An Op-Amp Approach for Bandpass VGAs With Constant Bandwidth

Two approaches to implement variable gain amplifiers based on Miller op-amps are discussed. One has true constant bandwidth while the other has essentially reduced bandwidth variations with varying gain. Servo-loops and ac coupling techniques with quasi floating gate transistors are used to provide a bandpass response with very low cutoff frequency in the range of hertz. In practice, one of the schemes is shown to have bandwidth variations close to a factor two while the second one has true constant bandwidth over the gain tuning range. Experimental results of test chip prototypes in 180-nm CMOS technology verify the theoretical claims

IF-Sampling Digital Beamforming with Bit-Stream Processing.

Beamforming in receivers improves signal-to-noise ratio (SNR), and enables spatial filtering of incoming signals, which helps reject interferers. However, power consump-tion, area, and routing complexity needed with an increasing number of elements have been a bottleneck to implementing efficient beamforming systems. Especially, digital beamforming (DBF), despite its versatility, has not been attractive for low-cost on-chip implementation due to its high power consumption and large die area for multiple high-performance analog-to-digital converters (ADCs) and an intensive digital signal process-ing (DSP) unit. This thesis presents a new DBF receiver architecture with direct intermediate frequency (IF) sampling. By adopting IF sampling in DBF, a digital-intensive beamforming receiver, which provides highly flexible and accurate beamforming, is achieved. The IF-sampling DBF receiver architecture is efficiently implemented with continuous-time band-pass delta-sigma modulators (CTBPDSMs) and bit-stream processing (BSP). They have been separately investigated, and have not been considered for DBF until now. The unique combination of CTBPDSMs and BSP enables low-power and area-efficient DBF by removing the need for digital multipliers and multiple decimators. Two prototype digital beamformers (prototype I and prototype II) are fabricated in 65 nm complementary metal-oxide-semiconductor (CMOS) technology. The prototype I forms a single beam from four 265 MHz IF inputs, and an array signal-to-noise-plus-distortion ratio (SNDR) of 56.6 dB is achieved over a 10 MHz bandwidth. The prototype I consumes 67.2 mW, and occupies 0.16 mm2. The prototype II forms two simultaneous beams from eight 260 MHz IF inputs, and an array SNDR of 63.3 dB is achieved over a 10 MHz bandwidth. The prototype II consumes 123.7 mW, and occupies 0.28 mm2. The two prototypes are the first on-chip implementation of IF-sampling DBF.PhDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/116778/1/jaehun_1.pd

Integrated Circuits for Medical Ultrasound Applications: Imaging and Beyond

Medical ultrasound has become a crucial part of modern society and continues to play a vital role in the diagnosis and treatment of illnesses. Over the past decades, the develop- ment of medical ultrasound has seen extraordinary progress as a result of the tremendous research advances in microelectronics, transducer technology and signal processing algorithms. How- ever, medical ultrasound still faces many challenges including power-efficient driving of transducers, low-noise recording of ultrasound echoes, effective beamforming in a non-linear, high- attenuation medium (human tissues) and reduced overall form factor. This paper provides a comprehensive review of the design of integrated circuits for medical ultrasound applications. The most important and ubiquitous modules in a medical ultrasound system are addressed, i) transducer driving circuit, ii) low- noise amplifier, iii) beamforming circuit and iv) analog-digital converter. Within each ultrasound module, some representative research highlights are described followed by a comparison of the state-of-the-art. This paper concludes with a discussion and recommendations for future research directions

Design of linear transmitters for wireless applications

Wireless standards for high data-rate communications typically employ complex modulation schemes that have large peak-to-average power ratios (PAPR), along with a significant bandwidth requirement. Transmitters for such applications often employ off-chip power amplifiers (PAs), that are typically operated in back-off, such that the peak output power is less than the output 1-dB compression point (P1dB), in order to minimize distortion. In mobile systems, architectures that can enhance the linearity of the transmit chain are highly attractive since these can reduce the PA's back-off requirement, which helps to enhance efficiency. In this dissertation, linearization techniques for mobile transmitters are explored. A Cartesian feedback-feedforward transmitter is proposed for linearity enhancement. The transmit path in the architecture is placed in a Cartesian feedback loop. The feedback error signal is applied to a Cartesian feedforward path for further linearity improvement. Linearity of the feedback-feedforward system is analyzed by using a Volterra series representation. System simulations using two-tone signals and modulated signals are also presented and are used to verify the linearity enhancement provided by the proposed architecture. A prototype transmitter IC that employs the Cartesian feedback-feedforward approach is implemented in a 0.13 μm CMOS process. Design considerations for critical transmitter circuits are discussed. A proof-of-concept Cartesian feedback-feedforward architecture that includes the prototype IC and external components is demonstrated. The implementation allows for a 8.7 dB improvement in the adjacent channel leakage ratio (ACLR), compared to an open-loop transmitter, for an output power of 16.6 dBm at 2.4 GHz while employing a 16-QAM LTE signal with 1.4 MHz bandwidth. The linearity of the Cartesian feedback-feedforward system is found to depend primarily on the loop gain of the Cartesian feedback and the linearity of the Cartesian feedforward path, which introduces a trade-off with power consumption. To enhance the linearity of the Cartesian feedback-feedforward transmitter even further within the Cartesian feedback loop, two modified Cartesian feedback-feedforward architectures are explored. System simulations show that both modified configurations can help to enhance linearity compared to the above Cartesian feedback-feedforward transmitter.Electrical and Computer Engineerin

