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Design of multi-channel radio-frequency front-end for 200mhz parallel magnetic resonance imagingLiu, Xiaoqun 15 May 2009 (has links)
The increasing demands for improving magnetic resonance imaging (MRI)
quality, especially reducing the imaging time have been driving the channel number of
parallel magnetic resonance imaging (Parallel MRI) to increase. When the channel
number increases to 64 or even 128, the traditional method of stacking the same number
of radio-frequency (RF) receivers with very low level of integration becomes expensive
and cumbersome. However, the cost, size, power consumption of the Parallel MRI
receivers can be dramatically reduced by designing a whole receiver front-end even
multiple receiver front-ends on a single chip using CMOS technology, and multiplexing
the output signal of each receiver front-end into one channel so that as much hardware
resource can be shared by as many channels as possible, especially the digitizer.
The main object of this research is focused on the analysis and design of fully
integrated multi-channel RF receiver and multiplexing technology. First, different
architectures of RF receiver and different multiplexing method are analyzed. After
comparing the advantages and the disadvantages of these architectures, an architecture
of receiver front-end which is most suitable for fully on-chip multi-channel design is proposed and a multiplexing method is selected. According to this proposed architecture,
a four-channel receiver front-end was designed and fabricated using TSMC 0.18μm
technology on a single chip and methods of testing in the MRI system using parallel
planar coil array and phase coil array respectively as target coils were presented. Each
channel of the receiver front-end includes an ultra low noise amplifier (LNA), a
quadrature image rejection down-converter, a buffer, and a low-pass filter (LPF) which
also acts as a variable gain amplifier (VGA). The quadrature image rejection downconverter
consists of a quadrature generator, a passive mixer with a transimpedance
amplifier which converts the output current signal of the passive mixer into voltage
signal while acts as a LPF, and a polyphase filter after the TIA. The receiver has an over
NF of 0.935dB, variable gain from about 80dB to 90dB, power consumption of 30.8mW,
and chip area of 6mm2.
Next, a prototype of 4-channel RF receiver with Time Domain Multiplexing
(TDM) on a single printed circuit board (PCB) was designed and bench-tested. Then
Parallel MRI experiment was carried out and images were acquired using this prototype.
The testing results verify the proposed concepts.
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Sub-Nyquist Rate Sampling Data Acquisition Systems Based on Compressive SensingChen, Xi 2011 May 1900 (has links)
This dissertation presents the fundamental theory and design procedure of the sub-Nyquist rate sampling receiver front-end that exploits signal sparsity by employing Compressive Sensing (CS) techniques. The CS receiver serves as an Analog-to-Information Conversion (AIC) system that works at sampling rates much lower than the Nyquist rate. The performance of a parallel path CS front-end structure that employs current mode sampling techniques is quantified analytically. Useful and fundamental design guidelines that are unique to CS are provided based on the analytical tools. Simulations with IBM 90nm CMOS process verify the theoretical derivations and the circuit implementations. Based on these results, it is shown that instantaneous receiver signal bandwidth of 1.5 GHz and 44 dB of signal to noise plus distortion ratio (SNDR) are achievable in simulations assuming 0.5 ps clock jitter is present. The ADC and front-end core power consumption is estimated to be 120.8 mW. The front-end is fabricated with IBM 90nm CMOS process, and a BPSK sub-Nyquist rate communication system is realized as a prototype in the testing. A 1.25 GHz reference clock with 4.13 ps jitter variance is employed in the test bench. The signal frequency, phase and amplitude can be correctly reconstructed, and the maximum signal SNR obtained in the testing is 40 dB with single tone input and 30 dB with multi-tones test. The CS system has a better FOM than state-of-art Nyquist rate data acquisition systems taking into account the estimated PLL power.
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RF transceiver front-end design for testabilityLi, Lin January 2004 (has links)
<p>In this thesis, we analyze the performance of a loop-back built-in-self-test for a RF transceiver front-end. The tests aim at spot defects in a transceiver front-end and they make use of RF specifications such as NF (Noise Figure), G (power gain) and IIP3 (third order Intercept point). To enhance fault detectability, RF signal path sensitization is introduced. We use a functional RF transceiver model that is implemented in MatLab™ to verify this analysis.</p>
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RF front-end CMOS design for build-in-self-testKantasuwan, Thana January 2004 (has links)
<p>In this master degree work, a digital attenuator and a low noise amplifier (LNA) have been designed and integrated with the RF front-end receiver for IEEE 802.11b Wireless LAN standard. Firstly, the 4-bit digitally controlled attenuator has been designed with theattenuation range of 50 to 80 dB and reflection coefficient less than -25 dB. Next, the single stage wide band low noise amplifier with voltage gain larger than 14 dB and noise figure below 4 dB has been designed to operate at frequency 2.4 GHz. Finally, the integration with a down-conversion mixer has been done and evaluated its performance.</p><p>The attenuator and low noise amplifier desired in this thesis have been implemented using standard CMOS 0.35µm technology and validated by the simulation tools Cadence Spectre-RF.</p>
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Design Aspects of Fully Integrated Multiband Multistandard Front-End ReceiversAdiseno, January 2003 (has links)
In this thesis, design aspects of fully integrated multibandmultistandard front-end receivers are investigated based onthree fundamental aspects: noise, linearity and operatingfrequency. System level studies were carried out to investigatethe effects of different modulation techniques, duplexing andmultiple access methods on the noise, linearity and selectivityperformance of the circuit. Based on these studies and thelow-cost consideration, zero-IF, low-IF and wideband-IFreceiver architectures are promising architectures. These havea common circuit topology in a direct connection between theLNA and the mixer, which has been explored in this work toimprove the overall RF-to-IF linearity. One front-end circuitapproach is used to achieve a low-cost solution, leading to anew multiband multistandard front-end receiver architecture.This architecture needs a circuit whose performance isadaptable due to different requirements specified in differentstandards, works across several RF-bands and uses a minimumamount ofexternal components. Five new circuit topologies suitable for a front-endreceiver consisting of an LNA and mixer (low-noise converter orLNC) were developed. A dual-loop wide-band feedback techniquewas applied in all circuits investigated in this thesis. Threeof the circuits were implemented in 0.18 mm RF-CMOS and 25 GHzbipolar technologies. Measurement results of the circuitsconfirmed the correctness of the design approach. The circuits were measured in several RF-bands, i.e. in the900 MHz, 1.8 GHz and 2.4 GHz bands, with S11 ranging from9.2 dB to17 dB. The circuits have a typicalperformance of 18-20 dB RF-to-IF gain, 3.5-4 dB DSB NF and upto +4.5 dBm IIP3. In addition, the circuit performance can beadjusted by varying the circuits first-stage biascurrent. The circuits may work at frequencies higher than 3GHz, as only 1.5 dB of attenuation is found at 3 GHz and nopeaking is noticed. In the CMOS circuit, the extrapolated gainat 5 GHz is about 15 dB which is consistent with the simulationresult. The die-area of each of the circuits is less than 1mm2.
