FR2888969A1 - Inductor for e.g. support, has conductors distributed over surface and connected with each other by connection conductors for forming circuit strands whose ends are connected to power supply circulating electric current in conductors - Google Patents

Abstract

The inductor has conductors (100 - 109), parallel, mutually equidistant and distributed over a surface (120). The conductors are connected with each other by connection conductors (130) to form strands of an electric circuit. Ends of the strands are connected to an electric power supply (140) that circulates an electric current in the conductors. The conductors are incorporated in a plane non conductive base (150) on which articles (160) are placed. The articles have electronic tags (170) whose antenna is in a plane forming an angle less than or equal to 45 degrees with the conductors` axis. An independent claim is also included for a device chosen among a support, a vane, a cash register and a base station and comprising an indicator.

Description

ELECTRONIC LABEL, READING METHOD, AND METHOD

  The present invention relates to an electronic tag, a read method and a method for interrogating such an electronic tag. It applies, in particular to radio frequency electronic tags.

  Radio Frequency Electronic Tags, known as Radio Frequency IDentification (RFID), are well known for their ability to provide an identification signal in response to base station or base station interrogation signals. , said signals modulating an electromagnetic field generated by the base station.

  However, when it is desired to read a set of labels whose orientation is arbitrary in a given volume, it is often necessary to provide, in the base station, a set of antennas which cover, each, parts of said volume and particular orientations of labels. Each antenna is implemented during a time interval constituting a part of a complete reading cycle, a time interval during which at least part of a tree of possible identifiers for the electronic tags is scanned. All tags whose antenna axis is not perpendicular to the axis of the magnetic field generated by the antenna are then likely to respond during the time interval considered.

  In this case, the risk exists that a large number of tags are identified more than once, during each time interval when it receives requests from the base station. In fact, the axes of the antennae of the labels, of any orientation, are rarely perpendicular to two or even one of the axes of the magnetic fields generated successively.

  For example, when six antennas are implemented (two antennas successively covering the entire given volume, for each of the three axes), some labels are read two or three times during a complete cycle.

  The identification of all the labels is thus slowed down by at least a factor of two. The speed of reading a label group is a key factor in the adoption of electronic tag technology.

  The present invention aims to remedy these disadvantages. For this purpose, the present invention aims a passive electronic tag to be read by a set of antennas of a base station, generating successively, during a reading cycle, magnetic fields, characterized in that said electronic tag comprises: - means for transmitting responses to requests modulating said magnetic field and an appropriate means of inhibition, even in the absence of any power supply from the base station, to inhibit the transmission means at least for the duration of said read cycle.

  Thanks to these provisions, when the electronic tag has been read, it is inhibited during the entire reading cycle and can not be read twice. The reading speed of a set of labels of arbitrary orientations is therefore greatly increased.

  It is observed that the implementation of the present invention does not require any modification of the base station, only the electronic tag being modified to inhibit for a duration several times longer than the inhibition times currently implemented, which concerns only one of the time intervals mentioned above.

  According to particular features, the electronic tag as briefly described above includes means for determining the complete identification of said electronic tag, said inhibiting means inhibiting the transmitting means when the determining means has determined that the electronic tag has been completely identified.

  According to particular features, the electronic tag comprises means for receiving an acknowledgment of receipt of the base station and the means for determining the complete identification of the electronic tag is adapted to determine that an accused received from the base station.

  According to particular features, the transmission means is adapted to successively transmit identification portions of said electronic tag and the determination means is adapted to determine that all the parts of the identifier of the electronic tag have been issued by the transmitting means.

  According to particular features, the inhibiting means comprises a capacitance. According to particular features, the inhibition means comprises a diode-mounted transistor for controlling the load of said capacitance.

  Thanks to these provisions, the inhibition time can last several tens of seconds.

  According to a second aspect, the present invention relates to a method of operating a passive electronic tag, characterized in that it comprises: a step of responding to requests from a base station and once the tag has provided its complete identification, a prolonged inhibition step of a duration at least equal to the duration of a said read cycle, even in the absence of any power supply from said base station.

  According to particular features, the prolonged inhibition step is performed after a step of receiving an acknowledgment of the complete identification of said electronic tag.

  According to particular features, the method as succinctly set forth above includes a step of outputting the inhibition, in response to receiving a prolonged inhibition output request, from said base station.

  According to a third aspect, the present invention relates to a method for interrogating passive electronic tags, characterized in that it comprises: a step of identifying at least one electronic tag during which a magnetic field is generated with at least a first antenna, a step of transmitting a prolonged inhibition request for each identified electronic tag, a step of identifying at least one electronic tag during which a magnetic field is generated with at least one second antenna different from each first antenna and - a step of issuing a request of prolonged inhibition output of each identified electronic tag during which a magnetic field is generated with each said first antenna.

  Since the advantages, particular characteristic goals of these methods are similar to those of the electronic label as briefly described above, they are not recalled here.

