RU40493U1 - SUPERREGERATIVE RECEIVER WITH HIGH STABLE RESONATOR - Google Patents

Abstract

The utility model relates to radio engineering, namely to information receiving devices, in particular to receivers in analog and digital radio channels, and can be used in aerological complexes, for example, in radio probes. It can also be used in automated traffic control systems. The technical task is to increase the processing speed of information signals with a significant reduction in GMC. To solve this problem, an ultra-regenerative receiver with a highly stable resonator is proposed, which contains a receiving antenna, an input microwave filter, a low-noise microwave amplifier (LNA), an ultra-regenerative detector, a low-pass filter (LPF), and an AGC video amplifier connected as follows: a receiving antenna, which is the input of the device, through the input microwave filter, is connected to the LNA, the output of which is connected to the input of the super regenerative detector, the output of the latter through the low-pass filter is connected to a video amplifier, the AGC of which is connected to the control LNA input and the output of the video amplifier is an output device; a PLL block can be inserted into it, holding a phase detector, a reference frequency generator and a scaling amplifier, connected as follows: the output of a superregenerative detector is connected to the signal input of a phase detector, with the reference input of which is connected the output of the reference frequency generator, the output of the phase detector through a low-pass filter is connected to the input of the video amplifier and through the scaling amplifier - with the power input of the super regenerative detector.

Description

The utility model relates to radio engineering, namely to information receiving devices, in particular to receivers in analog and digital radio channels, and can be used in aerological complexes, for example, in radio probes. It can also be used in automated traffic control systems.

Common tasks for information receiving devices are: high performance with minimal distortion of the received information, low energy consumption, low overall mass characteristics and low cost, at the same time high noise immunity. It can be seen that these requirements are rather contradictory, in addition, information transmission channels use both amplitude, frequency and phase modulation, so the question arises of the universality of receiving devices, which further emphasizes the relevance of these problems.

Known receivers with a transistor radio frequency amplifier (URC) up to 8 Hz, assembled according to the scheme with a common emitter on microstrip lines (MPL), on which selective, connecting and matching circuits are made on MPL, and matching is achieved by introducing special matching segments. To coordinate complex resistances and transform active resistances into MPL, their half-wave and quarter-wave segments are used, see Radio Receiving Devices ”, V.D. Ekimov et al., M, Communication, 1975, pp. 292-293.

The disadvantage of this device is its limited upper operating frequency, insufficient gain, etc.

Also known is a radio block receiver containing a microwave filter, a low noise amplifier (LNA), a filter of a mirror channel on a dielectric

a resonator, a local oscillator, a mixer, a frequency converter with AGC, connected according to the classical scheme, see “Microwave technologies in telecommunication systems”, T.N. Narytnik et al., Kiev, Technika, 2000, p. 258.

The disadvantage of this receiver is its circuit complexity (to obtain a sufficient gain) due to the construction according to the traditional scheme, hence the fairly high overall mass characteristics (GMX) with low generally technical.

Also known is a microwave radio receiver with a highly economical and stable super-regenerative resonator (SR) in the microwave range, in which the SR is made on a transistor, between the base and collector of which an LC circuit is connected, shunted (for fast attenuation of oscillations) by a resistor. The signal is input from the antenna into the lcb coupling coil connected to the LC loop inductance. A storage capacitor is connected between the emitter and the collector of the transistor, which is charged from the power source through a resistor, and the inductor isolates the collector from this capacitor by RF, see “Super Regenerators”, ed. M.K. Belkina, M, P and S, 1983, pp. 229-230, - PROTOTYPE.

The disadvantage of this microwave radio receiver is the limited frequency of superization, not more than 1-2 MHz, due to the peculiarity of constructing the electrical circuit, which does not allow to take advantage of the higher frequency range, for example, using the MPL, the latter leads to microminiaturization of the radio equipment, which is especially important for hard GMH requirements and energy consumption, further: the higher the frequency, the more high-speed communication system.

The technical task is to increase the processing speed of information signals with a significant reduction in GMC.

To solve this problem, we propose an ultra-regenerative receiver with a highly stable resonator containing a receiving antenna, an input microwave filter, a low-noise microwave amplifier (LNA), an ultra-regenerative detector, a low-pass filter (LPF), a video amplifier with AGC,

connected as follows: the receiving antenna, which is the input of the device, is connected through the microwave input filter to the LNA, the output of which is connected to the input of the super regenerative detector, the output of the latter through the low-pass filter is connected to the video amplifier, the AGC of which is connected to the control input of the LNA, and the output of the video amplifier is the output devices The superregenerative detector contains a microwave transistor, an RC filter, an RC timing circuit, a first and second MPL, a first and second quarter-wave chokes, connected as follows: the LNA output through the first MPL is energetically connected to the second MPL, which is connected to the microwave base at one end transistor, and the other with its collector and through the first quarter-wave choke is connected to the RC master circuit, the emitter of the microwave transistor through the second quarter-wave choke is connected to 0 V, the common point of the RC timing circuit is connected to the RC filter, the output is This is the detector output.

