RU2701719C1 - Radio receiving device for rs with extended dynamic range - Google Patents

Abstract

FIELD: radar ranging and radio navigation.

SUBSTANCE: invention relates to radio receiving device with quadrature digital signal processing and can be used in radar stations. Technical result is achieved due to that radio receiving device contains connected to each other in a certain way controlled amplifier, phase detector, source of quadrature oscillations, analogue-to-digital converter (ADC), digital control signal generating device, a buffer, a signal comparing device with a lower threshold level, a signal comparison device with an upper threshold level, a command decoder, a constant component subtractor, a unit for storing constants and a device for restoring dynamic range at the output of the receiver, wherein the radio receiving device controls the gain of the reception channel so that the signal at the input of the ADC is in the linear part of its dynamic range.

EFFECT: wider dynamic range at the input of the device while maintaining signal level information on the quadrature digital outputs of the radio receiving device and transmitting zero frequencies in the spectrum of the useful signal while simultaneously compensating for the parasitic constant component at the output of the analogue-to-digital converter (ADC).

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Description

The invention relates to radio receivers with quadrature digital signal processing and can be used in radar stations.

When constructing modern radio receivers with quadrature digital signal processing as part of the radar, complexes simulating a multi-purpose environment, simulators of radar targets and other devices, ensuring the linear operation of the receiving path is especially relevant. Violation of linearity leads to a distortion of the received signal and, as a consequence, a deterioration in the performance of the entire device. In the case of a radar, this is the probability of correct detection, the ability to detect a weak signal against a background of strong interference, resolving power in oblique range and azimuth.

In addition, in digitally processed radio receivers, nonlinear distortions in the analog and digital paths will lead to the appearance of secondary harmonic components in the signal working band, which will be practically impossible to eliminate.

The bottleneck in terms of dynamic range in radio receivers with digital quadrature processing is the analog-to-digital converter. As a rule, this device is characterized by a narrower dynamic range of input signals compared to other elements of the receiver. This is due to the capacity of the ADC. The lower the bit size, the smaller the dynamic range of the input signals that the ADC can transmit without distortion. At the same time, bit depth is related to the sampling rate.

If we assume that the ADC digitizes both the positive and negative half-waves of the input signal, then its dynamic range (in dB) will be equal to:

where P _max . _ADC / P _min . _ADC is the maximum / minimum allowable value of the signal power at the input of the ADC, U _{max. ADC} / U _{min. ADC} is the maximum / minimum allowable value of the signal voltage at the input of the ADC, N is the resolution of the ADC. So an 8-bit ADC will theoretically have a dynamic power range of 42.11 dB. In practice, most often this figure will be less, taking into account the influence of intrinsic noise and other factors. At the same time, for modern radio receivers, there is a tendency to expand the instantaneous signal processing band due to the use of complex modulated signals. So a radar with a synthesized aperture of the antenna processes signals with a band up to 1 GHz and higher. To process signals with such a band, it is necessary that the sampling frequency of the used ADCs by the Kotelnikov-Nyquist theorem is at least two times higher than the upper frequency in the spectrum of the useful signal of the intermediate frequency. Through the use of quadrature processing, the sampling rate is reduced by half. But at the same time, the higher the sampling rate, the lower the ADC bit depth. So ADCs with conversion frequencies of 1 GHz and higher, as a rule, have a resolution of no more than 8-10, and this imposes restrictions on the dynamic range of the processed signals. Thus, the task of expanding the dynamic range of the input signals for radio receivers with digital processing is relevant and requires special measures.

Known analogues of a radio receiver with digital outputs and an extended dynamic range [1], [2].

The analogue [1] (coherent radar receiving device) is a system of parallel-connected n-channels for receiving a signal with vector displacements of the operating range specially selected for each receiver and generating at the output sums of the same parts of the envelope of the output signal of parallel receivers. The disadvantage of this device is the insignificant dynamic range of a single coherent receiver, and, as a result, a large number of parallel processing channels are required to obtain the required linearity of the entire receiving path. A large number of channels leads to a very complex and cumbersome technical implementation of the device, as well as distortion of the output signal due to the inability to perfectly fit together all n receiving channels. Also, the local oscillator and the phase shifter have an increased level of side components in the spectrum of the output signal of the phase shifter, which leads to an error in the correction of the quadrature of the applied signals.

