Digital Receiver Research Articles

Effects of Laser Linewidth on the Performance of DP-QPSK DWDM System

Abstract This paper analyzes the effects of laser linewidth on the performance of eight-channel dual-polarization quadrature phase-shift keying (DP-QPSK) dense wavelength division multiplexing (DWDM) transmission at 50 GHz channel spacing. The performance of differential encoding and Gray coding is compared with the system without any coding for the DP-QPSK DWDM system. It is shown that the differentially-encoded system performs better for lasers with linewidth (∆ν) greater than 0.04 MHz compared to the system with Gray coding and system without any coding. However, for lasers with linewidth lesser than 0.04 MHz, the three systems considered here perform equally and there is no need for differential or Gray coding in such a case. It is also shown that if we apply frequency offset estimation (FOE) before adaptive equalization (AE) in the digital coherent receiver then it further improve the performance of the differentially encoded system with lasers sources having linewidth even greater than 0.1 MHz.

Accessibility of TV media for the dual-sensory impaired in Finland and in the UK

One of the most used media is television. Almost all of us have a television set at home. Television is commonly thought also to be accessible, and for most of us, it seems to be so. However, there are people who cannot enjoy televised programmes without special measures. These measures include subtitling, audio description and sign language interpretation. All these are mentioned in the in-force EU Audiovisual Media Services Directive.
 In this article we look at how these are broadcast in different countries, what equipment is needed for receiving them, and how accessible the programme information (EPG) and menus to choose these accessibility options are, as they most often are not automatic, but have to be turned on in the accessibility options menu or the TV set or digital terrestrial receiver box (digibox). This article focuses on accessibility with special interest on the dual-sensory impaired perspective over four days comparing two countries: the UK where all three accessibility features mentioned above are well-established and Finland, where accessibility features concentrate mainly on subtitling.

L대역 신호 수집을 위한 소형 디지털 수신기 설계 및 제작

In this paper, we have designed and fabricated a compact digital receiver for acquiring L-band signals. A receiver, based on direct RF sampling, has been designed for a compact multi-channel receiver. The design of the receiver is based on the system parameters and it is further fabricated on the basis of the simulation model. The performance of the fabricated digital receiver is analyzed by comparing it with the performance of the simulation model. It is observed that the fabricated digital receiver exhibits a receive sensitivity of −102 dBm, and eventually reaches the dynamic range of 62.7 dB.

Research on LDPC Coding Cooperative System Based on Intelligent Joint Iterative Decoding

Gain of multi-relay coding cooperation. As the number of joint iterations increases, the bit error rate performance increases rapidly, which is significantly better than the coding non-cooperative system under the same conditions. The source output should be represented with as few binary digits as possible. Various noises and interferences in the channel are the main causes of bit errors in digital communication system receivers. Collaborative technology can improve the performance of the system without significantly increasing the system bandwidth or increasing the transmit power, and has attracted more and more attention in the academic and engineering fields.

Adaptive Nonlinear Equalization for Digital Array Receivers

As low-cost fully digital array technology becomes more commercialized, techniques need to be developed to be able to deal with many of the inherent problems of these systems. This article focuses on mitigating the intermodulation distortion (IMD) caused by the low-input third-order intercept point (IIP3) of the low-noise amplifier (LNA) in a digital array element's channel. The performance of solid-state electronics also varies with the temperature of the device, thus changing the device's nonlinear characteristics. This article proposes an adaptive solution for nonlinear equalization (NLEQ) with the use of the least mean-square (LMS) algorithm. Data from a modern digital array channel are corrected using the proposed method; the channel nonlinearities are also characterized for further simulations. A simulation using these nonlinear coefficients shows that NLEQ can effectively mitigate the IMD of two strong interferers that had previously distorted the weak signal of interest. Finally, a nine-element fully digital array is simulated, showing the correlation of IMD with specific, predictable directions, and the decorrelation of these spurs after NLEQ is applied to each element of the array.

Development of modular and robust high power solid-state transmit–receive module for Gadanki Ionospheric Radar Interferometer

The study of ionospheric effects1 on the satellite-based communication signals has been a continued topic of interest both for academic interest and global positioning system aided navigation applications. These communication signals are affected by the field-aligned irregularities, suffers from fading and range spreading when they pass through the ionosphere. 2 To study the low latitude ionospheric plasma irregularities, dedicated radar with wide beam steering capabilities is required. Recently Gadanki Ionospheric Radar Interferometer, which operates at 30 MHz frequency, has been realized at National Atmospheric Research Laboratory, Gadanki, to scan a larger part of the sky up to ±50° in East-West direction. The radar system employs a 160 element phased antenna array, antenna system, state-of-the-art 8 kW high power solid-state transmit–receive modules, and direct digital receiver. In order to carryout round-the-clock scientific observations, highly reliable, robust designs are required to realize the high power transmit–receive modules. Detailed design philosophies are described with modular concept and better thermal designs in this paper to achieve the high power requirements. Performance results of the transmit–receive module and the sample scientific results obtained by employing these transmit–receive modules are presented in this paper.

