Device for locating one or more mobile elements in a predetermined zone, and method implemented in such a device

Abstract

A method for locating a mobile element in a predetermined zone, including supplying power to an on-board module in the mobile element, where the on-board module includes an electronic circuit and an on-board coil, generating a locating signal by the electronic circuit and transmission of the locating signal via the on-board coil, picking up the locating signal by receiver coils on a support in proximity to the predetermined zone, each of the receiver coils configured to pick up the locating signal when the mobile element is in proximity, and determining a location of the mobile element in the predetermined zone by detecting a signal level on the support in the form of an array by a processing unit connected to the support. The electronic circuit and the on-board coil constitute an RLC circuit that oscillates, generating the locating signal by sudden interruption of the current through the on-board coil.

Claims

1. A method. for locating at least one mobile element in a predetermined zone, the method comprising the following steps: supplying power to at least one on-board module in the mobile element, said at least one on-board module comprising an electronic circuit and at least one on-board coil; generating a locating signal by the electronic circuit and transmission of said locating signal via said at least one on-board coil; picking up said locating signal by receiver coils distributed on a support in proximity to the predetermined zone, each of said receiver coils having the function of picking up said locating signal when the mobile element is in proximity: and determining a location of the mobile element in the predetermined zone by detecting a signal level on said support which is addressed in rows and columns in the form of an array by a processing unit connected to said support, wherein said electronic circuit and said at least one on-hoard coil constitute an RLC (Resistor-Inductor-Capacitor) circuit that oscillates, generating the locating signal by sudden interruption of the current through said at least one on-board coil.

2. The method according to claim 1, wherein supplying power to said at least one on-board module is carried out periodically; in a supply phase, wherein energy is stored in each of said at least one on-board module for later use in a non-supply phase.

3. The method according to claim 1, wherein generating the locating signal is carried out at a different time for each of said at least one on-board module so as to carry out multiplexing with time-distributed multiple access (TDMA) to distinguish the on-board modules from one another.

4. The method according to claim 1, wherein generating the locating signal is carried out by generating a signal of a predetermined frequency that is different for each of said at least one on-board module so as to carry out multiplexing with frequency-distributed multiple access (FDMA) to distinguish the on-board modules from one another.

5. The method according to claim 1, wherein each locating signal contains a unique identifier.

6. The method according to claim 1, wherein the sudden interruption is carried out when the current is at its highest value.

7. A device for locating at least one mobile element in a predetermined zone, the device comprising: at least one on-board module in the at least one mobile element, said at least one on-board module comprising an electronic circuit and at least one on-board coil for transmitting a locating signal; a power supply for said at least one on-board module; receiver coils distributed on a. support in proximity to the predetermined zone; each of said receiver coils having the function of detecting said locating signal when the at least one mobile element is in proximity; a processing unit connected to the receiver coils for determining a location of the at least one mobile element in the predetermined zone by detecting a signal level on said support that is addressed in rows and columns in the form of an array; and the electronic circuit and the on-board coil constitute an oscillating RLC (Resistor-Inductor-Capacitor) circuit, the electronic, circuit being configured to suddenly interrupt the current through the at least one on-board coil to generate the locating signal.

8. The device according to claim 7, wherein the power supply comprises a magnetic winding arranged in proximity to the predetermined zone to supply each of said at least one on-board module remotely, by a magnetic field.

9. The device according to claim 7, wherein the power supply consists of an array to supply each said at least one on-board module remotely, by a magnetic field.

10. The device according to claim 8, wherein the at least one on-board module comprises a supply coil having the function of picking up the remote power supply magnetic field.

11. The device according to claim 10, wherein the at least one on-board coil and the power supply coil constitute are the same coil.

12. The device according to claim 7, wherein the at least one on-board module comprises at least three on-board coils in a trihedral arrangement.

13. The device according to claim 7, wherein each said at least one on-board coil comprises a ferrite core.

14. The device according to claim 13, wherein the ferrite core comprises hemispherical ends.

Description

BRIEF DISCRIPTION OF THE DRAWINGS

(1) Other advantages and characteristics of the invention will become apparent on examination of the detailed description of an embodiment which is in no way limitative, and the attached diagrams, in which:

(2) FIG. 1 is a diagrammatic view of a hand moving in front of a television screen, a telephone screen or other, according to the device according to the invention,

(3) FIG. 2 is a diagrammatic view of a device for measuring the activity of a mouse according to the present invention,

(4) FIG. 3 is a simplified electronic circuit diagram of an on-board coil connected to an electronic circuit for generating the locating signal,