The analogue [2] (a coherent radar receiver with a large dynamic range) is also a multichannel system consisting of n-channels. Each channel consists of an analog adder, resonant amplifiers with a controlled transmission coefficient, two synchronous frequency converters, low-pass filters and an ADC. The output quadrature digital signals from each channel are added up in digital adders. This analogue, unlike the previous one, is devoid of side components in the spectrum of the output signal and allows coherent processing of phase-coded signals. The disadvantage is the increased complexity of the technical implementation of the multichannel system, the influence of the dispersion of the electrical parameters of the circuit elements on the quality of the resulting signal and, as a consequence, the increased requirements for circuit elements, an increased level of quantization noise in the resulting signal due to the use of a large number of ADCs, distortion of the output quadrature signals due to imperfect cross-linking of the dynamic range from many individual ones.

The closest in technical essence to the claimed radio receiver with digital outputs and an extended dynamic range is a radar receiver of complex signals [3], adopted as a prototype.

The radar receiver contains an adjustable input amplifier, two quadrature channels connected in parallel with it, each of which consists of a phase detector connected in series, the controllable inputs of which are connected to a quadrature oscillation source, ADC, DC component subtractor (comparison blocks), low-pass filters. Phase detectors are connected to a quadrature oscillation source, the output of which is also connected to a chronizer and low-pass filters. The receiver also contains a constant storage unit and an automatic gain control (AGC) unit, the output of which is connected to a controlled input of the amplifier. The output signal enters the block selection of moving targets.

The essence of this known solution is that between the output of the ADC and the input of the selection block, an adaptive subtraction of the constant component is switched on and an AGC block is connected parallel to its output, the output of which controls an adjustable amplifier. The AGC device is made of a series-connected detector, a comparison unit with a fixed threshold level, a low-pass filter and a digital-to-analog converter.

In this device, the input signal is fed to an adjustable amplifier, shifted to an intermediate frequency using two phase detectors with the formation of two quadrature signals (having a phase shift relative to each other 90 °), which are converted into digital form by two analog-to-digital converters, constant compensation and fluctuation component at the output of each quadrature, the gain of the amplifier is adjusted in accordance with the result of the evaluation of the rms value I was a random process at the output of the compensation blocks DC component.

However, this prototype device [3] has its drawbacks. Thus, the DC component compensation circuit eliminates the DC component caused by the intrinsic noise of phase detectors and ADCs, as well as a useful signal, which in some cases is unacceptable, since zero frequencies in the signal spectrum can also carry useful information. In addition, due to the adjustment of the gain of the input amplifier of the radio receiving device, the dynamic range of the signal is compressed at the output of the entire device. In this case, information about the signal level is lost, since there is no feedback on the output. The use of an analogue control signal for adjusting the gain of an adjustable amplifier leads to an increase in the instability of the AGC circuit with external factors.

The technical result (task) of the proposed solution is to expand the dynamic range at the input of the device while maintaining information about the signal level at the quadrature digital outputs of the radio receiving device and transmitting zero frequencies in the spectrum of the useful signal while simultaneously compensating for the stray DC component at the ADC output.

The technical result is achieved due to the fact that a digital control signal generating device is introduced into the receiver with a digital output, which provides control of the gain of the adjustable amplifier based on information about the level of the ADC output signal. On the digital quadrature outputs of the radio receiver, a dynamic range recovery device is introduced to store signal level information. At the same time, high requirements are achieved in terms of the linearity of the analog-to-digital converter.

In each quadrature channel of a radio receiver with digital outputs containing phase-detectors and ADCs connected in series, a buffer and a zero offset compensation circuit are included between the detectors and ADCs at the ADC output. Also parallel to the outputs of the ADC is a circuit for determining the signal level of the intermediate frequency, which sets the gain of the input adjustable amplifier.

The zero offset compensation device at the ADC output consists of a circuit for subtracting the constant component (from the useful signal) and a constant storage unit. The ADC output signal of each of the quadrature channels is fed through buffers to the input of the constant subtraction circuit, and a digital code is read from the constant storage unit to the second input of this circuit.