Wavelength-Division Demultiplexing Enhanced by Silicon-Photonic Tunable Filters in Ultra-Wideband Optical-Path Networks

With the recent growth of network traffic demands, a high-capacity optical-path network based on reconfigurable optical add-drop multiplexers (ROADMs) is highly desirable. Among the various technologies available, extending the useable frequency band is one of the most promising solutions since it can enlarge the network capacity with relatively small signal-quality degradation. However, increasing the number of wavelength signals detracts flexible signal-drop capabilities of the ROADM because the effective dynamic range of the digital coherent receiver is restricted by the number of wavelength signals input to the receiver. To overcome this difficulty, we adopt the ROADM structure that sets an optical wavelength-tunable filter in front of each receiver. This scheme retains the effective receiver dynamic range even if a large number of wavelength signals are multiplexed. In this paper, we demonstrate flexible signal drop in a C+L-band optical-path network by using an optical wavelength-tunable filter implemented on a single silicon-photonic chip. The prototype filter is monolithically implemented in conjunction with an input-port selector so as to reduce the total system loss. The filter comprises multiple asymmetric Mach-Zehnder interferometers for wavelength tuning and symmetric Mach-Zehnder interferometers for input-port selection. Its effectiveness is experimentally confirmed by measuring the bit-error ratios of 32-Gbaud/100-Gbps dual-polarization quadrature-phase-shift-keying signals and 32-Gbaud/200-Gbps dual-polarization 16-ary quadrature-amplitude-modulation signals. A single wavelength signal is extracted out of 285 wavelength signals multiplexed over the C+L band and successfully demodulated with negligible penalty in terms of the optical signal-to-noise ratio. The net fiber capacity reaches 57 Tbps.

Principle of Coherence Optical Systems-Current Applications and Future Challenges

This paper reviews the concept of coherent optical systems as future digital optical communication systems having capacity of achieving 100Gbps speed. While the transmission capacity increases in wavelength-division multiplexed (WDM) system, coherent technologies have been in large interest in recent years. The interest lies in finding methods of increasing the bandwidth demand with multilevel modulation formats based on coherent technologies. We also discuss about requirements and challenges in implementation of respective digital receivers and associated signal processing.

Dose assessment of medical exposure of radiographic dental studies

The purpose of the study is to evaluate the effective doses of patients for the most common radiographic dental studies, comparing the obtained data with the literature and reference values given in the guidelines “Filling in the forms of the federal state statistical observation No. 3-DOZ” and are still often used for form filling instead of measured values. In the framework of this work in 2016-2018, 44 X-ray units were examined at 37 dental medical facilities in St. Petersburg and the Leningrad Region. Seven radiographic studies were included: radiographs of three groups of teeth (incisors, premolars, and molars) for the upper and lower jaw and bite radiography. Physical-technical and geometrical parameters were collected for selected types of the standard patient studies: X-ray tube voltages, total filtration, radiation output, combination of the time and the current of exposure or the exposure, area of the study, size of the irradiation field; the focal length. Further, the input (surface) dose was calculated from the radiation output of the device. Then, based on the initial information about the parameters of the procedures and the input dose, the absorbed doses and the effective dose were calculated using the PCXMC program. For most devices, the dose values are in the range of 0.5 to 10.7 µSv, which is significantly lower than the values used to fill in the 3-DOS form. The results of evaluating the effective dose for these devices are fairly homogeneous, but on one device, there were doses exceeding not only the values of doses on other devices, but also the values from the recommendations for 3-DOS for devices with digital receivers, as well as those approaching similar values for film devices. An almost linear dependence of the effective dose on the exposure time was established, while a similar dependence on the voltage on the X-ray tube was not found. The median value of the effective dose for the units with films detectors was 3.2 µSv for the maxillary incisors, 3.8 µSv for the maxillary premolars, 6.8 µSv for the maxillary molars, and for the mandibular incisors, premolars and molars – 3.2, 3.4 and 5.8 µSv, and for bitewing – 6.7 µSv. For the unit with digital detectors, effective doses were 1 µSv, 1,2 µSv, 2,2 µSv for maxilla, 1 µSv, 1,3 µSv, 2 µSv for mandibula and 2,8 µSv for bitewing. Attention is drawn to the substantial width of the ranges without emissions for the examination of premolars of the upper jaw, molars of both jaws and occlusion, which is the reason for the possible enhancement of optimization measures in these studies. When comparing with published data, it was found that the effective doses in St. Petersburg and the regional institutions are lower than the values obtained using standard round collimator and medium and high sensitivity films (class D and F, respectively), as well as lower dose levels in the European Commission Guidelines. In addition, the dose values deduced in this study are significantly lower than the values given in the guidelines “Filling in the forms of federal state statistical observation No. 3-DOZ” and which are still often used to fill in the form instead of the measured values. This indicates an overestimation of estimates of patient doses when using reference values from the 3-DOZ manual and the need to use individual patient doses, obtained on the basis of measurements. However, the effective doses in St. Petersburg and the Leningrad Region are higher than those obtained using a square collimator and high-sensitivity films. The above results suggest that it is necessary and possible to carry out optimization in X-ray dental studies in St. Petersburg and the Leningrad Region. Analysis of similar studies on other X-ray diagnostic techniques allows to extrapolate this statement to other regions of Russia.

