28 research outputs found
Cancellation of OpAmp virtual ground imperfections by a negative conductance applied to improve RF receiver linearity
High linearity CMOS radio receivers often exploit linear V-I conversion at RF, followed by passive down-mixing and an OpAmp-based Transimpedance Amplifier at baseband. Due to nonlinearity and finite gain in the OpAmp, virtual ground is imperfect, inducing distortion currents. This paper proposes a negative conductance concept to cancel such distortion currents. Through a simple intuitive analysis, the basic operation of the technique is explained. By mathematical analysis the optimum negative conductance value is derived and related to feedback theory. In- and out-of-band linearity, stability and Noise Figure are also analyzed. The technique is applied to linearize an RF receiver, and a prototype is implemented in 65 nm technology. Measurement results show an increase of in-band IIP3 from 9dBm to >20dBm, and IIP2 from 51 to 61dBm, at the cost of increasing the noise figure from 6 to 7.5dB and <10% power penalty. In 1MHz bandwidth, a Spurious-Free Dynamic Range of 85dB is achieved at <27mA up to 2GHz for 1.2V supply voltage
A self-interference-cancelling receiver for in-band full-duplex wireless with low distortion under cancellation of strong TX leakage
In-band full-duplex (FD) wireless communication, i.e. simultaneous transmission and reception at the same frequency, in the same channel, promises up to 2x spectral efficiency, along with advantages in higher network layers [1]. the main challenge is dealing with strong in-band leakage from the transmitter to the receiver (i.e. self-interference (SI)), as TX powers are typically >100dB stronger than the weakest signal to be received, necessitating TX-RX isolation and SI cancellation. Performing this SI-cancellation solely in the digital domain, if at all possible, would require extremely clean (low-EVM) transmission and a huge dynamic range in the RX and ADC, which is currently not feasible [2]. Cancelling SI entirely in analog is not feasible either, since the SI contains delayed TX components reflected by the environment. Cancelling these requires impractically large amounts of tunable analog delay. Hence, FD-solutions proposed thus far combine SI-rejection at RF, analog BB, digital BB and cross-domain
An in-band full-duplex radio receiver with a passive vector modulator downmixer for self-interference cancellation
In-band full-duplex (FD) wireless, i.e., simultaneous transmission and reception at the same frequency, introduces strong self-interference (SI) that masks the signal to be received. This paper proposes a receiver in which a copy of the transmit signal is fed through a switched-resistor vector modulator (VM)that provides simultaneous downmixing, phase shift, and amplitude scaling and subtracts it in the analog baseband for up to 27 dB SI-cancellation. Cancelling before active baseband amplification avoids self-blocking, and highly linear mixers keep SIinduced distortion low, for a receiver SI-to-noise-and-distortionratio (SINDR) of up to 71.5 dB in 16.25 MHz BW. When combined with a two-port antenna with only 20 dB isolation, the low RX distortion theoretically allows sufficient digital cancellation for over 90 dB link budget, sufficient for short-range, low-power FD links
Design of a Precision Low Voltage Resistor Multiplying Digital-to-Analog Converter
This work aims to model the effect of the input offset voltage of an operational amplifier
on the performance of a high-precision, voltage-mode, resistor-based multiplying
digital-to-analog converter (M-DAC). Based on the model, a high precision current buffer is proposed to isolate the resistor ladder from the operational amplifier. A 14-bit M-DAC operating with a ±1V reference of the proposed architecture. Post-layout simulations show that the proposed architecture reduces the offset voltage to an offset error in the DAC transfer function. The maximum DNL is maintained at -0.385 LSB for an input offset voltage of up to 60mV (1024 LSB). The current buffer also introduces an inversion of the output voltage, yielding a non-inverted output. This alleviates the need for an additional high precision op-amp to invert the output voltage
Continuous-time low-pass filters for integrated wideband radio receivers
This thesis concentrates on the design and implementation of analog baseband continuous-time low-pass filters for integrated wideband radio receivers. A total of five experimental analog baseband low-pass filter circuits were designed and implemented as a part of five single-chip radio receivers in this work.
