RU87055U1 - DEVICE OF INTERFERENCE-RESISTANT RECEIVER OF ON-BOARD EQUIPMENT OF RADIO-TECHNICAL SYSTEM OF MIDDLE NAVIGATION AND LANDING - Google Patents

Abstract

A noise-immunity receiver device for the on-board equipment of a short-range navigation and landing radio engineering system, comprising a receiving antenna connected to a power divider, the first output of which is the input of the receiver of ranging signals, and the second output is the input of the receiver of azimuth signals, and a decoder of ranging signals, the output of which is the first input range meter, azimuthal pulse shaper connected by its output to the first input of the azimuth meter, reference signal decoder, s a single output with a second input and a second output with a third input of an azimuth meter, a landing signal transducer, the first output of which is a second input of a range meter, which is connected with a range indicator by its output, and the second output of the landing signal transducer is connected to the fourth input of the azimuth meter, which is connected by its output to the azimuth indicator, characterized in that the receiver of the ranging signals with its first output is connected to the first input, and the second output to the second the digital signal processing submodule, and the azimuth signal receiver is connected with its first output to the fourth input, the second output with the fifth input, and the third output with the third input of the digital signal processing submodule, which is connected with the first output to the range finder, the second output is connected to the first the input, and the third output with the second input of the landing signal converter, the fourth output, the digital signal processing submodule is connected to the reference signal decoder, and the fifth output is soy

Description

The utility model relates to the field of radio engineering, in particular to devices for limiting or suppressing noise and interference in a receiver and can be used to ensure high-quality signal reception (increasing noise immunity) under the influence of interference.

A device for suppressing narrowband and impulse noise / A device for suppressing narrowband and impulse noise. - author St. USSR 1329577, class H04B 1/10, 05.12.85 /, designed to suppress narrowband and impulse noise at the input of the device. This device includes: a filter, three delay elements, a switch, a phase corrector, a narrow-band filter, a computer, two keys, a unit for estimating the rms value of the signal voltage, a voltage divider, an amplitude comparator, an envelope detector, and an averaging element. The disadvantage of this device is that it can only suppress stationary narrowband and impulse noise.

A device known as an interference canceller / interference compensator is known. - author St. USSR 1358756, class H04B 1/10, 05.06.85 /, designed to suppress broadband interference at the input of the device. This device contains: two dispersion delay lines, two frequency converters, an adder, a frequency-controlled generator, an integrator, a mixer and a phase shifter. The disadvantage of this device is that it can only suppress stationary broadband interference.

The prototype of the utility model in technical essence is the device of the receiver of the on-board equipment of the radio technical system of short-range navigation and landing (BO RSBN), shown in Fig. 1 / Troyanovsky A.D., Kluga A.M., Tsilker B.Ya. On-board equipment of short-range navigation systems - M .: Transport, 1990. P.132 /. The device comprises: a receiving antenna (1), a power divider (2), a rangefinder signal receiver (3), an azimuth signal receiver (4), a rangefinder signal decoder (5), an azimuth pulse generator (6), a reference signal decoder (7), landing signal transducer (8), range meter (9), azimuth meter (10), range indicator (11) and azimuth indicator (12).

The device operates as follows. The input signal received by the antenna’s receiving aperture (1) is a mixture of range, azimuth, course, glide path and reference signals of the 35 and 36 series signals, and is fed to two receivers: range-finding (3) and azimuthal through a power divider (2) (4) signals.

Range response signals and glide paths are amplified and detected in the receiver of rangefinder signals (3), while range response signals are allocated at its broadband output 1, and the narrowband glide path signal at output 2 of the receiver. Range response signals are fed to the input of the rangefinder signal decoder (5), where they are decoded. Range response pulses allocated by the encoder of rangefinder signals (5) are sent to input 1 of the range meter (9), in which the slant range is determined from the time interval between the interrogation and response signals taking into account the delay time constant.

The glide path signal is fed to input 1 of the landing signal converter (8), which operates on the basis of the principle of creating equal signal directions (glide path and course), where it is converted to a differential voltage proportional to the deviation from the glide path equal direction and from output 1 is fed to input 2 of the range meter (9 )

From the output of the range meter, the values of the measured range and deviations from the glide path go to the range indicator (11), where they are displayed.

The azimuth, heading, and reference signals of the 35 and 36 series are amplified and detected in the azimuth signal receiver (4). The reference signals of the “35” and “36” series are allocated at the broadband output of 1 receiver (4), and the narrow-band azimuth and course signals are respectively at outputs 2 and 3 of the receiver (4).

The reference signals of the series "35" and "36" are fed to the input of the decoder of the reference signals (7), and the azimuth signal to the input of the azimuthal pulse shaper (6). The decoded reference pulses of the 35 and 36 series from the outputs 1 and 2 of the decoder (7), respectively, and the azimuthal pulse from the output of the azimuthal pulse shaper (6) are fed to the inputs 2, 3, and 1, respectively, of the azimuth meter (10), in which the mutual temporal alignment of the reference signals and the azimuthal pulse determines the azimuth value.

