RU113098U1 - RECEIVER - Google Patents

Abstract

A receiving device containing a series-connected input switch, high and low frequency filters, a preselector, an input attenuator, a first mixer, a first intermediate frequency amplifier, an IF attenuator, a second mixer, a second intermediate frequency amplifier, as well as a local oscillator, a reference oscillator, switches of the first and second local oscillators, the first and second amplifiers with AGC and the first and second splitters, the driver and attenuator of the pilot signal, and the control unit, which is connected via the control bus to the input switch, preselector, input attenuator, IF attenuator, driver and attenuator of the pilot signal, local oscillator and switches the first and second local oscillator, the output of the first local oscillator through the switch of the first local oscillator connected in series, the first amplifier with AGC and the first splitter is connected to the second input of the first mixer, the output of the reference oscillator through the switch of the second local oscillator connected in series, the second amplifier a radiator with an AGC and the second splitter is connected to the second input of the second mixer, the second and third outputs of the second splitter are connected, respectively, to the local oscillator input and through the serially connected driver and attenuator of the control signal with the second input of the input switch, characterized in that an RF choke, a control filter and a switch, the input of which is connected to the second output of the splitter of the first local oscillator, and the output and the control input are interconnected through a control filter, while the second input of the switch of the first local oscillator is connected to the control unit through an RF choke and buses

Description

The utility model relates to the field of radio engineering and can be used to solve problems of radio surveillance, radio monitoring and direction finding, as well as in surface wave radars for monitoring a 200-mile economic zone and radio monitoring of the water surface.

A receiver device is known comprising an intermediate frequency amplifier, a mixer, a series-connected switch, high and low frequency filters, two local oscillators, a reference oscillator, one output of which is connected to the input of the switch, and two other outputs are connected to the inputs of the local oscillators, the output of the first local oscillator connected to the second input of the frequency converter, and the output of the second local oscillator to the second input of the mixer (RF Patent No. 2085036 according to class Н04В 1/16 of 07/20/1997).

This receiving device allows you to receive and highlight information, both on mobile and stationary installations. The disadvantage of this receiving device is that it is optimized for receiving FM signals and does not allow you to fully analyze the radio frequency and noise conditions of the KB range ..

A closer technical solution for the combination of essential features is a receiving device containing a series-connected switch, high and low frequency filters, a preselector, an input attenuator, a first mixer, an intermediate frequency amplifier, a second mixer, a second intermediate frequency amplifier, as well as two local oscillators, a reference oscillator , one output of which is connected to the first input of the switch, and two other outputs are connected to the inputs of the local oscillators, and the output of the first local oscillator is connected to the second the input of the first frequency mixer, and the output of the second local oscillator to the second input of the second mixer, while the control unit is connected via a control bus to a switch, a selector, an input attenuator, and two local oscillators. (RF patent No. 52548 according to CL H04Q 1/26 dated 09/28/20005).

This receiving device provides the reception of arbitrary signals for the subsequent separation of information from them, which allows you to analyze the radio frequency and noise environment of the KB range. The disadvantage of this receiving device is that it does not provide work in multi-channel synchronous systems, which limits the scope of this utility model for direction finding and location.

The closest technical solution for the combination of essential features is a receiving device containing a series-connected input switch, high and low frequency filters, a selector, an input attenuator, a first mixer, a first intermediate frequency amplifier, an IF attenuator, a second mixer, a second intermediate frequency amplifier, and local oscillator, reference generator, switches of the first and second local oscillators, first and second amplifiers with AGC and first and second splitters, shaper and attenuator control one signal, and a control unit. The control unit is connected via the control bus to the input switch, preselector, input attenuator, IF attenuator, control signal shaper and attenuator, local oscillator and switches of the first and second local oscillator. The output of the first local oscillator through the switchboard of the first local oscillator connected in series, the first amplifier with AGC and the first splitter is connected to the second input of the first mixer, the output of the reference generator through the serial switch of the second local oscillator, the second amplifier with AGC and the second splitter is connected to the second input of the second mixer, the second and the third outputs of the second splitter are connected respectively to the input of the local oscillator and through the shaper and attenuator of the control signal connected in series la to the second input of the input switch. (RF patent No. 107653 according to class H04B 1/26 dated 04/27/2011).

