receiving and detecting electromagnetic waves emitted by an external electromagnetic generator, the unit being independent of the module and comprising a detection output, the detection output having been connected to the control input of the controlled switching circuit power supply so that when the electromagnetic wave is detected, the Bluetooth® communication module is supplied.

The method of the invention according to this other modality can be declined according to all the operational modalities which can be envisaged in relation to one or more of the material means previously listed in the system according to this other modality.

The invention according to this other modal ity also relates to a radiocommunication assembly. According to this part of the invention according to this other modality, the assembly comprises:

- At least one system according to any one or more of the preceding characteristics and comprising an autonomous power source, a Bluetooth® communication module with power controlled by a power switching circuit controlled by a reception and detection unit. 'electromagnetic waves,

- At least one electromagnetic generator physically independent of the system making it possible to generate electromagnetic waves capable of controlling the supply of the module via the reception and detection unit.

In various modes of implementation of the whole of the invention according to this other modality: -the unit for receiving and detecting electromagnetic waves is an electronic label and in that the generator is an electronic label reader, and / or: - the electronic label reader also includes a Bluetooth® radio communication device able to communicate with a base station and the system module.

The invention according to this other modality also relates to a method of implementing the preceding radiocommunication assembly according to the invention according to this other modality and in which in: - a first phase, the electronic tag reader is activated in order to generate electromagnetic waves allowing the reception and detection unit to control the power supply of the module

Bluetooth® and power said module,

a second phase, at least one data exchange is carried out between the Bluetooth® module and the Bluetooth® radiocommunication device of the electronic tag reader,

- a third phase, the Bluetooth® module controls the shutdown of its own power supply.

The invention according to this other modality also relates to an electronic label reader for the generation of electromagnetic waves intended for the control of a system according to any one or more of the preceding corresponding characteristics and comprising an autonomous power source. , a Bluetooth® communication module with power supply controlled by a power switching circuit controlled by a unit for receiving and detecting electromagnetic waves, said unit being an electronic tag, said reader further comprising a radio communication device from the generator Bluetooth® capable of communicating the reader with a base station and the system module. The invention according to this other modality finally relates to an electronic tag reader for generation of electromagnetic waves intended for the control of a system according to any one or more of the preceding corresponding characteristics and comprising an autonomous power source, a Bluetooth® communication module with power supply controlled by a power switching circuit controlled by an electromagnetic wave reception and detection unit, said unit being an electronic tag intended to receive and detect electromagnetic waves according to the Bluetooth® protocol, the dud it reader generator being a Bluetooth® radio communication device capable of communicating the reader with a base station and the system module.

The invention, by adding a unit for receiving and detecting electromagnetic waves and a controlled supply switching circuit, the costs of which can be low and the physical footprint reduced, makes it possible to benefit from Bluetooth® functionality in long-lasting equipment without having to use a bulky and expensive power source. The advantage of an active tag type unit over passive tags is the increased range. In any event, the power consumption of a radio tag remains much lower than the consumption of a Bluetooth® module in listening mode.

The present invention will now be exemplified without being limited thereto with the description which follows in relation to the following figures: FIG. 1 which represents a system according to the invention, FIG. 2 which represents an operational diagram of the operation of an application implementing the system of the invention, Figure 3 which represents an example of an electronic diagram of the system. The Figu re 1 system includes a unit for receiving and detecting electromagnetic waves which is a radio electronic tag 1 0 (“TAG”), a source of electrical power 1 6, a Bluetooth® module 1 8 and means for switching the power supply of the Bluetooth® module 1 8. The radio electronic label 1 0 comprises an antenna 1 1 intended to receive waves from an external generator not shown and a reception and detection circuit 1 2 comprising a integrated circuit (“RF IC”) producing a control signal 1 3 on a detection output when the generator adapted to the label is in operation. Conventionally, in the case of a label, the integrated circuit of the label performs the decoding, respectively the coding, of the information received, respectively sent. The label therefore exchanges information with the external generator. The integrated circuit can record an identifier in a reprogrammable non-volatility memory (of the EEPROM type). This identifier is a character string from a few bytes to a few kilobytes. The size of the information contained in the chip is limited by the memory capacity and by the radio transmission speed. A Bluetooth® module has no imitation of this type, it can store information of the image, video or sound recording type. In a simplified version, the label is simply receiving. However, an identifier label allows specific activation of the module according to an identifier.

