A low Jitter Wide-range Delay-Locked Loop with the Rail to Rail Differential Multi Control Delay Line Implementation

Tsai, Yi-Sing

12 August 2010

A Rail to Rail Differential Control Delay Line using multi-band technology can provide wider range on a delay-locked loop (DLL) is proposed in this thesis. Delay-Locked Loops (DLLs) have been widely used for clock deskew instead of Phase-Locked Loop (PLLs) because of easy design and inherent stable. The main object of this thesis is the description and discussion in Delay-Locked Loop and Rail to Rail Differential Control Delay Line; uses TSMC 0.18£gm 1P6M CMOS process to design a 70 MHz¡ã750 MHz DLL and the supply voltage is 1.8V. This thesis is characterized by utilizing rail to rail input to reduce noise interference and enhance the signal integrity¡]low distortion, low noise, low power and high gain¡^.By the phase selection circuit is used to extend operation frequency. The operate frequency range of DLL is 70MHz to 750MHz, the power consumption of the Entire system is less than 32mW. The phase error is 10 ps at 70MHz and <10 ps at 750MHz in lock. The proposed DLL can provide wider range and lower jitter in this thesis.

CMOS

Delay-locked loop

Multiphase

Phase-locked loop

A CMOS Variable Gain Amplifier with DC/AC Switched Control and A Low Jitter 80 MHz PLL for DVB-T Receivers

Lin, Li-Pin

07 July 2005

The first topic of this thesis presents a novel VGA (variable gain amplifier) design which is applied in the AGC (automatic gain control) loop of digital video broadcasting - terrestrial (DVB-T) receivers. A total of three digital variable gain amplifiers (DVGA) are cascaded to provide a 70 dB dynamic range and 95 MHz operation frequency. The proposed digital VGA implemented by 0.35um 2P4M CMOS technology possesses 70 dB dynamic tuning range with a 0.3 dB gain error and 95 MHz bandwidth, and the power consumption is found to be 32.7 mW given a 3.3 V power supply. The second topic presents a design of a 60 ps peak-to-peak jitter, 80MHz, phase-locked loop (PLL) circuit for DVB-T receivers. The simulation results using the TSMC (Taiwan Semiconductor Manu-facturing Company) 0.35um 2P4M CMOS process show that the proposed PLL achieves as low as 60 ps peak-to-peak jitter when the output frequency is 80 MHz and the power consumption is merely 10.5 mW given a 3.3 V power supply.

Variable gain amplifier

Digital variable gain amplifier

Phase-locked loop

NTSC Digital Video Decoder and Digital Phase Locked Loop

Chang, Ming-Kai

12 August 2005

The first topic of the thesis presents an NTSC digital video decoder which is designed by using two lines delay comb filter to decode the luminance signal (Y) and the chrominance signal (C). The coefficients of the low pass filter are tuned properly to reduce the gate count without losing any original performance of the chroma demodulator. The second topic of the thesis is to propose a method and a circuitry to resolve the out-of-phase problem between the color burst and the sub-carrier in NTSC TV receivers. The feature of the method is that a delay means is inserted which leads to the synchronization of the color burst and the sub-carrier such that the following color demodulator is able to extract right color signals. Besides, the locking of the two signals will be fastened without any extra large circuit cost.

Video Decoder

Digital Phase Locked Loop

Comb Filter

Study of Noise Suppression and Circuit Design of a Dual Phase-Locked Loop System

Tsai, Wen-shiou

23 July 2009

This thesis is composed of three parts. In the first part, analysis and discussion of phase noise in phase-locked loop is made. Because OFDM upconverter requires high phase noise performance, we therefore study the mechanism of noise suppression in a proposed dual phase-locked loop, and then derive the formula to predict the circuit characteristics. In the second part, experiment and simulation of a dual phase-locked loop is performed for comparison. The experiment uses hybrid circuit combined with related equipment and components to measure the noise suppression characteristics in a dual phase-locked loop. The simulation relies on the component behavioral model in ADS. Comparison between simulation and measurement shows good agreement. In the third part, this thesis carries out a 1.55¡V2.3 GHz frequency synthesizer RFIC design for DVB up-down architecture using TSMC 0.18£gm CMOS process. The test results validate the chip design.