The automatic gain control unit (AGC) includes a circuit for comparing a signal with an upper and lower threshold level, the output of each of these circuits is connected to the input of a digital control signal generating device that sets the gain of the adjustable amplifier and the dynamic range recovery circuit at the outputs of the receiver's quadrature channels.

The block diagram of the proposed radio receiver with digital outputs and an extended dynamic range is presented. The receiver contains an adjustable amplifier 1, a phase detector 2, a source of quadrature oscillations 3, an analog-to-digital converter 4, a device for generating a digital control signal 5, a buffer 6, a device for comparing a signal with a lower threshold level 7, a device for comparing a signal with a upper threshold level 8, a decoder commands 9, a device for subtracting a constant component 10, a storage unit for constants 11 and a device for restoring the dynamic range at the output of the receiver 12.

The principle of operation of the device is as follows. The input signal is fed to input 1 of an adjustable amplifier 1 with digital electrical adjustment. An amplifier with digital gain control consists of a decoder (decoder) of the commands that converts the digital control signal into a gain control signal and an adjustable amplifier.

Using this device allows you to adjust the gain of the receive path so that the signal at the input of the ADC 4 is in the linear part of its dynamic range. Denote the signal at input 1 of tunable microwave amplifier 1 as S in _x (t).

определяет динамический диапазон входных сигналов, где Р_maх/P_min - максимальная/минимальная мощность сигнала S_вx(t). Сигнал на выходе усилителя с учетом его коэффициента передачи Ку_сил будет равен Kу_сил.⋅S_вх(t). Основной критерий при выборе усилителя - максимальная скорость перестройки коэффициента передачи и линейная работа во всем динамическом диапазоне ΔP_вх входных сигналов. Для простоты положим, что в начальный момент времени работы изделия коэффициент передачи усилителя 1 равен максимальной величине Ку_{сил.макс}.Value

determines the dynamic range of the input signals, where P _max / P _min - the maximum / minimum signal power S _in (t). The signal at the output of the amplifier, taking into account its transmission coefficient Ku _forces, will be equal to Ku _forces. ⋅S _in (t). The main criterion for selecting an amplifier - the maximum speed adjustment gain and linear operation over the entire dynamic range of input signals _Rin ΔP. For simplicity, we assume that at the initial time of the product’s operation, the gain of amplifier 1 is equal to the maximum value of _Ku.smax . _Max .

The next element in the receiving path, connected to the output 3 of the adjustable amplifier, is a phase detector 2. This device provides the transfer of the spectrum of the useful signal Ku _forces. ⋅S _Rin (t) to an intermediate frequency (hereinafter IF). The formation of two quadrature channels of signal processing is ensured by the fact that two phase detectors are used in the circuit. The output signal of the amplifier is supplied simultaneously to the inputs of 1 phase detectors, and the local oscillator signal is fed to the inputs of 2 phase detectors from outputs 2 and 3 of the quadrature oscillation source 3. The quadrature oscillation source 3 is a harmonic oscillation generator, the output 2 of which goes directly to the heterodyne input 2 phase detector, and output 3 is the output of the phase shifter 90 °, through which the signal of the generator passes and then goes to input 2 of the second phase detector.

A tunable frequency synthesizer with phase-locked loop (PLL) is used as a harmonic oscillation generator. Structurally, it can be made in the form of a separate integrated circuit. The presence of such a synthesizer allows you to set the required local oscillator frequency, with an accuracy of several kHz, and this procedure is performed by programmatically loading control information into the working registers of the synthesizer. The low level of phase noise due to the use of the PLL system ensures that the coherence condition is satisfied during the signal processing. The required frequency is set by loading the control information into the working registers of the synthesizer through the control input 1 of the source of quadrature oscillations. The control information comes from output 1 of the command decoder.

The choice of synthesizer frequency is determined by the instantaneous working band of the signal. If you designate the lower limit of the operating range as F _lower. , and the top as F _Вepx. , then the frequency of the synthesizer should be equal to F _synt. = (F down _. + F _upx. ) / 2, i.e. the center frequency of the operating range. The width of the working band of the signal is ΔF = F _vepx. - F _lower . Then, the intermediate frequency band after down-converting by the phase detector for the local oscillator frequency indicated above will be ΔF _IF = 0 ... ± ΔF / 2 for each quadrature.

