RU59354U1 - WIDTH MULTI-CHANNEL RADIO RECEIVER OF HF RANGE - Google Patents

Abstract

The utility model relates to radio engineering and can be used in the equipment of broadband systems for multi-channel communication of the KB frequency range. The technical result is the provision of multi-channel signal reception in a wide frequency band, as well as increased noise immunity due to the possibility of preliminary frequency selection of signals. The device comprises an input, a preselector, an amplifier with variable amplification, a low-pass filter, an analog-to-digital converter, a sampling frequency generator, channels of digital processing from the first to M, a key, random access memory, a USB interface unit, and a PC.

Description

The utility model relates to radio engineering and can be used in the equipment of broadband systems for multi-channel communication of the KB frequency range.

Known radio receiver KB range containing a low-pass filter (LPF), the first and second mixers, the first and second bandpass filters, a step attenuator, and the output of the step attenuator is connected to the first input of the second mixer, the output of which is connected to the input of the LPF. (see CDR-3374 HF Broadband Precision Tuner. Technical Specification. CDR-3374 Block Diagram. http://www.cubic.com/cdal/pdf/CDR-3374.pdf) [1].

A disadvantage of the known device is the lack of a preselector at the input, which is why overloading of the analog part of the path is possible. Other disadvantages are high complexity (two frequency conversions) and a limited band of processed frequencies equal to 4 MHz. In many cases, it is required to control the entire KB range, which is about 30 MHz.

It is also known that a radio receiver containing a preselector, mixer, local oscillator and an intermediate frequency amplifier, the output of the local oscillator connected to the second input of the mixer, the output of which is connected to the input of the intermediate frequency amplifier (see Radio receivers / Yu.T. Davydov, Yu.S. Danich, A.P. Zhukovsky and others; edited by A.P. Zhukovsky. - M.: Higher School, 1989. p. 9, Fig. 1.5) [2].

The disadvantage of this device is the impossibility of multi-channel reception, due to the lack of the necessary technical means. Another disadvantage is the narrow band of received frequencies, limited to a fixed band of the preselector.

It is also known that a radio receiving device comprising a first mixer, a first local oscillator, a first intermediate frequency amplifier and a second mixer, the output of the first mixer through a first intermediate frequency amplifier connected to the first input of the second

mixer (see. Manual on the educational design of receiving-amplifying devices / M.K. Belkin, V.T. Belinsky, Yu.L. Mazor, PM Tereshchuk. - 2nd ed. - K .: Vyshka shk., 1988. p. 377, fig. 13.4) [3].

The disadvantage of this device is the impossibility of multi-channel reception, due to the lack of the necessary technical means. Another disadvantage is the high complexity of implementing a tunable preselector in a wide band, as well as the presence of two frequency conversions, which complicates the suppression of combination frequencies.

A KB range broadband radio receiver is also known, comprising a variable-gain amplifier, a low-pass filter, a key, an analog-to-digital converter (ADC), a sampling frequency generator, a USB and a PC interface, and the output of the sampling frequency generator connected to the ADC input and the digital clock input frequency synthesizer, and the LPF output through a key is connected to the input of the ADC. (see Aquila Wideband HF Receiver. SDR Block Diagram. http://www.monteriallc.com/downloads/Aquila.pdf) [4] - prototype.

The well-known radio receiver was selected as a prototype as coinciding with the claimed utility model for most technical features.

The disadvantages of the known device is the inability to implement multichannel reception due to the lack of the necessary technical means, as well as an insufficiently wide dynamic range due to the lack of preliminary analog selection.

The requirement of multichannel reception is due to the large number of narrow-band emissions in the HF range. Since the ADC of this frequency range with the required dynamic range is very expensive, the use of one channel of digital reception for one ADC is not economically justified. In addition, since signals in the KB frequency range occupy a narrow (no more than several kilohertz) frequency band, the resources of the digital part of the receiver are used inefficiently.

Since the dynamic range of signals in the KB range is very wide and significantly depends on the region and time of day, preliminary frequency selection of certain parts of the range is relevant to ensure maximum reception quality.

In a known device, these operations are not implemented.

A utility model is proposed for a broadband multi-channel radio receiver of the KB range, which does not have these drawbacks.

The technical result is the provision of multi-channel signal reception in a wide frequency band, as well as increased noise immunity due to the possibility of preliminary frequency selection of signals.

The technical result is achieved due to:

- the introduction of additional channels for digital signal processing, connected to the output of the ADC and providing an increase in the number of digital reception channels.

- introducing at the input of a switchable preselector, which increases the noise immunity of the reception by suppressing interference.

