SU1659933A1 - Doppler signal simulator - Google Patents

Abstract

The invention relates to radio engineering. The purpose of the invention is to change the sign of the Doppler frequency offset. The simulator contains a segment 1 of a rectangular waveguide (OPV) curved along a semicircle, in the wide wall of which a longitudinal slit 2 is made, a matched load (CH) 3 and additional CH 4 connected to the ends of OPV 1, additional OPV 5 connected to a narrow wall of OPV 1 in the middle of its curved section, and the probe 6, one end of which, together with the reflector 9, is inserted into the OPV cavity 1, and the other end connected to the motor axis through the disk 8. When the disk 8 rotates clockwise and the reflector 9 is in the axial half of the curved section and OPV 1 in the additional OPV 5, which serves both as an input and output of the device, there is a reflected wave with a Doppler frequency offset corresponding to the approaching target, and when the reflector 9 goes into the right half of the curved OPV 1, the sign of the Doppler frequency offset changes to the opposite . 2 Il. Ј O el Yu Yu CJ SO V

Description

The invention relates to radio engineering and can be used to control the parameters and settings of devices using the Doppler effect.

The aim of the invention is to change the sign of the Doppler frequency shift.

FIG. 1 shows the simulator, a general view; in fig. 2 shows section A-A in FIG. one.

The Doppler signal simulator contains a segment 1 of a rectangular waveguide, bent along a semicircle, in a wide wall of which a longitudinal slit 2 is made, a matched load 3 and an additional matched load 4 connected to the ends of a segment 1 of a rectangular waveguide, an additional piece 5 of a rectangular waveguide connected to a narrow wall of segment 1 of a rectangular waveguide in the middle of its curved section, and a probe 6, one end of which is inserted through a longitudinal slit 2 into the cavity of segment 1 of a rectangular waveguide and the other end is connected to the axis of the engine 7 through the disk 8. To select the magnitude of the reflected signal, there is a reflector 9 installed at the end of the probe 6. An additional segment 5 of the rectangular waveguide forms H-tee with segment 1 of the rectangular waveguide and device output.

The Doppler signal simulator works as follows.

The microwave divider signal entering the additional segment 5 of the rectangular waveguide is equally divided between both arms of segment 1 of the rectangular waveguide, with both arms being excited phase-wise. Suppose that with the engine 7 turned on, the disk 8 rotates clockwise and at the initial time the reflector 9 and the probe 6 are outside segment 1 of the rectangular waveguide. At the same time, all the power arriving at segment 1 of the rectangular waveguide is dissipated in matched load 3 and additional matched load 4 and the reflected wave is absent. When the reflector 9 enters the cavity of the left shoulder of the segment 1 of a rectangular waveguide, a part of the power is reflected from the reflector 9 and enters an additional segment 5 of the rectangular waveguide. When moving the reflector 9 from the point of entry into

segment 1 of the rectangular waveguide to the point where the additional segment 5 of the rectangular waveguide is connected, it contains a reflected wave with a Doppler frequency shift corresponding to the approaching target. When the reflector 9 passes through the middle of the curved section of segment 1 of a rectangular waveguide, the sign of the Doppler frequency shift reverses and in the additional segment 5

A rectangular waveguide has a reflected wave with a Doppler frequency shift corresponding to a moving target. The number of periods of the Doppler frequency depends on the number of half-waves contained in the curved portion of segment 1 of a rectangular waveguide. Thus, if the disk 8 rotates clockwise, in one cycle of operation of the device, a radio signal is generated containing a Doppler

a frequency offset corresponding first to an approaching one, and to a distance target.

Claims (1)

The invention The Doppler signal simulator containing a segment of a rectangular waveguide, curved along a semicircle, in a wide wall of which a longitudinal slit is made, a matched load connected to one of the ends of the segment a rectangular waveguide, and a probe, one end of which is inserted through a longitudinal slit into the cavity of a rectangular waveguide segment, and the other end connected to an axis of a motor located coaxially with a curved portion of a rectangular waveguide, which is characterized by the fact that nor the sign of the Doppler frequency shift, an additional segment of a rectangular waveguide is introduced, connected to 5 is a narrow wall of a rectangular waveguide segment in the middle of its curved portion, and an additional matched load is connected to the other end of the rectangular waveguide portion. A -A / / / / FIG g