METHOD FOR PERFORMING IMAGING POLARIMETRY, TRANSPONDER, AND SYSTEM FOR PERFORMING IMAGING POLARIMETRY

Abstract

A method serves for imaging polarimetry. A chipless, passive transponder which has a plurality of surface regions with different polarimetric properties is illuminated fully polarimetrically by radar radiation. At least one polarization-encoded image of the transponder is generated using the radar radiation reflected thereby, and the different surface regions of the transponder in the polarization-encoded image can be recognized by their at least one polarimetric property. The passive, chipless transponder has at least two surface regions with different polarimetric structures.

Claims

1. A method for imaging polarimetry, which comprises the steps of: irradiating a chipless, passive transponder having a number of surface regions with different polarimetric properties by means of radar radiation with at least two differently polarized waves; generating at least one polarization-encoded image of the chipless, passive transponder on a basis of the radar radiation reflected from the chipless, passive transponder; and recognizing the surface regions of the chipless, passive transponder in the polarization-encoded image by means of at least one polarimetric property of each of the surface regions.

2. The method according to claim 1, which further comprises recognizing at least one of the surface regions from an associated polarization-encoded partial image by analytical calculation of the at least one polarimetric property.

3. The method according to claim 2, which further comprises recognizing at least one of the surface regions on a basis of an image comparison of the associated polarization-encoded partial image with at least one reference image.

4. The method according to claim 1, which further comprises subjecting the at least one polarization-encoded image of the chipless, passive transponder to a Pauli decomposition and the surface regions of the chipless, passive transponder are recognized from at least one Pauli-decomposed image by means of the at least one polarimetric property.

5. The method according to claim 1, which further comprises generating the at least one polarimetric property of at least one of the surface regions on a basis of an incorporated polarimetrically effective structure.

6. The method according to claim 1, which further comprises generating the at least one polarimetric property of at least one of the surface regions on a basis of a material of the surface regions.

7. The method according to claim 1, which further comprises determining a temperature of the chipless, passive transponder from the at least one polarimetric property of at least one of the surface regions.

8. The method according to claim 5, wherein at least one of the surface regions has a structure that changes in terms of its polarimetric effect temperature-dependently.

9. The method according to claim 1, which further comprises illuminating the chipless, passive transponder fully polarimetrically.

10. A passive, chipless transponder, comprising: at least two surface regions having different polarimetric structures.

11. The transponder according to claim 10, wherein at least one of said polarimetric structures has at least one side wall, which has a predetermined angle of inclination.

12. The transponder according to claim 10, wherein said at least two surface regions have said polarimetric structures with a same basic form, but different dimensioning and/or alignment.

13. The transponder according to claim 10, wherein the chipless, passive transponder is formed of one material or a composite of materials.

14. The transponder according to claim 10, wherein different ones of said surface regions are assigned materials with different polarimetric backscattering behavior.

15. A system, comprising: at least one passive, chipless transponder having at least two surface regions with different polarimetric structures; and at least one reader for radar-based reading of said at least one passive, chipless transponder, said at least one reader programmed to: irradiate said chipless, passive transponder by means of radar radiation with at least two differently polarized waves; generate at least one polarization-encoded image of said chipless, passive transponder on a basis of the radar radiation reflected from said chipless, passive transponder; and recognize the surface regions of said chipless, passive transponder in the polarization-encoded image by means of at least one polarimetric property of each of said surface regions.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

[0056] FIG. 1 is a polarimetric radar image of a radar transponder according to the invention with various surface regions;

[0057] FIG. 2 is a diagram showing surface regions of the radar transponder from FIG. 1;

[0058] FIG. 3 is an image of the radar transponder of which the image points indicate the intensities of the scattering processes;

[0059] FIG. 4 is a Pauli-decomposed image of the radar transponder which indicates double reflection;

[0060] FIG. 5 is a Pauli-decomposed image of the radar transponder which indicates subsurface scattering;

[0061] FIG. 6 is an image showing an intensity of the component of the double reflection of the Pauli decomposition in the case of a Pauli-decomposed image of the transponder; and

[0062] FIG. 7 is an image showing an intensity of the component of the subsurface scattering of the Pauli decomposition in the case of a Pauli-decomposed image of the transponder.

