17 research outputs found
Calibrated Continuous-Time Sigma-Delta Modulators
To provide more information mobility, many wireless communication systems such
as WCDMA and EDGE in phone systems, bluetooth and WIMAX in communication
networks have been recently developed. Recent efforts have been made to build the allin-
one next generation device which integrates a large number of wireless services into a
single receiving path in order to raise the competitiveness of the device. Among all the
receiver architectures, the high-IF receiver presents several unique properties for the
next generation receiver by digitalizing the signal at the intermediate frequency around a
few hundred MHz. In this architecture, the modulation/demodulation schemes, protocols,
equalization, etc., are all determined in a software platform that runs in the digital signal
processor (DSP) or FPGA. The specifications for most of front-end building blocks are
relaxed, except the analog-to-digital converter (ADC). The requirements of large
bandwidth, high operational frequency and high resolution make the design of the ADC
very challenging.
Solving the bottleneck associated with the high-IF receiver architecture is a major
focus of many ongoing research efforts. In this work, a 6th-order bandpass continuous time sigma-delta ADC with measured 68.4dB SNDR at 10MHz bandwidth to
accommodate video applications is proposed. Tuned at 200 MHz, the fs/4 architecture
employs an 800 MHz clock frequency. By making use of a unique software-based
calibration scheme together with the tuning properties of the bandpass filters developed
under the umbrella of this project, the ADC performance is optimized automatically to
fulfill all requirements for the high-IF architecture.
In a separate project, other critical design issues for continuous-time sigma-delta
ADCs are addressed, especially the issues related to unit current source mismatches in
multi-level DACs as well as excess loop delays that may cause loop instability. The
reported solutions are revisited to find more efficient architectures. The aforementioned
techniques are used for the design of a 25MHz bandwidth lowpass continuous-time
sigma-delta modulator with time-domain two-step 3-bit quantizer and DAC for WiMAX
applications. The prototype is designed by employing a level-to-pulse-width modulation
(PWM) converter followed by a single-level DAC in the feedback path to translate the
typical digital codes into PWM signals with the proposed pulse arrangement. Therefore,
the non-linearity issue from current source mismatch in multi-level DACs is prevented.
The jitter behavior and timing mismatch issue of the proposed time-based methods are
fully analyzed. The measurement results of a chip prototype achieving 67.7dB peak
SNDR and 78dB SFDR in 25MHz bandwidth properly demonstrate the design concepts
and effectiveness of time-based quantization and feedback.
Both continuous-time sigma-delta ADCs were fabricated in mainstream CMOS
0.18um technologies, which are the most popular in today?s consumer electronics
industry
High Performance Integrated Circuit Blocks for High-IF Wideband Receivers
Due to the demand for highâperformance radio frequency (RF) integrated circuit
design in the past years, a systemâonâchip (SoC) that enables integration of analog and
digital parts on the same die has become the trend of the microelectronics industry. As
a result, a major requirement of the next generation of wireless devices is to support
multiple standards in the same chipâset. This would enable a single device to support
multiple peripheral applications and services.
Based on the aforementioned, the traditional superheterodyne frontâend
architecture is not suitable for such applications as it would require a complete receiver
for each standard to be supported. A more attractive alternative is the highintermediate
frequency (IF) radio architecture. In this case the signal is digitalized at an
intermediate frequency such as 200MHz. As a consequence, the baseband operations,
such as downâconversion and channel filtering, become more power and area efficient
in the digital domain. Such architecture releases the specifications for most of the frontâend building blocks, but the linearity and dynamic range of the ADC become the
bottlenecks in this system. The requirements of large bandwidth, high frequency and
enough resolution make such ADC very difficult to realize. Many ADC architectures
were analyzed and ContinuousâTime Bandpass SigmaâDelta (CTâBPâÎŁÎ) architecture was
found to be the most suitable solution in the highâIF receiver architecture since they
combine oversampling and noise shaping to get fairly high resolution in a limited
bandwidth.
A major issue in continuousâtime networks is the lack of accuracy due to powervoltageâ
temperature (PVT) tolerances that lead to over 20% pole variations compared
to their discreteâtime counterparts. An optimally tuned BP ÎŁÎ ADC requires correcting
for center frequency deviations, excess loop delay, and DAC coefficients. Due to these
undesirable effects, a calibration algorithm is necessary to compensate for these
variations in order to achieve high SNR requirements as technology shrinks.
