PLL design for inverter grid connection : Simulations for ideal and non-ideal grid conditions

Ögren, Jim

January 2010

In this report a phase locked loop (PLL) system for grid voltage phase tracking has been investigated. The grid voltage phase angle contains critical information for connecting a power plant, such as a wave energy converter, to the grid. A synchronous reference frame PLL system with PI-regulator gains calculated with the symmetrical optimum method has been designed and simulations in SIMULINK have been made. For ideal grid conditions the phase angle was tracked fast and accurate. For non-ideal conditions the phase angle was tracked but with less accuracy, due to slow dynamics of the system, but still within acceptable margins. In order to test this system further it has to be implemented in a control system and tested when connected to the grid.

PLL

inverter

Phase locked loop

symmetrical optimum method

Engineering physics

Teknisk fysik

A Self-compensated, Bandwidth Tracking Semi-digital PLL Design in 65nm CMOS Technol-ogy

Yogesh, Mitesh

January 2012

In a conventional charge-pump based PLL design, the loop parameters such as the band-width, jitter performance, charge-pump current, pull-in range among others govern the ar-chitecture and implementation details of the PLL. Different loop parameter specificationschange with a change in the reference frequency and inmost cases, requires careful re-designof some of the PLL blocks. This thesis describes the implementation of a semi-digital PLLfor high bandwidth applications, which is self-compensated, low-power and exhibits band-width tracking for all reference frequencies between 40 MHz and 1.6 GHz in 65nm CMOStechnology.This design can be used for a wide range of reference frequencies without redesigning anyblock. The bandwidth can be fixed to some fraction of the reference frequency during designtime. In this thesis, the PLL is designed to make the bandwidth track 5% of the referencefrequency. Since this PLL is self-compensated, the PLL performance and the bandwidthremains same over PVT corners.

PLL

semi-digital

Bandwidth tracking

Adaptive bandwidth

Compensation

PVT

Self-Bias

charge-pump

VCO

65nm

Offset-PLL based frequency up-conversion for low spurious transmission / Offset-PLL-baserad modulator för högpresterande sändarsystem

Nilsson, Anders

January 2003

The goal of this final year project is to investigate various techniques to up-convert a baseband signal into radio frequency signals, and to investigate the practical problems encountered in an offset phase locked loop design by implementation. Phase locked loops are commonly used in radio transmitters and receivers to generate accurate RF signals from a low-frequency reference. This thesis will highlight some of the problems and strengths of various up-conversion schemes, and suggest an offset-PLL architecture free from many of those problems. An offset-PLL is often used in mobile communication systems where the required levels of out of band transmission are tough and the use of superheterodyne up-conversion cannot be used due to spectrum or bandwidth requirements. However a drawback of an offset-PLL is the high locking time; this can render the offset-PLL useless in TDMA communication systems. This problem among others has been studied theoretically as well as practically on an actual implementation of an offset-PLL for mobile communications. The offset-PLL was designed and manufactured as part of this project.

Electronics

Offset-PLL

low spurious

up-conversion

radio

transmitter

modulator

Elektronik

Electronics

Elektronik

Low Power Clock and Data Recovery Integrated Circuits

Ardalan, Shahab

22 October 2007

Advances in technology and the introduction of high speed processors have increased the demand for fast, compact and commercial methods for transferring large amounts of data. The next generation of the communication access network will use optical fiber as a media for data transmission to the subscriber. In optical data or chip-to-chip data communication, the continuous received data needs to be converted to discrete data. For the conversion, a synchronous clock and data are required. A clock and data recovery (CDR) circuit recovers the phase information from the data and generates the in-phase clock and data. In this dissertation, two clock and data recovery circuits for Giga-bits per second (Gbps) serial data communication are designed and fabricated in 180nm and 90nm CMOS technology. The primary objective was to reduce the circuit power dissipation for multi-channel data communication applications. The power saving is achieved using low swing voltage signaling scheme. Furthermore, a novel low input swing Alexander phase detector is introduced. The proposed phase detector reduces the power consumption at the transmitter and receiver blocks. The circuit demonstrates a low power dissipation of 340µW/Gbps in 90nm CMOS technology. The CDR is able to recover the input signal swing of 35mVp. The peak-to-peak jitter is 21ps and RMS jitter is 2.5ps. Total core area excluding pads is approximately 0.01mm2.