Channelization Techniques For Wideband Radios

University of Minnesota Ph.D. dissertation. May 2017. Major: Electrical Engineering. Advisor: Ramesh Harjani. 1 computer file (PDF); x, 110 pages.From the very start of mobile communications, wireless data traffic volume and the number of applications have increased continuously and this continued increase will eventually necessitate the use of wider signal bandwidths by the fundamental constraints imposed by Shannon’s theorem. Additionally, the air channel is a common limited resource that is shared by all users and applications. While this limited wireless resource has mostly been pre-allocated, the utilization at any given time is often very low. For this environment, cognitive radio and carrier aggregation are potential solutions. Both cognitive radio and carrier aggregation require the processing of wideband signals unlike what is normally the focus of conventional narrow band receivers. This, in turn, makes it necessary to design receivers with a large BW and high dynamic range, and these conflicting requirements typically form the bottleneck in existing systems. Here, we discuss channelization techniques using an analog FFT (fast Fourier transform) to solve the bottleneck. First, a fully integrated hybrid filter bank ADC using an analog FFT is presented. The proposed structure enables the signals in each channel of a wideband system to be separately digitized using the full dynamic range of the ADC, so the small signals in wideband can benefit in terms of lowered quantization noise while accommodating large in-band signals. The prototype which is implemented in TSMC’s 40nm CMOS GP process with VGA gains ranging from 1 to 4 shows 90.4mW total power consumption for both the analog and digital sections. Second, analog polyphase-FFT technique is introduced. Polyphase-FFT allows for low power implementations of high performance multi-channel filter banks by utilizing computation sharing not unlike a standard FFT. Additionally, it enables a longer “effective window length” than is possible in a standard FFT. This characteristic breaks the trade-off between the main-lobe width and the side-lobe amplitudes in normal finite impulse response (FIR) filters. The 4-channel I/Q prototype is implemented in TSMC’s 65nm GP technology. The measured trans- fer function shows >38dB side-lobe suppression at 1GS/s operation. The average measured IIP3 is +25dBm differential power and the total integrated output noise is 208µVrms. The total power consumption for the polyphase-FFT filter bank (8- channels total) is 34.6mW (34.6pJ/conv)

Microwave and Millimeter-Wave Multi-Band Power Amplifiers, Power Combining Networks, and Transmitter Front-End in Silicon Germanium BiCMOS Technology

This dissertation presents new circuit architectures and techniques for designing high performance microwave and millimeter-wave circuits using 0.18-µm SiGe BiCMOS process for advanced wireless communication and sensing systems. The high performance single- and multi-band power amplifiers working in microwave and millimeter-wave frequency ranges are proposed. A 10-19, 23-39, and 33-40 GHz concurrent tri-band power amplifier in the respective Ku-, K-, and Ka-band using the distributed amplifier structure is presented first. Instead of utilizing multi-band matching networks, this amplifier is realized based on distributed amplifier structure and two active notch filters employed at each gain cell to form tri-band response. In addition, a power amplifier operating across the entire K-band is proposed. By employing lumped-element Wilkinson power divider and combiner, it produces high output power, high gain, and power added efficiency characteristics over broadband due to its inherent low-pass filtering response. Moreover, a highly integrated V-band power amplifier is presented. This power amplifier consists of four medium unit power cells combined with a four-way parallel power combining network. Secondly, microwave and millimeter-wave power combining and dividing networks are proposed. A wideband power divider and combiner operating up to 67 GHz is developed by adopting capacitive loading slow-wave transmission line to reduce size as well as insertion loss. Also, two-way and 16-way 24/60 GHz dual-band power divider networks in the K/V-band are proposed. The two-way dual-band power divider is realized with a slow-wave transmission line and two shunt connected LC resonators in order to minimize the chip size as well as insertion loss. Furthermore, a 16-way dual-band power dividing and combining network is developed for a dual-band 24/60 GHz 4×4 array system. This network incorporates a two-way dual-band power divider, lumped-element based Wilkinson power dividers, and multi-section transmission line based Wilkinson structures. Finally, a K-/V-band dual-band transmitter front-end is proposed. To realize the transmitter, a diplexer with good diplexing performance and K- and V-band variable gain amplifiers having low phase variation with gain tuning are designed. The transmitter is integrated with two diplexers, K- and V-band variable gain amplifiers, and two power amplifiers resulting in high gain, high output power, and low-phase variation with all gain control stages