  Other advantages, aims and features of the present invention will emerge from the description which follows, made for an explanatory and non-limiting purpose, with reference to the appended drawings, in which: FIG. 1 represents, schematically, an example of placing of the present invention in a system for reading radio frequency electronic tags; FIGS. 2A and 2B show an electronic circuit integrated in an electronic tag; FIG. 3 represents an operating logic diagram of an electronic tag and FIG. 4 represents an operating chronogram of electronic tags.

  FIG. 1 shows a set of antennas 105 and 110 of a base station (not shown) and passive electronic tags 115, 120, 125 and 130 placed between the set of antennas 105 and 110. base station successively feeds the antennas of the set of antennas 105 and 110 to successively generate, during a reading cycle, a vertical magnetic field symbolized by the arrow 140, a lateral magnetic field symbolized by the arrow 145 and a longitudinal magnetic field symbolized by the arrow 150.

  The electronic tags are powered by the electromagnetic field generated by the set of antennas 105 and 110 when the plane of their antenna intersects enough magnetic field lines.

  In the configuration shown, the electronic tag 115 is powered by the magnetic field 140, the tag 120 by the magnetic field 145, the tag 125 by the magnetic field 150 and the tag 130 by each of the magnetic fields 140, 145 and 150.

  Each of the tags 115, 120, 125 and 130 comprises a communication means, respectively 116, 121, 126 and 131, with the base station and a prolonged inhibition means, respectively 117, 122, 127 and 132.

  The communication means are adapted to respond to queries emitted, via successive magnetic fields, by the base station in order to be identified by this base station. The prolonged inhibition means 117, 122, 127 and 132 are adapted to inhibit the response to the interrogation requests once the corresponding label is completely identified, for a duration at least equal to a complete reading cycle, even in the lack of supply of the corresponding electronic label by a magnetic field, such that an electronic tag is not likely to be identified successively by means of the magnetic fields successively generated by the set of antennas 105 and 110.

  With this essential feature, each electronic tag can be read at most once per read cycle, which greatly improves the number of electronic tags that can be identified per unit of time.

  In contrast, in the prior art, when they were no longer powered, the tags were quickly no longer inhibited and responded to the identification requests of the base station as soon as they were again powered, causing a plurality of successive identification of the same electronic tag during a same read cycle and therefore a loss of time and identification speed.

  Indeed, apart from the particular orientations of the electronic labels 115, 120 and 125, the arbitrary orientations of the electronic tags make them readable by means of several successive magnetic fields, as is the case for the electronic tag 130.

  FIGS. 2A and 2B show the mounting of a MOS transistor 225, diode-mounted, ie the drain is connected to the source and the gate is connected to the substrate.

  At power-up, the switch K1 220 is closed, the capacitor C 230 is discharged. As soon as the tag is identified, the switch K1 220 closes allowing the capacitor C 230 to charge, through the transistor 225, constant current generated by the current source 215.

  The switch K2 235 makes it possible, at any time, to reset the prolonged inhibition information stored in the capacitor 230, that is to say, to leave the prolonged inhibition state.

  The level stored in the capacitor C 230 is present on the point Vp 240 making it possible to compare the potential Vp 240 with a fixed reference voltage Vref 245. The signal present at the output Vout 255 of the comparator 250 is the signal shaping. Vp 240 and represents the state of prolonged inhibition of the electronic tag.

  FIG. 3 shows the operating steps of an electronic tag according to the present invention.

  The passive electronic tag wakes up when it receives a magnetic field sufficient for its power supply, step 305.

  During a step 310, it initializes, for example by zeroing counters. During a step 315 it receives a reset signal from a base station, through a magnetic reading field, generally identical to the magnetic field supply.

  During a step 320, it responds to requests from the base station and provides, in one or more parts, its identification. Optionally, during this step 320, it temporarily inhibits itself for not responding to requests concerning the identification of other electronic tags.

  During a step 325, the electronic tag determines whether it has been completely identified, either according to the responses it has emitted or after receiving an acknowledgment signal from the radio station. base, for example in the form of a single pulse or in the form of a message repeating the entire identification of the label concerned.

  If the result of step 325 is negative, which may, for example, have happened if the tag has not correctly received all the requests sent by the base station to its attention or if the base station has not not correctly received the responses emitted by the electronic tag, the tag returns to step 315 and waits for a new reset request.

  If the result of step 325 is positive, during a step 330, the electronic tag goes into inhibit extended until it receives a request for extended inhibition output, step 335 or until that its prolonged inhibition means can no longer maintain a prolonged inhibition signal, this prolonged inhibition being able to reach a duration at least equal to the duration of a said read cycle, even in the absence of any power supply from said base station.

  If it receives a prolonged inhibition output request, the electronic tag exits the prolonged inhibition state, step 340, and returns to step 315. If the energy conserved by the inhibiting means, by example, by the capacity 230, is exhausted, the tag resumes sleep until a step 305 occurs.