DETAILED DESCRIPTION OF THE INVENTION

[0063] Referring now to the figures of the drawings in detail and first, particularly to FIG. 1 thereof, there is shown a transponder 1, which is formed as a plate-shaped aluminum part with a contour that is square in plan view. An edge length may be for example about 10 cm. The transponder 1 may be irradiated by a reader G with fully polarized radio waves, in particular radar radiation R. The radiation reflected or backscattered at the transponder 1 can be detected by the reader G and evaluated there or in an independent evaluation device (not depicted). In particular, at least one image B1 to B3 (see for example FIGS. 3 to 5) of which the image points carry a piece of polarization information can be generated by means of the detected backscattered radiation.

[0064] FIG. 2 shows a diagram of nine zones or surface regions T1 to T9 of the transponder 1. The surface regions T1 to T9 likewise have a square form and are of the same size.

[0065] The polarimetric characteristics of the surface regions T1 to T9 can be differentiated and unequivocally assigned with the aid of the radar-interrogating measuring method used. The information of the transponder 1 is encoded in the polarimetric backscattering behavior. Since the backscattering behavior of the surface regions T1 to T9 used is defined and known, during the evaluation they can be sought and classified on the basis of their properties. Each existing, previously defined backscattering behavior describes a possible information state. By arranging a number of surface regions T1 to T9 that can be differentiated from one another here by their geometrical surface structure or the absence thereof, and consequently different information states, information can be stored on the transponder 1.

[0066] In the case of the transponder 1, for example, there are surface regions T1 to T9 with five different information states. For this purpose, the two surface regions T1 and T5 are formed as smooth surface regions. The surface region T2 is formed as a roof mirror with a tilting angle a of a longitudinal axis L of parallel longitudinal grooves 2 incorporated therein of +45 with respect to the horizontal H. The surface regions T3, T4 and T8 are formed as roof mirrors with a tilting angle of the parallel longitudinal grooves 2 incorporated therein of +0 with respect to the horizontal H. The surface regions T6 and T7 are formed as roof mirrors with a tilting angle a of the parallel longitudinal grooves 2 incorporated therein of 90 with respect to the horizontal H and the surface region T9 is formed as a roof mirror with a tilting angle of the parallel longitudinal grooves 2 incorporated therein of 45 with respect to the horizontal H. In this example, a code size of 20 bits would be obtained. In this case, the information content of a transponder 1 depends on the one hand on the number of possible information states per zone or surface region and on the other hand on the number of usable zones or surface regions. With more surface regions, high data rates can in this way be achieved.

[0067] In practice, surface regions with triple mirrors, dipole structures (for example wires, planar dipoles or planar meandering elements), diffuse scattering bodies or the like may be used for example as structures. In this case, it should be generally ensured that the individual surface regions are separable from one another both polarimetrically and spatially. This means that the geometrical dimensions of the surface regions should be chosen on the basis of the available resolving power of the imaging system. The geometrical form of the surface regionshere a squarecan in this case be freely chosen as desired. The surface regions can be freely combined and arranged as desired on a transponder. The maximum geometrical dimensions determine the maximum number of elements of a transponder.

[0068] FIG. 3 shows an image of the transponder 1 of which the image points indicate the intensities of the scattering processes. In particular, this applies to the overall intensity represented, i.e. the sum of all the individual results of the Pauli decomposition. In this case, FIG. 3 shows a grayscale image B1, while the intensities of the scattering processes can also be advantageously represented on the basis of an RGB color scale. The image B1 has partial images TB1 to TB9, which correspond to the surface regions T1 to T9 and represent the radiation backscattered from these surface regions T1 to T9. On the basis of this graphic representation, first the smooth surface regions T1 and T5 can be unequivocally differentiated from the other surface regions T2 to T4 and T6 to T9, which act as roof mirrors for the incident radar radiation. Furthermore, some of these surface regions T2 to T4 and T6 to T9 can already be differentiated from one another.