A LINEARIZATION METHOD FOR A UWB VCO-BASED CHIRP GENERATOR USING DUAL COMPENSATION

Ultra-Wideband (UWB) chirp generators are used on Frequency Modulated Continuous Wave (FMCW) radar systems for high-resolution and high-accuracy range measurements. At the Center for Remote Sensing of Ice Sheets (CReSIS), we have developed two UWB radar sensors for high resolution measurements of surface elevation and snow cover over Greenland and Antarctica. These radar systems are routinely operated from both surface and airborne platforms. Low cost implementations of UWB chirp generators are possible using an UWB Voltage Controlled Oscillator (VCO). VCOs possess several advantages over other competing technologies, but their frequency-voltage tuning characteristics are inherently non-linear. This nonlinear relationship between the tuning voltage and the output frequency should be corrected with a linearization system to implement a linear frequency modulated (LFM) waveform, also known as a chirp. If the waveform is not properly linearized, undesired additional frequency modulation is found in the waveform. This additional frequency modulation results in undesired sidebands at the frequency spectrum of the Intermediate Frequency (IF) stage of the FMCW radar. Since the spectrum of the filtered IF stage represents the measured range, the uncorrected nonlinear behavior of the VCO will cause a degradation of the range sensing performance of a FMCW radar. This issue is intensified as the chirp rate and nominal range of the target increase. A linearization method has been developed to linearize the output of a VCO-based chirp generator with 6 GHz of bandwidth. The linearization system is composed of a Phase Lock Loop (PLL) and an external compensation added to the loop. The nonlinear behavior of the VCO was treated as added disturbances to the loop, and a wide loop bandwidth PLL was designed for wideband compensation of these disturbances. Moreover, the PLL requires a loop filter able to attenuate the reference spurs. The PLL has been designed with a loop bandwidth as wide as possible while maintaining the reference spur level below 35 dBc. Several design considerations were made for the large loop bandwidth design. Furthermore, the large variations in the tuning sensitivity of the oscillator forced a design with a large phase margin at the average tuning sensitivity. This design constraint degraded the tracking performance of the PLL. A second compensation signal, externally generated, was added to the compensation signal of the PLL. By adding a compensation signal, which was not affected by the frequency response effects of the loop compensation, the loop tracking error is reduced. This technique enabled us to produce an output chirp signal that is a much closer replica of the scaled version of the reference signal. Furthermore, a type 1 PLL was chosen for improved transient response, compared to that of the type 2 PLL. This type of PLL requires an external compensation to obtain a finite steady state error when applying a frequency ramp to the input. The external compensation signal required to solve this issue was included in the second compensation signal mentioned above. Measurements for the PLL performance and the chirp generator performance were performed in the laboratory using a radar demonstrator. The experimental results show that the designed loop bandwidth was successfully achieved without significantly increasing the spurious signal level. The chirp generator measurements show a direct relationship between the bandwidth of the external compensation and the range resolution performance

Advancements in Multinuclear Multichannel NMR and MRI

The introduction of receive arrays revolutionized ^1H MRI and in vivo NMR by increasing SNR and enabling accelerated imaging. All MRI scanners manufactured today are equipped to receive signals from ^1H array coils, but few support multi-channel reception for other nuclei. The extension of receive arrays to non^1H nuclei has proven difficult because of the lack of broadband array receivers. These nuclei often have low sensitivity and stand to benefit greatly from the increase in SNR arrays provide. This dissertation presents a variety of technologies that have been developed to enable the development and use of X-nuclear and multi-nuclear arrays. Frequency conversion receiver front-ends provide a straightforward and cost-effective approach for adapting standard ^1H multi-channel array receivers for use with other nuclei. Two generations of frequency translation receiver front-ends have been developed that use active mixers to convert the received signal from a non^1H array to the ^1H frequency for reception by the host system receiver. This first-generation system has been demonstrated on 4.7T and 7T systems without any decrease in SNR as compared to the stock systems, and has been shown to be capable of accommodating ^1H decoupling. The second-generation receiver was developed to add the capability to simultaneously convert signals received from multiple nuclei as well as to streamline the setup and use of the translation system. Frequency translation has been shown to be able to convert ^1H-only multi-channel receivers for use with other nuclei with minimal degradation of SNR. In addition, a standalone broadband system capable of simultaneous multi-nuclear imaging and spectroscopy at 1T and 4.7T has been developed. This system can either operate completely independently or interface with existing systems. The broadband system has been demonstrated with simultaneous imaging and spectroscopy of three nuclei. This work allows existing multi-channel MRI receivers to be adapted to receive signals from nuclei other than hydrogen, allowing for the use of receive arrays for in vivo multi-nuclear NMR