The heading signal is fed to input 2 of the landing signal transducer (8), where it is converted to a differential voltage proportional to the deviation from the equal-signal direction of the course and from output 2 it is fed to input 4 of the azimuth meter (10).

From the output of the azimuth meter, the values of the measured azimuth and deviation from the course go to the azimuth indicator (12), where they are displayed.

The disadvantage of this device is that it can provide quasi-optimal processing of received signals under the influence of only stationary noise and chaotic impulse noise. However, the intensive development of the radio frequency range in which the RSBN operates, for example, by a mobile radio communication network, leads to the fact that this device is forced to function in a complex, changing (non-stationary) interference environment, characterized by a significant increase in the level of the total interference field at its input with a priori uncertainty regarding the properties of interference and signals. This leads to a decrease in the power of the received signals (up to the disappearance) while increasing the relative and absolute levels of the received active and passive interference, as well as to distortion of the form and strong fluctuations of the signals when operating outside the radio horizon, especially in the interference zone of diffraction and tropospheric radio waves, and as a result, a significant deterioration in the total signal-to-noise + noise ratio in the receiver of the RSBN receiver and a sharp decrease in the accuracy of estimation of navigation parameters.

The objective of the utility model is to increase the noise immunity of the RSBN receiver in the presence of an unsteady total noise field at its input with a priori uncertainty regarding the properties of signals and noise in the interest of improving the accuracy of measuring navigation parameters.

The technical result that provides the solution of this problem is to increase the generalized signal-to-noise + noise ratio in the receiver of the RSBN receiver, achieved by using methods that implement adaptive signal processing algorithms that allow for the suppression of non-stationary interference in the conditions of a priori uncertainty in the reception channels.

The specified task and the achievement of the claimed technical result are achieved by the fact that according to the utility model, the proposed device of the noise-resistant receiver BO RSBN additionally introduces a submodule of digital signal processing (DSP) based on digital programmable processors / Korneev V.V., Kisilev A.V. Modern microprocessors, M.: Nolidzh, 2000 /, operating on the basis of adaptive filtering algorithms given, for example, in / Zanozin A.V., Mikhanov N.P. Sai P.A. Improving the security of the on-board receiver of a short-range navigation radio system and landing from interference of mobile radio communications of the GSM-900 standard. - Radio Engineering, 2009, No. 1, p.113-116 / and performing analog-to-digital signal processing, their adaptive filtering with subsequent digital-to-analog conversion / Borisov Yu.V. The first domestic continuous monitoring system with a high-speed DAC / ADC of 600 Small samples / s via two quadrature channels. - Electronics: science, technology, business, 2004, No. 2 /.

Figure 2 presents a diagram of the proposed device noise-resistant receiver BO RSBN. The device comprises: a receiving antenna (1), a power divider (2), a rangefinder signal receiver (3), an azimuth signal receiver (4), a rangefinder signal decoder (5), an azimuth pulse generator (6), a reference signal decoder (7), landing signal converter (8), range meter (9), azimuth meter (10), range indicator (11), azimuth indicator (12) and DSP submodule (13).

The proposed device anti-interference receiver BO RSBN works as follows. The input signal received by the antenna’s receiving aperture (1) is a mixture of range, azimuth, course, glide path and reference signals of the 35 and 36 series signals, and is fed to two receivers: range-finding (3) and azimuthal through a power divider (2) (4) signals.

Range response signals and glide paths are amplified and detected in the receiver of rangefinder signals (3), while range response signals are allocated at its broadband output 1, and the narrowband glide path signal at output 2 of the receiver. The range response signals and the glide path signal are fed to input 1 and input 2, respectively, of the DSP submodule (13) similar to the submodule given in / Zanozin A.V., Mikhanov N.P. Sai P.A. Improving the security of the on-board receiver of a short-range navigation radio system and landing from interference of mobile radio communications of the GSM-900 standard. - Radio Engineering, 2009, No. 1, p.113-116 /, based on digital programmable processors / Korneev VV, Kisilev A.V . Modern microprocessors, M .: Nolidzh, 2000 /, which operates on the basis of adaptive algorithms for filtering broadband and narrowband signals given, for example, in / Zanozin A.V., Mikhanov N.P. Sai P.A. Improving the security of the on-board receiver of a short-range navigation radio system and landing from interference of mobile radio communications of the GSM-900 standard. - Radio Engineering, 2009, No. 1, p.113-116 / and performing analog-to-digital processing of these signals, their adaptive filtering followed by digital-to-analog transformation / Borisov Yu.V. The first domestic continuous monitoring system with a high-speed DAC / ADC of 600 Small samples / s via two quadrature channels. - Electronics: science, technology, business, 2004, No. 2 /. The processed range response signals from the output 1 of this submodule are fed to the input of the rangefinder signal decoder (5), where they are decoded. Range response pulses allocated by the encoder of rangefinder signals (5) are sent to input 1 of the range meter (9), in which the slant range is determined from the time interval between the interrogation and response signals taking into account the delay time constant. The processed glide path signal from the output 2 of the DSP submodule (13) is fed to input 1 of the landing signal converter (8), which operates on the basis of the principle of creating equal-signal directions (glide path and course), where they are converted into a difference voltage proportional to the deviation from the glide path direction and from the output 1 is fed to input 2 of the range meter (9). From the output of the range meter, the values of the measured range and deviations from the glide path go to the range indicator (11), where they are displayed.