CDR

Low Power

CMOS

PLL

Clock and Data Recovery

Integrated Circuit

Electrical and Computer Engineering

A Radiation Tolerant Phase Locked Loop Design for Digital Electronics

Kumar, Rajesh

2010 August 1900

With decreasing feature sizes, lowered supply voltages and increasing operating frequencies, the radiation tolerance of digital circuits is becoming an increasingly important problem. Many radiation hardening techniques have been presented in the literature for combinational as well as sequential logic. However, the radiation tolerance of clock generation circuitry has received scant attention to date. Recently, it has been shown that in the deep submicron regime, the clock network contributes significantly to the chip level Soft Error Rate (SER). The on-chip Phase Locked Loop (PLL) is particularly vulnerable to radiation strikes. In this thesis, we present a radiation hardened PLL design. Each of the components of this design-the voltage controlled oscillator (VCO), the phase frequency detector (PFD) and the charge pump/loop filter-are designed in a radiation tolerant manner. Whenever possible, the circuit elements used in our PLL exploit the fact that if a gate is implemented using only PMOS (NMOS) transistors then a radiation particle strike can result only in a logic 0 to 1 (1 to 0) flip. By separating the PMOS and NMOS devices, and splitting the gate output into two signals, extreme high levels of radiation tolerance are obtained. Our design uses two VCOs (with cross-coupled inverters) and charge pumps, so that a strike on any one is compensated by the other. Our PLL is tested for radiation immunity for critical charge values up to 250fC. Our SPICE-based results demonstrate that after exhaustively striking all circuit nodes, the worst case jitter of our hardened PLL is just 37.4 percent. In the worst case, our PLL returns to the locked state in 2 cycles of the VCO clock, after a radiation strike. These numbers are significant improvements over those of the best previously reported approaches.

Radiation tolerant circuits

Heavy ions

split output gates

Hardened VCO

hardened charge pump

hardened PLL

A 2.5GHz Frequency Synthesizer for Mobile Device of WiMAX

Shih, Ming-hung

29 July 2009

This thesis presents a low power consumption, low phase noise, and fast locking CMOS fractional-N frequency synthesizer with optimalied voltage-controlled oscillator. The frequency synthesizer is designed in a TSMC 0.18£gm CMOS 1P6M technology process. It can be used for IEEE 802.16e mobile Wimax¡¦s devices and outputing frequency is ranged from 2.3GHz to 2.45GHz for the local oscillator in RF front-end circuits. The proposed frequency synthesizer consists of a phase-frequency detector (PFD), a charge pump (CP), a low-pass loop filter (LPF), a voltage-controlled oscillator (VCO), a multi-modulus divider, and a delta-sigma modulator (DSM). In system design, two voltage-controlled oscillators we presented to achieve low power consumption, low phase noise, and stable output swing. Delta-sigma modulator (DSM) is adopted to produce high frequency resolution, switching over frequency fast and very low phase noise. This thesis proposes a switch circuit which can reduce the lock of time of synthesizer. In the mean time it also reduces the emergence of lose lock.

Frequency synthesizer

PLL

Charge Pump

Phase Frequency Detector

VCO

divider

Delta-sigma modulator (DSM)

High performance pulse width modulated CMOS class D power amplifiers

Lu, Jingxue

04 March 2014

The objective of this research is to explore circuit techniques and architectures suitable for implementation in digital technologies, that can be used to enhance the efficiency of power stages. Specifically, the use of switching power stages with pulse-width modulation techniques is considered. Switching power stages, such as Class D amplifiers, are inherently well-suited for implementation in deep-submicron CMOS. Pulse-width modulation (PWM) employs discrete amplitude levels and encodes signal information in local time-based averages, and as such can also benefit from such technologies. Additionally PWM does not suffer from quantization noise, and is well-suited for low noise applications. PWM designs, that can be applied for a range of signal bandwidth requirements, spanning several tens to hundreds of kHz are proposed. Applications for these architectures include audio systems, powerline communications and wireless communications. Design challenges and requirements that can arise in different application contexts are considered in the specification of the architectures. A common goal in the definition of the architectures is to minimize complexity of the designs. In the first part of the dissertation, a third-order self-oscillating PWM class-D amplifier for audio applications, that utilizes a hysteretic comparator is described. The design is analyzed and its THD is theoretically determined by employing an equivalent model, that relates the approach to natural sampling pulse-width modulation. The architecture eliminates the requirement for a high-quality carrier generator. A low-cost hysteresis compensation technique is utilized to enhance distortion performance at high output power levels. An implementation is presented in a 0.7um CMOS process. The design achieves a dynamic range (DR) of 116.5 dB, and a THD+N of 0.0012%, while delivering a power of 125 mW into an 8[Omega] load at 1 kHz. The THD+N is under 0.006% up to 90% of the maximum output power. The amplifier can deliver 1.45 W into the load with a THD of 5% with a 5 V power supply. The efficiency is greater than 84% for output power larger than 1 W. The area of the amplifier is 6 mm². The achieved performance indicates that the design is well-suited for high-performance audio applications. A class D line driver that utilizes a phase-locked loop (PLL) based PWM generation technique is presented next. The principle of operation, and implementation details relating to loop stability, linearity and noise performance are analyzed. An implementation is presented in a 130nm CMOS process. The amplifier can deliver 1.2 W into an 6.8[Omega] load with a 4.8 V power supply. The architecture eliminates the requirement for a high-quality carrier generator and a fast, continuous voltage comparator that are often required in PWM implementations. The design can achieve a THD of -65 dB, with a switching frequency that can be as high as 20 MHz. The peak efficiency is 83% for output power larger than 1 W, for a switching frequency of 10 MHz. The area of the amplifier is 2.25 mm². This architecture is potentially suitable for powerline applications. Finally, a phase-locked loop based PWM Cartesian transmitter with the capability to drive switched power amplifiers, such as a Class D power amplifier, is proposed. A phase-locked loop based technique is employed to generate a high-frequency PWM pulse stream centered at 1.28 GHz. The prototype is simulated in a 130 nm CMOS process, and achieves 35% peak efficiency for 17 dBm output power with a carrier frequency of 900 MHz. Operation of the architecture with non-constant envelope modulation, such as that employed in the WCDMA standard, is verified in simulation. / text