After the motivation for the research work presented in this thesis has been introduced, an overview of analog baseband filters in radio receivers is given first. In addition, a review of the three receiver architectures and the three wireless applications that are adopted in the experimental work of this thesis is presented. The relationship between the integrator non-idealities and integrator Q-factor, as well as the effect of the integrator Q-factor on the filter frequency response, are thoroughly studied on the basis of a literature review. The theoretical study that is provided is essential for the gm-C filter synthesis with non-ideal lossy integrators that is presented after the introduction of different techniques to realize integrator-based continuous-time low-pass filters. The filter design approach proposed for gm-C filters is original work and one of the main points in this thesis, in addition to the experimental IC implementations.
Two evolution versions of fourth-order 10-MHz opamp-RC low-pass filters designed and implemented for two multicarrier WCDMA base-station receivers in a 0.25-µm SiGe BiCMOS technology are presented, along with the experimental results of both the low-pass filters and the corresponding radio receivers. The circuit techniques that were used in the three gm-C filter implementations of this work are described and a common-mode induced even-order distortion in a pseudo-differential filter is analyzed. Two evolution versions of fifth-order 240-MHz gm-C low-pass filters that were designed and implemented for two single-chip WiMedia UWB direct-conversion receivers in a standard 0.13-µm and 65-nm CMOS technology, respectively, are presented, along with the experimental results of both the low-pass filters and the second receiver version. The second UWB filter design was also embedded with an ADC into the baseband of a 60-GHz 65-nm CMOS radio receiver. In addition, a third-order 1-GHz gm-C low-pass filter was designed, rather as a test structure, for the same receiver. The experimental results of the receiver and the third gm-C filter implementation are presented
Analysis and design of low-power data converters
In a large number of applications the signal processing is done exploiting both
analog and digital signal processing techniques. In the past digital and analog
circuits were made on separate chip in order to limit the interference and other
side effects, but the actual trend is to realize the whole elaboration chain on a
single System on Chip (SoC). This choice is driven by different reasons such as the
reduction of power consumption, less silicon area occupation on the chip and also
reliability and repeatability. Commonly a large area in a SoC is occupied by digital
circuits, then, usually a CMOS short-channel technological processes optimized to
realize digital circuits is chosen to maximize the performance of the Digital Signal
Proccessor (DSP). Opposite, the short-channel technology nodes do not represent
the best choice for analog circuits. But in a large number of applications, the signals
which are treated have analog nature (microphone, speaker, antenna, accelerometers,
biopotential, etc.), then the input and output interfaces of the processing chip are
analog/mixed-signal conversion circuits. Therefore in a single integrated circuit (IC)
both digital and analog circuits can be found. This gives advantages in term of total
size, cost and power consumption of the SoC. The specific characteristics of CMOS
short-channel processes such as:
• Low breakdown voltage (BV) gives a power supply limit (about 1.2 V).
• High threshold voltage VTH (compared with the available voltage supply) fixed
in order to limit the leakage power consumption in digital applications (of the
order of 0.35 / 0.4V), puts a limit on the voltage dynamic, and creates many
problems with the stacked topologies.
• Threshold voltage dependent on the channel length VTH = f(L) (short channel
effects).
• Low value of the output resistance of the MOS (r0) and gm limited by speed
saturation, both causes contribute to achieving a low intrinsic gain gmr0 = 20
to 26dB.
• Mismatch which brings offset effects on analog circuits.
make the design of high performance analog circuits very difficult. Realizing lowpower
circuits is fundamental in different contexts, and for different reasons: lowering
the power dissipation gives the capability to reduce the batteries size in mobile
devices (laptops, smartphones, cameras, measuring instruments, etc.), increase the
life of remote sensing devices, satellites, space probes, also allows the reduction of
the size and weight of the heat sink. The reduction of power dissipation allows the
realization of implantable biomedical devices that do not damage biological tissue.