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Design and simulation of beam steering for 1D and 2D phased antenna arrays using ADS.Afridi, Muhammad Zeeshan, Umer, Muhammad, Razi, Daniyal January 2012 (has links)
Phased arrays eliminate the problems of mechanical steering by using fast and reliable electronic components for steering the main beam. Modeling and simulation of beam steering for 1D and 2D arrays is the aspect that is considered in this thesis. A 1D array with 4 elements and a 2D array with 16 elements are studied in the X-band (8-12 GHz). The RF front-end of a phased array radar is modeled by means of ADS Momentum (Advanced design system).
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RF transceiver front-end design for testabilityLi, Lin January 2004 (has links)
In this thesis, we analyze the performance of a loop-back built-in-self-test for a RF transceiver front-end. The tests aim at spot defects in a transceiver front-end and they make use of RF specifications such as NF (Noise Figure), G (power gain) and IIP3 (third order Intercept point). To enhance fault detectability, RF signal path sensitization is introduced. We use a functional RF transceiver model that is implemented in MatLab™ to verify this analysis.
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RF front-end CMOS design for build-in-self-testKantasuwan, Thana January 2004 (has links)
In this master degree work, a digital attenuator and a low noise amplifier (LNA) have been designed and integrated with the RF front-end receiver for IEEE 802.11b Wireless LAN standard. Firstly, the 4-bit digitally controlled attenuator has been designed with theattenuation range of 50 to 80 dB and reflection coefficient less than -25 dB. Next, the single stage wide band low noise amplifier with voltage gain larger than 14 dB and noise figure below 4 dB has been designed to operate at frequency 2.4 GHz. Finally, the integration with a down-conversion mixer has been done and evaluated its performance. The attenuator and low noise amplifier desired in this thesis have been implemented using standard CMOS 0.35µm technology and validated by the simulation tools Cadence Spectre-RF.
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A Highly Linear Broadband LNAPark, Joung Won 2009 August 1900 (has links)
In this work, a highly linear broadband Low Noise Amplifier (LNA) is presented.
The linearity issue in broadband Radio Frequency (RF) front-end is introduced, followed
by an analysis of the specifications and requirements of a broadband LNA through
consideration of broadband, multi-standard front-end design. Metal-Oxide-
Semiconductor Field-Effect Transistor (MOSFET) non-linearity characteristics cause
linearity problems in the RF front-end system. To solve this problem, feedback and the
Derivative Superposition Method linearized MOSFET. In this work, novel linearization
approaches such as the constant current biasing and the Derivative Superposition
Method using a triode region transistor improve linearization stability against Process,
Supply Voltage, and Temperature (PVT) variations and increase high power input
capability. After analyzing and designing a resistive feedback LNA, novel linearization
methods were applied. A highly linear broadband LNA is designed and simulated in
65nm CMOS technology. Simulation results including PVT variation and the Monte
Carlo simulation are presented. We obtained -10dB S11, 9.77dB S21, and 4.63dB Noise
Figure with IIP3 of 19.18dBm for the designed LNA.
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A CMOS radio-frequency front-end for multi-standard wireless communicationsCha, Jeongwon 26 August 2010 (has links)
The explosive growth of wireless communication market has led the development of low-cost, highly-integrated wireless communication systems. Even though most blocks in the front-end have successfully been integrated by using the CMOS technology, it is still a formidable challenge to integrate the entire front-end. Thus, the objective of this research is to demonstrate the feasibility of the integrated front-end by using improved circuit techniques as well as the improved process technologies. This dissertation proposes an improved control scheme to enhance the high-power handling capability of an antenna switch.
As a part of this research, an antenna switch controller for a GaAs antenna switch was first developed to enhance the performances of the GaAs antenna switch by using the boosted control voltage. To enhance the efficiency of the front-end, efficiency improvement techniques for the antenna switch controller has also been studied. With the suggested efficiency improvement techniques, a fully-integrated antenna switch was implemented using the SOI technology, and exceeding performances over many commercial products for watt-level high-power applications have been successfully demonstrated. As an effort to improve the efficiency of a power amplifier, a linear envelope detector was also implemented, and the results show that the envelope detector is suitable for dynamic biasing of the power amplifier. The research presented in this dissertation, thus, provides a low-cost and high-performance solution for highly-integrated RF front-end used in various wireless communication systems.
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