PWM

Class D

Power amplifier

Pulse-width modulation

Hysteresis

Phase locked loop

Pll

Transmitter

Κυκλώματα υψηλών συχνοτήτων για σύστημα υπερ-ευρείας ζώνης με διαμόρφωση συχνότητας FM-UWB / High frequency circuits for a frequency modulation ultra wideband system FM-UWB

Τσίτουρας, Αθανάσιος

03 April 2015

Ο κύριος στόχος της διατριβής είναι η σχεδίαση των κύριων κυκλωμάτων ενός τηλεπικοινωνιακού συστήματος υπέρ–ευρείας ζώνης (UWB). Συγκεκριμένα, σχεδιάζονται σε τεχνολογία CMOS 90nm και αναπτύσσονται τα πλέον κρίσιμα κυκλώματα του PLL του FM-UWB πομπού με βάση ένα σύστημα FM-UWB, το οποίο στηρίζεται στη διπλή διαμόρφωση FM ευρείας ζώνης (double wideband FM modulation). Αυτά είναι το VCO, η αντλία φορτίου, ο διαιρέτης συχνότητας, και η γεννήτρια τάσης αναφοράς. Επιπλέον σχεδιάζονται ο δέκτης ο οποίος περιλαμβάνει τον προενισχυτή και τον αποδιαμορφωτή FM, δύο αρμονικοί ταλαντωτές ελεγχόμενοι από τάση για το υποσύστημα του πομπού σε τεχνολογία RF CMOS 65nm και ένας ταλαντωτής ελεγχόμενος από τάση τύπου δακτυλίου. Συνεπώς, στα πλαίσια της διατριβής αυτής σχεδιάζεται ολόκληρο το σύστημα πομπού και το σύστημα δέκτη (front-end) ώστε να αναδειχθούν οι δυνατότητες ολοκλήρωσης και τα πλεονεκτήματα της υλοποίησης ενός συστήματος FM-UWB σε πρόσφατες τεχνολογίες όπως η CMOS των 90nm και 65nm σε αντιδιαστολή με διπολικές τεχνολογίες. Με βάση τις λεπτομερείς προδιαγραφές που εξήχθησαν για τα υποσυστήματα και κυκλώματα του πομποδέκτη επιλέχτηκε η αρχιτεκτονική και σχεδιάστηκαν τα επιμέρους κυκλώματα στη ζώνη συχνοτήτων 3.1-5GHz. Για τη σχεδίαση χρησιμοποιήθηκαν το εργαλείο σχεδίασης «Cadence 5.1.41» και ο εξομοιωτής «Spectre». Για τη φυσική σχεδίαση έγινε χρήση του εργαλείων «Virtuoso XL» και «Assura». Ο πομπός αποτελείται από ένα γραμμικό VCO μεγάλου εύρους ζώνης (2.1GHz-5GHz) του οποίου η κεντρική συχνότητα ρυθμίζεται από ένα βρόχο κλειδωμένης φάσης (PLL) όταν δεν γίνεται μετάδοση δεδομένων. Στην ουσία πρόκειται για ένα PLL ο βρόχος του οποίου διακόπτεται όταν πραγματοποιείται εκπομπή πληροφορίας μέσω της διπλής διαμόρφωσης FM ενώ παραμένει κλειστός κατά τη ρύθμιση της κεντρικής συχνότητας του VCO (calibration). Το πιο κρίσιμο κύκλωμα του πομπού είναι το FM-UWB VCO. Για την ολοκλήρωση όμως του πομπού απαιτείται η σχεδίαση των υπόλοιπων κυκλωμάτων του βρόχου όπως είναι η αντλία φορτίου, ο διαιρέτης συχνότητας του βρόχου και ο ανιχνευτής φάσης-συχνότητας. Η τροφοδοσία του πομπού FM-UWB επιλέχτηκε να είναι ίση με 1V προκειμένου να ενισχυθεί η ανταγωνιστικότητα του με άλλα παρόμοια σύγχρονα συστήματα της βιβλιογραφίας. Με αρχικό στόχο την πόλωση των αναλογικών κυκλωμάτων του πομπού FM-UWB (αντλία φορτίου, διαιρέτης συχνότητας του PLL) αναπτύχθηκε μια γεννήτρια συνεχούς τάσης σε τροφοδοσία κάτω του 1V. Ο δέκτης αποτελείται από ένα συντονιζόμενο προενισχυτή και έναν αποδιαμορφωτή συχνότητας FM που σχεδιάζονται στη κεντρική συχνότητα των 4GHz με εύρος ζώνης μεγαλύτερου από 500MHz. Ο προτεινόμενος ταλαντωτής ελεγχόμενος από τάση (VCO), χαρακτηρίζεται από μεγάλο εύρος ζώνης συχνοτήτων ταλάντωσης, χαμηλή κατανάλωση και είναι κατάλληλος για iii εφαρμογές FM-UWB. Ο ταλαντωτής αυτός αποτελεί το βασικό δομικό στοιχείο ενός FM-UWB πομπού. Σχεδιάστηκε στην τεχνολογία υλοποίησης TSMC 90-nm digital CMOS, σε τάση τροφοδοσίας 1V και χαρακτηρίζεται από γραμμικό εύρος ζώνης συχνοτήτων ταλάντωσης