Selection and Application of the Data Transfer Operating Protocol Software Architecture for the Software-Defined Radio

Introduction. The demodulator structure is described and decoding algorithm for signal-code constructions development is presented. The structure and functional description of the developed software (SW), which is designed for the installation of the software-defined radio in the radio stations layout, are presented. The frame structures of the broadcast and half-duplex protocols, modulation/demodulation and subsequent digital signal processing in existing and prospect radio communication systems are considered.Objective. Investigation of modulation/demodulation methods and subsequent digital signal processing along with requirements imposed by them on the network stations equipment and system operation algorithms.Materials and methods. The software for the software-defined radio system layout is developed to demonstrate the reliability and operability of the proposed algorithm and transmission protocol. It can be used to receive and transmit information by using ionospheric reflections. Present design takes into account existing standards and amateur systems such as WinLink and information systems (digital and analog) for the "physical" and "channel" levels.Results. The structure and functional description of the developed software for the software-defined radio system layout are given. The possible realization of the software-defined radio channel for data receiving and transfer by using ionospheric reflections is presented. The results of technical solutions experimental testing are shown. The software can use hardware and software to control the transceiver module, which includes the SunSDR2 transceiver and antenna amplifier.Conclusion. The structure and functional description of the developed software are presented as a result of the software architecture selection and its application investigation. It is concluded that the reliability and operability justification of the proposed algorithm and transmission protocol is relevant in a field of the digital receivers development for communication systems of various purposes. The presented experimental studies data on verification of the proposed algorithm show the feasibility of present solutions on the qualitative utilization of the channel resource by using the described code structure. The present results allow to determine the most appropriate and efficient way of the software development allowing to create a technique that can meet the maximum number of possible assignments of radio access channels.

Complex fuzzy sets with applications in signals

A complex fuzzy set is characterized by a membership function, whose range is not limited to [0, 1], but extended to the unit circle in the complex plane. In this paper, we introduce some new operations and laws of a complex fuzzy set such as disjunctive sum, simple difference, bounded difference, distributive law of union over intersection and intersection over union, equivalence formula, symmetrical difference formula, involution law, absorption law, and idempotent law. We introduce some basic results on complex fuzzy sets with respect to standard complex fuzzy intersection, union, and complement functions corresponding to the same functions for determining the phase term, and we give particular examples of these operations. We use complex fuzzy sets in signals and systems, because its behavior is similar to a Fourier transform in certain cases. Moreover, we develop a new algorithm using complex fuzzy sets for applications in signals and systems by which we identify a reference signal out of large number of signals detected by a digital receiver. We use the inverse discrete Fourier transform of a complex fuzzy set for incoming signals and a reference signal. Thus, a method for measuring the exact values of two signals is provided by which we can identity the reference signal.

