A 5-Gb/s 66 dB CMOS variable-gain amplifier with reconfigurable DC-offset cancellation for multi-standard applications

This paper proposes a variable gain amplifier (VGA) with reconfigurable DC-offset cancellation (DCOC) for multi-standard applications. In this design, a cell-based design method and some bandwidth extension technologies are adopted to achieve a high data rate and a wide gain control range simultaneously. In addition, the DCOC having a tunable lower-cutoff frequency can make an optimum compromise between BER and SNR according to the specified baseband standard. The measurements show that the VGA achieves a gain control range from −6 dB to 60 dB, a bandwidth beyond 3 GHz, and a tunable lower-cutoff frequency from 0 to 300 kHz. When entering a 2 23 −1 pseudo-random bit sequence signal at 5 Gb/s, the VGA consumes 17 mW from a 1.2-V supply and the output data peak-to-peak jitter is less than 40 ps. The VGA is fabricated in a 90-nm CMOS process with a chip size (including all pads) of 0.52×0.5 mm 2

HIGH LINEARITY UNIVERSAL LNA DESIGNS FOR NEXT GENERATION WIRELESS APPLICATIONS

Design of the next generation (4G) systems is one of the most active and important area of research and development in wireless communications. The 2G and 3G technologies will still co-exist with the 4G for a certain period of time. Other applications such as wireless LAN (Local Area Network) and RFID are also widely used. As a result, there emerges a trend towards integrating multiple wireless functionalities into a single mobile device. Low noise amplifier (LNA), the most critical component of the receiver front-end, determines the sensitivity and noise figure of the receiver and is indispensable for the complete system. To satisfy the need for higher performance and diversity of wireless communication systems, three LNAs with different structures and techniques are proposed in the thesis based on the 4G applications. The first LNA is designed and optimized specifically for LTE applications, which could be easily added to the existing system to support different standards. In this cascode LNA, the nonlinearity coming from the common source (CS) and common gate (CG) stages are analyzed in detail, and a novel linear structure is proposed to enhance the linearity in a relatively wide bandwidth. The LNA has a bandwidth of 900MHz with the linearity of greater than 7.5dBm at the central frequency of 1.2GHz. Testing results show that the proposed structure effectively increases and maintains linearity of the LNA in a wide bandwidth. However, a broadband LNA that covers multiple frequency ranges appears more attractive due to system simplicity and low cost. The second design, a wideband LNA, is proposed to cover multiple wireless standards, such as LTE, RFID, GSM, and CDMA. A novel input-matching network is proposed to relax the tradeoff among noise figure and bandwidth. A high gain (>10dB) in a wide frequency range (1-3GHz) and a minimum NF of 2.5dB are achieved. The LNA consumes only 7mW on a 1.2V supply. The first and second LNAs are designed mainly for the LTE standard because it is the most widely used standard in the 4G communication systems. However, WiMAX, another 4G standard, is also being widely used in many applications. The third design targets on covering both the LTE and the WiMAX. An improved noise cancelling technique with gain enhancing structure is proposed in this design and the bandwidth is enlarged to 8GHz. In this frequency range, a maximum power gain of 14.5dB and a NF of 2.6-4.3dB are achieved. The core area of this LNA is 0.46x0.67mm2 and it consumes 17mW from a 1.2V supply. The three designs in the thesis work are proposed for the multi-standard applications based on the realization of the 4G technologies. The performance tradeoff among noise, linearity, and broadband impedance matching are explored and three new techniques are proposed for the tradeoff relaxation. The measurement results indicate the techniques effectively extend the bandwidth and suppress the increase of the NF and nonlinearity at high frequencies. The three proposed structures can be easily applied to the wideband and multi-standard LNA design

A -5 dBm 400MHz OOK Transmitter for Wireless Medical Application

A 400 MHz high efficiency transmitter forwireless medical application is presented in this paper. Transmitter architecture with high-energy efficiencies isproposed to achieve high data rate with low powerconsumption. In the on-off keying transmitters, the oscillatorand power amplifier are turned off when the transmittersends 0 data. The proposed class-e power amplifier has highefficiency for low level output power. The proposed on-offkeying transmitter consumes 1.52 mw at -5 dBm output by 40Mbps data rate and energy consumption 38 pJ/bit. Theproposed transmitter has been designed in 0.18µm CMOStechnology