μεταξύ 2.1GHz και 5GHz, διαφορική ισχύ εξόδου ίση με -7.83dBm  0.78dB και χαμηλή κατανάλωση ισχύος 8.26mW, συμπεριλαμβανομένης και της κατανάλωσης ισχύος των απομονωτών τάσης εξόδου (output buffers), στη μέγιστη συχνότητα ταλάντωσης. Επιπροσθέτως, έχει βελτιστοποιηθεί ως προς το λόγο εύρους ζώνης συχνοτήτων ταλάντωσης προς την κατανάλωση ισχύος TR/PDC. Η πρώτη βελτιστοποίηση έδωσε τιμή 9.95dB και η τελική έδωσε 11.97dB. Η επιθυμητή ζώνη συχνοτήτων ταλάντωσης μεταξύ 3.1GHz και 5GHz για εφαρμογές FM-UWB υπερκαλύπτεται για ολόκληρο το εύρος θερμοκρασιών που συναντάται στη βιομηχανία (από -40 oC έως 125 oC). Το εύρος συχνοτήτων ταλάντωσης βελτιώθηκε στο 130.15% (από 81.69%) και το FOM αυξήθηκε σε 143.08 (από 137.03). Επιπλέον, στη διατριβή αυτή παρουσιάζεται η σχεδίαση προγραμματιζόμενων, αντλιών φορτίου μεγάλης ακριβείας σε τάση τροφοδοσίας 1V. Τρείς συνολικά τοπολογίες μελετώνται με βασικό στόχο το καλύτερο δυνατό ταίριασμα των ρευμάτων εξόδου καθώς και τη μείωση των απότομων παρυφών ρεύματος στην έξοδο για μεγάλο εύρος τάσης εξόδου ώστε να επιτυγχάνεται αποδοτική χρήση της διαθέσιμης τάσης τροφοδοσίας (ΔVout/Vdd). Οι αντλίες φορτίου Ι, ΙΙ και ΙΙΙ χαρακτηρίζονται από μη ταίριασμα DC ρευμάτων εξόδου ίσο με 1%, 1.846% και 8% αντίστοιχα. Επιτυγχάνεται μεγαλύτερη μείωση των απότομων παρυφών ρεύματος στην έξοδο της αντλίας φορτίου ΙΙΙ σε σχέση με τις αντλίες φορτίου Ι και ΙΙ και μεγαλύτερη ταχύτητα λειτουργίας εις βάρος όμως της κατανάλωσης ισχύος. Ένα ολοκληρωμένο κύκλωμα γεννήτριας τάσης αναφοράς (Voltage reference) σχεδιάζεται επίσης, ώστε να χρησιμοποιηθεί ως κύκλωμα πόλωσης χαμηλής τροφοδοσίας κάτω του 1V ολοκληρωμένων κυκλωμάτων γενικού σκοπού. Η συνολική απόλυτη μεταβολή της τάσης αναφοράς εξόδου ως προς την μεταβολή των παραμέτρων της τεχνολογίας υλοποίησης και τις μεταβολές της τάσης τροφοδοσίας σε ευρεία κλίμακα θερμοκρασίας από -360C και 1250C ισούται με +/-3.3%. Η συνολική κατανάλωση ισχύος ισούται με 208uW. Παρουσιάζεται ακόμη η σχεδίαση ενός υποσυστήματος (front-end) δέκτη FM-UWB χαμηλού ρυθμού μετάδοσης δεδομένων (LDR, Low Data Rate), 50Kbps και μικρής εμβέλειας (<10m) με εύρος ζώνης μεγαλύτερο από 500MHz στην κεντρική συχνότητα των 4GHz. Δίνεται αναλυτικά η σχεδίαση της προτεινόμενης τοπολογίας για τον δέκτη FM-UWB στην τεχνολογία RF CMOS 65 nm ώστε να ικανοποιούνται οι προδιαγραφές του συστήματος που εξήχθησαν κατόπιν ανάλυσης. Τα αποτελέσματα του τελικού σχεδιασμού αποδεικνύουν ότι η συγκεκριμένη τεχνολογία, όταν συνδυάζεται με προσεκτικές επιλογές στη σχεδίαση μπορεί να πετύχει επιδόσεις συγκρίσιμες με τεχνολογίες SiGe BiCMOS που έχουν ενδογενή πλεονεκτήματα λόγω των ειδικών χαρακτηριστικών τους. iv Ο δέκτης FM-UWB αποτελείται από έναν προενισχυτή και ένα αποδιαμορφωτή συχνότητας FM-UWB. Η τεχνολογία υλοποίησης επιλέχτηκε να είναι η CMOS IBM των 65nm. Το συνολικό ρεύμα που απαιτείται για τη λειτουργία του πυρήνα του δέκτη FM-UWB είναι 8.093mA σε τροφοδοσία 1.8V και η ευαισθησία του δέκτη ισούται με -75.78dBm για λόγο σήματος προς θόρυβο SNRsub ίσο με 13.539dB. Συνεπώς, ικανοποιούνται πλήρως οι προδιαγραφές οι οποίες τέθηκαν ύστερα από τη μελέτη του τηλεπικοινωνιακού συστήματος FM-UWB. Η ευαισθησία του δέκτη αποδεικνύεται ότι μπορεί να αυξηθεί σε -82.95dBm για SNRsub ίσο με 13.539dB εάν προστεθεί ένα ακόμα στάδιο ενίσχυσης στο στάδιο καθυστέρησης