In this work, a novel linearization technique for a Wideband LowâNoise
Amplifier (LNA) targeted for a frequency range of 3â7GHz is presented. Postâlayout
simulations show NF of 6.3dB, peak S21 of 6.1dB, and peak IIP3 of 21.3dBm,
respectively. The power consumption of the LNA is 5.8mA from 2V.
Secondly, the design of a CMOS 6th order CT BPâÎŁÎ modulator running at 800
MHz for HighâIF conversion of 10MHz bandwidth signals at 200 MHz is presented. A
novel transconductance amplifier has been developed to achieve high linearity and high
dynamic range at high frequencies. A 2âbit quantizer with offset cancellation is alsopresented. The sixthâorder modulator is implemented using 0.18 um TSMC standard
analog CMOS technology. Postâlayout simulations in cadence demonstrate that the
modulator achieves a SNDR of 78 dB (~13 bit) performance over a 14MHz bandwidth.
The modulatorâs static power consumption is 107mW from a supply power of Âą 0.9V.
Finally, a calibration technique for the optimization of the Noise Transfer
Function CT BP ÎŁÎ modulators is presented. The proposed technique employs two test
tones applied at the input of the quantizer to evaluate the noise transfer function of
the ADC, using the capabilities of the Digital Signal Processing (DSP) platform usually
available in mixedâmode systems. Once the ADC output bit stream is captured,
necessary information to generate the control signals to tune the ADC parameters for
best SignalâtoâQuantization Noise Ratio (SQNR) performance is extracted via Leastâ
Mean Squared (LMS) softwareâbased algorithm. Since the two tones are located
outside the band of interest, the proposed global calibration approach can be used
online with no significant effect on the inâband content
A 16-b 10Msample/s Split-Interleaved Analog to Digital Converter
This work describes the integrated circuit design of a 16-bit, 10Msample/sec, combination ââŹËsplitââŹâ˘ interleaved analog to digital converter. Time interleaving of analog to digital converters has been used successfully for many years as a technique to achieve faster speeds using multiple identical converters. However, efforts to achieve higher resolutions with this technique have been difficult due to the precise matching required of the converter channels. The most troublesome errors in these types of converters are gain, offset and timing differences between channels. The ââŹËsplit ADCââŹâ˘ is a new concept that allows the use of a deterministic, digital, self calibrating algorithm. In this approach, an ADC is split into two paths, producing two output codes from the same input sample. The difference of these two codes is used as the calibration signal for an LMS error estimation algorithm that drives the difference error to zero. The ADC is calibrated when the codes are equal and the output is taken as the average of the two codes. The ââŹËsplitââŹâ˘ ADC concept and interleaved architecture are combined in this IC design to form the core of a high speed, high resolution, and self-calibrating ADC system. The dual outputs are used to drive a digital calibration engine to correct for the channel mismatch errors. This system has the speed benefits of interleaving while maintaining high resolution. The hardware for the algorithm as well as the ADC can be implemented in a standard 0.25um CMOS process, resulting in a relatively inexpensive solution. This work is supported by grants from Analog Devices Incorporated (ADI) and the National Science Foundation (NSF)
High Performance Integrated Circuit Blocks for High-IF Wideband Receivers
Due to the demand for highâperformance radio frequency (RF) integrated circuit
design in the past years, a systemâonâchip (SoC) that enables integration of analog and
digital parts on the same die has become the trend of the microelectronics industry. As
a result, a major requirement of the next generation of wireless devices is to support
multiple standards in the same chipâset. This would enable a single device to support
multiple peripheral applications and services.
Based on the aforementioned, the traditional superheterodyne frontâend
architecture is not suitable for such applications as it would require a complete receiver
for each standard to be supported. A more attractive alternative is the highintermediate
frequency (IF) radio architecture. In this case the signal is digitalized at an
intermediate frequency such as 200MHz. As a consequence, the baseband operations,
such as downâconversion and channel filtering, become more power and area efficient
in the digital domain. Such architecture releases the specifications for most of the frontâend building blocks, but the linearity and dynamic range of the ADC become the
bottlenecks in this system. The requirements of large bandwidth, high frequency and
enough resolution make such ADC very difficult to realize. Many ADC architectures
were analyzed and ContinuousâTime Bandpass SigmaâDelta (CTâBPâÎŁÎ) architecture was
found to be the most suitable solution in the highâIF receiver architecture since they
combine oversampling and noise shaping to get fairly high resolution in a limited
bandwidth.