The link 1 7 for supplying the label has been shown in dotted lines since the latter may be passive, not requiring its own supply, or, as shown, active, requiring its own supply. The electronic label therefore includes an integrated circuit and an antenna. This antenna in the case of a passive tag has a role, both of inductance making it possible to generate an induced supply current from a wave electromagnetic incident and antenna allowing the reception of the radio signal. In the case of a so-called passive label, the integrated circuit is powered by the induced current. This induced current is generally quite low and the energy available for the emission of the label is consequently reduced, which results in a reading range reduced to a few centimeters, or even more depending on the frequency. As for the active electronic label, it operates on the same principles except that it includes a power source. This increases its power and therefore the reading distance. However, we are still limited in speed and memory capacity as well as reading distance compared to a Class 1 version of Bluetooth® with a transmission power of 1,00mW.

It is also possible to use hybrid sol utions in which the label includes a rechargeable battery. The battery can, for example, be recharged by ind uction, label placed on a recharging generator for an extended time. It can also be recharged by solar cells during the lighting periods of the solar cell label. Although the charging current is low, the battery is recharged for an extended time and accumulates significant energy which can be restored almost instantaneously when the label is activated, which can allow a greater range (type of operation active). In such a hybrid model, an energy management system can re-pass the label in short range mode operating only with the induced current (passive type operation) by the generator when the battery is charging is insufficient so that the label can always be activated regardless of the battery charge level.

The Bluetooth® module 1 8 is connected to an antenna 1 9 for exchanges according to the Bluetooth® standard and to equipment not represented by inputs outputs 9, by example a temperature or position sensor. The module 1 8 also has a power supply control output 14 which acts concurrently with the control signal 1 3 of the label detection output, on the means enabling the power to be switched. The latter essentially comprise, in this example, a regulator 1 5 controlled by the two previously indicated outputs, of the module and of the label in order to make the regulator functional during a detection to supply the modu on 1 8, to maintain the 'supply or cut the supply according to the orders of the module 1 8. The regulator is connected upstream to the battery by a link 20 permanently supplied and downstream to the module by a link 21 supplied or not according to order.

In FIG. 2, the system of the invention is incorporated in an autonomous equipment 7, the “BluetoothTAG” sensor, which comprises a sensor, for example of temperature. An independent device 6 includes a generator, “TAG” reader, intended to activate the module by means of a detection of its signal by the radio electronic tag. The device 6 further comprises a Bluetooth® module Bl allowing radio exchanges in particular with the equipment 7 comprising the system of the invention and with a remote base station 8. User interfaces, in particular a display screen, complete the apparatus 6. The apparatus 6 is in particular what is conventionally called "an electronic label reader" (simple reader or reader / label programmer) such as used for inventory management but which also includes means of radio connection according to the Bluetooth® protocol to allow remote exchanges (without "wire to paw") with a base station, conventionally a computer server inventory management. This device 6 can therefore also be used for simple reading or reading / programming of electronic labels. and exchanges with the base station, only for the activation of the "BluetoothTAG" sensor of the invention and exchanges with the latter via the Bluetooth® link.