του αποδιαμορφωτή FM-UWB με επιβάρυνση επιπλέον 8.033mW. Σχεδιάζεται επιπροσθέτως ένας αρμονικός ταλαντωτής για τον πομπό στα 65 nm ώστε να αναδειχθούν τα πιθανά οφέλη που μπορούν να προκύψουν όταν θυσιάζεται εύρος ζώνης και επιφάνεια ολοκλήρωσης εις όφελος της κατανάλωσης και των επιδόσεων του θορύβου φάσης. Για το συντονισμό αυτού του αρμονικού ταλαντωτή γίνεται χρήση μιας «hyperabrupt varactor» ώστε να επιτευχθεί εύρος ζώνης συχνοτήτων ταλάντωσης με καλή γραμμικότητα σε σύγκριση με αρμονικούς ταλαντωτές με απλή «varactor». Η συνολική κατανάλωση του πομπού FM-UWB ισούται με 5.11mW (συμπεριλαμβανομένης και της κατανάλωσης ισχύος του ενισχυτή εξόδου), ενώ το συνολικό γραμμικό εύρος ζώνης συχνοτήτων και το FOM του προτεινόμενου LC VCO ισούνται με 808ΜΗz και -173.679dB αντίστοιχα. Η ισχύς εξόδου του πομπού είναι μεγαλύτερη από -12dBm στη συχνότητα 4.14GHz και μεταβάλλεται λιγότερο από 0.5dB σε ολόκληρο το εύρος συχνοτήτων ταλάντωσης. Η καλή λειτουργία του εξασφαλίζεται στο εύρος θερμοκρασίας μεταξύ -40 0C και 1200C με θόρυβο φάσης στα 4.14GHz καλύτερο από -100dBc/Hz σε απόκλιση συχνότητας από τον φορέα 1ΜΗz. Στη συνέχεια, η ιδέα της επαναχρησιμοποίησης ρεύματος εφαρμόζεται στον παραπάνω αρμονικό ταλαντωτή-FM-UWB πομπό στα 65nm ούτως ώστε ο απομονωτής εξόδου να τοποθετείται πάνω από τον πυρήνα του LC VCO. Αυτό οδήγησε στη μείωση της αρχικής κατανάλωσης ισχύος (έως και 73.63%) ενώ διατηρήθηκαν τα παραπάνω χαρακτηριστικά του. Τέλος, σχεδιάστηκε ένα VCO τύπου δακτυλίου σε τροφοδοσία 1.8V, στα 65 nm. Καλύπτει τη ζώνη συχνοτήτων από 3.1GHz έως 5GHz με θόρυβο φάσης καλύτερο από -83dBc/Hz σε απόκλιση συχνότητας από τον φορέα ίση με 1MHz, με εύρος ζώνης διαμόρφωσης ίσο με 1MHz, παρέχοντας στην έξοδο του ισχύ μεγαλύτερη από -12dBm ενώ καταναλώνει 3.63mW. / The main purpose of this thesis is the design of the critical circuits of an Ultra Wideband (UWB) communication system. More specifically, circuits were designed for an FM-UWB system which relies on a double constant envelope FM modulation scheme. The most critical circuits of the transmitter PLL are designed in a 90nm CMOS process. These are the VCO, the loop divider, the charge pump and the voltage reference. In addition, the FM-UWB receiver front-end is designed in a 65nm RF CMOS process which includes an LNA/Preamplifier and a FM-UWB demodulator. Two harmonic LC-VCOs are also designed and one ring current-starved VCO to function as FM-UWB modulators in the transmitter path. Consequently, in this thesis the full transceiver front-end is designed in order to demonstrate the potential of its integration and the advantages of the implementation of an FM-UWB system in recent CMOS technologies such as those of 90nm and 65nm in comparison with bipolar implementations. Based on system study, the front-end circuits’ specifications were derived, the appropriate front-end architecture was selected and the front-end circuits were designed in the band of 3.1-5GHz. For the circuit design the tools of Cadence 5.1.41 and the Spectre RF Simulator were used. For the circuits layout designs the tools of Virtuoso XL and Assura were used. The transmitter consists of a linear VCO with wide tuning range (2.1GHz-5GHz) of which the central frequency is calibrated by a Phase Locked Loop when data transmission is ceased. The loop remains open when