(5) FIG. 4 is a diagrammatic view of three ferrite cores that can be incorporated in an on-board coil so as to improve its performance,

(6) FIGS. 5 and 6 are diagrammatic views of on-board coils in a trihedral arrangement in order to improve coupling with a device for remote power supply and location, in particular three-dimensional,

(7) FIG. 7 is a simplified internal electronic circuit diagram of the electronic circuit connected to the on-board coil,

(8) FIG. 8 is a curve representing a locating signal transmitted by the on-board module, this signal being in the form of a damped oscillating signal,

(9) FIG. 9 is a curve representing a locating signal transmitted by the on-board module, this signal being in the form of a highly damped oscillating signal,

(10) FIG. 10 is a curve representing a locating signal transmitted by the on-board module, this signal being in the form of a pulse that comprises a notable overvoltage that can be detected,

(11) FIG. 11 is a diagrammatic view illustrating the procedure for generating a pulse according to the invention,

(12) FIG. 12 is a simplified diagrammatic view of an electronic circuit inside an on-board module according to the invention,

(13) FIG. 13 is a simplified diagrammatic view illustrating the arrangement of coils in rows and columns in an array according to the invention,

(14) FIG. 14 is a curve obtained by simulation illustrating the (effective) counter-electromotive force produced at the terminals of a row of twenty antennas, at 1 cm from a plane of movement of an transmitting coil,

(15) FIG. 15 is a diagrammatic view illustrating the principle of operation of the device according to the invention,

(16) FIG. 16 is a diagrammatic view illustrating a method of identification by multiplexing with time-distributed multiple access (TDMA), and

(17) FIG. 17 is a diagrammatic view illustrating a method of identification by multiplexing with frequency-distributed multiple access (FDMA).

DETAILED DESCRIPTION

(18) The present invention can be applied advantageously to many fields. Hereinafter, only two embodiments will be described; other embodiments can easily be envisaged or deduced from the present description.

(19) A first embodiment will describe application of the device according to the invention in the field of displays for producing an interactive 3D screen.

(20) A second embodiment will describe a device for measuring the activity of several animals, in particular several mice in a cage. The present invention can quite obviously be applied in the same way for animals other than mice.

(21) In order to illustrate the first embodiment, FIG. 1 shows a very simplified diagram illustrating a screen 1, in particular a touch screen. This screen is said to be 3D interactive as it can receive instructions from a hand 7 positioned at a distance from the screen. Such a screen 1 comprises a rear panel 2 comprising hardware and software means, in particular a processing unit for data processing and display. A front panel 3, preferably of transparent glass, is arranged in front of the screen 1. This panel also serves to protect the internal components of the screen. According to the invention, an array of receiver coils 4 and a supply winding 5 are inserted between the rear panel 2 and the front panel 3. The winding 5 can be located on the inside as shown in FIG. 1 or on the outside. Other forms and means of power supply can be envisaged. This supply winding 5 has the purpose of supplying the on-board modifies 8-12, arranged on fingers of the hand 7, remotely by magnetic field. The fingers can be regarded as mobile elements. Each on-board module 8, . . . , 12 comprises intelligence, allowing it to transmit a locating signal that is intended to be picked up by the array of receiver coils 4. The latter is designed so that after processing by a processing unit, the location of each on-board module can be determined. Actions can be generated as a function of the position of each end of the finger where an on-board module is located. By extension, the movements of one or more on-board modules can be monitored perfectly so as to identify gestures, used as commands. These gestures are first interpreted by the processing unit, before commands are deduced from them.

(22) In the example in FIG. 1, the array of receiver coils is sandwiched between the power supply 5 and the front panel 3. Other arrangements can be envisaged, provided that the power supply can suitably supply the on-board modules 8 to 12 and the array of receiver coils can receive locating signals transmitted by the on-board modules. The power supply 5 can be sandwiched between the array 4 and the front panel 3.

(23) In FIG. 1, reference 6 denotes a predetermined zone, i.e. a volume in which the on-board modules are detectable. This predetermined zone 6 is defined by the physical characteristics of the receiver coils arranged in the array 4. The predetermined zone 6 represents the zone of influence of these receiver coils. The power supply 5 must also be suitably dimensioned in order to supply the on-board modules that are located in the predefined zone.

(24) In practice, the on-board modules can be incorporated in gloves worn by a user 7. These on-board modules can also be electronic devices designed to be held at the end of the fingers of the user 7.

