MULTIBAND 3D UNIVERSAL ANTENNA

Abstract

A multiband 3D universal antenna having a magnetic core surrounded by a multiaxial coil wound around each of three orthogonal axis X, Y, Z, the multiaxial coil including at least two different coils wound around at least one of the three orthogonal axis; a support providing backing and/or isolation of the coils and a connection box connected to the external connectors providing a reconfigurable connection between the external connectors, so that several different antenna coil circuits are obtainable. Each coil of each axis has a specific cross section and a given number of turns and each coil is provided with two external connectors.

Claims

1. A multiband 3D universal antenna system comprising: a magnetic core surrounded by a multiaxial coil wound around each of three orthogonal axis X, Y, Z, said multiaxial coil including at least two different coils wound around at least one of said three orthogonal axis, wherein each coil of each axis having a specific cross section and a given number of turns and each coil being provided with two external connectors, a support providing backing and/or isolation of said coils; and a connection box connected to said external connectors of the coils configured to provide a reconfigurable interconnection between said external connectors, whereby different external interconnections of the external connectors are established through the use of the connection box, and several different antenna coil circuits are obtained, wherein said established different external interconnections are provided according to a specific: given inductance range; quality factor, Q, range; and sensitivity range to operate within at least three different working frequencies.

2. The multiband antenna system according to claim 1, wherein said multiaxial coil includes at least two different coils wound around each of said three orthogonal axis, each of the at least two coils differing in cross section and in number of turns, said coils being spatially distributed to fit into a low profile enclosure defining a height, length and a width where the height of the enclosure is less than twice the length and less than twice the width.

3. The multiband antenna system according to claim 2, wherein said multiband antenna is a receiver antenna and wherein said connection box is configured to respond to a given working frequency emitted in a nearby region.

4. The multiband antenna system according to claim 1, wherein said at least three different working frequencies are within a RFID band.

5. The multiband antenna system according to claim 1, wherein said at least three different working frequencies are 20 kHz, 125 kHz and 134.2 kHz.

6. The multiband antenna system according to claim 1, wherein said given inductance range for a frequency of 20 kHz is 20 mH, and wherein said given inductance range for a frequency of 125 kHz or 134.2 kHz is between 2.38 mH to 7.2 mH.

7. The multiband antenna system according to claim 5, wherein said quality factor, Q, for a frequency of 20 kHz is over 3.5, for a frequency of 125 kHz is over 15, and for a frequency of 134.2 kHz is over 30.

8. The multiband antenna system according to claim 5, wherein said sensitivity for a frequency of 20 kHz is 22 mV/A/m and for a frequency of 125 kHz or 134.2 kHz is from 70 to 80 mV/A/m.

9. The multiband antenna system according to claim 5, including six coils (12X1, 12X2, 12Y1, 12Y2, 12Z1 and 12Z2) and arranged around axis X, Y and Z, wherein coils (12X1, 12Y1 and 12Z1) have a cross section and number of turns configured to operate under the 125 kHz or 134.2 kHz frequency and wherein coils (12X2, 12Y2 and 12Z2) have a cross section and number of turns configured to operate under a 20 kHz frequency, wherein the interconnection between some of the external connectors of each of the six coils is configured to provide at least the following antenna circuits: an antenna coil circuit providing a common ground to every coil (12X1, 12X2, 12Y1, 12Y2, 12Z1 and 12Z2) so that seven external connections are established with the connection box; an antenna coil circuit with an intermediate connection between the coils (12X1, 12X2), (12Y1, 12Y2), and (12Z1, 12Z2) of each axis, so that nine external connections are established with the connection box, an antenna coil circuit providing a common ground to a coil (12X1, 12Y1, 12Z1) of every axis and in addition an intermediate connection between the coils (12X1, 12X2), (12Y1, 12Y2), and (12Z1, 12Z2) of each axis, so that seven external connections are established with the connection box, and an antenna coil circuit providing two distinct common grounds, a first common ground shared by three coils (12X1, 12Y1, 12Z1) and a second common ground shared by the other three coils (12X2, 12Y2, 12Z2) so that eight external connections are established with the connection box.