Efficient and Interference-Resilient Wireless Connectivity for IoT Applications

With the coming of age of the Internet of Things (IoT), demand on ultra-low power (ULP) and low-cost radios will continue to boost tremendously. The Bluetooth-Low-energy (BLE) standard provides a low power solution to connect IoT nodes with mobile devices, however, the power of maintaining a connection with a reasonable latency remains the limiting factor in defining the lifetime of event-driven BLE devices. BLE radio power consumption is in the milliwatt range and can be duty cycled for average powers around 30μW, but at the expense of long latency. Furthermore, wireless transceivers traditionally perform local oscillator (LO) calibration using an external crystal oscillator (XTAL) that adds significant size and cost to a system. Removing the XTAL enables a true single-chip radio, but an alternate means for calibrating the LO is required. Innovations in both the system architecture and circuits implementation are essential for the design of truly ubiquitous receivers for IoT applications. This research presents two porotypes as back-channel BLE receivers, which have lower power consumption while still being robust in the presents of interference and able to receive back-channel message from BLE compliant transmitters. In addition, the first crystal-less transmitter with symmetric over-the-air clock recovery compliant with the BLE standard using a GFSK-Modulated BLE Packet is presented.PHDElectrical and Computer EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/162942/1/abdulalg_1.pd

A Q-enhanced 3.6 GHz tunable CMOS bandpass filter for wideband wireless applications

With the rapid development of information technology, more and more bandwidth is required to transmit multimedia data. Since local communication networks are moving to wireless domain, it brings up great challenges for making integrated wideband wireless front-ends suitable for these applications. RF filtering is a fundamental need in all wireless front-ends and is one of the most difficult parts to be integrated. This has been a major obstacle to the implementation of low power and low cost integrated wireless terminals. Lots of previous work has been done to make integrated RF filters applicable to these applications. However, some of these filters are not designed with standard CMOS technology. Some of them are not designed in desired frequency bands and others do not have sufficient frequency bandwidth. This research demonstrates the design of a tunable wideband RF filter that operates at 3.6 GHz and can be easily changed to a higher frequency range up to 5 GHz. This filter is superior to the previous designs in the following aspects: a) wider bandwidth, b) easier to tune, c) balancing in noise and linearity, and d) using standard CMOS technology. The design employs the state-of-the-art inductor degenerated LNA, acting as a transconductor to minimize the overall noise figure. A Q-enhancement circuit is employed to compensate the loss from lossy on-chip spiral inductors. Center frequency and bandwidth tuning circuits are also embedded to make the filter suitable for multi band operations. At first, a second order bandpass filter prototype was designed in the standard 0.18 ìm CMOS process. Simulation results showed that at 3.6 GHz center frequency and with a 60-MHz bandwidth, the input third-order intermodulation product (IIP3) and input-referred 1 dB compression point (P1dB) was -22.5 dBm and -30.5 dBm respectively. The image rejection at 500 MHz away from the center frequency was 32 dB (250 MHz intermediate frequency). The Q of the filter was tunable over 3000 and the center frequency tuning range was about 150 MHz. By cascading three stages of second order filters, a sixth order filter was designed to enhance the image rejection ability and to extend the filter bandwidth. The sixth order filter had been fabricated in the standard 0.18 ìm CMOS process using 1.8-V supply. The chip occupies only 0.9 mm 0.9 mm silicon area and has a power consumption of 130-mW. The measured center frequency was tunable from 3.54 GHz to 3.88 GHz, bandwidth was tunable from 35 MHz to 80 MHz. With a 65 MHz bandwidth, the filter had a gain of 13 dB, an IIP3 of -29 dBm and a P1dB of -46 dBm

Power-efficient current-mode analog circuits for highly integrated ultra low power wireless transceivers