The azimuth, heading, and reference signals of the 35 and 36 series are amplified and detected in the azimuth signal receiver (4). The reference signals of the “35” and “36” series are allocated at the broadband output of 1 receiver (4), and the narrow-band azimuth and course signals are respectively at outputs 2 and 3 of the receiver (4). The reference signals of the series “35” and “36” are input to the input 4 of the DSP submodule (13), and the azimuth and course signals are respectively to the inputs 5 and 3 of this submodule. The processed reference signals of the “35” and “36” series from the output 4 of the DSP submodule (13) are fed to the input of the reference signal decoder (7), and the azimuth signal from the output 5 of this submodule to the input of the azimuthal pulse generator (6). The decoded reference pulses of the 35 and 36 series from the outputs 1 and 2 of the decoder (7), respectively, and the azimuthal pulse from the output of the azimuthal pulse former (6) are fed to the inputs 2, 3 and 1, respectively, of the azimuth meter (10), in which the mutual temporal alignment of the reference signals and the azimuthal pulse determines the azimuth value. The processed heading signal from the output 3 of the DSP submodule (13) is fed to input 2 of the landing signal converter (8), where it is converted to a differential voltage proportional to the deviation from the equal-signal direction of the course and from output 2 is fed to input 4 of the azimuth meter (10). From the output of the azimuth meter, the values of the measured azimuth and deviation from the course go to the azimuth indicator (12), where they are displayed.

A comparative assessment of the effectiveness of the proposed device noise-resistant receiver BO RSBN and prototype device was carried out according to the method described in / Zanozin A.V., Mikhanov N.P. Sai P.A. Improving the security of the on-board receiver of a short-range navigation radio system and landing from interference of mobile radio communications of the GSM-900 standard. - Radio Engineering, 2009, No. 1, p.113-116 /. As an indicator of immunity to interference, the minimum ratio of the useful signal power to the interference power was used, which ensures the required quality of determining the navigation parameters achieved using the proposed device of the noise-resistant receiver BO RSBN instead of the prototype device. It can be quantified by the magnitude of the reduction of the signal / noise + noise ratio, at which the required quality of determining the navigation parameters is still ensured.

The table shows the results of evaluating the effectiveness of the proposed device noise-resistant receiver BO RSBN relative to the prototype device for all useful signals received by the BO RSBN receiver (narrowband - azimuth, course and glide path signals and broadband - range response signals and reference signals of the series "35" and "36" ) under the influence of interference from mobile radio communications of the GSM - 900 standard.

The analysis of the results in the table allows us to conclude that the application of the proposed noise protection measures in the proposed device of the noise-resistant receiver BO RSBN in comparison with the prototype device will reduce by 9-20 dB the required signal-to-noise + noise ratio that ensures the specified quality (accuracy) definition of navigation parameters.

The proposed device does not require significant structural refinement of the known device and can be implemented in existing receivers BO RSBN.

The device of a noise-resistant receiver of on-board equipment of a radio system of near navigation and landing

Table Received signal by the BO RSBN receiver Decrease in the signal-to-noise ratio + noise, dB Azimuthal 15-20 Course 9-13 Glide path 10-13 Range 9-15 Support - series "35", "36" 9-15

Claims (1)

A noise-immunity receiver device for the on-board equipment of a short-range navigation and landing radio engineering system, comprising a receiving antenna connected to a power divider, the first output of which is the input of the receiver of ranging signals, and the second output is the input of the receiver of azimuth signals, and a decoder of ranging signals, the output of which is the first input range meter, azimuthal pulse shaper connected by its output to the first input of the azimuth meter, reference signal decoder, s a single output with a second input and a second output with a third input of an azimuth meter, a landing signal transducer, the first output of which is a second input of a range meter, which is connected with a range indicator by its output, and the second output of the landing signal transducer is connected to the fourth input of the azimuth meter, which is connected by its output to the azimuth indicator, characterized in that the receiver of the ranging signals with its first output is connected to the first input, and the second output to the second the digital signal processing submodule, and the azimuth signal receiver is connected with its first output to the fourth input, the second output with the fifth input, and the third output with the third input of the digital signal processing submodule, which is connected with the first output to the range finder, the second output is connected to the first the input, and the third output with the second input of the landing signal converter, the fourth output, the digital signal processing submodule is connected to the reference signal decoder, and the fifth output is soy dinene with an azimuthal pulse former.