DE4244146C2 - Dielectric resonator - Google Patents

Description

The present invention relates to a dielectric Resonator, which is arranged in a housing has dielectric body.

There is a general requirement for microwave filters according to a frequency-stable filter characteristic. Dielectric resonators of the introduction, e.g. B. from DE 27 23 013 C2 known type, which is part of a Microwave filters are, but are often subject to temperature-dependent fluctuations in the resonance frequency. The is because the dielectric is either its electromagnetic properties or its volume changes. Such changes can be made by known tuning means, which in protrude the housing or also into the dielectric, be compensated.

From US 4 712 078 an oscillator is known, the one with a phase locked loop coupled dielectric resonator having. To compensate for the temperature-dependent Frequency drift of the dielectric resonator becomes its Ambient temperature measured and a control signal for derived the phase locked loop. The ambient temperature will measured by means of a temperature sensor, but the outside is arranged in the vicinity of the dielectric resonator.  

EP 0 520 665 A2 describes a temperature-compensated dielectric filter disclosed in which with the outer wall a chip capacitor is contacted in a ceramic block, its temperature-dependent behavior opposite to that of the ceramic block.

The invention is based on the object to specify dielectric resonator of the type mentioned at the outset, which is provided with means such. B. temperature dependent Register changes as quickly as possible, so that appropriate regulation and control measures initiated can be without these means the resonator quality significantly affect.

According to the invention, this object is achieved by the features specified in claim 1 solved. An advantageous development of Invention emerges from the subclaim.

Using one shown in the drawing The invention is described in more detail below explained.

The only figure in the drawing shows a schematic illustration of a dielectric resonator, which has a dielectric body 2 arranged in a housing 1 . A ceramic disk 3 fixed to the bottom of the housing 1 serves in a known manner as the holder for the dielectric body 2 .

At least one sensor 4 is arranged in the dielectric body 2 . It is a sensor that registers either changes in temperature, conductivity, pressure or volume of the dielectric body 2 . It is expedient to arrange the sensor 4 in the dielectric body 2 where the magnetic and electrical field lines are oriented as orthogonally as possible to the sensor 2 . Under these circumstances, the resonator quality is least affected. Connecting lines 5 and 6 , via which the measurement signals of the sensor 4 are discharged to the outside, are to be routed through the interior of the housing 1 in such a way that they are aligned as orthogonally as possible to the magnetic and electrical field lines in order not to influence the resonator quality too strongly.

The measurement signals of the sensor 4 can be fed to a controller 7 , which derives a manipulated variable for one or more adjustment elements, which act on the electromagnetic field of the resonator in such a way that resonance frequency changes caused by the dielectric body 2 are compensated for. Tuning elements are not shown in the drawing because they are generally known metallic or dielectric bodies which protrude into the housing 1 .

Depending on the measurement signals from the sensor z. B. also the the power feeding the resonator regulated or to protect the Resonators are switched off.

Claims (2)

1. Dielectric resonator, which has a dielectric body arranged in a housing, characterized in that in the dielectric body ( 2 ) at least one measuring sensor ( 4 ) is used and that the measuring sensor ( 4 ) is arranged in a region where the magnetic and electrical field lines in the dielectric body ( 2 ) are oriented as orthogonally as possible to the measuring sensor ( 4 ). 2. Dielectric resonator according to claim 1, characterized in that electrical connecting lines ( 5 , 6 ) to the sensor ( 4 ) are guided through the interior of the housing ( 1 ) to the outside in such a way that they are aligned as orthogonally as possible to the magnetic and electrical field lines are.