In this thesis, current-mode low-voltage and low-power techniques have been applied to implement novel analog circuits for zero-IF receiver backend design, focusing on amplification, filtering and detection stages. The structure of the thesis follows a bottom-up scheme: basic techniques at device level for low voltage low power operation are proposed in the first place, followed by novel circuit topologies at cell level, and finally the achievement of new designs at system level. At device level the main contribution of this work is the employment of Floating-Gate (FG) and Quasi-Floating-Gate (QFG) transistors in order to reduce the power consumption. New current-mode basic topologies are proposed at cell level: current mirrors and current conveyors. Different topologies for low-power or high performance operation are shown, being these circuits the base for the system level designs. At system level, novel current-mode amplification, filtering and detection stages using the former mentioned basic cells are proposed. The presented current-mode filter makes use of companding techniques to achieve high dynamic range and very low power consumption with for a very wide tuning range. The amplification stage avoids gain bandwidth product achieving a constant bandwidth for different gain configurations using a non-linear active feedback network, which also makes possible to tune the bandwidth. Finally, the proposed current zero-crossing detector represents a very power efficient mixed signal detector for phase modulations. All these designs contribute to the design of very low power compact Zero-IF wireless receivers. The proposed circuits have been fabricated using a 0.5μm double-poly n-well CMOS technology, and the corresponding measurement results are provided and analyzed to validate their operation. On top of that, theoretical analysis has been done to fully explore the potential of the resulting circuits and systems in the scenario of low-power low-voltage applications.Programa Oficial de Doctorado en Tecnologías de las Comunicaciones (RD 1393/2007)Komunikazioen Teknologietako Doktoretza Programa Ofiziala (ED 1393/2007

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

Characterization of 28 nm FDSOI MOS and application to the design of a low-power 2.4 GHz LNA

IoT is expected to connect billions of devices all over world in the next years, and in a near future, it is expected to use LR-WPAN in a wide variety of applications. Not all the devices will require of high performance but will require of low power hungry systems since most of them will be powered with a battery. Conventional CMOS technologies cannot cover these needs even scaling it to very small regimes, which appear other problems. Hence, new technologies are emerging to cover the needs of this devices. One promising technology is the UTBB FDSOI, which achieves good performance with very good energy efficiency. This project characterizes this technology to obtain a set of parameters of interest for analog/RF design. Finally, with the help of a low-power design methodology (gm/Id approach), a design of an ULP ULV LNA is performed to check the suitability of this technology for IoT

Radio-frequency integrated-circuit design for CMOS single-chip UWB systems

Low cost, a high-integrated capability, and low-power consumption are the basic requirements for ultra wide band (UWB) system design in order for the system to be adopted in various commercial electronic devices in the near future. Thus, the highly integrated transceiver is trended to be manufactured by companies using the latest silicon based complimentary metal-oxide-silicon (CMOS) processes. In this dissertation, several new structural designs are proposed, which provide solutions for some crucial RF blocks in CMOS for UWB for commercial applications. In this dissertation, there is a discussion of the development, as well as an illustration, of a fully-integrated ultra-broadband transmit/receive (T/R) switch which uses nMOS transistors with deep n-well in a standard 0.18-μm CMOS process. The new CMOS T/R switch exploits patterned-ground-shield on-chip inductors together with MOSFET’s parasitic capacitances in order to synthesize artificial transmission lines which result in low insertion loss over an extremely wide bandwidth. Within DC-10 GHz, 10-18 GHz, and 18-20 GHz, the developed CMOS T/R switch exhibits insertion loss of less than 0.7, 1.0 and 2.5 dB and isolation between 32-60 dB, 25-32 dB, and 25-27 dB, respectively. The measured 1-dB power compression point and input third-order intercept point reach as high as 26.2 and 41 dBm, respectively. Further, there is a discussion and demonstration of a tunable Carrier-based Time-gated UWB transmitter in this dissertation which uses a broadband multiplier, a novel fully integrated single pole single throw (SPST) switch designed by the CMOS process, where a tunable instantaneous bandwidth from 500 MHz to 4 GHz is exhibited by adjusting the width of the base band impulses in time domain. The SPST switch utilizes the synthetic transmission line concept and multiple reflections technique in order to realize a flat insertion loss less than 1.5 dB from 3.1 GHz to 10.6 GHz and an extremely high isolation of more than 45 dB within this frequency range. A fully integrated complementary LC voltage control oscillator (VCO), designed with a tunable buffer, operates from 4.6 GHz to 5.9 GHz. The measurement results demonstrate that the integrated VCO has a very low phase noise of –117 dBc/ Hz at 1 MHz offset. The fully integrated VCO achieves a very high figure of merit (FOM) of 183.5 using standard CMOS process while consuming 4 mA DC current