RU2248088C1 - Band filter automatic tuning device - Google Patents

Abstract

FIELD: radio engineering for radio communications and radar systems.

SUBSTANCE: proposed automatically tunable band filter has series-connected limiting amplifier 1, tunable band filter 2 in the form of first series-tuned circuit with capacitor whose value varies depending on voltage applied to control input, first buffer amplifier 3, parametric correcting unit 4 in the form of second series-tuned circuit incorporating variable capacitor, second buffer amplifier 5, first differential unit 6, first amplitude detector 7, first integrating device 9, and subtraction unit 9. Inverting input of subtraction unit 9 is connected to reference-voltage generator 10 and output, to control input of variable capacitors 2 and 4. Automatically tunable band filter also has series-connected second amplitude detector 11, second integrating unit 12, and threshold unit 13. Synchronous operation of this filter during reception and processing of finite-length radio pulses is ensured by synchronizer 14 whose output is connected to units 10, 8, and 12. This automatically tunable band filter also has second differential unit whose input is connected to output of buffer amplifier 3 and output, to second control input of variable capacitor of band filter 2.

EFFECT: enhanced noise immunity due to maintaining device characteristics within wide frequency range.

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Description

The invention relates to radio engineering and can be used in radio communication systems, radar, etc. when receiving and detecting quasi-harmonic signals with an unknown carrier frequency.

When constructing high-quality and noise-resistant radio engineering systems, for example, navigation, communication, and location-based radio systems, one of the most important problems is providing reliable posterior estimates of the values of the carrier frequencies in the propagated and processed signals received against the background of interference. Moreover, there are various methods for constructing systems for extracting radio signals from interference and determining estimates of the unknown carrier frequency [1-5]. Both algorithmically and hardware (i.e. circuitry) in these methods, the principles of narrow-band filtering, both adaptive and multi-channel, are used.

The tracking filters are used as analogs to the claimed one [1], however, their disadvantages include, firstly, insufficiently high noise immunity due to the use of nonlinear elements such as frequency detectors, which are necessary for determining and indicating frequency detunings and generating control signals; secondly, a relatively small tuning range, determined by a decrease in the value of the control signal during initial frequency disturbances that exceed the passband due to a dynamic change in the transmission coefficient of the bandpass filter during tuning (adaptation), which also reduces the real noise immunity of such devices.

Prototype, i.e. the closest device to the invention in technical essence is an automatic bandpass filter device containing a series-connected bandpass amplifier-limiter, the input of which is the input of the device, a bandpass filter in the form of a first single sequential oscillatory circuit, in which a capacitor of variable capacitance is connected to a common terminal by one terminal wire, and the second output to the output of the band-pass filter, and the first buffer amplifier, connected in series to the first amp udny detector and the first integrator [6].

The disadvantage of the prototype is the lack of noise immunity due to the use of additional test signals, in the interaction of which with the input signals and a change in the structure of the latter, the formation of control signals for tuning the bandpass filter. As in the analogs, in the prototype the magnitude of the control signals depends on the initial detuning and decreases with its increase, therefore, the noise immunity of the prototype deteriorates with an increase in the initial detuning from the initial resonant frequency of the bandpass filter.

The purpose of the invention is to increase noise immunity by maintaining the characteristics of the device in a wide range of frequency detunings.

This goal is achieved by the fact that in the device for automatic tuning of the band-pass filter, containing a series-connected band-pass amplifier-limiter, the input of which is the input of the device, a tunable band-pass filter in the form of a first single sequential oscillatory circuit, in which a capacitor of variable capacitance is connected to a common wire by one output, and the second output - to the output of the bandpass filter, and a buffer amplifier, as well as series-connected first amplitude detector and ne a second integrating device, a parametric correcting device is connected between the output of the first buffer amplifier and the output of the device in the form of a second single sequential oscillatory circuit connected to a common wire with a second variable capacitor, a second buffer amplifier, a second amplitude detector, a second integrating device and a threshold device, and also introduced the first differentiating device connected between the output of the second buffer amplifier and the input of the first amplitude detector, and a synchronizer, a reference voltage generator and a subtractor are connected in series, the output of which is connected to the control inputs of variable capacitors of the first and second single sequential oscillatory circuits of a tunable band-pass filter and a parametric correction device, respectively, and the non-inverting second input of the subtractor is connected to the output of the second integrating device, and the output of the synchronizer t It is also connected to the synchronizing inputs of both the first and second integrating devices and the threshold device, while the introduced second differentiating device is connected by an input to the output of the first buffer amplifier, and by an output to the second control input of a variable-capacity capacitor of a tunable band-pass filter.

