DE202010003614U1 - Waveguide horn antenna for high frequency electromagnetic sensor and signal transmission applications - Google Patents

Abstract

Waveguide horn antenna for high-frequency electromagnetic sensor and signal transmission applications, characterized in that in arbitrarily shaped antenna cross-section their interior is completely filled with a solid, dielectric material.

Description

The The present invention relates to waveguide horn antennas for High frequency sensor and signal transmission applications for medical diagnostic applications, such. B. ultrabroadband-based Imaging, its main feature on a dielectric adaptation between signal source and target area (patient) and on one as possible strong miniaturization by dielectric scaling of the wavelength lies.

In the field of sensor technology and information transmission, broadband radio technologies are increasingly being used ( Thiel F, Hoffmann W, Wojcik F, Hein M, Sachs J, Schwarz U, Helbig M, and Seifert F: "Evaluation of a combined magnetic resonance (MR) / ultra-wideband (UWB) radar" . WO 2007/140088 . DE 10 2008 019 862.5 . US Pat. No. 7,221,159 or US 2003/0058502 ). In addition to the matching electronics, the antennas to be used play an equally important role. Here, the requirements for operating bandwidth, low dispersion, directional characteristics and design must be adapted to the respective requirements. The largest restrictions in the antenna design are thus determined by the environmental and operating parameters.

at the planned application in the medical-diagnostic field the environmental conditions dominated by anatomical features. Especially for breast cancer diagnostics using high-frequency electromagnetic Signals play a significant role in geometric aspects. Around to apply a desired imaging method it is unavoidable, by a multiplicity of sensor elements to build a synthetic aperture. To the target area of interest, about the human breast, this requires a variety of miniaturized Sensor elements are positioned.

Of the trivial approach, microwave signals with shortest wavelengths fails to use at the naturally high Propagation damping in the human body, which Signal frequencies above 10 GHz in such applications are considered technically unusable. That's why one is sustainable compromise between penetration depth and wavelength manufacture. The challenge is even at relative big wavelengths of 30 cm (one frequency from 1 GHz) to develop small but efficient antennas. However, studies have shown that electrically small antennas with a size below one fifth Wavelength due to their low radiation efficiencies do not meet the systemic requirements.

task Therefore, the disadvantages of the present invention are the disadvantages of the present invention State of the art overcome and efficient and electric large but geometrically miniaturized antenna elements for biomedical applications.

According to the invention succeeds the solution of this task with the features of the first Protection claim. Advantageous embodiments of the invention Waveguide horn antenna are specified in the subclaims.

The Invention is defined below with reference to drawings. It demonstrate:

1 A first embodiment of a dielectrically scaled double-ridge horn antenna according to the invention with an elastic, gelatin-based filling material

2 - An embodiment of a dielectric base body in final antenna form

3 - Functional waveguide horn antenna according to the invention

According to the invention resorting to the known method of dielectric scaling, when guided by the use of dielectric materials Wavelength and thus also a possible antenna geometry reduced according to the root of the dielectric constant can be. Accordingly, the waveguide horn antennas become complete filled with a dielectric.

Antenna applications in connection with dielectrics such as "Dielectric Rod Antennas" (US Pat. Blech M, Leibfritz M, and Eibert T: "Ultra Wideband Dielectric Rod Antenna with Biconical Dipole and Reflector" (IEEE 2007), from the US 5,550,553 and the EP 2105991-A4 , The use of low-dielectric materials (ε '<16) causes the lowest possible loss angle tan (δ). Here, the main motivation is to look in a specially designed radiation in the open space. Similar motivations exist in the form of lens antennas in which low-dielectric lenses are introduced only in the aperture surroundings of otherwise air-filled horn antennas in order to achieve a specific radiation characteristic similar to optical lenses. In these applications, essentially the refraction of the selected lenses is exploited. Shortening the wavelength to reduce the geometric antenna size is not a primary motivation in such cases. Typical materials used in corresponding applications are Teflon (ε '≈ 2.1), Al ₂ O ₃ (ε' ≈ 9.4), LTCC (ε '≈ 7.5), FR4 (ε' ≈ 4.1) and other plastics with low permittivities (ε '<10). For the present task In biomedical diagnostics, the potential for wavelength shortening resulting from these parameters is far too low. In addition, the use of the dielectric does not seek to deform the radiation properties. For physical reasons, dielectrically scaled antennas are only suitable for radiation into free space if the dielectric contrast between the dielectric and the environment is low.

With the present invention, however, is a radiation in a also sought dielectric medium. The human body Due to its high water content, it has some considerable permittivities on (ε '= 20-65). By this circumstance can the use of dielectrically scaled antennas in addition be justified for size reduction.

Of the The novelty value of the present development is now in addition to low-dielectric materials (ε '<16) highest possible dielectric (ε '≥ 16) and partly to date in high-frequency engineering unusual materials as filling medium for To use waveguide horn antennas. As a waveguide horn antenna is here and below denotes an antenna type, which is made up of the expansion of the cross section of a waveguide in E-plane, H-plane or a combination of both. The feeding point is included typically executed as a coaxial-to-waveguide transition.