Figure 1 shows a structural diagram of a super regenerative receiver of amplitude and frequency modulated signals (AM and FM, respectively), figure 2 is a diagram of a receiver of AM and FM signals with a PLL, figure 3 is a circuit diagram of a super regenerative detector (SRD), figure 4 - amplitude-frequency characteristic (AFC) of the AM detector, figure 5 - AFC of the FM detector, which shows: 1 - input microwave filter, 2 - LNA, 3 - SRD, 4 - low-pass filter, 5 - video amplifier with AGC, 6 - PLL, 7 - reference frequency generator (GOCH), 8 - phase detector, 9 - scaling amplifier b. A - receiving antenna, T - microwave transistor, MPL 1 and MPL 2 - the first and second microstrip coupled lines, respectively, Др1 and Др2 - the first and second microstrip quarter-wave chokes, respectively, RC - timing circuit, R f and C f - low-pass filter , Ep - power input with a remote sensing.

For AM and FM signals:

antenna A through the input microwave filter 1 is connected to the input of the LNA 2, the output of which through the SRD 3 and the low-pass filter 4 is connected to the video amplifier 5, the AGC of which

connected to the control input of the LNA 2, and the output of the video amplifier 5 is the output of the receiver.

For AM and FM signals with PLL:

antenna A through the input microwave filter 1 is connected to the input of the LNA 2, the output of which through the DRS 3, the PLL 6 and the low-pass filter 4 is connected to the video amplifier 5, the AGC of which is connected to the control input of the LNA 2, and the output of the video amplifier 5 is the output of the receiver, the output of the low-pass filter 4, in addition, through a scaling amplifier 9 is connected to the power input of the SRD 3.

SRD 3, in turn, is made on a microwave transistor T, the base of which is energetically connected through MPL 2 to MPL 1, and directly through MPL 2 to a collector, the input of MPL 1 is the input of SRD 3, the emitter of transistor T through the second quarter-wave choke is connected to 0 B, the collector of the microwave transistor T through a series-connected first quarter-wave choke and a resistor of the timing circuit is connected to a power source, the capacitor of the timing circuit is connected to 0 V at one end and to the common point of the timing circuit resistors at the other end and izkochastotnogo filter output is the output of the LPF 3 RAN; in the PLL 6, the signal input of the phase detector 8 is connected to the output of the SRD 3, the reference input is connected to the output of the RF part 7, the output of the phase detector 8 is connected through the low-pass filter 4 to the input of the video detector 5 and is connected via feedback amplifier 9 to the power input of the SRD 3.

These nodes and blocks can be performed on the following elements: the input narrow-band microwave filter 1 can be performed on dielectric resonators, see "Radio receivers", ed. N.N. Fomina, M, R & S, 1996, pp. 201-202, LNA 2 - can be performed on an integrated gallium arsenide IC type MGA-86563, see the Hewlett Packard catalog "Communications Components Designer s Catalog" , 1998, pp. 6-220, AGC of video amplifier 4 can be performed according to the scheme, see "Radio receivers" under the editorship of N.N. Fomina, M, P and S, 1996, pp. 404-404,

LVU 5 can be performed on a high-speed operational amplifier, for example, on IC 140 UD 11, see "Linear Integrated Circuits" by V.L.Shilo, M, Sov. Radio, 1979, p. 155, Fig. 4.4, also on this IMS can be made US 9, PD 8 can be performed according to the scheme, see "Broadband radio-electronic devices and systems", Interuniversity collection of scientific papers, Sverdlovsk, 1989 , pp. 88-91, GOCH 7 can be performed according to the scheme of a highly stable quartz oscillator, see “The Art of Circuit Engineering”, vol. 1, P. Horowitz, M, Mir, pp. 279, MPL 1, MPL 2, Dr 1 and Dr 2 can be calculated, see "Reference on the elements of strip technology", M, Communication, 1979, pp. 20-31, transistor T can be taken, for example, 2T3115A, see the Reference "New transistors ry ", part 2, M, SOLON, 1996, p. 39, capacitor. It is advisable to choose a positive-TKE with a positive TKE for temperature compensation of the entire resonator from the SRD 3 timing circuit; special requirements are not imposed on the other radio elements of the SRD 3, except for the material for MPL, which is selected from the conditions of the temperature range and allowable losses of microwave energy.

The superregenerative receiver operates as follows: the input circuit of the receiver contains a microwave filter 1 tuned to the operating frequency using dielectric volume resonators, this filter sets the passband of the entire receiving device, because SRD 3's own bandwidth is much wider. The signal allocated by the microwave filter 1 is amplified by the LNA 2, which has the ability to change its gain according to the AGC signal from the IED 5. The LNA 2 compensates for losses in the microwave filter 1, reduces the noise figure of the entire receiver, suppresses spurious radiation of the SRD 3 into antenna A and in turn, it reduces the influence of the latter on tuning the DRS 3. Next, the signal is fed to the DRS 3, where the modulated signal is amplified and transferred from the microwave range to the autosuperization frequency, where useful information is extracted from it.