Dual Phase Locked Loop

Noise Suppression

Frequency Synthesizer

Phase-Locked Double-Loop Speed Regulation of a Temperature controlled Fan

Li, Chun-wei

24 August 2009

Cooling fans, widely used in desktop and laptop computers, have been designed toward the tendency of low noise and low consumption power. This thesis purposes a efficient low-noise double-loop control method to regulate the fan speed according to environmental temperature. The proposed controller consists of three parts. The first part is a command generator which generates a train of pulses with its frequency varying proportionally with temperature. The second part is a phase locked loop which intends to synchronize the command pulses with the pulses fed back from the Hall IC of the motor. The third part is an inner loop quantized control that switches the fan according to the error signal sent by the phase locked loop. This double-loop design of feedback achieves accurate fan speed regulation with the nice properties of low noise and high efficiency. The experimental results show an average regulation error of 0.4188% in the fan speed range of 306.6~1953 R.P.M which corresponds to the temperature range 10~70 Celsius.

Sliding Mode

Relay Control

BLDC

Phase-Locked Loop

Design of frequency synthesizers for short range wireless transceivers

Valero Lopez, Ari Yakov

30 September 2004

The rapid growth of the market for short-range wireless devices, with standards such as Bluetooth and Wireless LAN (IEEE 802.11) being the most important, has created a need for highly integrated transceivers that target drastic power and area reduction while providing a high level of integration. The radio section of the devices designed to establish communications using these standards is the limiting factor for the power reduction efforts. A key building block in a transceiver is the frequency synthesizer, since it operates at the highest frequency of the system and consumes a very large portion of the total power in the radio. This dissertation presents the basic theory and a design methodology of frequency synthesizers targeted for short-range wireless applications. Three different examples of synthesizers are presented. First a frequency synthesizer integrated in a Bluetooth receiver fabricated in 0.35μm CMOS technology. The receiver uses a low-IF architecture to downconvert the incoming Bluetooth signal to 2MHz. The second synthesizer is integrated within a dual-mode receiver capable of processing signals of the Bluetooth and Wireless LAN (IEEE 802.11b) standards. It is implemented in BiCMOS technology and operates the voltage controlled oscillator at twice the required frequency to generate quadrature signals through a divide-by-two circuit. A phase switching prescaler is featured in the synthesizer. A large capacitance is integrated on-chip using a capacitance multiplier circuit that provides a drastic area reduction while adding a negligible phase noise contribution. The third synthesizer is an extension of the second example. The operation range of the VCO is extended to cover a frequency band from 4.8GHz to 5.85GHz. By doing this, the synthesizer is capable of generating LO signals for Bluetooth and IEEE 802.11a, b and g standards. The quadrature output of the 5 - 6 GHz signal is generated through a first order RC - CR network with an automatic calibration loop. The loop uses a high frequency phase detector to measure the deviation from the 90° separation between the I and Q branches and implements an algorithm to minimize the phase errors between the I and Q branches and their differential counterparts.

Frequency Synthesizer

Wireless Communications

Phase-Locked Loop

Quadrature Calibration

Modelling and applications of MOS varactors for high-speed CMOS clock and data recovery

Sameni, Pedram

05 1900

The high-speed clock and data recovery (CDR) circuit is a key building block of modern communication systems with applications spanning a wide range from wireline long-haul networks to chip-to-chip and backplane communications. In this dissertation, our focus is on the modelling, design and analysis of devices and circuits used in this versatile system in CMOS technology. Of these blocks, we have identified the voltage-controlled oscillator (VCO) as an important circuit that contributes to the total noise performance of the CDR. Among different solutions known for this circuit, LC-VCO is acknowledged to have the best phase noise performance, due to the filtering characteristic of the LC tank circuit. We provide details on modelling and characterization of a special type of varactor, the accumulation-mode MOS varactor, used in the tank circuit as a tuning component of these types of VCOs. We propose a new sub-circuit model for this type of varactor, which can be easily migrated to other technologies as long as an accurate model exists for MOS transistors. The model is suitable whenever the numerical models have convergence problems and/or are not defined for the specific designs (e.g., minimum length structures). The model is verified directly using measurement in a standard CMOS 0.13µm process, and indirectly by comparing the tuning curves of an LC-VCO designed in CMOS 0.13µm and 0.18µm processes. Using a varactor, a circuit technique is proposed for designing a narrowband tuneable clock buffer, which can be used in a variety of applications including the CDR system. The buffer automatically adjusts its driving bandwidth to that of the VCO, using the same control voltage that controls the frequency of the VCO. In addition, a detailed analysis of the impact of large output signals on the tuning characteristics of the LC-VCO is performed. It is shown that the oscillation frequency of the VCO deviates from that of an LC tank.