For this reason, the analysis and design of low power and high precision analog
circuits is important in order to obtain high performance in technological processes
that are not optimized for such applications. Different ways can be taken to reduce
the effect of the problems related to the technology:
• Circuital level: a circuit-level intervention is possible to solve a specific problem
of the circuit (i.e. Techniques for bandwidth expansion, increase the gain,
power reduction, etc.).
• Digital calibration: it is the highest level to intervene, and generally going to
correct the non-ideal structure through a digital processing, these aims are
based on models of specific errors of the structure.
• Definition of new paradigms.
This work has focused the attention on a very useful mixed-signal circuit: the
pipeline ADC. The pipeline ADCs are widely used for their energy efficiency in
high-precision applications where a resolution of about 10-16 bits and sampling
rates above hundreds of Mega-samples per second (telecommunication, radar, etc.)
are needed. An introduction on the theory of pipeline ADC, its state of the art
and the principal non-idealities that affect the energy efficiency and the accuracy
of this kind of data converters are reported in Chapter 1. Special consideration is
put on low-voltage low-power ADCs. In particular, for ADCs implemented in deep
submicron technology nodes side effects called short channel effects exist opposed to
older technology nodes where undesired effects are not present. An overview of the
short channel effects and their consequences on design, and also power consuption
reduction techniques, with particular emphasis on the specific techniques adopted
in pipelined ADC are reported in Chapter 2. Moreover, another way may be
undertaken to increase the accuracy and the efficiency of an ADC, this way is the
digital calibration. In Chapter 3 an overview on digital calibration techniques, and
furthermore a new calibration technique based on Volterra kernels are reported. In
some specific applications, such as software defined radios or micropower sensor,
some circuits should be reconfigurable to be suitable for different radio standard
or process signals with different charateristics. One of this building blocks is the
ADC that should be able to reconfigure the resolution and conversion frequency. A
reconfigurable voltage-scalable ADC pipeline capable to adapt its voltage supply
starting from the required conversion frequency was developed, and the results are
reported in Chapter 4. In Chapter 5, a pipeline ADC based on a novel paradigm for
the feedback loop and its theory is described
High performance continuous-time filters for information transfer systems
Vast attention has been paid to active continuous-time filters over the years. Thus as the cheap, readily available integrated circuit OpAmps replaced their discrete circuit versions, it became feasible to consider active-RC filter circuits using large numbers of OpAmps. Similarly the development of integrated operational transconductance amplifier (OTA) led to new filter configurations. This gave rise to OTA-C filters, using only active devices and capacitors, making it more suitable for integration. The demands on filter circuits have become ever more stringent as the world of electronics and communications has advanced. In addition, the continuing increase in the operating frequencies of modern circuits and systems increases the need for active filters that can perform at these higher frequencies; an area where the LC active filter emerges. What mainly limits the performance of an analog circuit are the non-idealities of the used building blocks and the circuit architecture. This research concentrates on the design issues of high frequency continuous-time integrated filters.
Several novel circuit building blocks are introduced. A novel pseudo-differential fully balanced fully symmetric CMOS OTA architecture with inherent common-mode detection is proposed. Through judicious arrangement, the common-mode feedback circuit can be economically implemented.
On the level of system architectures, a novel filter low-voltage 4th order RF bandpass filter structure based on emulation of two magnetically coupled resonators is presented. A unique feature of the proposed architecture is using electric coupling to emulate the effect of the coupled-inductors, thus providing bandwidth tuning with small passband ripple.
As part of a direct conversion dual-mode 802.11b/Bluetooth receiver, a BiCMOS 5th order low-pass channel selection filter is designed. The filter operated from a single 2.5V supply and achieves a 76dB of out-of-band SFDR. A digital automatic tuning system is also implemented to account for process and temperature variations.
As part of a Bluetooth transmitter, a low-power quadrature direct digital frequency synthesizer (DDFS) is presented. Piecewise linear approximation is used to avoid using a ROM look-up table to store the sine values in a conventional DDFS. Significant saving in power consumption, due to the elimination of the ROM, renders the design more suitable for portable wireless communication applications