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Efficient antenna based interference cancellation systems for narrowband and broadband signalsPonnekanti, S. January 1995 (has links)
No description available.
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EXTREME PROCESSORS FOR EXTREME PROCESSING : STUDY OF MODERATELY PARALLEL PROCESSORSBangsgaard, Christian, Erlandsson, Tobias, Örning, Alexander January 2005 (has links)
<p>Future radars require more flexible and faster radar signal processing chain than commercial radars of today. This means that the demands on the processors in a radar signal system, and the desire to be able to compute larger amount of data in lesser time, is constantly increasing. This thesis focuses on commercial micro-processors of today that can be used for Active Electronically Scanned Array Antenna (AESA) based radar, their physical size, power consumption and performance must to be taken into consideration. The evaluation is based on theoretical comparisons among some of the latest processors provided by PACT, PicoChip, Intrinsity, Clearspeed and IBM. The project also includes a benchmark made on PowerPC G5 from IBM, which shows the calculation time for different Fast Fourier Transforms (FFTs). The benchmark on the PowerPC G5 shows that it is up to 5 times faster than its predecessor PowerPC G4 when it comes to calculate FFTs, but it only consumes twice the power. This is due to the fact that PowerPC G5 has a double word length and almost twice the frequency. Even if this seems as a good result, all the PowerPC´s that are needed to reach the performance for an AESA radar chain would consume too much power. The thesis ends up with a discussion about the traditional architectures and the new multi-core architectures. The future belongs with almost certainty to some kind of multicore processor concept, because of its higher performance per watt. But the traditional single core processor is probably the best choice for more moderate-performance systems of today, if you as developer looking for a traditional way of programing processors.</p>
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EXTREME PROCESSORS FOR EXTREME PROCESSING : STUDY OF MODERATELY PARALLEL PROCESSORSBangsgaard, Christian, Erlandsson, Tobias, Örning, Alexander January 2005 (has links)
Future radars require more flexible and faster radar signal processing chain than commercial radars of today. This means that the demands on the processors in a radar signal system, and the desire to be able to compute larger amount of data in lesser time, is constantly increasing. This thesis focuses on commercial micro-processors of today that can be used for Active Electronically Scanned Array Antenna (AESA) based radar, their physical size, power consumption and performance must to be taken into consideration. The evaluation is based on theoretical comparisons among some of the latest processors provided by PACT, PicoChip, Intrinsity, Clearspeed and IBM. The project also includes a benchmark made on PowerPC G5 from IBM, which shows the calculation time for different Fast Fourier Transforms (FFTs). The benchmark on the PowerPC G5 shows that it is up to 5 times faster than its predecessor PowerPC G4 when it comes to calculate FFTs, but it only consumes twice the power. This is due to the fact that PowerPC G5 has a double word length and almost twice the frequency. Even if this seems as a good result, all the PowerPC´s that are needed to reach the performance for an AESA radar chain would consume too much power. The thesis ends up with a discussion about the traditional architectures and the new multi-core architectures. The future belongs with almost certainty to some kind of multicore processor concept, because of its higher performance per watt. But the traditional single core processor is probably the best choice for more moderate-performance systems of today, if you as developer looking for a traditional way of programing processors.
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Ultra wideband antenna array processing under spatial aliasingShapoury, Alireza 15 May 2009 (has links)
Given a certain transmission frequency, Shannon spatial sampling limit de¯nes
an upper bound for the antenna element spacing. Beyond this bound, the exceeded
ambiguity avoids correct estimation of the signal parameters (i.e., array manifold
crossing). This spacing limit is inversely proportional to the frequency of transmis-
sion. Therefore, to meet a wider spectral support, the element spacing should be
decreased. However, practical implementations of closely spaced elements result in a
detrimental increase in electromagnetic mutual couplings among the sensors. Further-
more, decreasing the spacing reduces the array angle resolution. In this dissertation,
the problem of Direction of Arrival (DOA) estimation of broadband sources is ad-
dressed when the element spacing of a Uniform Array Antenna (ULA) is inordinate.