The conversion of the analog signal from the output of the phase detector to digital is performed by the ADC. In this case, the sampling frequency should exceed the upper boundary of the IF bandwidth ΔF / 2 at least 2 times.

Next, a digital signal of intermediate frequency from the output of the ADC is fed to the input of buffers 6, which are necessary to interface the sampling frequency of the ADC with the clock frequency of the signal processing in the radio receiver. These elements receive a digital signal from the ADC, accumulate it and transmit it at a lower frequency, but with a larger information capacity, to input 1 of the device for subtracting the constant from the useful signal.

The output signal of the buffers passes through a zero offset compensation circuit at the ADC output, consisting of elements 10 and 11, and is supplied to the device for determining the signal level of the intermediate frequency and sets the transmission coefficient of the adjustable input amplifier and dynamic range recovery device at the receiver output.

The decoder commands 9 is an element that performs the operation of receiving information from an external control device, decoding the received packages and their further addressing and transmission via information buses to the main control elements of the circuit: a quadrature oscillation source, constant storage units, signal comparison devices with a lower / upper threshold level and device for generating a digital control signal.

In this implementation of a radio receiver with digital outputs, two operating modes are provided. Depending on which mode of operation is used, the algorithm for functioning of the zero offset compensation circuit at the ADC output, consisting of blocks 10 and 11, differs. The first mode is calibration. In this mode, after the supply voltage to all nodes of the device, from the external control device through the interface input "g" to the input 3 of the decoder 9 receives commands for presetting the circuit elements. This is necessary to eliminate additional sources of introducing errors into the offset of the ADC output signal. To do this, the adjustable microwave amplifier 1 using the digital control signal generating device is set to the minimum transmission coefficient, and the tunable frequency synthesizer of the quadrature oscillation source 3 does not generate a heterodyne signal for phase detectors 2. At the same time, a constant parasitic voltage will be present at the ADC inputs 4 own noise of the radio receiving device, the error in the installation of the reference voltage of the ADC and the amplitude imbalance of the quadrature signals. We designate ΔS _ADC.OUT.1 (t) and ΔS _ADC.BY.2.2 (t) as a stray nonzero offset at the ADC output of the first and second quadrature channels, respectively. These errors without distortion will pass through the buffers 6 and get to the input 1 of the device for subtracting the constant component 10.

где n - количество усреднений, ΔS_{АЦП.ВЫХ.1}(t_i) - отсчет сигнала в момент времени t_i. Таким образом, S_конст. представляет собой математическое ожидание случайного процесса ΔS_{АЦП.ВЫХ.}.Before starting calibration, after presetting the circuit elements, a constant value equal to 0 is received from the output of the constant storage unit 11. In this case, the device 10 performs the operation of subtracting from the input signal coming to the input 1 from the output of the buffer, a constant value equal to 0 read from the storage unit constants. Thus, the input signal, which is ΔS _ADC.OUT.1 (t) (or ΔS _ADC.BY.2.2 (t) depending on the channel) passes to output 3 of device 10 without changes. After the receipt of the calibration command from the external control device, the decoder 9 generates a save command, which is input 1 of the constant storage unit. At the same time, accumulation is performed over a period of time with averaging ΔS _ADC.OUT.1 (t) (ΔS _ADC.BY.2.2 (t) for the second processing channel into the storage unit of constants). In fact, the value is entered into the constant storage unit

where n is the number of averagings, ΔS _{ADC. OUT.1} (t _i ) is the signal sample at time t _i . Thus, S _const. represents the mathematical expectation of a random process ΔS _ADC.OUT. .

After calibration, the device for subtracting the constant component 10 subtracts the constant _value S _const from input signal S of the _FCU (t) supplied to input 1 from the output of buffer 6 _. coming from the 2 outputs of the constant storage unit 11. The output signal of the subtraction device, regardless of the sign of the useful signal and the value of S _const. will be equal to S _{Out. habits} (t) = S _BUF (t) -S _const . Since before the second mode of operation S, the _BUF (t) is equal to ΔS _ADC.OFF. (t), the output signal will be equal _Vyh.vych S (t) = S _BUF (t) -S _intercept ≈0.