data transmission has to take place and stays closed when the VCO central frequency has to be calibrated. The most important block of the transmitter is the FM-UWB VCO. For the completion of the FM-UWB transmitter the design of other blocks such as the charge pump, the loop divider, the phase frequency detector and the voltage reference generator design is important as well. The supply voltage of 1V was selected for the FM-UWB transmitter in order to become competitive against other recent published implementations. Targeting at the biasing of the loop divider and the charge pump at the low supply voltage of 1V, a Sub-1V voltage reference generator was designed. The receiver consists of a wideband LNA/Preamplifier and a wideband FM demodulator with a center frequency at 4GHz and a useful bandwidth higher than 500MHz. Targeting at the implementation of wide frequency range (3.1-5GHz), the main purpose was the design of a linear, inductorless, low power (less than 10mW), low area, low supply voltage controlled oscillator with a phase noise better than -70dBc/Hz at 1MHz offset and small output power variation over the entire tuning range. The proposed FM-UWB VCO was designed in a 90-nm standard digital CMOS process at a supply voltage of 1V and a relatively linear tuning range is achieved between the frequencies of 2.1GHz and 5GHz, a differential vi output power of -7.83dBm 0.78dB and a low power consumption of 8.26mW when the output buffers power consumption is included at the maximum frequency of oscillation. The proposed FM-UWB VCO was optimized for the ratio of tuning range over the power consumption TR/PDC. The first optimization yields TR/PDC equal to 9.95dB and the final optimization yields TR/PDC equal to 11.974dB. The desired oscillation frequency band between 3.1GHz and 5GHz for FM-UWB applications is fully covered for the entire industrial temperature range of -40 0C to 125 0C. The tuning range of the improved VCO equals 130.15% (from 81.69%) whereas the improved VCO FOM was increased to 143.08 (from 137.03). Afterwards, programmable charge pumps with high accuracy were designed operating at the supply voltage of 1V. These charge pumps can be used in the PLL of the FM-UWB transmitter or in PLLs used for different telecommunication applications. Three in total charge pumps were designed aiming at a very good DC mismatch between the output source and sink currents, the reduction of the output source and sink current glitches for the maximum possible output voltage range. Charge pumps I, II and III achieve DC mismatch of 1%, 1.846% and 8% respectively. Charge pump III achieve lower output current glitches and higher speed of operation when compared to charge pumps I and II at the expense of higher power consumption. Furthermore, an integrated sub-1V voltage reference generator is presented. It is designed in standard 90-nm CMOS technology. The output reference voltage achieves a total absolute variation of ±3.3% over all process and supply voltage variations. The total power consumption equals 208μW. The proposed low data rate (50Kbps), short range (<10m), FM-UWB receiver front-end is designed in 65nm RF CMOS technology at a supply voltage of 1.8V with a useful bandwidth higher than 500MHz at the center frequency of 4GHz and the current reuse technique is