It is illustrated that one can resolve the aliasing ambiguity by utilizing the frequency
diversity of the broadband sources. An algorithm, based on Maximum Likelihood
Estimator (MLE), is proposed to estimate the transmitted data signal and the DOA
of each source. In the sequel, a subspace-based algorithm is developed and the prob-
lem of order estimation is discussed. The adopted signaling framework assumes a
subband hopping transmission in order to resolve the problem of source associations
and system identi¯cation. The proposed algorithms relax the stringent maximum
element-spacing constraint of the arrays pertinent to the upper-bound of frequency
transmission and suggest that, under some mild constraints, the element spacing can be conveniently increased. An approximate expression for the estimation error has
also been developed to gauge the behavior of the proposed algorithms. Through con-
¯rmatory simulation, it is shown that the performance gain of the proposed setup
is potentially signi¯cant, speci¯cally when the transmitters are closely spaced and
under low Signal to Noise Ratio (SNR), which makes it applicable to license-free
communication.
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Wideband phased array antennas and compact, harmonic-suppressed microstrip filtersTu, Wen-Hua 15 May 2009 (has links)
Modern satellite, wireless communications, and radar systems often demand
wideband performance for multi-channel and multi-function operations. Among these
applications, phased array antennas play an important role. This dissertation covers two
wideband phased array antennas, one produces linear polarization and one produces
circular polarization. The main difference between these two phased array antennas is
the antenna array. For the linearly polarized array, a wideband microstrip line to slotline
transition is used to feed a Vivaldi antenna. For the circularly polarized array, a
wideband microstrip line to parallel stripline transition is used to feed a spiral antenna.
From 3 to 12 GHz, the linearly polarized beam is steered over ± 15º.
Since the electromagnetic spectrum is limited and has to be shared, interference is
getting serious as more and more wireless applications emerge. Filters are key
components to prevent harmonic interference. The harmonic signals can be suppressed
by cascading additional lowpass filters or bandstop filters. A bandstop filter combining
shunt open stubs and a spurline is proposed for a compact size and a deeper rejection.
Two lowpass filters with interdigital capacitors and slotted ground structures are also studied.
Harmonic suppression can also be achieved with the modification of bandpass
filters. Three conventional bandpass filters with spurious passbands are investigated. The
first one is a dual-mode patch bandpass filter. The second passband of the proposed filter
is at 2.88fo, where fo is the fundametal frequency. The second filter is an open-loop
bandpass filter. Two open stubs are added to achieve high suppression in the second
harmonic signal. The suppression of 35 dB at the second harmonic is obtained. For the
third filter using half-wavelength open stubs, a T-shaped line is used to replace the
quarter-wavelength connecting line. The T-shaped line has the same response with the
connecting line in the passband. Furthermore, the T-shaped line works as a bandstop
filter at the second harmonic.
Finally, a new compact slow-wave resonator and bandpass filters are presented. A
simple transmission-line model is used to predict the resonant frequency. Compared with
the conventional uniform half-wavelength resonator, the slow-wave resonator shows a
25% size reduction.
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Receiving Frequency Diverse Array Antenna for Tracking Low Earth Orbit SatellitesElbelazi, Issa January 2020 (has links)
No description available.
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AN AIRBORNE TELEMETRY RELAY SYSTEM FOR THE GULF RANGEZoledziowski, Severyn 10 1900 (has links)
International Telemetering Conference Proceedings / October 13-16, 1986 / Riviera Hotel, Las Vegas, Nevada / The Airborne Platform Telemetry Relay System (AP/TM) is currently being built for the Gulf Range Instrumentation System. The AP/TM will allow air-to-air missile test and training missions to be conducted beyond the line-of-sight of land-based instrumentation.