The scenario for using this set in Figure 2 is as follows. Initially the Bluetooth® module of the “BluetoothTAG” sensor 7 (the equipment) is switched off (the voltage regulator / control transistor acts as a blocking switch). An operator seeks to exchange information with the sensor 7 via a Bluetooth® link and activates the generator, “TAG” reader, of the device 6 in order, for example, to write in a non-volatile memory of the electronic tag via radio wave. This activation which causes detection by the label and the power supply of the equipment module 7 corresponds to reference 1. The Bluetooth® module of the equipment 7 is now powered and goes into listening mode. A data exchange can then take place between the operator's device 6 and the Bluetooth® module of the equipment 7, which is referenced by 2 and 3. Once the data exchange has been carried out, the Bluetooth® module of the equipment 7 commands the voltage regulator to switch to blocking mode which turns off the Bluetooth® module of the equipment 7. Finally, FIG. 2 shows the possibility of exchanging data by the references 4 and 5 between the apparatus 6 and a base station 8. It is understood that once the equipment module 7 is supplied, it can also communicate with any other means of Bluetooth® radio communication of its environment and, for example, directly with the base station. Therefore, data exchanges between the "BluetoothTAG" sensor and other computer equipment can therefore be done either by the intermediary of the device 6 then of the base station 8 and the same connected to said equipment, or by only through the base station 8 itself connected to said equipment, either directly on this other equipment IT if the latter is in the radio communication environment of the "BluetoothTAG" sensor and has Bluetooth® radio means.

In a first case, the reading device 6 has, as shown in FIG. 2, two transmitters / receivers, one for the "TAG" reader (its receiver can possibly be omitted) and one for the Bluetooth® module.

In a second case, not shown, the reading device 6 has a single transmitter / receiver, the Bluetooth® module only, and this in case the “BluetoothTAG” sensor can be directly activated and supplied following reception by the unit for receiving equipment 7 of Bluetooth® radio signals.

The first case is where the coding used by the electronic label is dissociated from the coding used by the Bluetooth® protocol of the sensor module

“BluetoothΘTAG” 7. In this case, the label part of the equipment 7 may include its own programming means.

The second case is that where the electronic label of the equipment 7 uses the frequency of 2.4 GHz which corresponds to the frequency of the Bluetooth® standard and, preferably, in this case, the label detects the signal or packet of identity (ID_Packet) as defined in version 1.1. (sped .1) of the Bluetooth® standard, page 55, chapter "4.4.1 .1 ID Packet". This identification (ID_Packet) corresponds according to this standard to the access code of the device ("Device Access Code" or DAC) or access search code ("Inquiry Access Code" or IAC) forming a data packet of a length of 68 bits. This type of packet is used to search for remote Bluetooth® devices. It takes the form of an alternating sequence of 68 ms or “burst” with a non-zero radio frequency amplitude on a carrier of 2.4 GHz and followed by 244.5 ms without emission. This 68ms emission burst followed by 244.5 ms without transmission, forming a period of the identity packet, is repeated and corresponds to a time modulation.

It can be noted that although the Bluetooth® standard uses radio communication with frequency hopping, the frequency selectivity of the label is such that the frequency hopping of the Bluetooth® transmission is not detectable by the label and that 'it receives all the Bluetooth® signal inside its reception band, the electronic label only "sees" one carrier at 2.4G Hz. In practice the label reception band is at least the width of the frequency band including jumps according to the Bluetooth® standard.

At 1 m distance, with a Bluetooth® Class 2 transmitter (+ 4dBm = 2.5mW approximately), the signal received at the label is -50dBm. To ensure detection and possible decoding of this time modulation (68ms of emission, 244.5ms without emission) it is desirable to use a resonant antenna on the 2.4G Hz frequency with a high overvoltage coefficient but, however , a selectivity allowing to receive the signal in spite of the jumps in frequency. There is also a signal amplification circuit in the label. Preferably, the amplification circuit is switchable so as to activate it only periodically in order to reduce the average consumption of the system. Thus, for example, the amplifier can be operated for 1 s every 10 s, which makes it possible to have a satisfactory level of amplification on average with a substantial reduction in average consumption. The values given are only examples. The switching of the amplification circuit, in addition to all or nothing, can also affect the amplification level in order to adapt the amplification to the environment (near or distant transmitter). Thus, it is envisaged to increase the amplification to allow connection from further away only when necessary. Indeed, in general, the greater the amplification, the more the consumption increases.

