SU1027647A1 - Device for measuring distribution of magnetic field of wave-guide - Google Patents

Description

The invention relates to a technique of measuring at ultrahigh frequencies and can be used in the development and calibration of waveguide communication devices operating on higher types of waves, for example, on a circular waveguide wave. A device is known for measuring the distribution of a field in a waveguide containing a segment of a multi-phase Novod, shorted by a piston with an accurate reading mechanism, a narrow slit is cut through the surface of the waveguide, connecting a multimode waveguide with a secondary tunable resonator, in which a quadratic detector is placed, using a piston detector tune to the resonance of any higher type of wave and measure its amplitude l. The disadvantage of the device is a significant difference in communication for all waves E ... and H, since it is impossible cut a slit on the surface of the waveguide so that it is parallel to the line currents of all types of waves. The device also does not distinguish in-phase types of H waves, and the closest to the present invention is a device for measuring the distribution of the electromagnetic field in a waveguide, which contains a matched load placed in a circular waveguide section and probes connected to an indicator through a switch. However, the known device does not measure the distribution of the fields of various types of waves, since the probes have a weak connection with the waves. The purpose of the invention is to expand the range of the measured types of waves. This goal is achieved by the fact that in a device for measuring the distribution of an electromagnetic field in a waveguide containing matched loads placed in a circular waveguide segment and probes connected through a switch to an indicator, a conical cavity is made with the probes placed on the surface the conical cavity in the spiral of Archimedes, and the matched load is installed with the possibility of axial. Fig. 1 shows the structure of the device; Fig. 2 shows a section A-A in Fig. 1. A device for measuring the distribution of the electromagnetic field in a waveguide contains a segment 1 of a circular waveguide, into which is placed the co-loaded load 2 and the probes 3 in the form of segments of the central conductors of the coaxials. The matched tier 2 is rotatably mounted in bearings k with the aid of drive 5. All probes 3 are switched to one common output by switch 6 connected to an indicator (not shown |, the height of the conical cavity is chosen according to the condition that the whole spectrum of e.g. (lO-12) A, where is the lower wavelength in the circular waveguide section 1. The device operates as follows. When the wave mixture is incident on the matched load 2, the field is measured at each point where probe 3 is located, with known coordinate The probes 3 are switched by the switch 6. When the next probe 3 is connected, the remaining loads are loaded with matched loads; they are built into the switch 6. When the next probe 3 is connected to measure wave fields whose polarization is not maintained, the matched load 2 rotates around its axis. each probe 3 describes a circle on a conic surface of a matched load 2. The measured values of the total amplitudes of the field under study at points with known coordinates for each probe 3 contain information about amplitudes of the waves and the phases of the test floor. The latter are determined by solving a system of linear algebraic equations. The proposed device aligns the coupling of the probes 3 with the TlinoB E and H waves, significantly improves matching across all propagating wave types, allows for measuring waves with arbitrary polarization, as well as common-mode wave types, and provides automation of measurements.

Claims (1)

DEVICE FOR MEASUREMENT ELECTROMAGNETIC FIELD DISTRIBUTIONS IN A WAVEGUIDE containing a matched load placed in a segment of a circular waveguide and probes connected via a switch to an indicator, characterized in that, in order to expand the range of measured role types, a conical cavity is made along the axis of the matched load, while the probes are placed on the surface of the conical cavity in a spiral of Archimedes, and the coordinated load is installed with the possibility of axial rotation.