10. The multiband antenna system according to claim 1, wherein the multiband antenna is included within the connection box.

11. The multiband antenna system according to claim 1, wherein said connection box is an integrated circuit, IC.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0036] The foregoing and other advantages and features will be more fully understood from the following detailed description of an embodiment with reference to the accompanying drawings, to be taken in an illustrative and non-limitative manner, in which:

[0037] FIG. 1 shows a prior art of a 3D coil corresponding to an embodiment of cited US10505278B2 based on a special core on which three orthogonal coils are directly wind and each coil is separated in two coil portions by partitions walls of the own core.

[0038] FIG. 2 schematically shows an embodiment of the proposed universal 3D coil with reconfigurable interconnection, arranged inside a connection box integrated circuit.

[0039] FIGS. 3, 4, 5 and 6 show some of the several possible embodiments of the antenna circuits according to a common ground, intermediate connections and combinations thereof, provided from the connection box.

DETAILED DESCRIPTION OF AN EMBODIMENT

[0040] To solve the problem posed for this invention there are needed at least 3 windings to work at 125-134 kHz and 3 windings to work at 20 kHz. The working frequencies are within a RFID band.

[0041] Requirements in terms of Q and sensitivity are quite different at these 3 frequencies. Current chips that work at 125 kHz suit coils with Qmin 15 but current chips that work at 134 kHz require a Qmin of 30. And at 20 kHz what it is required is a high inductance value to reach the sensitivity needs.

[0042] So, for 125 kHz and 134 kHz it will be the same three coils, but the goal is to achieve a Q of 30 min.

[0043] It has to be decided to provide separate connection for the 6 coils which means the need for-12 different contacts.

[0044] However same axis coils at 125 kHz and 20 kHz can share a pin that will be the end of the 125 kHz coil and the beginning of the 20 kHz coil, therefore 9 different contacts are needed.

[0045] It an alternative it can be also that the 6 coils share a ground connection and then there would be needed 7 different contacts.

[0046] It has to be decided also how to wind the coils: first both X windings, first X and Y windings at 125 kHz.

[0047] According to an embodiment the invention proposes a multiband 3D universal antenna that comprises: [0048] a magnetic core surrounded by a multiaxial coil wound around each of three orthogonal axis X, Y, Z, said multiaxial coil including at least two different coils 12 wound around at least one of said three orthogonal axis; [0049] a support providing backing and/or isolation of said coils 12,

[0050] wherein each coil of each axis has a specific cross section and a given number of turns; and

[0051] wherein each coil is provided with two external connectors 11; and [0052] a connection box 10 is connected to said external connectors 11 and is configured to provide a reconfigurable interconnection 16 between said external connectors 11, so that several different antenna coil circuits are obtainable.

[0053] According to a preferred embodiment the coils are spatially distributed to fit into a low-profile enclosure defining a height, length and a width where the height of the enclosure is less than twice the length and less than twice the width.

[0054] In case that in some axis there is only one winding instead of at least two, this would make that the 3Dcoil could work in 3 bands (20, 125 or 134.2 KHz) in the axes that have two windings and in one in which there is one.

[0055] And likewise, the proposal of this invention contemplates the case in which there is only one multiband axis.

[0056] However, in a preferred embodiment the multiaxial coil includes at least two different coils 12 wound around each of said three orthogonal axis, each of the at least two coils 12 differing in cross section and in number of turns.

[0057] As illustrated in FIG. 2, the multiband antenna 1 is included within the connection box 10.

[0058] In a preferred embodiment the connection box 10 is an integrated circuit, IC.