In addition, it is also possible to make the maintenance of the amplification (or the operation of the label, more generally,) for a determined time dependent on the presence or not of a modulation. It is then possible to reduce the duration of amplification (or operation) to a minimum time corresponding to a period of the identity packet signal (68 + 244, 5 ms) and in the presence of a modulation to maintain the amplification ( or operation) to allow detection of a number of modulations with Bluetooth® identity packet characteristics.

The means for detecting the identity packet (ID_Packet) in the label can be a simple binary counter whose reset to zero is delayed (the reset timer is reset by reception of a signal) by a delay greater (in practice slightly greater) than the time between two successive bursts, ie greater than 244.5 ms, the counter thus making it possible to count a certain number of modulations which must be repeated regularly with a given periodicity before an output switches.

In this second case, it is therefore possible to use a label reader 6 using Bluetooth® as a radio interface to a communication network with one or more computer equipment. The Bluetooth® interface of the reader 6 can then serve both as a connection protocol between the reader 6 and a base station 8 or a network, as well as a communication protocol between the reader 6 and a “BluetoothTAG” sensor 7 .

The electromagnetic wave reception and detection unit can be simplified to the extreme by being almost passive and include, downstream of a possible antenna, an LC frequency selection circuit followed by a detector with a rectifying diode and filtering capacity output or a voltage doubling detector with two diodes and capacities. A voltage amplifier, for example a transistor, can optionally be provided at the detector output if the generator field is insufficient to allow a level to be produced at the detector output enabling the controlled supply switching circuit to be controlled.

FIG. 3 shows an example of a system comprising such a simplified unit. The unit corresponds to the circuits of block 1 0 or 1 0 'in the case of additional LC bridge filtering. The unit 1 0 comprises an antenna 1 1 on a frequency selection LC circuit followed by a capacity driving a rectifier / demodulator with voltage doubling with two capacities and diodes. The diodes are preferably H F diodes. If the sensitivity of the unit is too high, a resistive load or resistive divider bridge can be added at the output. The signal output detected in the unit goes to high 1 when a signal sent by an external generator of suitable frequency is detected.

The signal output detected in the unit is sent to a first input of an AND gate 25 which, when the Bluetooth® module 1 8 is not supplied, receives a high signal 1 on its second input, line 25 ' module inhibition being low 0 and passing through a 25 "inverter. When the module 1 8 is supplied, the signal 25 'can be set high which blocks the output of gate AND 25 low 0 preventing new ones activations by detection The output of the AND gate is sent to a first input of an OR gate 24 receiving by its second input a forcing line 24 'coming from the module 1 8 and intended when it is 1 to force the power supply of the module The output of the OR gate 24 is sent to a diode, capacitance and (if any) resistance timing circuit allowing the gate voltage of a MOS transistor 22 to be kept high for 1 time determined after the output of the OR gate 24 has gone to low 0. The MOS transistor 22 is mounted as a switch (gate at 0) / conductor (gate at 1) of the supply 1 6 entering the transistor 22 through the line 20 and returned to module 18 by line 21. The module 18 includes an antenna 19 and inputs / outputs 9 to in particular a sensor or the like. The module 18 being physically close to the unit 1 0, 1 0 ', the inhibition line 25' makes it possible to prevent transmissions from the module 18 received and detected by the unit 1 0, 1 0 'causing a involuntary persistence of feeding in the case of a simplified unit.

In this example of FIG. 3, an inhibition line 25 ′ and a forcing line 24 ′ from module 1 8 have been used. These two lines are connected to the low potential 0 (ground) by resistors so that l hen module 1 8 is not powered, their levels are at zero. However, in order to reduce consumption, as far as possible, avoid loading (too much) the module lines or other lines. In other embodiments, a single line can be used which has these dual functions: forcing preventing the action of a detection. In case the module 1 8 requires a regulated voltage, a voltage regulator is interposed in the supply line of the module, either on line 20, or, preferably, on line 21 or in common with transistor 22 , the regulator then being controlled.

Thus, it is preferable that it is the module 1 8 which can control the maintenance and stopping of the power supply once activated by signal detection by the unit 1 0.