Results of work of new spectropolarimeter for solar radio emission observations in the range 50–500 MHz

Ground-based observations within meter radio range are of importance for understanding processes occurring in the solar corona.
 We present concepts, block diagram, and results of first observations of the Solar Spectropolarimeter of Meter Range (SSMD), launched for solar observations in the range 50–500 MHz in April 2016. The main purpose of this work was to develop an up-to-date digital radio spectropolarimeter able to record the full Stokes vector for sporadic solar phenomena taking place in the 50–500 MHz range.
 We use a crossed log periodic antenna to detect solar radio emission. This antenna can simultaneously obtain horizontal and vertical polarization components. The main part of SSMD is a digital receiver based on an FX correlator architecture. We use the Fast Fourier Transform (FFT) algorithm based on the real-time pipeline circuit to construct amplitude dynamic spectra (intensity vs frequency and time).
 SSMD has 4608 frequency channels with 97.66 kHz channel bandwidth and 97.66 kHz spacing. Time resolution is 1 s. The spectropolarimeter has a 50–500 MHz range. It can record the full Stokes vector. At present, SSMD observes two of four parameters in regular mode (I and V). We have observational data since 2016. The catalog development is in progress.
 We plan to improve time and frequency characteristics, record all Stokes parameters, and conduct a calibration. We are working on providing access to the data archive via the Internet.

Результаты работы нового спектрополяриметра для наблюдения солнечного радиоизлучения в диапазоне 50–500 МГц

Ground-based observations within meter radio range are of importance for understanding processes occurring in the solar corona.
 We present concepts, block diagram, and results of first observations of the Solar Spectropolarimeter of Meter Range (SSMD), launched for solar observations in the range 50–500 MHz in April 2016. The main purpose of this work was to develop an up-to-date digital radio spectropolarimeter able to record the full Stokes vector for sporadic solar phenomena taking place in the 50–500 MHz range.
 We use a crossed log periodic antenna to detect solar radio emission. This antenna can simultaneously obtain horizontal and vertical polarization components. The main part of SSMD is a digital receiver based on an FX correlator architecture. We use the Fast Fourier Transform (FFT) algorithm based on the real-time pipeline circuit to construct amplitude dynamic spectra (intensity vs frequency and time).
 SSMD has 4608 frequency channels with 97.66 kHz channel bandwidth and 97.66 kHz spacing. Time resolution is 1 s. The spectropolarimeter has a 50–500 MHz range. It can record the full Stokes vector. At present, SSMD observes two of four parameters in regular mode (I and V). We have observational data since 2016. The catalog development is in progress.
 We plan to improve time and frequency characteristics, record all Stokes parameters, and conduct a calibration. We are working on providing access to the data archive via the Internet.

A Novel Design of Matched Filter for Digital Receivers

In this paper, a brief review regarding introduction to the digital signal processing techniques particularly Digital Pulse Compression and Linear Frequency Modulation involved in matched filtering and some designs being used is presented. Also, the matched filter being developed is discussed by highlighting its pros and cons. The introduction of matched filter in the communication receivers has simplified the design of the system. The matched filter has improved the signal to noise ratio of the receiver system and hence has become an important element in the communication system. This paper also presents the possible challenges; the matched filter design and simulation results in MATLAB have shown satisfactory outputs of the receiver.

Low Probability of Intercept Triangular Modulated Frequency Modulated Continuous Wave Signal Characterization Comparison Using the Wigner Ville Distribution and the Choi Williams Distribution

Digital intercept receivers are currently moving away from Fourier-based analysis and towards classical time frequency analysis techniques for the purpose of analyzing low probability of intercept radar signals. This paper presents the novel approach of characterizing low probability of intercept triangular modulated frequency modulated continuous wave radar signals through utilization and direct comparison of the Wigner Ville Distribution versus the Choi Williams Distribution. The following metrics were used for evaluation: percent error of: carrier frequency, modulation bandwidth, modulation period, chirp rate, and time-frequency localization (x and y direction). Also used were: percent detection, lowest signal-to noise ratio for signal detection, and plot (processing) time. Experimental results demonstrate that overall, the Wigner Ville Distribution produced more accurate characterization metrics than the Choi Williams Distribution. An improvement in performance may well translate into an increase in personnel safety.

Detecting and Receiving Phase-Modulated Signals With a Rydberg Atom-Based Receiver

Recently, we introduced a Rydberg-atom based mixer capable of detecting and measuring the phase of a radio-frequency field through the electromagnetically induced transparency (EIT) and Autler-Townes (AT) effect. The ability to measure phase with this mixer allows for an atom-based receiver to detect digital modulated communication signals. In this paper, we demonstrate detection and reception of digital modulated signals based on various phase-shift keying approaches. We demonstrate Rydberg atom-based digital reception of binary phase-shift keying (BPSK), quadrature phase-shift keying (QPSK), and quadrature amplitude (QAM) modulated signals over a 19.626~GHz carrier to transmit and receive a bit stream in cesium vapor. We present measured values of Error Vector Magnitude (EVM, a common communication metric used to assess how accurate a symbol or bit stream is received) as a function of symbol rate for BPSK, QPSK, 16QAM, 32QAM, and 64QAM modulation schemes. These results allow us to discuss the bandwidth of a Rydberg-atom based receiver system.