(25) The diagram in FIG. 1 is not to scale. The screen 1 can be a computer screen, a television, a portable telephone, a smart phone or any other display device or more simply an input device with or without contact (without display) connected to a processing unit.

(26) An embodiment will now be described, utilizing a device according to the invention making it possible to measure the movements of several mice in a cage for example of the Eurostandard Type II type (267207140 mm).

(27) This device is intended to evaluate the treatment of diseases and for monitoring motor performance. This priority area of research is justified by the need to improve the quantitative monitoring of clinical trials in particular in the context of the evaluation of pharmacological, gene or cell therapies.

(28) FIG. 2 shows such a measuring device, with the general reference 13, connected to a computer 14. The latter can comprise a processing unit provided with suitable hardware and software means that are known per se in particular for communicating with the measuring device 13. The processing unit can comprise a microprocessor mounted on a motherboard, random-access memory, a power supply, a hard disk, conventional input means and expansion boards connected to the measuring device 13. Software means can be developed for controlling the measuring device 13 and processing the data originating from this measuring device 13 so as to display the progress of the mice on a display screen.

(29) The microprocessor in particular makes it possible to implement the steps of the method according to the invention.

(30) The measuring device 13 according to the invention makes it possible to locate in real time for example eight mice S1 to S8 on an area of 267 mm207 mm, which corresponds to the bottom of a Eurostandard Type II cage 15. The mice can move freely in this cage 15.

(31) An on-board module MS1 to MS8 is implanted in each mouse S1 to S8 respectively and regularly transmits an electromagnetic signal allowing it to be located by the array of receiver coils 4. This array can operate on the same principle as the array described in FIG. 1, although it may differ from the latter in physical and geometrical characteristics. The array of receiver coils 4 is arranged under the cage 15 and has substantially the same dimensions as the bottom of the cage 15. In the present case, the array 4 is flat, rectangular and positioned parallel to the bottom of the cage 15.

(32) The on-board modules MS1 to MS8 do not have a battery. They are supplied remotely (remote power supply) by the winding 5, which is arranged under the array of receiver coils 4. However, other arrangements can be envisaged, for example above the cage 15. For reasons of space, the array of receiver coils 4 and the winding 5 can be placed integral with one another in a case (not shown), the whole constituting a support capable of receiving the cage 15. The cage 15 can be placed so that it can be removed. Different cages can thus be used on one and the same support.

(33) The measuring device 13 operates with a connection to the computer 14, on which the position of the mice to be located is displayed in real time and is recorded. An expansion board can be provided in the computer 14 for supplying and exchanging data with the array of receiver coils 4 via a wired 16 or wireless link. An expansion board can also be provided in the computer 14 in order to control the power supply of the winding 5 via a link 17.

(34) The spatial accuracy of location is 5 mm and the time resolution is 1 second. The accuracy of location depends on the geometry of the receiver coils that serve as receiving antennas.

(35) The array of receiver coils 4 and the winding 5 can be arranged in a cabinet with other components allowing the signals to be relayed between the measuring device 13 and the computer 14. The dimensions of the measuring device are such that these measuring devices can be used in racks of cages for mice.

(36) With this measuring device, the winding 5 remotely supplies the on-board modules MS1 to MS8, which in turn generate and transmit locating signals, which are picked up by the array of receiver coils 4. The latter is designed so as to be able to determine the location of each on-board module. For this purpose, a computer 14 is used in order to control the measuring device and to method the data originating from the array of receiver coils. The movement of each mouse in real time can thus be monitored.

(37) In addition to the foregoing, FIG. 3 shows a diagram illustrating an on-board module MS1, . . . , MS8. Each on-board module comprises an on-board coil 18 and an electronic circuit 19. The latter is provided with electronic components and a microcontroller making it possible to generate a locating signal at predetermined times, regularly or irregularly.

(38) More precisely, the remote power supply of the on-board modules is carried out by inductive coupling between the on-board coil 18 and the winding 5. The winding 5 is a coil placed in proximity to the cage 15, and transmits a magnetic field in the entire detection zone, so as to supply the on-board modules regardless of their positions and their orientations in the cage.

(39) This variable magnetic field induces voltages at the terminals of the on-board coils inside the on-board modules and serves to supply the electronic circuits 19.

(40) Advantageously, ferrite cores can be used in the on-board coils 18 to increase the performance of remote power supply. The geometry of the ferrite cores may allow the system to be made less sensitive to the orientation of the on-board modules. Thus, a ferrite core with hemispherical ends as shown in A in FIG. 4 makes it possible to channel a portion of the magnetic field transmitted by the remote supply winding 5, even when the axis of the ferrite core is orthogonal to the axis of the winding 5 transmitting the remote power supply field.