In more advanced and active versions, the unit is a direct or heterodyne receiver. However, a unit is preferred in which the high frequency part is reduced to the minimum possible and / or there is no high frequency oscillator. Indeed, in addition to consumption additional due to high frequency operation, shielding problems (radio frequency compatibility) or stability may arise. In the latter case, the system may be required to operate under extreme environmental conditions (temperature for example) or under a voltage which varies over time, in particular at the end of the life of the power source, a receiving unit too Selective may become non-operational when a less selective unit could have continued to operate. The unit is therefore chosen according to the applications and the autonomy envisaged. In order to guarantee correct operation of the system in the case where the module can directly control its power supply, it is ensured that when the power to the module is cut, the power control output remains stable (corresponding level at the cut). Otherwise, if the level of the power control output varies (goes back to a level corresponding to power supply), there will be a refeeding of the module and the latter can never be practically de-energized. Preferably, the level corresponding to the cut-off will be 0 (zero voltage le) and for power supply level 1 (high voltage). With such a choice of levels, in the event that the level of the power control output varies when the module is cut off, an integrator filter may be provided on the second control input of the controlled switching circuit. supply in order to prevent the passage of a high transient during the power cut. It is understood that one of the aims of the invention being to reduce the consumption of the system when it is not in use, it is possible, as an alternative to cutting the supply to the module which is the preferred solution and described in detail, choose, instead of cutting the power and in case the module can be placed in a low mode consumption (sleep), to command the standby rather than cutting the power, the controlled power switching circuit instead of acting on the module power acting on the standby control input of the module. The latter solution has the advantage of not requiring a power element in the controlled supply switching circuit, the intensity to be sent to the standby control input of the module being extremely low.

Claims

1. System for controlling equipment by radio electromagnetic waves, the system comprising a reception and detection unit independent from the equipment, radio electromagnetic waves being according to a radiocommunication standard for voice or data in a radio frequency band , the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a pattern of defined temporal structure comprising moments of emission of a radio-frequency signal modulated in frequency and / or phase separated by moments of no transmission, characterized in that the defined time structure pattern is transmitted by an electromagnetic generator (6) according to the standard and external to the system and in that the reception unit and detection is a reception circuit, in the determined radio frequency band, and detection of an amplitude modulation (ASK) with a detection output, the detector not being sensitive to frequency and / or phase modulation, the level of the detection output toggling when the pattern of defined time structure is received and detected.

2. System according to claim 1, characterized in that the standard is chosen from the BLU ETOOTH®, Wi-Fi® or GSM / GPRS® protocols and, in the case of the BLUETOOTH® standard, the radio frequency band is the ISM band 2.4GHz to 2.48G Hz, the function is an identification function and the data packet is an identity packet pattern (I D_packet), and in the case of the GSM / GPRS® standard, the function is a connection establishment function and the data packet is a random access channel (RACH) packet pattern.

3. System according to claim 2, characterized in that it is intended for switching the electrical supply of the equipment and that the detection output of the reception and detection unit is connected to a control input of a controlled circuit (1 5, 22) for switching the power supply of the equipment so that when the detection output switches, the equipment is supplied.

4. System according to claim 3, characterized in that the equipment is a Bluetooth® communication module (1 8) comprising an autonomous power source (1 6), the communication module being with controlled power, the unit (10) for receiving and detecting electromagnetic waves is according to amplitude modulation (ASK) for detection of an identity packet (ID_Packet) of DAC or IAC type transmitted by the external electromagnetic generator (6) according to the BLUETOOTH® standard, the detection output of the reception and detection unit being connected to the control input of the controlled power switching circuit so that, when the radio electromagnetic wave of the packet transmission function identification (I D_packet) is received and detected by the unit, the Bluetooth® communication module is powered by the autonomous power source.

5. System according to claim 1, 2, 3 or 4, characterized in that the reception and detection unit is a passive electronic label (1 0), the supply of the label being provided by the electromagnetic generator. , the electromagnetic waves of the electromagnetic generator being used to supply the label.

6. System according to claim 1, 2, 3 or 4, characterized in that the reception and detection unit is an active electronic label (10), the supply of the label being ensured (1 7) by a source autonomous supply (1 6) of the equipment.