When several such receiving devices (PUs) are connected via a conveyor circuit into a multi-channel system, operation is ensured both in asynchronous and in synchronous mode. Figure 1 shows an example of a multi-channel receiving system in a four-channel version. The pipeline connection scheme allows for the analysis of the radio frequency and interference conditions of the KB range, not only to carry out radio monitoring simultaneously at several frequencies, but also to direction finding the detected radio signal source due to the operational switching of operating modes. However, when this receiver operates in the asynchronous mode of several receivers, additional side channels of reception arise due to the simultaneous use of several signals of the first local oscillator operating at different frequencies in the multichannel system and insufficient suppression of the external signals of the first local oscillator by the corresponding switches.

The problem to which the claimed utility model is directed is to eliminate the side reception channels arising in asynchronous operation while using several signals of the first local oscillator operating at different frequencies in a multi-channel system.

This goal is achieved due to the fact that in the receiving device, containing in series connected input switch, high and low frequency filters, preselector, input attenuator, first mixer, first intermediate frequency amplifier, IF attenuator, second mixer, second intermediate frequency amplifier, and a local oscillator, a reference oscillator, switches of the first and second local oscillators, the first and second amplifiers with AGC and the first and second splitters, the driver and attenuator of the control signal, and the control unit, which is connected via a control bus to an input switch, a selector, an input attenuator, an IF attenuator, a driver and a control signal attenuator, a local oscillator and switches of the first and second local oscillator, the output of the first local oscillator through a series-connected switch of the first local oscillator, the first amplifier with AGC and the first splitter is connected to the second input of the first mixer, the output of the reference generator through a series-connected switch of the second local oscillator, the second amplifier with AGC and the second the driver is connected to the second input of the second mixer, the second and third outputs of the second splitter are connected respectively to the input of the local oscillator, and an RF choke, a control filter, and a key, the input of which is connected to the second output of the splitter are introduced through a servo driver and attenuator of the control signal connected to the second input of the input switch in series the first local oscillator, and the control output and input are interconnected via a control filter, while the second input of the switch of the first local oscillator is connected to the control unit ee through the RF choke and control bus.

Figure 2 shows a diagram of the receiving device, where the following notation is introduced: input switch 1, high-pass filter (HPF) 2, low-pass filter (LPF) 3, selector 4, input attenuator 5, first mixer 6, first intermediate frequency amplifier ( UPCH1) 7, the attenuator of the inverter 8, the second mixer 9, the second intermediate frequency amplifier (UPCH2) 10, the first local oscillator 11, the switch of the first local oscillator 12, the first amplifier with automatic gain control 13, the first splitter 14, the reference oscillator 15, the switch of the second local oscillator 16, second effort An amplifier with automatic gain control 17, a second splitter 18, a control signal driver 19, a control signal attenuator 20, a control unit 21, a control bus 22, an RF choke 23, a key 24, a control filter 25.

The receiving device operates as follows.

The signal from the Fc antenna through the input switch 1, which ensures the receiver antenna input is switched off in the internal calibration mode, is fed to the high-frequency and low-frequency filters connected in series. The low-pass filter 3 is designed to suppress the interference of direct passage at the first intermediate frequency and along the mirror channel. High-pass filter 2 reduces the overload of the high-frequency path by powerful broadcasting stations in the DV and CB ranges.

Next, the signal is fed to one of the sub-octave bandpass filters of the multi-channel preselector 4. The preselector 4 together with the low-pass filter 3 provides attenuation of interference at the intermediate frequency and along the first mirror channel. The use of dividing the input frequency range into sub-octave bands reduces the likelihood of third-order Raman components and reduces the level of second-order Raman components.

From the output of the preselector 4, the signal is fed to the input attenuator 5, which is designed to interface the receiving path with the interference environment, i.e. reduce path congestion by powerful out-of-band signals that can cause intermodulation interference.

From the output of the attenuator 5, the signal is supplied to the first frequency mixer 6, in which there is a differential conversion of the signal Fg1 of the first local oscillator 12 and the input signal Fc to the first intermediate frequency Fp1.

From the output of the first mixer 6, the signal is fed to an intermediate frequency amplifier 7, which provides frequency selectivity with a low noise level and intermodulation. The selective system of the amplifier 7 is made on quartz filters, which provide selectivity for the adjacent channel, suppression of the signal of the first local oscillator and interference coming from the second mirror channel.

The IF 8 attenuator provides adjustment of the transfer coefficient and is designed to eliminate the overload of the second mixer 9 with powerful input signals inside the passband. In the mixer 9 there is a differential conversion of the signal Fpch1 and the signal of the second local oscillator Fg2 to the second intermediate frequency Fpch2. Next, the signal FPC2 through the second intermediate frequency amplifier 10 is supplied to the output of the receiving device. The amplifier 10 provides suppression of the signal of the second local oscillator Fg2 and out-of-band reception channels, due to the discretization of the signal in an external digital signal processing device (DSP) (not shown in Fig. 1), and also limits the broadband noise in the spectrum of the signal at the input of the DSP.