A KB broadband multichannel radio receiver includes a variable-gain amplifier, a low-pass filter, an analog-to-digital converter, a sampling frequency generator, a first digital processing channel (CCC), a key, random access memory (RAM), a USB and PC interface unit, and the amplifier output with variable amplification via The low-pass filter is connected to the input of the ADC, the output of the sampling frequency generator is connected to the clock inputs of the ADC and CCC, the output of the ADC is connected to the signal input of the CCC, the complex output of which is connected to the first input of the key, the output of which is connected to the input of RAM, the first port of the USB interface unit is connected to the PC.

According to a utility model, a switchable preselector and a CCC from 2 to M are introduced into a broadband multi-channel KB radio receiver, the input of the device being an input of a switchable selector, the output of which is connected to the input of a variable-gain amplifier, the control input of which is connected to the second port of the USB interface unit, with the control input of the preselector and with the control inputs of the central control center from 2 to M, the signal inputs of which are connected to the output of the ADC, and the complex outputs are connected to the corresponding inputs of the key, RAM output is connected to the third port of the USB interface unit.

Figure 1 shows a functional diagram of a utility model. Figure 2 shows an embodiment of a CCC. Figure 3 shows the portion of the spectrum in which the received signals are located.

The inventive device contains an input 1, a selector 2, an amplifier with variable gain 3, low-pass filter 4, ADC 5, a frequency generator

sampling 6, KCO from the first to M 7, key 8, RAM 9, interface unit USB 10, PC 11.

The input of the switchable selector 2 is the input 1 of the device, its output through an amplifier 3 with variable gain and a low-pass filter 4 is connected to the input of the ADC 5. The clock input of the ADC 5 is connected to the output of the sampling frequency generator 6 and to the clock inputs of all the CCC 7, the signal inputs of which are connected to the ADC output 5, and the control inputs are connected to the control input of the preselector 2, the control input of the amplifier 3 and to the second port of the USB 10 interface block. The outputs of the KCO 7 from the first through M are connected to the inputs of the key 8, the output of which is connected to the input of RAM 9, the output to which is connected to the third port of the USB interface unit 10. The first port of the USB interface unit 10 is connected to the PC 11.

An embodiment of KCC 7 in the inventive device comprises a first and second multiplier 12, a direct synthesis synthesizer (ATP) 13, a dual cascaded integrating-comb (in the original: Cascaded Integrator Comb) (CIC) filter 14, a dual filter with a finite impulse response (FIR) 15 and dual sampling decimator 16.

The first inputs of the first and second multipliers 12 are combined and are the input of the KCC 7, the second inputs are connected to the outputs of the real and imaginary parts of the reference signal SPS 13, respectively. The outputs of the multipliers 12 through a dual CIC filter 14 and a dual FIR filter 15 are connected to the corresponding inputs of the dual device of decimation of samples 16. The outputs of the real and imaginary parts of the device of decimation of samples 16 are the outputs of CCC 7.

The device operates as follows.

At the input of the switchable selector 2, a group spectrum is received containing a large number of individual signals. The switchable selector has a set of bandwidths in accordance with the electromagnetic environment. As an example, we divide the input frequency range from 0.1 to 32 MHz into 6 bands:

1) 0.1-2.5 MHz;

2) 2.5 - 4.8 MHz;

3) 4.8-9.0 MHz;

4) 9.0-17.0 MHz;

5) 17.0-32.0 MHz;

6) 0.1-32.0 MHz.

It can be seen that the first 5 values are selected based on the distribution of the spectral power of signals and noise in the specified frequency range [5]. The sixth filter passes the entire working frequency band and is used when it is necessary to receive signals in the entire band. The preselector band is controlled from the PC through the second port of the USB interface unit.

The signal from the output of the preselector 2 is fed to amplifier 3, the gain of which is also set via the second port of the USB interface unit. The gain of the amplifier 3 is selected from the condition of ensuring the optimal signal level at the input of the ADC 5. The output signal of the amplifier 3 is fed to the ADC 5 through the low-pass filter 4, the suppression frequency of which F _{low-pass filter} (see figure 4) determines, in accordance with Kotelnikov’s theorem, the minimum value the sampling frequency of the ADC 5. The signal of the sampling frequency Fd is generated in the oscillator 6 and is used to synchronize the ADC 5 and all the CCC 7.

The group digital signal from the output of the ADC is fed to the inputs of KCO 7, where it is supplied to a quadrature converter made on two multipliers 12. Here, the real digital signal Sвx (kT) is multiplied with the complex reference signal Sr (kT) = cos (ωkT) + j · sin (ωkT), where T = 1 / Fd, k = 0, 1, 2, ... is the measure number, ω is the frequency of setting the central control center.

The complex reference signal is generated by digital ATP 13. The frequency of the generated signal is determined by an integer K _F , recorded by the battery of the ATP phase and determined from the formula: where L is the number of discharges of the battery of the ATP phase.