7. System according to any one of claims 3 to 6, characterized in that the controlled supply switching circuit further comprises a delay means activatable by the control input and making it possible to maintain for a predetermined holding time the supply of said equipment after an end of detection of the electromagnetic wave, the supply of the equipment being cut off at the end of the predetermined hold time whether or not there have been new detections during the hold time .

8. System according to any one of claims 3 to 6, characterized in that the controlled supply switching circuit further comprises a delay means (23) activatable by the control input and making it possible to maintain for a time of predetermined initial maintenance of the supply of said equipment after an end of detection of the electromagnetic wave, the supply of the equipment being cut off at the end of the predetermined maintenance time in the absence of n new detection during maintenance, the detection of the electromagnetic wave during the maintenance causing the continuation of the maintenance during the detection and the maintenance during the predetermined maintenance time at the end of the detection.

9. System according to one of claims 7 or 8, characterized in that the equipment comprises a power control output (24 ') connected to a second control input of the controlled power switching circuit, the equipment thus being able to directly control its supply once supplied following the detection of electromagnetic waves.

1 0. System according to claim 9, characterized in that it comprises a watchdog for monitoring the supply, the controlled supply switching circuit comprising the delay means activatable by the control input with detection of wave electromagnetic during the hold time causing the hold to continue for a new predetermined hold time, the delay means can also be activated by the second control input of the controlled power switching circuit, said second input being active on a transition , the equipment must regularly send said transitions to its power control output in order to maintain its power.

1 1. System according to claim 9, characterized in that the activatable delay means is replaced by a logic flip-flop with at least one R / S function and with: - an arming input (S),

- a disarming input (R), the arming input being connected to the detector output and the disarming input being connected to the power control output.

1 2. Method of operating a system for controlling equipment by radio electromagnetic waves, the system comprising a reception and detection unit independent of control of the equipment, the radio electromagnetic waves being according to a radiocommunication standard of voice or data in a radio frequency band, the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a pattern of defined time structure comprising transmission moments d '' a radio-frequency signal modulated in frequency and / or phase separated by moments of no transmission, characterized in that with a system according to any of the preceding claims, the time pattern is transmitted defined by an electromagnetic generator (6) according to the standard and external to the system and in that a reception and detection unit is implemented controls that i is a circuit for receiving, in the determined radio frequency band, and for detecting an amplitude modulation (ASK) with a detection output, the detector not being sensitive to frequency and / or phase modulation, the level of the detection output toggling when the defined time structure pattern is received and detected.

1 3. Method according to claim 1 2, characterized in that one implements an equipment which is a module (1 8) of Bluetooth® communication with power source (1 6) autonomous, and that one controls the supply of the module as a function of the reception and detection of electromagnetic waves emitted by the electromagnetic generator according to the Bluetooth® standard with a controlled circuit (15) for switching the supply of said communication module (18) comprising an input of control, the detection output having been connected to the control input of the controlled power switching circuit so that when the detection output switches, the Bluetooth® communication module is supplied, the external generator operating in the frequency band ISM 2.4GHz to 2.48G Hz radio with a function which is an identification function and a data packet which is an identity packet pattern (ID_packet).

14. Radiocommunication assembly comprising at least one system for controlling equipment by radio electromagnetic waves and at least one electromagnetic generator physically independent of the system, the system comprising a reception and detection unit for control independent of the equipment, radio electromagnetic waves being according to a standard for radiocommunication of voice or data in a determined radio frequency band, the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a structural pattern defined time comprising moments of emission of a radio-frequency signal modulated in frequency and / or phase separated by moments of absence of emission, characterized in that it comprises a system according to any one of claims 1 to 1 1, the command reception and detection unit being a reception circuit, in the determined radio frequency band, and for detecting amplitude modulation (ASK) with a detection output, the detector not being sensitive to frequency and / or phase modulation, the level of the detection output toggling when the defined time structure pattern is received and detected, and in that the time structure pattern is emitted by an electromagnetic generator (6) according to the standard.