The AP/TM is comprised of the following subsystems:
C a Telemetry Data Relay C a Sea Surveillance Radar and Radar Data Link C a Drone Control Relay C a UHF Radio Relay
The Telemetry Data Relay Subsystem will receive telemetry signals from five independent sources and will retransmit them to land based receiving sites. This subsystem contains a 75 square foot, electronically steerable, five beam phased array antenna and uses polarization diversity to eliminate polarization mismatch loss and to improve reception in the presence of multipath propagation.
The AP/TM will also have the capability of relaying four channels of voice communications and drone tracking data and to perform sea surveillance of the mission area. The coordinates of targets detected by the radar will be relayed to the range control center over a high frequency (HF) data link.
In addition to the airborne equipment, the system also includes a ground support instrumentation van which is used for pre- and post-flight checkout and maintenance.
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Single-band and Dual-band Beam Switching Systems and Offset-fed Beam Scanning ReflectarrayLee, Jungkyu 2012 May 1900 (has links)
The reflectarray has been considered as a suitable candidate to replace the conventional parabolic reflectors because of its high-gain, low profile, and beam reconfiguration capability. Beam scanning capability and multi-band operation of the microstrip reflectarray have been main research topics in the reflectarray design. Narrow bandwidth of the reflectarray is the main obstacle for the various uses of the reflectarray. The wideband antenna element with a large phase variation range and a linear phase response is one of the solutions to increase the narrow bandwidth of the reflectarray.
A four beam scanning reflectarray has been developed. It is the offset-fed microstrip reflectarray that has been developed to emulate a cylindrical reflector. Unlike other microstrip reflectarrays which integrates phase tuning devices such as RF MEMS switches and another phase shifters to the reflectarray elements and control the reflected phase, the beam scanning capability of the reflectarray is implemented by a phased array feed antenna. This method can reduce the complexity of the design of the beam switching reflectarray. A simple method has been investigated to develop multi-band elements in this dissertation. In approach to increase the coverage of the operation bands, a six-band reflectarray has been developed with two layers. Each layer covers three frequency bands.
A Butler matrix is one of the useful beamforming networks for a phased array antenna. A Double-Sided Parallel-Strip Line (DSPSL) is adapted for the feeding network of eight array elements. The DSPSL operate very well to feed the microstrip antenna array over the bandwidth to reduce the sidelobe level and a high gain. In another topic of a Butler matrix, a dual-band Butler matrix has been proposed for multi-band applications. A modified Butler matrix is used to reduce a size and a sidelobe level.
The bandwidth of the microstrip antenna is inherently small. A broadband circularly polarized microstrip antenna with dual-offset feedlines is introduced in this dissertation. Aperture-coupled feed method is used to feed the stacked patch antennas and a slotcoupled
directional coupler is used for the circularly polarized operation.
The research presented in this dissertation suggests useful techniques for a beam scanning microstrip reflectarray, phased array antenna, and wideband antenna designs in the modern wireless communication systems.
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Optical and Microwave Beamforming for Phased Array AntennasFakharzadeh Jahromi, Mohammad 24 November 2008 (has links)
Phased array antenna has been used for a variety of military and civil applications, over the past five decades. Being structurally conformal and flexible, phased array antenna is highly suitable for
mobile applications. Besides, it can form the agile or shaped beams required for interference cancellation or multifunction systems. Moreover, the spatial power combination property increases the
effective radiated power of a transmitter phased array system. Similarly, in a receiver phased array, beamforming increases the signal to noise ratio by coherent integration of the desired signals.
Despite its impressive potentials and properties, phased array antenna has not become a commercial product yet. Cost and complexity of phased array antenna are beyond the scales of consumer electronics devices. Furthermore, calibration is an essential requirement of such a complex system, which is a fairly time-consuming process and requires skilled man power. Moreover, the narrow bandwidth of microwave components degrades the broadband performance of phased array system. Finally, the majority of the beamforming algorithms developed so far have preconditions, which
make them unsuitable for a low-cost system.