Thus, the digital synthesizer generates a signal with a frequency equal to the center frequency of the received signal. Next, the complex signal is fed to a dual CIC filter 14, which performs preliminary frequency selection and decimation. Then the signal enters the FIR filter 15, where the main signal selection and suppression of out-of-band components in the spectrum are carried out. The signal at the output of the filter is supplied to the decimation device 16 to reduce the speed of the output stream.

The proposed device contains M KCC 7, each of which is tuned to the center frequency of the selected signal ω _m , where

m = 1.2 ... M (Fig. 3). Frequency tuning commands are received from the PC 11 through the first and then the second ports of the USB 10 interface block.

Various options for the functional implementation of the CCC are possible. Many global manufacturers of digital signal processing (DSP) hardware components produce microchips for implementing the digital part of receivers. Examples include AD6624 and AD6634 chips from Analog Deveces, GC4014 and GC4016 from Graychip, IP cores for programmable logic integrated circuits (FPGAs) from Xilinx, as well as a variant implemented in the prototype and shown in FIG. 2. The differences in the indicated design options for CCCs are, as a rule, in the implementation of a quadrature transducer (with or without a Hilbert transducer), as well as a digital filter of the main selection. It can be built using CIC filters, recursive, non-recursive filters, as well as their various combinations [6, 7].

It should be noted that when implementing CCC in FPGAs, there is an additional opportunity to increase the number of channels due to the implementation of pipeline processing and the use of time-distributed computing.

The signals from the outputs of KCO 7 are fed to the corresponding inputs of the key 8. Since the signals were thinned out in the KCC, the key 8 in turn switches the signals from each of the M KSC 7 to its output.

Each of the signals is recorded in the allocated area of RAM 9, which serves as a buffer that prevents signal breaks when transferring it to the PC 11 through the third and then the first ports of the USB 10 interface block. The RAM capacity 9 is selected based on the number of central control centers and the information transfer rate. A typical value when using USB version 2.0 (in High Speed mode) [8] and receiving signals with a 4 kHz band is no more than 256 complex samples per channel.

Introduction to the device of additional channels for digital signal processing, connected to the ADC output and providing an increase in the number of digital reception channels, as well as a switchable selector that improves reception noise immunity due to noise suppression, provides a technical result - multi-channel signal reception in a wide frequency band, as well as increased noise immunity due to the possibility of preliminary frequency selection of signals.

List of sources

1. CDR-3374 HF Broadband Precision Tuner. Technical Specification. CDR-3374 Block Diagram. http://www.cubic.com/cdal/pdf/CDR-3374.pdf.

2. Radio receivers / Yu.T. Davydov, Yu.S. Danich, A.P. Zhukovsky and others; under the editorship of A.P. Zhukovsky. - M.: Higher School, 1989.

3. A guide to the educational design of receiving-amplifying devices / M.K. Belkin, V.T. Belinsky, Yu.L. Mazor, P.M. Tereshchuk. - 2nd ed. - K .: Vyshka school., 1988.

4. Aquila Wideband HF Receiver. SDR Block Diagram. - prototype.

5. Red E.T. Reference manual on high-frequency circuitry: circuits, blocks, 50-ohm technology // Trans. with him. - M.: Mir, 1990.

6. Goldenberg L. M., Matyushkin B. D., Polyak M. N. Digital Signal Processing: A Guide. - M .: Radio and communications, 1985.

7. Solonina A.I., Ulahovich D.A., Arbuzov S.M., Solovieva E.B., Guk I.I. Fundamentals of Digital Signal Processing: Lecture Course. - SPb .: BHV-Petersburg, 2003.

8. Jan Axelson. USB Complete: Everything You Need to Develop Custom USB Peripherals. - Lakeview Research, 2005.

Claims (1)

A KB broadband multichannel radio receiver comprising a variable-gain amplifier, a low-pass filter, an analog-to-digital converter, a sampling frequency generator, a first digital processing channel, a key, random access memory, a USB and a PC interface unit, the variable-gain amplifier output being connected with the input of the low-pass filter, the output of the sampling frequency generator is connected to the clock inputs of the analog-to-digital converter and the channel of digital processing, the output is analog -digital converter is connected to the signal input of the digital processing channel, the complex output of which is connected to the first input of the key, the output of which is connected to the input of random access memory, the first port of the USB interface unit is connected to the PC, characterized in that a switchable selector and digital channels are inserted into it processing from 2 to M, and the input of the device is the input of the switchable selector, the output of which is connected to the input of the amplifier with variable gain, the control input of which is connected to the second port of the USB interface unit, with the control input of the preselector and with the control inputs of the digital processing channels from 2 to M, the signal inputs of which are connected to the output of the analog-to-digital converter, and the complex outputs are connected to the corresponding inputs of the key, the output of the random access memory is connected to the third port USB interface unit.