applied aiming at the reduction of the overall power consumption around 14mW. It consists of a wideband preamplifier and a wideband FM demodulator. Final results show that CMOS technology at 65nm when it is combined with careful circuit design and specific circuit topologies can achieve comparable performance to SiGe BiCMOS technologies which have inherent advantages due to their special characteristics. The total bias current of the FM-UWB receiver core is only 8.093mA at a supply voltage of 1.8V and the receiver sensitivity equals -75.78dBm at a signal to noise ratio, SNRsub equal to 13.539dB. The receiver sensitivity can be improved to -82.95dBm at a signal to noise ratio, SNRsub equal to 13.539dB when an additional amplification stage is included in the delay element of the FM-UWB demodulator at the price of extra 8.033mW. Moreover, the design of an FM-UWB LC VCO in the 65nm RF CMOS technology is proposed as the main block of an FM-UWB transmitter. A hyperabrupt varactor is used in the vii tank of the proposed LC VCO in order to achieve linear tuning range. The total power consumption of the proposed LC FM-UWB VCO is 5.11mW including the power consumption of the output buffers, the total linear frequency range and the figure of merit, FOM equal 808MHz and -173.679dB respectively. The suggested LC VCO output power level is higher -12dBm at the frequency of 4.14GHz and varies less than 0.5dB in the entire frequency range of operation. The operation of the suggested VCO is ensured for the entire industrial temperature range between -40 0C and 120 0C with a phase noise performance better than -100dBc/Hz at the frequency offset of 1MHz at 4.14GHz. The above described performance of the proposed FM-UWB LC VCO is improved in terms of power consumption by applying the current reuse technique for the LC VCO core and the output buffer. By stacking the LC VCO core with the output buffer the power consumption can be reduced by 73.63% in comparison with the previously described LC VCO whereas the other VCO characteristics remain the same apart from the output power level which is reduced. Furthermore, a linear, inductorless VCO is proposed. This VCO is designed in 65nm RF CMOS technology and is based on the current starved topology. The suggested VCO tuning is achieved by modulating the current of the VCO core linearly by a voltage to current converter. This VCO is suitable for the FM-UWB application since it covers the frequency range between 3.1GHz to 5GHz and it achieves a phase noise performance of better than -83dBc/Hz at 1MHz offset. The VCO buffer delivers to a 50 Ohm load output power of better than -12dBm. The total VCO power consumption equals 3.63mW (including the output buffer) at a supply voltage of 1.8V and the VCO maximum modulation bandwidth equals 1MHz. Finally, it should be noted that the design of LC harmonic VCOs based on the use of hyperabrupt varactor and the linear current starved VCO design which took place in the last period of this thesis shows our effort to improve the performance of our previous work in the area of VCO circuit design by taking into account the latest published achievements of the literature. In conclusion, in this thesis all of the main VCO topologies were studied and designed for the needs of an FM-UWB transmitter front-end.