A major issue in continuousâtime networks is the lack of accuracy due to powervoltageâ
temperature (PVT) tolerances that lead to over 20% pole variations compared
to their discreteâtime counterparts. An optimally tuned BP ÎŁÎ ADC requires correcting
for center frequency deviations, excess loop delay, and DAC coefficients. Due to these
undesirable effects, a calibration algorithm is necessary to compensate for these
variations in order to achieve high SNR requirements as technology shrinks.
In this work, a novel linearization technique for a Wideband LowâNoise
Amplifier (LNA) targeted for a frequency range of 3â7GHz is presented. Postâlayout
simulations show NF of 6.3dB, peak S21 of 6.1dB, and peak IIP3 of 21.3dBm,
respectively. The power consumption of the LNA is 5.8mA from 2V.
Secondly, the design of a CMOS 6th order CT BPâÎŁÎ modulator running at 800
MHz for HighâIF conversion of 10MHz bandwidth signals at 200 MHz is presented. A
novel transconductance amplifier has been developed to achieve high linearity and high
dynamic range at high frequencies. A 2âbit quantizer with offset cancellation is alsopresented. The sixthâorder modulator is implemented using 0.18 um TSMC standard
analog CMOS technology. Postâlayout simulations in cadence demonstrate that the
modulator achieves a SNDR of 78 dB (~13 bit) performance over a 14MHz bandwidth.
The modulatorâs static power consumption is 107mW from a supply power of Âą 0.9V.
Finally, a calibration technique for the optimization of the Noise Transfer
Function CT BP ÎŁÎ modulators is presented. The proposed technique employs two test
tones applied at the input of the quantizer to evaluate the noise transfer function of
the ADC, using the capabilities of the Digital Signal Processing (DSP) platform usually
available in mixedâmode systems. Once the ADC output bit stream is captured,
necessary information to generate the control signals to tune the ADC parameters for
best SignalâtoâQuantization Noise Ratio (SQNR) performance is extracted via Leastâ
Mean Squared (LMS) softwareâbased algorithm. Since the two tones are located
outside the band of interest, the proposed global calibration approach can be used
online with no significant effect on the inâband content
Single event upset hardened CMOS combinational logic and clock buffer design
A radiation strike on semiconductor device may lead to charge collection, which may manifest as a wrong logic level causing failure. Soft errors or Single Event Upsets (SEU) caused by radiation strikes are one of the main failure modes in a VLSI circuit. Previous work predicts that soft error rate may dominate the failure rate in VLSI circuit compared to all other failure modes put together. The issue of single event upsets (SEU) need to be addressed such that the failure rate of the chips dues to SEU is in the acceptable range. Memory circuits are designed to be error free with the help of error correction codes. Technology scaling is driving up the SEU rate of combinational logic and it is predicted that the soft error rate (SER) of combinational logic may dominate the SER of unpro-tected memory by the year 2011. Hence a robust combinational logic methodology must be designed for SEU hardening. Recent studies have also shown that clock distribution network is becoming increasingly vulnerable to radiation strike due to reduced capaci-tance at the clock leaf node. A strike on clock leaf node may propagate to many flip-flops increasing the system SER considerably. In this thesis we propose a novel method to improve the SER of the circuit by filtering single event upsets in the combinational logic and clock distribution network. Our ap-proach results in minimal circuit overhead and also requires minimal effort by the de-signer to implement the proposed method. In this thesis we focus on preventing the propagation of SEU rather than eliminating the SEU on each sensitive gate
Design of a Class-AB Amplifier for a 1.5 Bit MDAC of a 12 Bit 100MSPS Pipeline ADC
The basic building block of a pipeline analog-to-digital converter (ADC) is the multiplying digital-to-analog converter (MDAC). The performance of the MDAC significantly depends on the performance of the operational amplifier and calibration techniques. To reduce the complexity of calibration, the operational amplifier needs to have high-linearity, high bandwidth and moderate gain.