(41) Generally, during use, it is possible that the on-board coil that is intended to transmit the locating signal is not effectively oriented. This can in particular occur when its axis does not allow coupling with the array of receiver coils. In this case, the locating signal received is too weak to be exploited for locating the on-board module. One of the solutions for correcting this state is for example to use several transmitting coils oriented differently in each on-board module. The diagram in FIG. 5 shows such a topology of coils transmitting the locating signal in a trihedral arrangement. In fact, three coils are used instead of just one. These three coils are arranged on three orthogonal axes and transmit one and the same locating signal. Other configurations can be envisaged. Thus, regardless of the orientation of the on-board module with respect to the array, the receiving antennas always receive one or more signals of a high enough level originating from the on-board module.

(42) Exploiting the locating signals transmitted by one or more transmitting coils can also be envisaged in order to ascertain the orientation (rotation about the X, Y and Z axes) and even the direction (by combining several transmitting modules or using several transmitting coils) of the on-board module, in addition to the position.

(43) In general, multiplying the orientations of the transmitting and receiver coils can be envisaged for example in order to improve the locating and remote power supply of the on-board modules.

(44) In addition to these geometrical arrangements of the transmitting coils allowing optimization of location, optimization of the use of these various coils can be envisaged. For example, depending on the spatial position of a given transmitter, the transmitting coil or coils with the best geometrical arrangement of this transmitter in a given plane for locating could be used more than the other transmitting coils of the same on-board module. This principle can also be implemented for remote power supply of the on-board modules if the latter are for example supplied by means of a magnetic field transmitted by the array of receiver coils.

(45) The coils in FIG. 5 are elongated coils comprising a ferrite core. The shape of these coils is an elongated cylinder, the height along the axis of revolution being greater than the diameter of the cylinder.

(46) FIG. 6 shows another example of the shape of coils shown in FIG. 5. It is a flat cylinder having a height that is less than the diameter of the cylinder.

(47) The energy received by the on-board coils makes it possible to supply the electronic circuit of each on-board module so as to generate pulses by causing a sudden change in the current through the coil LR as shown in FIG. 7. The coil LR can be the same as the coil used for receiving the energy. FIG. 7 shows a simplified electronic circuit diagram in which LR and C1 are arranged in parallel. A second capacitor of greater capacitance C2 is connected to one end of C1. A switch M, which can be a MOSFET transistor, is arranged between the other ends of C1 and of C2.

(48) The supply voltage V.sub.SUP of the on-board module is used for charging the capacitor C2 via a charging resistor R.sub.charge C2.

(49) In order to generate the locating signal, which is advantageously a magnetic field, circulation of an electric current that varies over time through the coil LR comprising one or more turns is envisaged. Two methods for generating a signal allowing locating are resonance/oscillation of the capacitor C1 and coil LR and sudden change in the current through the coil LR. Generally the locating signal can be created as follows: it is possible to discharge one or more voltage-charged capacitors into one or more coils, it is possible to create a sudden variation in the currents passing through one or more coils.

(50) FIGS. 8 to 10 show three curves representing three solutions for a locating signal generated by the on-board module. Solution 1: the principle is to discharge a capacitor into a coil in a slightly damped pseudo-oscillating mode. FIG. 8 is a curve representing the variation of the voltage induced in the array of receiver coils. Solution 2: the principle is to discharge a capacitor into a coil in a highly damped pseudo-oscillating mode. FIG. 9 is a curve representing the variation of the voltage induced in the array of receiver coils. This second solution makes it possible to generate a pulse in the array of receiver coils that is of longer duration and has a greater amplitude than that of solution No. 1. Solution 3: the principle is, to significantly increase the voltage induced in the array of receiver coils by causing a rapid variation in the current in an inductor. For this purpose, a current is circulated through an inductor and this electric current is varied suddenly. This sudden variation in the current causes a sudden variation in the flux of the magnetic field generated by the inductor. A rapid variation in the magnetic flux transmitted by an on-board module leads to a high induced voltage in the array of receiver coils, since the voltages induced at the terminals of the receiver coils increase with the variation in the magnetic flux passing through them. FIG. 10 is a curve representing the profile of the voltage induced in the array of receiver coils.

(51) The induced voltage generated is higher than in the two preceding solutions under similar conditions.