Phase locked loop

Clock and data recovery

Modelling

Varactor

Modelling and applications of MOS varactors for high-speed CMOS clock and data recovery

Sameni, Pedram

05 1900

The high-speed clock and data recovery (CDR) circuit is a key building block of modern communication systems with applications spanning a wide range from wireline long-haul networks to chip-to-chip and backplane communications. In this dissertation, our focus is on the modelling, design and analysis of devices and circuits used in this versatile system in CMOS technology. Of these blocks, we have identified the voltage-controlled oscillator (VCO) as an important circuit that contributes to the total noise performance of the CDR. Among different solutions known for this circuit, LC-VCO is acknowledged to have the best phase noise performance, due to the filtering characteristic of the LC tank circuit. We provide details on modelling and characterization of a special type of varactor, the accumulation-mode MOS varactor, used in the tank circuit as a tuning component of these types of VCOs. We propose a new sub-circuit model for this type of varactor, which can be easily migrated to other technologies as long as an accurate model exists for MOS transistors. The model is suitable whenever the numerical models have convergence problems and/or are not defined for the specific designs (e.g., minimum length structures). The model is verified directly using measurement in a standard CMOS 0.13µm process, and indirectly by comparing the tuning curves of an LC-VCO designed in CMOS 0.13µm and 0.18µm processes. Using a varactor, a circuit technique is proposed for designing a narrowband tuneable clock buffer, which can be used in a variety of applications including the CDR system. The buffer automatically adjusts its driving bandwidth to that of the VCO, using the same control voltage that controls the frequency of the VCO. In addition, a detailed analysis of the impact of large output signals on the tuning characteristics of the LC-VCO is performed. It is shown that the oscillation frequency of the VCO deviates from that of an LC tank.

Phase locked loop

Clock and data recovery

Modelling

Varactor

Modelling and applications of MOS varactors for high-speed CMOS clock and data recovery

Sameni, Pedram

05 1900

The high-speed clock and data recovery (CDR) circuit is a key building block of modern communication systems with applications spanning a wide range from wireline long-haul networks to chip-to-chip and backplane communications. In this dissertation, our focus is on the modelling, design and analysis of devices and circuits used in this versatile system in CMOS technology. Of these blocks, we have identified the voltage-controlled oscillator (VCO) as an important circuit that contributes to the total noise performance of the CDR. Among different solutions known for this circuit, LC-VCO is acknowledged to have the best phase noise performance, due to the filtering characteristic of the LC tank circuit. We provide details on modelling and characterization of a special type of varactor, the accumulation-mode MOS varactor, used in the tank circuit as a tuning component of these types of VCOs. We propose a new sub-circuit model for this type of varactor, which can be easily migrated to other technologies as long as an accurate model exists for MOS transistors. The model is suitable whenever the numerical models have convergence problems and/or are not defined for the specific designs (e.g., minimum length structures). The model is verified directly using measurement in a standard CMOS 0.13µm process, and indirectly by comparing the tuning curves of an LC-VCO designed in CMOS 0.13µm and 0.18µm processes. Using a varactor, a circuit technique is proposed for designing a narrowband tuneable clock buffer, which can be used in a variety of applications including the CDR system. The buffer automatically adjusts its driving bandwidth to that of the VCO, using the same control voltage that controls the frequency of the VCO. In addition, a detailed analysis of the impact of large output signals on the tuning characteristics of the LC-VCO is performed. It is shown that the oscillation frequency of the VCO deviates from that of an LC tank. / Applied Science, Faculty of / Electrical and Computer Engineering, Department of / Graduate

Phase locked loop

Clock and data recovery

Modelling

Varactor

Principy generování RF signálů - laboratorní přípravek / Generation of RF signals - educational laboratory examples

Uhliar, Marek

January 2020

The work deals with design, simulation and preparation of laboratory preparation. The main aim of the thesis is to design and implement a simple noise generator, signal sources, mixer and phase lock loop for teaching purposes.