[0059] As previously indicated the connection box 10 provides said reconfigurable interconnection 16 according to a specific: [0060] given inductance range; [0061] quality factor, Q, range; [0062] sensitivity range

[0063] to operate within at least three different working frequencies.

[0064] In an embodiment the multiband antenna 1 is a receiver antenna and the connection box 10 is configured to respond to a given working frequency emitted in a nearby region.

[0065] Some data of a specific embodiment are following detailed: [0066] the given inductance range for a frequency of 20 kHz should be of 20 mH, for a frequency of 125 kHz or 134.2 kHz should be between 2.38 mH to 7.2 mH; [0067] the quality factor, Q, for a frequency of 20 kHz should be over 3.5, for a frequency of 125 kHz should be over 15, and for a frequency of 134.2 should be over 30; [0068] the sensitivity for a frequency of 20 kHz should be of 22 mV/A/m and for a frequency of 125 kHz or 134.2 kHz should be between 70 to 80 mV/A/m.

[0069] In the embodiments illustrated in FIGS. 3 to 6 six coils 12X1, 12X2, 12Y1, 12Y2, 12Z1 and 12Z2 and arranged around axis X, Y and Z, wherein coils 12X1, 12Y1 and 12Z1 have a cross section and number of turns configured to operate under the 125 kHz or 134.2 kHz frequency and wherein coils 12X2, 12Y2 and 12Z2 have a cross section and number of turns configured to operate under a 20 kHz frequency, said reconfigurable connection 16 involving the interconnection between some of the external connectors 11 of each of the six coils 12 according to at least the following different antenna coil circuits:

[0070] FIG. 3 [0071] an antenna coil circuit providing a common ground 13 to every coil 12X1, 12X2, 12Y1, 12Y2, 12Z1 and 12Z2 so that seven external connections 11 are established with the connection box 10.

[0072] FIG. 4: [0073] an antenna coil circuit providing an intermediate connection 15 between the coils 12X1, 12X2, 12Y1, 12Y2, and 12Z1, 12Z2 of each axis, so that nine external connections 11 are established with the connection box 10.

[0074] FIG. 5 [0075] an antenna coil circuit providing a common ground 13 to a coil 12X1, 12Y1, 12Z1 of every axis and in addition an intermediate connection 15 between the coils 12X1, 12X2, 12Y1, 12Y2, and 12Z1, 12Z2 of each axis, so that seven external connections 11 are established with the connection box 10.

[0076] FIG. 6 [0077] an antenna coil circuit providing two distinct common grounds, a first common ground 13a shared by three coils 12X1, 12Y1, 12Z1 and a second common ground 13b shared by the other three coils 12X2, 12Y2, 12Z2 so that eight external connections 11 are established with the connection box 10.

[0078] The above different connection configurations should not be considered restrictive within the proposed solution of reconfiguring the interconnections of the different coils.

[0079] The invention also provides that around each axis there may be more than two coils.

[0080] According to different tests performed by the inventors it has been concluded that:

[0081] For Q reasons, it is better to wind in the following order: X1+Y1+X2+Y2+Z1+Z2.

[0082] With a common connection for every two windings it is reduced the number of pins from 12 to 9 but the Q factor decreases in a 15%. If we use common ground connection for the coil at 20 kHz (L2) the number of pins can be lowered from 9 to 8.

[0083] With a common ground connection for an option like the 4th it is reduced the number of pins from 12 to 7 but Q factor in x1 decreases in a 25% and sensitivity decrease is about 30%.

[0084] The best option that lowers the pin number 12 with a better Q compromise is a common connection for every two windings (125 kHz and 20 kHz); and a common ground connection for L2; refer to 6th sample.

[0085] These results are based on samples wound over a drum core shape of 11×11×3.75 mm.

[0086] It will be understood that various parts of one embodiment of the invention can be freely combined with parts described in other embodiments, even being said combination not explicitly described, provided there is no harm in such combination.

[0087] The scope of the present invention is defined in the following set of claims.