The second mode of operation of the radio receiver is the operating mode. In this mode, the external control device through the input "g" transmits initialization commands for the main blocks of the circuit. At the same time, using the command decoder, the gain of the adjustable amplifier is set to the maximum value, the frequency of the quadrature oscillation source is set in accordance with the operating range, the threshold value is transmitted for two signal comparison devices with a lower / upper threshold level, and the time during which the level is determined the signal at the ADC output, the transmission coefficient of the dynamic range recovery device at the receiver output is set to the minimum value Ie.

The digital code is written to the constant storage unit at the time of calibration of the device and is performed from the output of the subtraction circuit.

In the operating mode, the input useful signal, passing through the elements of the microwave path, as well as the ADC and the buffers, enters the input of the subtraction device. The parasitic nonzero offset S _const is subtracted from the signal _. , which is read from the constant storage unit and which was recorded in the calibration mode of the radio receiver. Next, the useful signal from the output 3 of the subtractor 10 of one of the quadrature channels is fed to the inputs of the AGC circuit, which consists of devices for comparing the signal with the lower and upper threshold levels, as well as the device for generating the digital control signal. The thresholds D _lower and D _upper devices 7 and 8 are set using command decoder 9 through inputs 2. Device 7 performs the operation of taking the signal module S _{Exit habit} (t) and compares | S _{Exit habit} (t) | with a lower threshold level D _lower . If | S _{Out. Habit} (t) | <D _lower then a logical “1” is generated; otherwise, “0”. In the device 8, the operation is carried out of taking the signal module S _Exit (t) and comparing the upper threshold D _Bepx . with signal | S _{Out. habit} (t) |. If | S _{Out. Habit} (t) | > D _verx ., Then device 8 generates a logical “1” at a given time, otherwise - “0”. The choice of thresholds is determined based on the following conditions:

1) D _upx . should be less than 20% of the maximum possible value at the output of the ADC.

2) D _lower should be 20% more than the minimum possible value at the output of the ADC.

Thus, the choice of thresholds is determined based on the fact that the useful signal is in the middle of the ADC operating range, without going into the region of overflow of the discharge grid and quantization noise.

The device 5 performs the formation of a digital control signal for an adjustable amplifier 1 and a dynamic range recovery device at the outputs of the receiver in accordance with the information received from the signal comparison devices 7-8. This element consists of two counters, which count the number of logical “1” coming from devices 7-8 during the time t _counting. . At the end of the counting time, the contents of the counters are compared with the values of N _Вepx. and N _lower which are transmitted to device 5 via a command decoder. The value of t _count. determines the time interval sufficient to determine the signal level at the ADC output, and is also programmatically set using the command decoder.

The values of N _Vepx and N _lower. determine the number of digital samples of the desired signal that must exceed D _vepx. and D _lower during time t _count. so that the AGC circuit works.

The algorithm of the device 5 is as follows:

1) Since the start of the operating mode for a time t _counting. , the counters counting the number “1” at the output of the comparison devices 7 and 8 are launched.

2) If after the end of time t _counts. , the contents of the counter counting “1” at the output of the device 8 exceeds the value of N _Вepx ., the device 5 generates a digital control signal for the adjustable amplifier in such a way as to reduce its transfer coefficient by dK _P (step of adjusting the transfer coefficient). At the same time, for the dynamic range recovery devices 12 at the receiver output, which in their technical implementation are digital adjustable amplifiers, a digital control signal is generated that increases the transmission coefficient of the digital quadrature channel by dK _P. Those. when the dynamic range is compressed at the input of the device, it is inversely proportional to its expansion over the outputs, and information about the signal level is not distorted. In that case, if the current transfer coefficient of the adjustable amplifier To _us. less than dK _P , the transmission coefficient is set to the minimum value of K _us.min. .