The work of the SRD 3 itself is as follows, see figure 3. SRD 3 is implemented on the active semiconductor element T (for example,

on a microwave transistor) and microstrip lines MPL 1 and MPL 2, creating an oscillatory circuit tuned to the frequency of the input signal. To obtain the regime of intermittent generation, the collector of the transistor T through DR 1, made on the MPL, is connected to the power source through an inertial timing RC circuit. The value of the RC time constant determines the autosuperization period Tc. The time constant of the RC circuit must be greater than the time constant of the oscillatory circuit of the SRD 3 due to the principle of superization. Dr 1 serves to prevent microwave oscillations from entering the power circuit. Dr 2 is designed to reduce the impact on the DRS 3 of external electromagnetic fields. The output signals of the DRS 3 are the generation pulses (autosuperization), modulated in frequency by the transmitted message. In the subsequent processing of superization pulses, the low-pass filters 4 emit AM or FM signals.

The operation of the DRS 3 can occur in three modes: the processing mode of AM signals, the mode of FM signals and the PLL mode.

AM signal processing mode. In this mode, the loop of the DRS 3 is tuned so that the carrier frequency of the input microwave signal is located at the maximum frequency response (see Fig. 4), the information is extracted from the frequency change relative to fnes in one direction or another.

FM signal processing mode. In this mode, the loop of the DRS 3 is tuned so that the carrier frequency of the input microwave signal is located on the side of the frequency response (see Fig. 5), the information is extracted from the frequency change relative to fnes in one direction or another.

In both modes, a change in the frequency of the carrier oscillation according to the modulation law causes a corresponding change in the input power level on the DRS 3. This leads to a change in the frequency of the envelopes of the microwave generation flashes in the DRS 3 according to the modulation law embedded in the input signal. After processing the signal in the low-pass filter 4 (you can also use the frequency detector on the detuned circuits), a digital information sequence is obtained.

Processing mode for AM and FM signals using PLL. This mode is used to process signals in conditions of increased noise and interference of natural and artificial origin, as well as to increase the stability of the receiver in a wide temperature range. In this mode, the signal from the output of the SRD 3 is processed at the phase detector 8 and, after amplification by a scaling amplifier 9, is fed to the input of the power supply (instead of power) of the SRD 3, thereby regulating the frequency of autosuperization, which leads to linearization of the receiver characteristics and to an increase in the signal ratio /noise.

The construction of this receiver according to the proposed electrical circuit allows to obtain high technical characteristics of the device itself under conditions of destabilizing factors, such as: a large range of changes in ambient temperature from minus 60 ° C to plus 80 ° C, an increased level of electromagnetic interference and a small signal to noise ratio, while minimizing GMC, low energy consumption, high manufacturability and ease of setup. Thus, this super-regenerative receiver meets the main criterion for evaluating modern developments: "cost-effectiveness".

Claims (5)

1. An ultra-regenerative receiver with a highly stable resonator, comprising a receiving antenna, an input microwave filter, a low-noise microwave amplifier (LNA), an ultra-regenerative detector, a low-pass filter (LPF), a video amplifier with AGC, connected as follows: a receiving antenna, which is the input of the device, through the input microwave filter it is connected to the LNA, the output of which is connected to the input of the super regenerative detector, the output of the latter through the low-pass filter is connected to the video amplifier, the AGC of which is connected to the control input of the LNA, and the output of the video amplifier is device output. 2. The ultra-regenerative receiver with a highly stable resonator according to claim 1, characterized in that a PLL block is introduced into it, comprising a phase detector, a reference frequency generator and a scaling amplifier, connected as follows: the output of the super-regenerative detector is connected to the signal input of the phase detector, with a reference input of which the output of the reference frequency generator is connected, the output of the phase detector through the low-pass filter is connected to the input of the video amplifier and, through the scaling amplifier, to the power input of the super-regenerative detector. 3. An ultra-regenerative receiver with a highly stable resonator according to claims 1 and 2, characterized in that the super-regenerative detector comprises a microwave transistor, an RC filter, an RC timing circuit, a first and second MPL, a first and second quarter-wave chokes, an Epit bus and a zero bus connected as follows: the LNA output through the first MPL is energetically connected to the second MPL, which is connected at one end to the base of the microwave transistor, and the other through the first quarter-wave choke with its collector, which is connected to the common point of the RC master circuit, Sator resistor and second ends which are connected to the zero line and a enum respectively, the emitter of the microwave transistor through a second quarter-wave choke connected to the zero bus common point RC-time-setting circuit is connected to the RC-filter input, whose output is the output of the detector. 4. The ultra-regenerative receiver with a highly stable resonator according to claim 1, characterized in that the Epit bus is connected to an external constant voltage source. 5. The ultra-regenerative receiver with a highly stable resonator according to claim 2, characterized in that the Epit bus is connected to an internal constant voltage source, which is the output of a scaling amplifier.