15. Radiocommunication assembly according to claim 14, characterized in that the unit (1 0) for reception and detection of electromagnetic waves is an electronic label and in that the generator (10) is a reader (6) of electronic tag.

16. Radiocommunication assembly according to claim 1 5, characterized in that the equipment is a Bluetooth® communication module (1 8) comprising an autonomous power source (1 6), the communication module being with controlled supply, the system being intended for switching the power supply to the communication module and the label detection output being connected to a control input of a controlled circuit (15, 22) for switching the power supply to the communication module communication so that when the detection output switches, the communication module is supplied, and in that the electronic tag reader also includes a Bluetooth® radio communication device which can make it communicate with a base station and the module (1 8) of the system.

1 7. Radiocommunication assembly according to claim 1 5, characterized in that the equipment is a Bluetooth® communication module (1 8) comprising an autonomous power source (1 6), the communication module being powered ordered, the system being intended for switching the power supply of the communication module and the detection output of the label being connected to a control input of a controlled circuit (1 5, 22) for switching the power supply of the communication module so that when the detection output switches, the communication module is supplied, and in that the electromagnetic generator of the electronic tag reader operates in the radio frequency band ISM 2.4 GHz to 2.48 GHz with a function which is an identification function and a data packet which is an identity packet pattern (I D_packet).

1 8. Method for implementing the radiocommunication assembly of claim 1 6 or 1 7, characterized in that q ue in:

- a first phase, the electronic label reader (6) is activated in order to generate electromagnetic waves allowing the reception and detection unit (1 0) to control the supply of the Bluetooth® module (18) and supply said module (1 8),

- a second phase, at least one data exchange is carried out between the Bluetooth® module and the Bluetooth® radio communication device of the electronic label reader, - a third phase, the Bluetooth® module (1 8) controls the cutting off its own power supply.

1 9. Reader (6) of electronic label for generation of radio electromagnetic waves intended for the control of a system comprising a receiving unit and control detection independent of the equipment, the radio electromagnetic waves being according to a standard for radiocommunication of voice or data in a determined radio frequency band, the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a pattern of defined time structure comprising time transmission of a radio frequency signal modulated in frequency and / or phase separated by moments of no transmission, characterized in that the system is according to any one of claims 1 to 1 1 corresponding, that l reception and detection unit is a circuit for receiving, in the determined radio frequency band, and for detecting an amplitude modulation (ASK) with a detection output, the detector not being sensitive to modulation frequency and / or phase, the level of the detection output toggling when the pattern of defined time structure is received and detected, said unit (1 0) of reception and detection being an electronic tag and the pattern of defined time structure being emitted by the electromagnetic generator (6) of the label reader according to the standard, the label reader further comprising a Bluetooth® radiocommunication device capable of communicating the reader (6) with ec a base station and the module (1 8) of the system.

20. Electronic tag reader (6) for generating radio electromagnetic waves intended for the control of a system comprising a reception unit and control detection independent of the equipment, the radio electromagnetic waves being according to a standard of radiocommunication of voice or data in a radio frequency band, the standard proposing at least one function causing, in a transmitter according to the standard, the transmission of a data packet corresponding to a pattern of defined temporal structure comprising moments of transmission of a radio frequency signal modulated in frequency and / or phase separated by moments of absence of emission, characterized in that the system is according to any one of claims 1 to 1 1 corresponding, the unit receiving and detecting a command being a receiving circuit, in the determined radio frequency band, and for detecting an amplitude modulation (ASK) with ec a detection output, the detector not being sensitive to the frequency and / or phase modulation, the level of the detection output toggling when the pattern of defined time structure is received and detected, in that the reception and detection unit (10) is an electronic label intended to receive and detect electromagnetic waves according to the Bluetooth® standard, and the electronic label reader (6) comprises an electromagnetic generator which is a radiocommunication device emitting according to the Bluetooth® standard, the radio frequency band being the ISM band 2, 4GHz to 2.48GHz, the function being an identification function and the data packet being an identity packet pattern (! D_packet).