If the contents of the counter counting "1" at the output of the device 7 exceeds the value of N _lower. , then the device 5 generates a digital control signal for the adjustable amplifier in such a way as to increase its transfer coefficient by dK _P. Moreover, for the dynamic range recovery devices 12, a digital control signal is generated at the receiver output, which reduces the transmission coefficient of the output of quadrature channels by dK _P. In that case, if the current transfer coefficient of the adjustable amplifier To _us. equal to the maximum value of K _us.max. , then the transmission coefficient is set to the maximum value of K _us.max. .

After the end of the cycle (duration t _count ), the measurement of the useful signal level counters of the device 5 are reset, while the digital control signals for the adjustable amplifier 1 and device 12 remain unchanged.

3) A new measurement cycle is _{started with a} duration t _counting. .

4) The steps of paragraph 2-3 are repeated until the operation of the radio receiver is stopped.

The range of adjustment of the gain of the amplifier 1, equal to ΔK _P = K _usm.max. / K _usmin , defines the main capabilities of the AGC circuit to expand the dynamic range of signals at the input of the ADC.

Achievable technical result:

The use of an adjustable amplifier 1 and a dynamic range recovery device at the output of the receiver 12 with a transmission coefficient adjustment range ΔK _p allows us to expand the dynamic range of signals at the ADC input by ΔK _p without significantly complicating the technical implementation of the radio receiving device. The zero offset compensation circuit at the ADC output improves the accuracy of determining the level of the output signal and the transmission of the useful constant component in the spectrum of intermediate frequency quadrature signals. The introduction of digital control of the gain of the adjustable amplifier and the dynamic range recovery device at the outputs of the radio receiver improves the stability and accuracy of the AGC circuit, in addition, the reliability and high repeatability of the results in serial production increase.

This result is achieved due to the fact that in each quadrature channel of a radio receiving device with digital outputs containing phase-detectors and ADCs connected in series, a buffer and a zero offset compensation circuit are included between the detectors and ADCs at the ADC output, which remembers the constant component at the time of calibrating the device in the absence of a useful signal at the input and subtracts it from the useful signal during operation, as well as parallel to the ADC outputs, a circuit for determining the signal level frequency and setting the gain of the input adjustable amplifier so that the signal at the input of the ADC does not lead to its overload (overflow of the bit grid) and exceeds the inherent noise of quantization of the ADC). The introduction of the digital outputs of the additional dynamic range recovery device allows you to restore information about the signal level at the outputs of the radio receiver.

Analog 1 - "Radio coherent radar device", RF patent 2189054.

Analog 2 - "Coherent radar receiver with a large dynamic range", RF patent 2231807.

Working prototype 3 - "Radar receiver of complex signals", RF patent 2033625.

Claims (1)

A radio receiver with digital outputs and an extended dynamic range, containing an adjustable amplifier, the input of which is the input of a radio receiver, two parallel-connected quadrature channels, each of which consists of a series-connected phase detector, analog-to-digital converter (ADC) and a device for subtracting the DC component, the input of each of the phase detectors is connected to the output of the adjustable amplifier, and the controlled input is connected to the quadrature source to oscillations, as well as containing an automatic gain control (AGC) unit, characterized in that the adjustable amplifier is digitally controlled, a buffer between the ADC and the DC subtracting device is introduced into each channel, and a constant storage unit is introduced into each channel, one from the inputs of which is connected to the output of the device for subtracting the constant component of its channel, and the output of the constant storage unit is connected to the second input of the device for subtracting the constant component of its channel, at the output In order to subtract the constant component in each channel, a dynamic range recovery device is introduced, the outputs of the dynamic range recovery devices are the outputs of the radio receiving device, an instruction decoder is also introduced into the radio receiving device associated with the constant storage unit in each channel and with the quadrature oscillation source, while the AGC block contains a device for generating a digital control signal and two devices for comparing a signal with lower and upper threshold levels; The signal comparison devices with the lower and upper threshold levels are connected to the corresponding inputs of the digital control signal generating device, and the inputs of the signal comparison devices with the lower and upper threshold levels are connected to the output of the device for subtracting the DC component of one of the channels, as well as to one of the outputs of the command decoder, the first and second outputs of the digital control signal generating device of the AGC block are connected respectively to the input of the adjustable amplifier and to the input of the recovery devices ment of the dynamic range of both channels, forming one of the digital control signal input device connected with the decoder output corresponding commands for which the input information is received from an external control device.

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