In this work, the Op-amp specifications were derived from the pipeline ADC requirements. A novel class-AB bias scheme with feed-forward compensation, which provides high linearity and bandwidth consuming low power is proposed. The advantages of the new topology over Monticelli bias scheme and Millerâs compensated amplifiers is explained. The amplifier is implemented in IBM 130nm technology and the MDAC design is used as a test bench to characterize the Op-amp performance. The proposed architecture performance is compared with class A and class-AB output stage amplifiers with Millerâs compensation reported in literature. The proposed class-AB amplifier with feed forward compensation provides an open loop gain of 47dB, unit gain bandwidth of 1040 MHz and IM3 of 75dB consuming 3.88mA current. The amplifier provides the required linearity and bandwidth at much lower power consumption than the amplifiers using conventional class-AB bias schemes
Low-voltage, low-power circuits for data communication systems
There are growing industrial demands for low-voltage supply and low-power consumption circuits and systems. This is especially true for very high integration level and very large scale integrated (VLSI) mixed-signal chips and system-on-a-chip. It is mainly due to the limited power dissipation within a small area and the costs related to the packaging and thermal management. In this research work, two low-voltage, low-power integrated circuits used for data communication systems are introduced. The first one is a high performance continuous-time linear phase filter with automatic frequency tuning. The filter can be used in hard disk driver systems and wired communication systems such as 1000Base-T transceivers. A pseudo-differential operational transconductance amplifier (OTA) based on transistors operating in triode region is used to achieve a large linear signal swing with low-voltage supplies. A common-mode (CM) control circuit that combines common-mode feedback (CMFB), common-mode feedforward (CMFF), and adaptive-bias has been proposed. With a 2.3V single supply, the filters total harmonic distortion is less than 44dB for a 2VPP differential input, which is due to the well controlled CM behavior. The ratio of the root mean square value of the ac signal to the power supply voltage is around 31%, which is much better than previous realizations. The second integrated circuit includes two LVDS drivers used for high-speed point-to-point links. By removing the stacked switches used in the conventional structures, both LVDS drivers can operate with ultra low-voltage supplies. Although the Double Current Sources (DCS) LVDS driver draws twice minimum static current as required by the signal swing, it is quite simple and achieves very high speed operation. The Switchable Current Sources (SCS) LVDS driver, by dynamically switching the current sources, draws minimum static current and reduces the power consumption by 60% compared to the previously reported LVDS drivers. Both LVDS drivers are compliant to the standards and operate at data rates up to gigabits-per-second
Circuits de transmission sans fil Ă faible puissance pour dispositifs implantables
Les systèmes de tÊlÊmÊtrie existants -- Architectures et circuits des systèmes d'Êmission -- Système de transmission pour applications biomÊdicales -- Système de transmission proposÊ
All Digital, Background Calibration for Time-Interleaved and Successive Approximation Register Analog-to-Digital Converters
The growth of digital systems underscores the need to convert analog information to the digital domain at high speeds and with great accuracy. Analog-to-Digital Converter (ADC) calibration is often a limiting factor, requiring longer calibration times to achieve higher accuracy. The goal of this dissertation is to perform a fully digital background calibration using an arbitrary input signal for A/D converters. The work presented here adapts the cyclic Split-ADC calibration method to the time interleaved (TI) and successive approximation register (SAR) architectures. The TI architecture has three types of linear mismatch errors: offset, gain and aperture time delay. By correcting all three mismatch errors in the digital domain, each converter is capable of operating at the fastest speed allowed by the process technology. The total number of correction parameters required for calibration is dependent on the interleaving ratio, M. To adapt the Split-ADC method to a TI system, 2M+1 half-sized converters are required to estimate 3(2M+1) correction parameters. This thesis presents a 4:1 Split-TI converter that achieves full convergence in less than 400,000 samples. The SAR architecture employs a binary weight capacitor array to convert analog inputs into digital output codes. Mismatch in the capacitor weights results in non-linear distortion error. By adding redundant bits and dividing the array into individual unit capacitors, the Split-SAR method can estimate the mismatch and correct the digital output code. The results from this work show a reduction in the non-linear distortion with the ability to converge in less than 750,000 samples
Primitives and design of the intelligent pixel multimedia communicator
Communication systems arc an ever more essential component of our modern global society. Mobile communications systems are still in a state of rapid advancement and growth. Technology is constantly evolving at a rapid pace in ever more diverse areas and the emerging mobile multimedia based communication systems offer new challenges for both current and future technologies. To realise the full potential of mobile multimedia communication systems there is a need to explore new options to solve some of the fundamental problems facing the technology. In particular, the complexity of such a system within an infrastructure framework that is inherently limited by its power sources and has very restricted transmission bandwidth demands new methodologies and approaches