Following this approach, acetone (ε '≈ 21), oil-gelatin compositions (ε' ≈ 20-75) and high-dielectric ceramics (ε '> 60) have hitherto been used successfully in conjunction with correspondingly dielectrically scaled waveguide horn antennas. The dielectric in these applications completely fills the antenna and replaces the otherwise common air, which in such implementations becomes essential to the desired operation of the antenna. The complete filling of the antenna is therefore not to be confused with the introduction of a lens. A strict distinction to dielectric antennas, such as out EP 2105991-A4 It is known that all original design details of a waveguide horn antenna are preserved. The only exception is the invention complete filling with a dielectric.

The Spectrum of own technical realizations covered similarly the listed materials antennas based on liquid, Permanently elastic and solid fillers. Especially at the use of liquid materials can, depending on the application, a seal will be required, which due to this approach has less relevance to practical considerations.

Physically are caused by the use of dielectric substances in the area guided electromagnetic waves not only the propagation velocity and hence the wavelength, but also the field wave impedance scaled by √ε '. This has the consequence that at a dielectrically scaled antenna the typical impedance conditions of 120π ohms at the aperture and the most technically used Feeding impedance of 50 ohms can be changed. Especially in the area the feed impedance is not always ready, to rely on different values. Then next to a linear one geometric scaling also re-optimizes the actual Antenna geometry required, resulting in different function parameters in Can lead to comparison to the original.

Finally, the above aspects have produced two antenna designs according to the invention. In 1 a double-ridge horn antenna is shown optimized for operation in conjunction with a gelatin-based filler. In the case of operating parameters comparable to the original, which correspond to the usual requirement profile for double-ridge horn antennas, the aperture area could be reduced eightfold through the use of the dielectric.

Another embodiment is in 2 and 3 presented. Based on a dry-pressed, then sintered and machined ceramic body in horn antenna form, a double-ridge horn antenna was produced in which a subsequently electrochemically applied copper layer ensures electrical functionality. The antenna shown is designed for a feed impedance of 50 ohms and has by using a ceramic with ε '= 65 over a twenty-fold reduced aperture area compared to an original for operation with or in air. In the 3 to be recognized extension of the aperture is technologically conditioned and is as well as the arbitrary set feed impedance of 50 ohms no requirement for the function of the antenna concept according to the invention.

Finally, it is noted that already ceramic horns are known ( US 7,297,238 B2 ). However, these relate entirely to ultrasound applications, thus addressing a completely different mechanism of action. A reference to the dielectric constant and in particular to electromagnetic waves does not exist.

ε '

real part the complex valency permittivity at the frequency of use

Al ₂ O ₃

Aluminum oxide

LTCC

low Temperature Cofired Ceramics

FR4

With Epoxy resin impregnated glass fiber mats

tan (δ)

dielectric loss angle

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• WO 2007/140088 [0002]
• - DE 102008019862 [0002]
• US 7221159 [0002]
• US 2003/0058502 [0002]
• US 5550553 [0012]
• - EP 2105991 A4 [0012, 0015]
• US 7297238 B2 [0020]

Cited non-patent literature

• Hoffmann W, Wojcik F, Hein M, Sachs J, Schwarz U, Helbig M, and Seifert F: "Evaluation of a combined magnetic resonance (MR) / ultra-wideband (UWB) radar" [0002]
• - Sheet metal M, Leibfritz M, and Eibert T: "Ultra Wideband Dielectric Rod Antenna with Biconical Dipole and Reflector" [0012]

Claims (10)

Waveguide horn antenna for high-frequency electromagnetic sensor and signal transmission applications, characterized in that in arbitrarily shaped antenna cross-section their interior is completely filled with a solid, dielectric material. Waveguide horn antenna according to claim 1, characterized that the material with which the antenna cross-section is filled is, has high dielectric properties (ε '> 10). Waveguide horn antenna according to one of the claims 1 or 2, characterized in that the material with which the Antenna cross-section is filled in the aperture area inclusions low-dielectric substances. Waveguide horn antenna according to one of the claims 1 to 3, characterized in that the material with which the antenna cross section is filled, is elastic. Waveguide horn antenna according to one of the claims 1 to 3, characterized in that the material with which the antenna cross section is filled, is a ceramic. Waveguide horn antenna according to one of the claims 1 to 5, characterized in that the material with which the antenna cross section is filled, one to the surface of a DUT has matching termination surface. Waveguide horn antenna according to one of the claims 1 to 6, characterized in that the electrically conductive antenna components massively and independently existing existent and that dielectric material with which the antenna cross section is filled is to wear mechanically. Waveguide horn antenna according to one of the claims 1 to 6, characterized in that the electrically conductive antenna components are not existent independently and only by the dielectric material with which the antenna cross section is filled is to be carried. Waveguide horn antenna according to one of the claims 1 to 7, characterized in that the electrically conductive regions the antenna side walls have recesses. Waveguide horn antenna according to one of the claims 1 to 9, characterized in that they are double-horned antenna is executed.