621.384 152

FM-UWB system

Phase lock loop (PLL)

Design Techniques for Timing Circuits in Wireline and Wireless Communication Systems

Huang, Deping

January 2014

Clock and data recovery (CDR) circuit and frequency synthesizer are two essential timing circuits in wireline and wireless communication systems, respectively. With multigigabits/s high speed links and emerging 4G wireless system widely used in communication backbone infrastructures and consumer electronic devices, effective design of CDR and frequency synthesizer has become more and more important. The advanced scaled-down CMOS process has the limitations of leakage current, low supply voltage and process variation which pose great challenge to the analog circuit design. To overcome these issues, a digital intensive CDR solution is needed. Besides, it is desirable for the CDR to cover a wide range of data-rate and to be reference-less for improved flexibility. As for the frequency synthesizer design, the support for multi-standard to reduce the cost and area is desirable. In this work, a digital reference-less CDR is proposed to support continuous datarate ranging from 1 Gbps to 16 Gbps. The CDR adopts an 8 GHz~16 GHz DCO to achieve low random noise performance. A reference-less digital frequency locking loop is included in the system as the acquisition assistance for the CDR loop. To address the difficulty of jitter and stability evaluations for bang-band CDR, a Simulink model is developed to find out the jitter transfer (JTRAN), jitter generation (JGEN) and jitter tolerance (JTOL) performances for the CDR. The prototype CDR is implemented in a 65 nm CMOS process. The core area is 0.68 mm². At 16 Gbps, the CDR consumes a power of 92.5 mW and is able to tolerate a sinusoidal jitter with an amplitude of 0.4 UI and a frequency of 4 MHz. The second part of this dissertation develops a frequency synthesizer for multistandard wireless receivers. The frequency synthesizer is based on an analog fractional-N PLL. Optimally-coupled quadrature voltage-controlled-oscillator (QVCO), dividers and harmonic rejection single sideband mixer (HR-SSBmixer) are combined to synthesize the desired frequency range without posing much phase noise penalty on the QVCO. The QVCO adopts a new phase-shift scheme to improve phase noise and to eliminate bimodal oscillation. Combining harmonic rejection and single sideband mixing, the HR-SSBmixer is developed to suppress spurious signals. Designed in a 0.13-μm CMOS technology, the synthesizer occupies an active area of 1.86 mm² and consumes 35.6 to 52.62 mW of power. Measurement results show that the synthesizer frequency range, the phase noise, the settling time and the spur performances meet the specifications of the wireless receivers for the above standards. For a wide range frequency synthesizer, an automatic frequency calibration circuit (AFC) is needed to select proper oscillator tuning curve before the PLL settling. An improved counter-based AFC is proposed in this dissertation that provides a more robust and faster tuning curve searching process. The proposed AFC adopts a time-to-digital converter (TDC), which is able to captures the fractional VCO cycle information within the counting window, to improve the AFC frequency detection accuracy. The TDC-based AFC is designed in a 0.13-μm CMOS technology. Simulation results show that the TDCbased AFC greatly improves the frequency detection accuracy and consequently for a given frequency detection resolution reduces the AFC calibration time.

clock and data recovery

frequency synthesizer

oscillator

PLL

Electrical & Computer Engineering

automatic frequency calibration

Frequency Synthesizers and Oscillator Architectures Based on Multi-Order Harmonic Generation

Abdul-Latif, Mohammed

2011 December 1900

Frequency synthesizers are essential components for modern wireless and wireline communication systems as they provide the local oscillator signal required to transmit and receive data at very high rates. They are also vital for computing devices and microcontrollers as they generate the clocks required to run all the digital circuitry responsible for the high speed computations. Data rates and clocking speeds are continuously increasing to accommodate for the ever growing demand on data and computational power. This places stringent requirements on the performance metrics of frequency synthesizers. They are required to run at higher speeds, cover a wide range of frequencies, provide a low jitter/phase noise output and consume minimum power and area. In this work, we present new techniques and architectures for implementing high speed frequency synthesizers which fulfill the aforementioned requirements. We propose a new architecture and design approach for the realization of wideband millimeter-wave frequency synthesizers. This architecture uses two-step multi-order harmonic generation of a low frequency phase-locked signal to generate wideband mm-wave frequencies. A prototype of the proposed system is designed and fabricated in 90nm Complementary Metal Oxide Semiconductor (CMOS) technology. Measurement results demonstrated that a very wide tuning range of 5 to 32 GHz can be achieved, which is costly to implement using conventional techniques. Moreover the power consumption per octave resembles that of state-of-the art reports. Next, we propose the N-Push cyclic coupled ring oscillator (CCRO) architecture to implement two high performance oscillators: (1) a wideband N-Push/M-Push CCRO operating from 3.16-12.8GHz implemented by two harmonic generation operations using the availability of different phases from the CCRO, and (2) a 13-25GHz millimeter-wave N-Push CCRO with a low phase noise performance of -118dBc/Hz at 10MHz. The proposed oscillators achieve low phase noise with higher FOM than state of the art work. Finally, we present some improvement techniques applied to the performance of phase locked loops (PLLs). We present an adaptive low pass filtering technique which can reduce the reference spur of integer-N charge-pump based PLLs by around 20dB while maintaining the settling time of the original PLL. Another PLL is presented, which features very low power consumption targeting the Medical Implantable Communication Standard. It operates at 402-405 MHz while consuming 600microW from a 1V supply.

millimeter-wave

oscillators

LC

ring oscillators

coupled oscillators

phase locked loops

PLL

MICS

wideband

low noise