  FIG. 4 shows successively, on a time axis going from the bottom upwards, that the magnetic field 150 is first emitted to identify electronic tags located in said field. During this phase of the read cycle, the electronic tag 125 is completely identified and it is assumed here that the electronic tag 130, powered by the magnetic field 150 is not completely identified, for example because of its orientation or communication faults between it and the base station. The electronic tag 125 then enters in prolonged inhibition which can last at least the duration of a complete reading cycle using the different combinations of antennas provided in this cycle.

  Once the base station has identified the electronic tags capable of correctly communicating through the magnetic field 150, the magnetic field 145 is transmitted and the electronic tag 120 is completely identified. Due to its prolonged inhibition, even if it is powered by the magnetic field 145 and receives the requests issued by the base station, the electronic tag 125 does not respond to these requests or to the reset issued by the base station.

  It is assumed here that the electronic tag 130 is also completely identified during the emission phase of the magnetic field 145.

  As soon as they are completely identified, the electronic tags 120 and 130 come into prolonged inhibition which can last at least the duration of a complete reading cycle using the different combinations of antennas provided in this cycle.

  Once the base station has identified the electronic tags able to communicate correctly through the magnetic field 145, the magnetic field 140 is emitted and the electronic tag 115 is completely identified. Due to their prolonged inhibition, even if they are powered by the magnetic field 140 and they receive the requests issued by the base station, the electronic tags 120, 125 and 130 do not respond to these requests or the delivery to zero emitted by the base station.

  As soon as it is completely identified, the electronic tag 115 enters into prolonged inhibition which can last at least the duration of a complete reading cycle using the different combinations of antennas provided in this cycle.

  It is assumed here that the base station does not issue an extended inhibition output request as long as tags remain to be identified. The base station therefore performs a new read cycle, implementing, successively, the magnetic fields 150, 145 and 140 and does not identify any new electronic tags.

  Then the base station issues a prolonged inhibition output request, through each of the magnetic fields 150, 145, and 140, and all the tags exit the extended inhibition and wait for a reset to zero. reproduce a reading cycle. This step of issuing a prolonged inhibition output request is, for example, made to verify that the electronic tags are still present within range of the base station or to uninhibit any electronic tag that could have come within range of the base station in a prolonged inhibition state, for example under the effect of a reading by another base station.

  It is observed that the labels leave the extended inhibition state when they receive the exit request. Thus, because of their particular orientations, the electronic tags 120 and 115 leave the extended inhibition state later than the electronic tags 125 and 130.

Claims (8)

8 claims   1 - Passive electronic label (115, 120, 125, 130) intended to be read by a set of antennas (105, 110) of a base station, generating successively, during a reading cycle, fields magnetic, characterized in that it comprises: - means for transmitting (116, 121, 126, 131) responses to requests modulating said magnetic field and - a means of inhibition (117, 122, 127 and 132) adapted, even in the absence of any power supply from the base station, to inhibit the means for transmitting responses at least during the duration of said read cycle.   2 electronic label according to claim 1, characterized in that it comprises means for determining the complete identification of said electronic tag, said inhibiting means (117, 122, 127 and 132) inhibiting the transmitting means when the determining means has determined that the electronic tag (115, 120, 125 and 130) has been fully identified.   3 Electronic label according to any one of claims 1 or 2, characterized in that it comprises means for receiving reception of an acknowledgment of receipt of the base station and the means for determining the complete identification of the The electronic tag is adapted to determine that an acknowledgment has been received from the base station.   4 Electronic label according to any one of claims 1 to 3, characterized in that the transmitting means (116, 121, 126, 131) is adapted to emit successively identifying portions of said electronic tag and the means of determination is adapted to determine that all parts of the identifier of the electronic tag have been issued by the transmitting means.     Electronic label according to any one of claims 1 to 4, characterized in that the inhibiting means comprises a capacitor (230).   Electronic label according to claim 5, characterized in that the inhibiting means comprises a diode-mounted transistor (225) for controlling the charge of said capacitor (230).   7 Operating method of a passive electronic tag (115, 120, 125, 130), characterized in that it comprises: - a step of response (320) to requests from a base station and - once that the tag has provided its complete identification, a prolonged inhibition step (330) of a duration at least equal to the duration of a said read cycle, even in the absence of any power supply from said station basic.   8. Process according to claim 7, characterized in that the prolonged inhibition step (330) is carried out after a step of receiving an acknowledgment (325) of the complete identification of said electronic tag.   Method according to any one of claims 7 or 8, characterized in that it comprises an inhibition output step (340), in response to the receipt of a prolonged inhibition output request, from of said base station.     A method for interrogating passive electronic tags (115, 120, 125, 130), characterized in that it comprises: a step of identifying (320) at least one electronic tag during which a field is generated magnetic circuit with at least a first antenna, a step of transmitting a prolonged inhibition request (325) for each identified electronic tag, - a step of identifying at least one electronic tag during which a digital tag is generated. magnetic field with at least a second antenna different from each first antenna and a step of transmitting a prolonged inhibition output request (340) of each identified electronic tag during which a magnetic field is generated with each said first antenna.