[0069] FIG. 4 shows a Pauli-decomposed image B2 of the transponder 1 which only indicates the double reflection components of the scattering processesto be more precise the phases associated with double reflection. In this case, corresponding partial images (without designations) are generated, bordered here by the lines depicted as dashed.

[0070] FIG. 5 shows a Pauli-decomposed image B3 of the transponder 1 which only indicates the subsurface scattering components of the scattering processesto be more precise the phases associated with subsurface scattering. Here, too, corresponding partial images (without designations) are generated, bordered here by the lines depicted as dashed.

[0071] FIG. 6 shows an intensity of the component of the double reflection of the Pauli decomposition in the case of a Pauli-decomposed image B4 of the transponder 1. In this case, here again nine schematically shown corresponding partial images are generated.

[0072] FIG. 7 shows an intensity of the component of the subsurface scattering of the Pauli decomposition in the case of a Pauli-decomposed image B5 of the transponder 1. Here, too, again nine schematically shown corresponding partial images are generated.

[0073] FIGS. 4 to 7 also show grayscale images, while the intensities of the scattering processes can advantageously also be represented on the basis of an RGB color scale.

[0074] By means of a comparison of the partial images from, for example, FIGS. 3-5 (in any suitable combination desired and/or with at least one reference (partial) image [not depicted]), also the previously not yet differentiated surface regions T2 to T4 and T6 to T9 with roof mirrors of different tilting angles can thus be unequivocally differentiated from one another. The partial images of FIGS. 6 and 7 can also be used for this.

[0075] In comparison with many previous RFID systems, the information in the transponder 1 presented is not encoded in either the time-domain or frequency-domain response. The reading out of the data of the transponder 1 takes place by means of an imaging radar method. In this case, the information of the transponder 1 is stored purely in the polarimetric reflection properties of the surface regions T1 to T9 and in their arrangement on the transponder 1.

[0076] The polarimetric backscattering behavior of the surface regions T1 to T9 used can be analytically specified. In the case of the smooth surface regions T1 and T5, the backscattering behavior is independent of the polarization. For the surface regions T2 to T4 and T6 to T9 with roof mirrors, the backscattering behavior can be calculated in dependence on the tilting angle. Conversely, the tilting angle can be calculated back from the polarimetric backscattering behavior determined by the imaging radar. This allows the exact alignment of the surface regions T1 to T9, and consequently the composition of the transponder 1, to be unequivocally inferred. Consequently, the information transmission between the transponder 1 and the reader G is ensured by way of the polarimetric imaging.

[0077] The combination of RFID, in particular radar reading, and polarimetry represents a new type of chipless, passive RFID systems, which though based on imaging, uses polarimetry for storing information. Furthermore, the system represents a novel application of polarimetric imaging, which is used here for storing information.

[0078] The flexible choice of material and the structure of the individual surface regions T1 to T9 make it possible for the transponder 1 to be used at high temperatures, where in addition to information transmission it can also be used as a temperature sensor.

[0079] Although the invention has been more specifically illustrated and described in detail by the exemplary embodiments shown, the invention is not restricted to these, and other variations may be derived from them by a person skilled in the art without departing from the scope of protection of the invention.

[0080] In general, a, one, etc. may be understood as meaning a singular or a plural, in particular in the sense of at least one or one or more, etc., as long as this is not explicitly excluded, for example by the expression exactly one, etc.

[0081] A numerical indication may also comprise the indicated number exactly and also a customary tolerance range, as long as this is not explicitly excluded.