(52) A system for forcing the sudden variation in the current passing through the inductor transmitting the locating signal when the latter reaches its maximum can be envisioned. Thus, the voltage created at the terminals of the receiving antennas will be maximum. This search for the maximum can be carried out for example by calculation, by detection of the maximum current or by other means.

(53) As an example, the illustrations in FIG. 11 describe an embodiment of the electronic circuit for generating a locating signal, which is advantageously a pulse as described in the third solution. FIG. 11 is a more simplified representation of the electronic components already shown in FIG. 7.

(54) The inductor LR and the capacitor C1 are in parallel. C2 is a high-value capacitor initially charged to U0 and M is the controllable switch constructed for example with a transistor or other means. The steps for generating the locating signal can be as follows.

(55) In a first phase, energy is stored in the capacitor C2:

(56) Phase 1: energy stored in C2 M is open V.sub.C1=0 V no current passes through LR or C1 V.sub.C2=U.sub.0

(57) In a second phase, energy is transferred to the coil LR:

(58) Phase 2: energy transfer to LR M is closed V.sub.C1=U.sub.0 LR is charged with current

(59) In a third phase, an overvoltage is created: Phase 3: sudden variation in the current ichargeL passing through LR M is open The large variation in current ichargeL due to the sudden opening of M leads to a sudden variation in the magnetic flux generated by the inductor LR and therefore a high induced voltage at the terminals of the receiver coils.

(60) Thus, the locating signal can be a resonant signal damped by causing the circuit LR and C1 to resonate, or making it more characteristic by implementing the sudden variation described above.

(61) It is possible to produce other topologies by modifying the arrangement, and the number of components (LR, C1, C2, M, etc.) and the choice of components (LR with a low series resistance, etc.) in order to optimize the locating signal received by the array of receiver coils.

(62) Generally, one or more receiving antennas can be used in order to locate the on-board modules. These antennas can for example form an array of antennas (by being put side by side) in order to locate the transmitting modules. Each antenna is advantageously a coil, so that an array of receiver coils 4 as shown for example in FIGS. 1 and 2 is obtained.

(63) Topologies other than an array of antennas can be envisioned. The pattern of the arrangement of the antennas is not necessarily regular. Placing the receiving antennas only at certain places where it is desired to detect the position of an on-board module envision can be envisaged for example. The most typical case would be a regular arrangement of the receiving antennas in the form of an array. The array of receiving antennas is not necessarily flat and is not necessarily single. It is possible to envisage q arrays or sub-arrays (q being an integer greater than or equal to 1), placed orthogonally or not placed orthogonally, in order to calculate the position of one or more on-board modules in space (locating in a volume).

(64) In order to simplify the measurement electronics, it is possible to reduce the number of channels (output of the antennas) to be measured. This can be done by wiring the receiving antennas in series or by group of antennas. These antennas in series can then be arranged in rows and columns of antennas so as to be able to determine the position of the on-board modules (see FIG. 13).

(65) The position of the on-board module is then calculated from the levels received on the receiving rows and columns on which the signals are received.

(66) The receiving antennas can be formed on a flexible or rigid printed circuit and can be present on several layers of the printed circuit so as to have more turns for example or a higher density of receiving antennas. The receiving antennas can also be coils of the solenoid type, in order to improve the level of the signals received.

(67) In general, it can be envisioned that the receiving antennas are produced (printing, deposition, etc.) on all types of flexible or rigid, opaque or transparent support. For example, it is possible to place an array of transparent antennas above a surface where it is desired to determine the position of on-board module(s) (glass pane, computer screen, etc.). An array of antennas could for example be made of indium-tin oxide, which is a transparent conductor that is also used for touch screens.

(68) FIG. 12 shows an embodiment example of an electronic circuit of an on-board, module. There are five main functions:

(69) Function 1: circuit for reception of the remote power supply and transmission of the locating signal. In the simplest configuration, this stage can consist of a tuned parallel circuit LC that serves firstly for reception of the energy from the remote power supply (conversion of the energy transmitted in the form of a magnetic field into electric current that can be used for supplying the elements of the on-board module) and that serves secondly for transmitting the locating signal (transmission of a magnetic field that will be picked up for locating the on-board module).

(70) Function 2: circuit for storing energy for locating: This stage stores a portion of the energy received from the remote power supply that will serve for creating the locating signal. In the simplest configuration, this stage can consist of a capacitor. During the remote supply phase, this capacitor accumulates energy. The remote power supply phase is followed by a waiting phase, during which the capacitor stores energy. Finally, during the locating phase, the energy accumulated in this capacitor is transmitted to the stage that transmits the locating signal in order to create the locating signal.