The objective of this thesis is to provide a novel cost-effective solution to minimize the system complexity of the future intelligent antenna systems, without sacrificing the performance. This research demonstrates that a powerful, robust beamforming algorithm, integrated in an efficient single-receiver architecture, constitutes the essence of a low-cost phased array antenna. Thus, a novel beamforming technique, called Zero-knowledge algorithm is
developed. It is investigated, both theoretically and experimentally, that the proposed algorithm can compensate for the
hardware errors and imperfections of the low-cost components of the system.
Zero-knowledge beamforming algorithm possesses significant properties. Neither a priori knowledge of the incoming signal
direction, nor the exact characteristics of the phase control network are required in this method. Proper adjustment of the
parameters, makes this algorithm appropriate for mobile systems, particularly those installed on vehicles. The algorithm alleviates the drawbacks of analog phase shifters, such as imbalanced insertion
loss and fabrication tolerances. Furthermore, this algorithm can serve as the core of a direction-of-arrival estimation technique, which senses the minor deflections of the array heading.
For broadband applications optical delay lines must be used in the phase control network of the phased array systems, which are costly. Nevertheless, employing miniaturized delay lines can significantly
reduce the device area, and consequently, the fabrication cost. Thus, in this research four types of miniaturized optical delay
lines, designed in slow-wave structures, are analyzed, which can provide a large delay per length. In addition, two novel optical
beamforming techniques, based upon the properties of Zero-knowledge algorithm, are developed for transmitter and receiver phased arrays.
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Optical and Microwave Beamforming for Phased Array AntennasFakharzadeh Jahromi, Mohammad 24 November 2008 (has links)
Phased array antenna has been used for a variety of military and civil applications, over the past five decades. Being structurally conformal and flexible, phased array antenna is highly suitable for
mobile applications. Besides, it can form the agile or shaped beams required for interference cancellation or multifunction systems. Moreover, the spatial power combination property increases the
effective radiated power of a transmitter phased array system. Similarly, in a receiver phased array, beamforming increases the signal to noise ratio by coherent integration of the desired signals.
Despite its impressive potentials and properties, phased array antenna has not become a commercial product yet. Cost and complexity of phased array antenna are beyond the scales of consumer electronics devices. Furthermore, calibration is an essential requirement of such a complex system, which is a fairly time-consuming process and requires skilled man power. Moreover, the narrow bandwidth of microwave components degrades the broadband performance of phased array system. Finally, the majority of the beamforming algorithms developed so far have preconditions, which
make them unsuitable for a low-cost system.
The objective of this thesis is to provide a novel cost-effective solution to minimize the system complexity of the future intelligent antenna systems, without sacrificing the performance. This research demonstrates that a powerful, robust beamforming algorithm, integrated in an efficient single-receiver architecture, constitutes the essence of a low-cost phased array antenna. Thus, a novel beamforming technique, called Zero-knowledge algorithm is
developed. It is investigated, both theoretically and experimentally, that the proposed algorithm can compensate for the
hardware errors and imperfections of the low-cost components of the system.
Zero-knowledge beamforming algorithm possesses significant properties. Neither a priori knowledge of the incoming signal
direction, nor the exact characteristics of the phase control network are required in this method. Proper adjustment of the
parameters, makes this algorithm appropriate for mobile systems, particularly those installed on vehicles. The algorithm alleviates the drawbacks of analog phase shifters, such as imbalanced insertion
loss and fabrication tolerances. Furthermore, this algorithm can serve as the core of a direction-of-arrival estimation technique, which senses the minor deflections of the array heading.
For broadband applications optical delay lines must be used in the phase control network of the phased array systems, which are costly. Nevertheless, employing miniaturized delay lines can significantly
reduce the device area, and consequently, the fabrication cost. Thus, in this research four types of miniaturized optical delay
lines, designed in slow-wave structures, are analyzed, which can provide a large delay per length. In addition, two novel optical
beamforming techniques, based upon the properties of Zero-knowledge algorithm, are developed for transmitter and receiver phased arrays.
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