The goal of increasing noise immunity is achieved, firstly, by introducing into the state control of a tunable band-pass filter, namely the instantaneous state of the resonant frequency of this filter; secondly, by introducing, in order to compensate for changes in the frequency response of the tunable bandpass filter, parametric correction that changes synchronously with the changes in the bandpass filter; thirdly, due to the introduction of more noise-resistant compared to other methods of linear identification of the frequency detuning using the first differentiating device.

The use of these essential features in conjunction with the optimal operation of the prototype - integration ensures the operation of the device for automatic tuning of the bandpass filter with high noise immunity in a larger range of frequency detunings than the prototype. The introduction of feedback on the derivative, due to which the nonlinear operating modes of the tunable bandpass filter are realized, provides automatic instantaneous control of the state of this filter under the action of powerful interference, i.e. robustness (insensitivity) to these interferences, which also increases the noise immunity of the device.

Since the characteristics of the proposed device are improved in a wider range of frequency tunings, the device can also be designated as a tunable automatic band-pass filter (PAPF), i.e. also with a more compact abbreviation.

The drawing shows a structural diagram of the proposed device for automatic tuning of a band-pass filter.

PAPF contains a serially connected band-amplifier-limiter 1, tunable band-pass filter 2 in the form of a first sequential oscillatory circuit with a capacitor, the capacitance of which changes under the action of the voltage applied to the control input, a first buffer amplifier 3, and a parametric correction device 4 in the form of a second serial oscillatory circuit with variable capacity, the second buffer amplifier 5, the first differentiating device 6, the first amplitude detector 7, the first integr a subtractor 8, a subtractor 9. The output of the subtractor is connected to the control inputs of the variable capacitors of the tunable bandpass filter 2 and the parametric correction device 4, and the second, inverting, input of the subtractor 9 is connected to the output of the reference voltage generator 10. The PAPF also contains a second an amplitude detector 11, a second integrating device 12 and a threshold device 13, the output of which is the output of the entire device. Synchronous operation of PAPF when receiving and processing radio pulses of finite duration is provided by a synchronizer 14, the output of which is connected to the synchronizing inputs of the generator 10, integrating devices 8 and 12, and the threshold device 13. In addition, the PAPF contains a second differentiating device 15, the input of which is connected to the output of the buffer amplifier 3, and the output is connected to the second control input of the variable capacitor of the bandpass filter 2.

PAPF works as follows.

An input signal in the form of an additive mixture of noise and a radio pulse with a constant amplitude, finite duration, and with an unknown carrier frequency is fed to the input of a band amplifier-limiter 1, where two-sided limitation and formation of a random process in the form of radio pulses with a constant amplitude and a random time-varying total a phase containing a monotonic component due to an unknown, i.e. random, but constant on the observation interval, bearing the frequency of the radio pulse.

The basis of PAPF is a tunable bandpass filter 2, made in the form of a single sequential oscillatory circuit with a variable capacitor, which has two control inputs for changing the capacitance. Feedback voltage is applied to one control input using the second differentiating device 15, which is proportional to the derivative of the voltage across the alternating capacitor. At the same time, the noise immunity increases due to the fact that the presence of large values of the variable noise component, the spectrum of which coincides with the current setting of the tunable bandpass filter 2, the derivative of this component not correlated with it changes (decreases) the value of the capacitance of the variable capacitor, i.e. provides instant tuning of tunable band-pass filter 2 from interference. Thus, when controlling due to the derivative, an automatic detuning from powerful interference spectral components occurs.

Similarly, the process of automatic tuning occurs when a random noise structurally coincides with the signal, i.e. suppresses him. Only in this case, due to a decrease in the derivative, an instantaneous increase in capacitance occurs, i.e. the current resonant frequency of the tunable band-pass filter 2 changes (decreases), and the band-pass filter is automatically tuned out from such a powerful interference.

In order for this process to occur when the band-pass filter is tuned for the useful signal, a second additional feedback branch is used - control feedback formed by blocks 4, 5, 6, 7, 8, 9, and 10. Moreover, the radio pulse signal having in the general case, an arbitrary carrier frequency, i.e. upset relative to the resonant frequency of the tunable band-pass filter 2, the constant amplitude is accordingly maintained due to the correcting device 4. The correcting device has an amplitude-frequency characteristic (AFC) inverse to the frequency response of the tunable band-pass filter 2. This is realized using a serial oscillatory circuit connected to the output of the amplifier operating in current generator mode. In order for this correspondence to be maintained in the necessary frequency tuning range, the correcting device is parametric, namely, the capacitance of the variable capacitor during tuning changes synchronously with the capacity of the tunable bandpass filter 2.