(71) Function 3: sequencer supply circuit: this stage stores a portion of the energy received from the remote power supply in order to supply a sequencer F5 of the on-board module. By sequencer is meant the entire circuit used to trigger the locating signal.

(72) Function 4: synchronization circuit: The synchronization circuit makes it possible to detect the start and end of the remote power supply phases so that the module can transmit the locating signal at the desired time, i.e. when the remote power supply phase has ended. (This stage is in particular useful when the TDMA method is used for identifying the on-board modules from one another).

(73) Function 5: sequencer circuit: The sequencer is the whole circuit used to trigger the locating signal. Based on the synchronization signal, the sequencer makes it possible to trigger the transmission of the locating signal at the desired time. When the TDMA method is used for identifying the on-board modules from one another, each on-board module transmits its locating signal at a different time after the remote power supply phase.

(74) For the example in FIG. 13, the receiving antennas are coils etched on a printed circuit and allow an accuracy of 5 mm. This solution has the advantage of being less expensive than the use of conventional coils, in addition to being easily implemented. The receiver coils are arranged in rows and columns. Two superposed layers are provided. A first layer on the upper face comprises several rows of flat coils in series. There is also a second layer under the first layer, comprising several rows of flat coils in series. The rows of the first layer are perpendicular to the rows of the second layer, thus constituting an array addressable by rows and columns. The position of an on-board module is indicated by the intersection of a row and a column that have detected the highest level of locating signal.

(75) The ends of the rows comprise connectors for transmitting the signals to the processing unit in the computer 14.

(76) FIG. 14 shows a simulated curve representing the counter-electromotive force induced (in effective volts) in a row of twenty antennas for a transmitting coil moving on a plane at a height of 1 cm from the receiving row. The transmitting coil is the on-board coil with one turn, an exciting current of 1 mAeff at a frequency of 1 kHz, and a diameter of 1 cm.

(77) Examples of functional modes of the device according to the invention will now be described.

(78) The general principle consists of locating one or more elements (on-board modules) moving with respect to an array of receiver coils or vice versa.

(79) The locating device according to the invention is constituted by: various transmitting modules (=on-board modules): S1, S2, S3, . . . , Sn (n being an integer greater than or equal to 1) an array comprising 1 to p antennas (p being an integer greater than or equal to 1) a power supply module of the transmitting modules, which can be: a remote power supply of the transmitting modules to be located (remote power supply) an on-board power supply in the transmitting modules to be located (for example a battery)

(80) FIG. 15 shows the basic principle of the method utilized in the present invention. The n transmitting modules are supplied, and in turn they transmit a locating signal to the receiving module (the array of receiver coils).

(81) FIG. 16 shows a first embodiment of the method according to the invention. After a power supply phase, each module waits a given length of time before transmitting its locating signal. The transmitting modules therefore transmit responses which are time-separated. It can be envisioned in this case that the locating signals have the same spectrum whether they are periodical or pseudoperiodical signals. In other words, identification of the TDMA (Time Division Multiple Access) type is applied: each module transmits its locating signal in the time that is allotted to it. Thus, if the cage contains 8 mice, 8 responses are received one after another. Knowing the response delay associated with each on-board module, it is possible to identify the on-board module (time slot method).

(82) FIG. 17 shows a second embodiment of the method according to the invention. In this embodiment, the power supply phase can be superimposed on the locating phase. Identification of the FDMA (Frequency Division Multiple Access) type is applied in this case: all the on-board modules transmit their locating signals at the same time but at different frequencies. Knowing the frequency associated with each transmitting module (on-board module), it is possible to identify each on-board module independently. This is a frequency slot method. The operating cycle can be very short, but this requires considerable resources at the level of the processing unit for discriminating the different frequencies.

(83) In addition to the foregoing, an identifier can be associated with each on-board module. In order to be identified, each mouse sends a unique code. To this end, the above two methods can be used. However, in contrast to the preceding two solutions, the signals sent comprise additional identification information (unique code of each mouse).

(84) The invention can therefore be utilized for example for locating rodents, locating human fingers (glove comprising several transmitting modules, one in each finger), locating objects with respect to a surface (pieces for a board game, etc.), locating objects on a graphics tablet (for example with an transmitting module at the end of the stylus), etc.

(85) Of course, the invention is not limited to the examples which have just been described and numerous adjustments can be made to these examples without exceeding the scope of the invention.