FPGA implementation of high performance digital down converter for software defined radio

Digital down converter (DDC) is one of the crucial components in digital radio receiver. The working function of DDC is to convert the frequency translation from Intermediate Frequency (IF) band to baseband signal. This paper briefs a hardware efficient DDC architecture which is made of COordinate Rotation Digital Computer (CORDIC) processor act as a digital oscillator followed by multi-stage Cascaded Integrator Comb (CIC) performs as a high rate decimation filter and then Multi-channel Systolic Finite Impulse Response (MSFIR) decimation filter allows perfect output. All of these components of the proposed DDC architecture have been designed in Xilinx ISE 14.7 simulator using optimization techniques and targeted to the Xilinx Kintex-7 Field Programmable Gate Array (FPGA) device. Implementation of DDC on FPGA provides high flexibility, moderate cost and customizability. The result analysis of the proposed DDC model is superior to the similar design with regard to area, operating speed and power consumption. The implemented DDC design is used to transform input bandwidth from about 70 MHz to 137 kHz, matching in Software Defined Radio (SDR) system requirements.

Millimeter-Wave Ultra Wideband Multilayer Superconducting Filter

Ultra wideband (UWB) millimeter-wave filters are needed in the realization of analog front ends of superconductor digital receivers. In this paper, a multi-layer niobium-based superconducting bandpass filter operating over the frequency range 30-60 GHz is demonstrated for the first time. The filter is realized in a co-planar waveguide structure, where cross-overs in the multilayer structure are employed to reduce the filter size. The paper also illustrates how these cross-overs can be utilized to fine tune the filter performance. An 8-pole superconductor niobium-based filter with a size of 0.88 × 2.2 mm designed with a center frequency of 45 GHz and a bandwidth of 30 GHz has been developed, fabricated, and tested. The results demonstrate the feasibility of monolithically integrating UWB millimeter-wave filters with a superconductor receiver on single-chip.

On Oversampling-Based Signal Detection

The availability of inexpensive devices allows nowadays to implement cognitive radio functionalities in large-scale networks such as the internet-of-things and future mobile cellular systems. In this paper, we focus on wideband spectrum sensing in the presence of oversampling, i.e., the sampling frequency of a digital receiver is larger than the signal bandwidth, where signal detection must take into account the front-end impairments of low-cost devices. Based on the noise model of a software-defined radio dongle, we address the problem of robust signal detection in the presence of noise power uncertainty and non-flat noise power spectral density (PSD). In particular, we analyze the receiver operating characteristic of several detectors in the presence of such front-end impairments, to assess the performance attainable in a real-world scenario. We propose new frequency-domain detectors, some of which are proven to outperform previously proposed spectrum sensing techniques such as, e.g., eigenvalue-based tests. The study shows that the best performance is provided by a noise-uncertainty immune energy detector (ED) and, for the colored noise case, by tests that match the PSD of the receiver noise.

Amplitude variance and 4th power transformation based modulation format identification for digital coherent receiver

This paper demonstrates the use of amplitude variance in combination with only one time of 4th power transformation and fast Fourier transform (FFT) for modulation format identification (MFI) in digital coherent receiver. The incoming signals are firstly classified into two main categories, polarization-division multiplexing (PDM) m-ary phase-shift keying modulation (mPSK) and m-ary quadrature amplitude modulation (mQAM), based on the amplitude variance after constant modulus algorithm (CMA) equalization. Then, the sub-categories of PDM-mPSK or PDM-mQAM are further identified by utilizing the logical regression (LR) algorithm on a two-dimensional (2-D) plane which is constructed by using the mean and maximum value after 4th power transformation and FFT. The feasibility is firstly verified via numerical simulation for 28GBaud/s PDM-QPSK/8PSK/16QAM/32QAM signals transmitted through additive Gaussian noise channel as well as long-distance standard single mode fiber (SSMF) channel. The simulation results demonstrate that 100% identification accuracy for all these modulation formats can be achieved at the optical signal noise ratio (OSNR) much lower than their respective 7% FEC thresholds and as high as 99% identification accuracy can be achieved even at the OSNR much lower or close to their respective 20% FEC thresholds. 100% identification accuracy can be also obtained in the presence of obviously nonlinear impairments. Proof-of-concept experiments are finally implemented to evaluate the MFI performance among 28GBaud/s PDM-QPSK/8PSK/16QAM, and 21.5GBaud/s PDM-32QAM signals, which further confirm the feasibility of our proposed MFI scheme.