Information about the frequency detuning of the signal is contained in the value of the derivative, i.e. for signal

s (t) = A ₀ sin (ω t + φ ₀ ), t∈ [0, T],

the derivative y (t) is equal to

y (t) = A ₀ ω cos (ω t + φ ₀ ) = B (ω) cos (ω t + φ ₀ ), t∈ [0, T] (T is the signal duration).

This frequency detuning is determined by the first differentiating device 6 and then extracted using the first amplitude detector 7, which can be performed, for example, as a module identifier.

Since the main operation in identifying frequency detunings is performed by a linear operator, i.e., by differentiating, in the entire range of frequency detunings, the noise immunity of the entire PAPF device is realized as potential. Structurally and technically, this is achieved by using the first integrating device 8 that performs the optimal operation of calculating the autocorrelation function over the output voltage of the amplitude detector 7.

In order for the voltage that controls the frequency tuning of the device to be either positive or negative depending on the sign of the initial detuning frequency, a subtractor 9 is used, to the inverting input of which voltage is supplied from the generator 10, the shape of which is similar to the output signal of the integrator 8 at zero initial frequency detuned.

For the operation of the PAPF device, the blocks 11, 12, and 13 are used as a noise-resistant detector, with the help of which optimal incoherent filtering of the radio pulse is performed and a decision is made on the presence or absence of a signal in noise by the threshold device 13.

Synchronous operation of the device is provided by the synchronizer 14.

Thus, the device for automatic tuning of the band-pass filter provides high noise immunity due to the suppression of powerful noise components by instantly tuning when the derivative of the voltage filtered by the band-pass filter is introduced into the capacity control of the tunable band-pass filter, as well as determining the frequency detuning by a linear differentiating device and further optimal filtering due to the operation integration.

Industrial applicability.

The device for automatic tuning of a band-pass filter can be used in various fields of radio engineering as an effective filter for receiving radio signals with an unknown frequency in radio communication systems, radar systems, synchronization systems, etc.

Sources of information

1. Kantor L.Ya., Dorofeev V.M. Immunity to receiving FM signals. - M.: Communication, 1977.

2. Phase locked loop systems with discretization elements / Shakhgildyan VV, Lyakhovkin AA, Karyakin VL et al. Ed. V.V.Shahgildyan. - M.: Communication, 1979.

3. Shelukhin O.I. Short range radio systems. M .: Radio and communications 1989.

4. Shakhtarin B.I. Random processes in radio engineering. M .: Radio and communications, 2002.

5. Tikhonov V.I. Optimum signal reception. M .: Radio and communications, 1983.

6. A.S. 1626336 (51), 5 Н 03 J 3/00, Yu.A. Skripnik, V.I. Vodotovka, Yu.A. Sokurets, I.Yu. Skripnik. Automatic bandpass filter.

Claims (1)

A device for automatic tuning of a bandpass filter, containing a series-connected bandpass amplifier-limiter, the input of which is the input of the device, a tunable bandpass filter in the form of a first single sequential oscillatory circuit, in which a variable capacitor is connected to a common wire by one output, and by a second output to the output of the bandpass filter, and a buffer amplifier, as well as serially connected the first amplitude detector and the first integrating device, characterized the fact that a parametric correcting device is connected between the output of the first buffer amplifier and the output of the device in the form of a second single sequential oscillatory circuit connected to a common wire with a second variable capacitor, a second buffer amplifier, a second amplitude detector, a second integrating device and a threshold device, and also introduced the first differentiating device connected between the output of the second buffer amplifier and the input of the first amplitude detector, and a synchronizer, a reference voltage generator and a subtractor are connected in series, the output of which is connected to the control inputs of variable capacitors of the first and second single sequential oscillatory circuits of a tunable bandpass filter and a parametric correction device, respectively, and the inverting second input of the subtractor is connected to the output of the second integrating device, and the output of the synchronizer is also connected n with the clock inputs of both the first and second integrators and the threshold device, the introduction of a second differentiating unit is connected to the output of the first input buffer amplifier, and output to the second control input of the variable capacitor of tunable bandpass filter.