The signal frequency of the highly stable reference oscillator 15 is chosen equal to the frequency of the signal of the second local oscillator Fg2. The same signal can be used for analog-to-digital conversion of an external DSP device. This solution allows you to minimize the number of internal interference of the receiving device.

When the receiver is in stand-alone asynchronous mode, the signal from the reference oscillator 15 with a frequency of Fg2 through the switch of the second local oscillator 16, in the corresponding position, the amplifier with AGC 17 and the second splitter 18 is fed to the second input of the second mixer 9. From the other outputs of the splitter 18, the signal of the second local oscillator is received to the shaper of the first local oscillator 11, the shaper of the control signal 19 and to the output of the receiving device, which is not used in this mode.

Similarly, in asynchronous mode, the signal from the shaper of the first local oscillator 11 through the switch of the first local oscillator 12, the amplifier with AGC 13 and the first splitter 14 is fed to the second input of the first mixer 6. From the second output of the splitter 14, the signal of the first local oscillator through the public key 24 is fed to the output of the receiving device which is not used in this mode.

When the receiver is in multi-channel synchronous mode or combined, all the receivers included in the multi-channel system are connected in series, as shown in figure 2, i.e. the output Fg1 of the first device is connected to the input Fg1 of the second, the output Fg1 of the second with the input Fg1 of the third and so on. Similarly, the receiving devices are connected and the signal Fg2. The first receiving device in this circuit is the leading one and its operation does not differ from the asynchronous mode. The second and subsequent receiving devices are slaves, the switches of the first and second local oscillators 12 and 16 in them by the appropriate commands are set to external signals. Amplifiers with AGC 13 and 17 ensure the stability of the level of the signals of the first and second local oscillators supplied to the mixers 6 and 9, when several receiving devices are cascaded. The control signal of the switch of the first local oscillator 12 through the RF choke 23 in the form of a constant voltage is also supplied to the input of the switch. Thus, this control signal is supplied through the connecting RF cable to the output of the first local oscillator of the previous receiving device. In the previous device, this signal through the control filter 25 controls the passage of the signal of the first local oscillator through the key 24. In synchronous mode, this key 24 is open and since all the receiving devices are tuned to the same frequency or the drivers of the first local oscillator 11 are disabled in the slave devices, additional side reception channels do not occur . When you turn on the asynchronous mode with a signal coming through the cable, the key 24 closes and prevents the signal from the first local oscillator to the next receiving device. The total suppression of this side channel is provided by the switch 12 and the key 24, located in different receiving devices.

The driver of the control signal 19 range KB is made on the basis of direct digital synthesis (DDS). The control signal through the attenuator 20 is fed to the input switch and is used to periodically monitor the technical characteristics of the receiving device during operation.

Thus, the proposed receiving device allows you to analyze the radio frequency and interference environment of the KB range, and in the multi-channel version, thanks to the operational switching of the operating modes, not only radio monitoring simultaneously at several frequencies, but also direction finding of the detected radio signal source. The introduced additional key with control elements can significantly increase the suppression of side reception channels that occur in asynchronous operation while using several signals of the first local oscillator operating at different frequencies in a multi-channel system.

Claims (1)

A receiving device comprising a series-connected input switch, high and low-pass filters, a preselector, an input attenuator, a first mixer, a first intermediate frequency amplifier, an IF attenuator, a second mixer, a second intermediate frequency amplifier, as well as a local oscillator, a reference oscillator, switches of the first and second local oscillators, the first and second amplifiers with AGC and the first and second splitters, the driver and attenuator of the control signal, and a control unit that is connected via the control bus to the input switch, preselector, input attenuator, frequency attenuator, driver and attenuator of the control signal, local oscillator and switches of the first and second local oscillator, the output of the first local oscillator through a series-connected switch of the first local oscillator, the first amplifier with AGC and the first splitter connected to the second input of the first mixer, the output of the reference generator through a series-connected switch of the second local oscillator, a second amplifier with AGC and a second splitter connected to the second input of the second mixture Firing, the second and third outputs of the second splitter are connected respectively to the input of the local oscillator and through a shaper and attenuator of the control signal connected in series with the second input of the input switch, characterized in that an RF choke, a control filter and a key are inserted, the input of which is connected to the second output of the splitter of the first local oscillator and the control output and input are interconnected via a control filter, while the second input of the switch of the first local oscillator is connected to the control unit through an RF choke and buses management.